ABCC7 p.Lys464Ala

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PMID: 16442101 [PubMed] Frelet A et al: "Insight in eukaryotic ABC transporter function by mutation analysis."
No. Sentence Comment
98 Two mutations, K464A (NBD1) and K1250A (NBD2) reduced ATP binding and hydrolysis [60-64].
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ABCC7 p.Lys464Ala 16442101:98:15
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100 In contrast, K464A led singly to a reduced overall hydrolytic activity [61,62,65].
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ABCC7 p.Lys464Ala 16442101:100:13
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103 Indeed, K1250A dramatically prolonged burst duration, suggesting that hydrolysis at NBD2 might be coupled to burst termination [52,65,67], whereas K464A slowed channel opening to a burst, suggesting that NBD1 might be a site of ATP interactions governing opening [68].
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ABCC7 p.Lys464Ala 16442101:103:147
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PMID: 10398691 [PubMed] Csanady L et al: "CFTR channel gating: incremental progress in irreversible steps."
No. Sentence Comment
13 The CFTR mutants K464A and K1250A, for instance, lie at the heart of challenges to the simple answers to both key questions.
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ABCC7 p.Lys464Ala 10398691:13:17
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15 And recent direct measurements on purified, reconstituted CFTR have revealed virtual abolition of ATPase activity by K1250A, a more than sevenfold reduction of ATP hydrolysis (compared with WT) for K464A, but only an approximately twofold decrement in open probability (Po) for K1250A channels (because the effect of their markedly slower closing is more than offset by that of their slowed opening) and an even smaller drop in Po (due to slightly slower opening) for K464A relative to WT (Ramjeesingh et al., 1999), prompting the conclusion that ATP hydrolysis and channel gating are not tightly coupled.
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ABCC7 p.Lys464Ala 10398691:15:198
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ABCC7 p.Lys464Ala 10398691:15:468
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17 Although it is harder to reconcile the substantially reduced ATPase activity of K464A with its barely altered gating (Ramjeesingh et al., 1999), others have noted that K464A CFTR channels open two- (Gunderson and Kopito, 1995) or fivefold (Carson et al., 1995) more slowly than WT.
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ABCC7 p.Lys464Ala 10398691:17:80
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ABCC7 p.Lys464Ala 10398691:17:168
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PMID: 10398692 [PubMed] Weinreich F et al: "Dual effects of ADP and adenylylimidodiphosphate on CFTR channel kinetics show binding to two different nucleotide binding sites."
No. Sentence Comment
324 Their conclusions were derived from studying the gating (temperature not specified) and the ATPase activity (at 30ЊC) of purified CFTR protein, either WT or the mutants K464A or K1250A.
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ABCC7 p.Lys464Ala 10398692:324:175
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PMID: 10880569 [PubMed] Ikuma M et al: "Regulation of CFTR Cl- channel gating by ATP binding and hydrolysis."
No. Sentence Comment
36 In CFTR, the NBD1 mutation K464A reduces ATPase activity to Ϸ15%, and the NBD2 mutation K1250A eliminates ATPase activity (24).
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ABCC7 p.Lys464Ala 10880569:36:27
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136 We tested variants with mutations in the Walker A lysine, CFTR-K464A and -K1250A.
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ABCC7 p.Lys464Ala 10880569:136:63
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143 In contrast, with CFTR-K464A, the burst duration was the same with MgATP and ATP alone (Fig. 3 B and C).
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ABCC7 p.Lys464Ala 10880569:143:23
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144 There are two potential explanations for the difference between K464A and K1250A.
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ABCC7 p.Lys464Ala 10880569:144:64
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146 Alternatively, in K464A, most of the gating may be due to ATP interactions with NBD2.
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ABCC7 p.Lys464Ala 10880569:146:18
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155 Therefore, we studied CFTR-K1250A and CFTR-K464A at two different ATP concentrations.
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ABCC7 p.Lys464Ala 10880569:155:43
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161 Yet, prolonged burst durations have not been observed with K464A (10, 11, 14, 24).
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ABCC7 p.Lys464Ala 10880569:161:59
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164 However, if NBD1 has a higher ATP affinity than NBD2, this premise predicts that K464A would have long bursts at low MgATP concentrations.
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ABCC7 p.Lys464Ala 10880569:164:81
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166 With 1 mM ATP and 4 mM Mg2ϩ , CFTR-K464A showed durations approximately the same as observed with wild-type CFTR.
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ABCC7 p.Lys464Ala 10880569:166:41
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198 Our finding that the K464A mutation can generate bursts with a prolonged duration (Fig. 4) supports this conclusion.
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ABCC7 p.Lys464Ala 10880569:198:21
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203 Effect of MgATP and ATP alone on CFTR-K1250A and -K464A.
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ABCC7 p.Lys464Ala 10880569:203:50
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238 Effect of ATP concentration on gating of CFTR-K1250A (A and C) and K464A (B and D) channels.
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ABCC7 p.Lys464Ala 10880569:238:67
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PMID: 11279083 [PubMed] Aleksandrov L et al: "Differential interactions of nucleotides at the two nucleotide binding domains of the cystic fibrosis transmembrane conductance regulator."
No. Sentence Comment
23 EXPERIMENTAL PROCEDURES Materials- BHK-21 cells stably expressing wild-type human CFTR were prepared and maintained as described previously (20) as were cells expressing the K464A and K1250A mutants.
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ABCC7 p.Lys464Ala 11279083:23:174
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63 A, membranes from BHK cells expressing wild-type and the K1250A (15 ␮g of protein) and K464A variants (60 ␮g of protein) were incubated with 20 ␮M 8-azido-[␣-32 P]ATP in the presence of 0.5 mM orthovanadate and processed as under "Experimental Procedures."
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ABCC7 p.Lys464Ala 11279083:63:94
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65 Note that 4 times more K464A membrane protein was used than wild type and K1250.
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ABCC7 p.Lys464Ala 11279083:65:23
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66 The cells expressing K464A had also been grown at 26 °C to promote maturation of the mutant CFTR. B, 15 ␮g of BHK membrane protein containing wild-type CFTR was incubated at 0 °C for 1 h with 50 ␮g/ml purified immunoglobulin from each of the mouse monoclonal antibodies.
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ABCC7 p.Lys464Ala 11279083:66:21
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70 In contrast the comparable substitution in NBD1 (K464A) greatly diminished labeling compared with wild type indicating that the majority of labeling and trapping may occur at NBD1.
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ABCC7 p.Lys464Ala 11279083:70:49
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PMID: 11341822 [PubMed] Zou X et al: "ATP hydrolysis-coupled gating of CFTR chloride channels: structure and function."
No. Sentence Comment
158 Although earlier studies showed that converting lysine 464 to alanine (K464A) slowed opening (31, 32), a more recent report found that single-channel gating kinetics of the K464A mutant was almost indistinguishable from that of the wild-type CFTR (46-48).
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ABCC7 p.Lys464Ala 11341822:158:48
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ABCC7 p.Lys464Ala 11341822:158:71
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ABCC7 p.Lys464Ala 11341822:158:173
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159 The apparent affinity for ATP is little changed for the K464A channel (48).
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ABCC7 p.Lys464Ala 11341822:159:56
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160 Nevertheless, the ATP hydrolysis rate of the K464A mutant is decreased (46).
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ABCC7 p.Lys464Ala 11341822:160:45
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236 Their model is based mainly on the studies of the K464A and K1250A mutants, assuming mutations of the Walker A lysines diminish the level of ATP hydrolysis at respective NBDs.
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ABCC7 p.Lys464Ala 11341822:236:50
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240 This model explains the results showing that the K464A mutant shows a longer open time at micromolar ATP concentrations than that at millimolar ATP concentrations, whereas the K1250A mutant shows an opposite pattern of gating in response to changes in the ATP concentration (cf. ref 38).
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ABCC7 p.Lys464Ala 11341822:240:49
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242 For example, on the basis of the assumption of two open states in the NBD1 cycle, it is desirable to observe two distinct populations of open time for the K464A mutant especially at millimolar ATP concentrations.
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ABCC7 p.Lys464Ala 11341822:242:155
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248 To explain this result for the K464A mutant, one needs to speculate that hydrolysis of one ATP molecule may trigger several open-close events.
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ABCC7 p.Lys464Ala 11341822:248:31
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PMID: 11788611 [PubMed] Berger AL et al: "Mutations that change the position of the putative gamma-phosphate linker in the nucleotide binding domains of CFTR alter channel gating."
No. Sentence Comment
22 However, the effects of mutations in the two NBDs are not symmetrical; the K1250A mutation dramatically prolongs the burst duration, whereas the K464A mutation reduces the frequency of channel opening but does not change burst duration.
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ABCC7 p.Lys464Ala 11788611:22:145
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PMID: 11861646 [PubMed] Aleksandrov L et al: "The First Nucleotide Binding Domain of Cystic Fibrosis Transmembrane Conductance Regulator Is a Site of Stable Nucleotide Interaction, whereas the Second Is a Site of Rapid Turnover."
No. Sentence Comment
28 To distinguish between these possibilities, the Walker A lysine mutants K464A and K1250A were used; K464A ablated labeling of NBD1 without influencing that at NBD2, and hence the N3ADP that labeled * This work was supported by Grant DK51619 from the NIDDK, National Institutes of Health and by the Cystic Fibrosis Foundation.
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ABCC7 p.Lys464Ala 11861646:28:72
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ABCC7 p.Lys464Ala 11861646:28:100
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43 Stable BHK-21 cell lines expressing wild-type and K464A and K1250A variants of CFTR were established and cultured as described previously (16, 17).
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ABCC7 p.Lys464Ala 11861646:43:50
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130 As expected, the mutations K464A and K1250A prevented photolabeling with either 8-azido-ATP or 8-azido-ADP of NBD1 and NBD2, respectively.
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ABCC7 p.Lys464Ala 11861646:130:27
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131 However, there was no indication that the mutation in one domain had any influence on the labeling of the other, i.e. in K464A, NBD2 was labeled as in wild-type and in K1250A, NBD1 was not different from wild type.
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ABCC7 p.Lys464Ala 11861646:131:121
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141 Hence, as with a mutation (K464A) that prevents labeling of NBD1 by N3ATP, occupation of the domain by AMP-PNP leaves the labeling of NBD2 with [␣-32 P]N3ATP entirely intact.
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ABCC7 p.Lys464Ala 11861646:141:27
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191 Membranes from BHK cells expressing wild-type and K464A and K1250A variants of CFTR were incubated as in Figs.
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ABCC7 p.Lys464Ala 11861646:191:50
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193 The mobility of the large 95-kDa, NBD2 band is increased in the K464A variant, which does not mature and completely acquire the complex oligosaccharide chains, which contribute to the apparent size of the wild-type band.
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ABCC7 p.Lys464Ala 11861646:193:64
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PMID: 11882668 [PubMed] Powe AC Jr et al: "Mutation of Walker-A lysine 464 in cystic fibrosis transmembrane conductance regulator reveals functional interaction between its nucleotide-binding domains."
No. Sentence Comment
12 To address this issue, we examined channels with a Walker-A lysine mutation in NBD1 (K464A) using the patch clamp technique.
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ABCC7 p.Lys464Ala 11882668:12:85
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13 K464A mutants have an ATP dependence (EC50 ∆ 60 m) and opening rate at 2.75 m ATP (~2.1 s_1 ) similar to wild type (EC50 ∆ 97 m; ~2.0 s_1 ).
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ABCC7 p.Lys464Ala 11882668:13:0
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15 Delay of closing in wild type by adenylyl imidodiphosphate (AMP-PNP), a non-hydrolysable ATP analogue, is markedly diminished in K464A mutants due to reduction in AMP-PNP`s apparent on-rate and acceleration of its apparent off-rate (~2and ~10-fold, respectively).
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ABCC7 p.Lys464Ala 11882668:15:129
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17 In sharp contrast to K464A, K1250A single mutants exhibit reduced opening (~0.055 s_1 ) and closing (~0.006 s_1 ) rates at millimolar [ATP], suggesting a role for K1250 in both opening and closing.
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ABCC7 p.Lys464Ala 11882668:17:21
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18 At millimolar [ATP], K464A-K1250A double mutants close ~5-fold faster (~0.029s_1 )thanK1250Abutopenwithasimilarrate(~0.059s_1 ),indicatinganeffectofK464Aon NBD2 function.
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ABCC7 p.Lys464Ala 11882668:18:21
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24 Supporting this idea, some investigators reported that a mutation in NBD1`s Walker-A motif (i.e. K464A) reduces CFTR`s opening rate (Carson et al. 1995; Gunderson & Kopito, 1995; Vergani et al. 2000).
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ABCC7 p.Lys464Ala 11882668:24:97
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25 However, those earlier reports are being challenged by more recent demonstrations that K464A has little effect on channel opening (Sugita et al. 1998; Ramjeesingh et al. 1999; present study).
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ABCC7 p.Lys464Ala 11882668:25:87
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29 To examine the contribution of NBD1 during CFTR gating, we assessed the kinetic properties of the Walker-A mutant K464A.
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ABCC7 p.Lys464Ala 11882668:29:114
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31 The plasmids K464A-pRBG4 and K1250A-pRBG4 were gifts from Dr R. R. Kopito (Stanford University, CA, USA), and the plasmid CFTRwt-pBQ4.7 and the retroviral vector pLJ were gifts from Dr M. Drumm (Case Western Reserve University, Cleveland, OH, USA).
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ABCC7 p.Lys464Ala 11882668:31:13
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32 To construct K464A-pBQ and K1250A-pBQ, the 0.7 kb BspEI-BstZ171 fragment from K464A-pRBG4 and the 3.0 kb BspEI-NcoI fragment from K1250A-pRBG4, respectively, replaced the corresponding ones in CFTRwt-pBQ4.7.
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ABCC7 p.Lys464Ala 11882668:32:13
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ABCC7 p.Lys464Ala 11882668:32:78
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34 For construction of K464A-pLJ, the 3.6 kb BspEI-SalI fragment from K464A-pBQ was exchanged with the corresponding one in WT-pLJ.
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ABCC7 p.Lys464Ala 11882668:34:20
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ABCC7 p.Lys464Ala 11882668:34:67
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35 To generate WT-pCDNA, K464A-pCDNA and K1250A-pCDNA,the4.7 kbPstIfragmentsfromthecorresponding pBQ constructs were subcloned into the PstI site of pCDNA.
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ABCC7 p.Lys464Ala 11882668:35:22
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36 For the creation of K464A-K1250A-pCDNA, the 2.7 kb BspEI-PflMI fragment from K464A-pCDNA was used to substitute the corresponding region in K1250A-pCDNA.
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ABCC7 p.Lys464Ala 11882668:36:20
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ABCC7 p.Lys464Ala 11882668:36:77
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40 To obtain recordings with few channels per patch, we used NIH3T3 cells stably transfected with wild type CFTR (Berger et al. 1991), CFTR-K1250A and CFTR-K464A (Zeltwanger et al. 1999; present study).
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ABCC7 p.Lys464Ala 11882668:40:153
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54 Macroscopicdose-responseanalysisofK464Achannels To quantify the ATP dependence of K464A channels, we normalized baseline-subtracted mean current levels elicited by test [ATP] against mean current levels at 2.75 m ATP as previously described (Zeltwanger et al. 1999; see Fig. 1).
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ABCC7 p.Lys464Ala 11882668:54:82
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60 An analysis of flickery events in K464A channels using 100 Hz filtering and 500 Hz sampling justified the 50 ms cut-off (data not shown).
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ABCC7 p.Lys464Ala 11882668:60:34
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68 However, since the solution exchange in our system is relatively slow (~5 s; cf. Zeltwanger et al. 1999), relaxation times for K464A, but not wild type, are probably rate limited more by nucleotide removal rather than actual channel closing (see Results).
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ABCC7 p.Lys464Ala 11882668:68:127
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69 To estimate more accurately the AMP-PNP-dependent open time for K464A channels, we analysed recordings with only one or two channels; open events where two channels were open simultaneously were averaged and included as described previously (Fenwicketal.1982;Wangetal.1998).Dwelltimeswererankedin order of decreasing duration, normalized by the number of events and displayed as survivor plots (i.e. the probability of still being open at time t given that the channel was open at time zero versus time).
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ABCC7 p.Lys464Ala 11882668:69:64
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72 Based on our open time analysis of K464A channels in the presence of 250 µ ATP and 1 m AMP-PNP (see above), we used a cut-off of 842 ms for both wild type and K464A channels.
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ABCC7 p.Lys464Ala 11882668:72:35
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ABCC7 p.Lys464Ala 11882668:72:180
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73 Use of this cut-off for both types of channels is justifiable, since both K464A and wild type have similar open times (i.e. dwell times in O) at 250 µ ATP alone.
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ABCC7 p.Lys464Ala 11882668:73:74
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75 EstimationofkineticparametersforK1250Aand K464A-K1250A For recordings of quasi-macroscopic K1250A and K464A-K1250A channel currents, open probability was estimated by means of variance analysis (Sigworth, 1980): Po = (1 _ (s2 /Ii)), where Po represents open probability, s2 the variance of steady-state current, I the mean steady-state current and i the single channel amplitude.
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ABCC7 p.Lys464Ala 11882668:75:42
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ABCC7 p.Lys464Ala 11882668:75:102
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80 RESULTS As a step towards understanding how CFTR`s NBDs participate in gating, we examined the kinetic behaviour of the NBD1 mutant K464A, the NBD2 mutant K1250A and double mutant K464A-K1250A.
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ABCC7 p.Lys464Ala 11882668:80:132
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ABCC7 p.Lys464Ala 11882668:80:180
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81 K464A mutants were examined first.
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ABCC7 p.Lys464Ala 11882668:81:0
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82 To determine whether K464A affected CFTR`s ATP dependence, we performed a dose-response analysis.
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ABCC7 p.Lys464Ala 11882668:82:21
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83 Some earlier reports indicated that K464A reduced ATP affinity (Anderson & Welsh, 1992; Vergani et al. 2000).
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ABCC7 p.Lys464Ala 11882668:83:36
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89 From the fit, the Km for K464A channels was 59 ± 9 µ.
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ABCC7 p.Lys464Ala 11882668:89:25
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91 This comparison indicates that the K464A mutation had little effect on ATP sensitivity.
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ABCC7 p.Lys464Ala 11882668:91:35
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92 To estimate the ATP dependence of open probability in K464A mutants, the Po was measured in patches with one to four channels.
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ABCC7 p.Lys464Ala 11882668:92:54
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97 The fit results closely matched the measured data; the measured mean Po for K464A channels was 0.37 ± 0.02 (n = 18) at 2.75 m ATP, 0.21 ± 0.05 (n = 5) at 100 µ ATP, and 0.19 ± 0.02 (n = 3) at 50 µ ATP, indicating that the EC50 for ATP lies between 50 and 100 µ.
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ABCC7 p.Lys464Ala 11882668:97:76
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100 Furthermore, a comparison of K464A to wild type (Zeltwanger et al. 1999; present study, Fig. 1B) shows little change in ATP sensitivity of Po.
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ABCC7 p.Lys464Ala 11882668:100:29
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101 A Michaelis-Menten fit to our previous wild type data gave a Km of 137 µ with a maximum Po of 0.41, slightly higher than K464A.
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ABCC7 p.Lys464Ala 11882668:101:134
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102 We next tested how [ATP] affected channel opening and closing rates in K464A mutants.
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ABCC7 p.Lys464Ala 11882668:102:71
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105 ATP dose-response relationships for CFTR-K464A A, representative trace of macroscopic CFTR-K464A channel current stimulated by 2.75 m and 25 µ ATP after steady-state activation by PKA phosphorylation (not shown).
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ABCC7 p.Lys464Ala 11882668:105:41
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ABCC7 p.Lys464Ala 11882668:105:91
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106 B, trace of CFTR-K464A channels exposed to different [ATP] after steady-state activation by PKA and ATP.
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ABCC7 p.Lys464Ala 11882668:106:17
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107 C, macroscopic dose-response relationship for CFTR-K464A (•; present study) and wild type CFTR (ª; data taken from Zeltwanger et al. 1999).
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ABCC7 p.Lys464Ala 11882668:107:51
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108 D, open probability versus [ATP] for CFTR-K464A (0; present study) and wild type (1; data taken from Zeltwanger et al. 1999).
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ABCC7 p.Lys464Ala 11882668:108:42
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109 The maximum Po for CFTR-K464A at 2.75 m ATP is ~0.37.
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ABCC7 p.Lys464Ala 11882668:109:24
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112 Dashed lines are fits of the Michaelis-Menten equation to the CFTR-K464A data (see Methods).
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ABCC7 p.Lys464Ala 11882668:112:67
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113 shows sweeps from a recording of a single CFTR-K464A channel exposed to 2.75 m and 100 µ ATP.
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ABCC7 p.Lys464Ala 11882668:113:47
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115 In 100 µ ATP the K464A channel exhibits longer closures, while the duration of openings at both concentrations appears similar.
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ABCC7 p.Lys464Ala 11882668:115:30
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116 Figure 2B shows the closed and open time distributions from the K464A recordings in Fig. 2A.
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ABCC7 p.Lys464Ala 11882668:116:64
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121 The relationship between rates and [ATP] for K464A mutants is shown in Fig. 3A; the data shown represent the mean rates pooled from 18 experiments.
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ABCC7 p.Lys464Ala 11882668:121:45
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124 To quantify the ATP sensitivity of opening in K464A mutants, the data were fitted to a Michaelis-Menten equation (Fig. 3A).
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ABCC7 p.Lys464Ala 11882668:124:46
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127 Our findings confirm that ATP-dependent opening is not impaired by the K464A mutation, qualitatively consistent with the data of Sugita et al. (1998) and Ramjeesingh et al. (1999).
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ABCC7 p.Lys464Ala 11882668:127:71
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128 Unlike opening, K464A channel closing exhibits little, if any, dependence on ATP.
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ABCC7 p.Lys464Ala 11882668:128:16
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131 Single-channel kinetics of CFTR-K464A A, representative sweeps from experiments with single CFTR-wild type (left-hand sweeps; taken from Zeltwanger et al. 1999) and CFTR-K464A channels (right-hand sweeps) exposed to 2.75 m (top sweeps) and 100 µ MgATP (bottom sweeps) subsequent to activation by PKA (40 U ml_1 ) and ATP (2.75 m).
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ABCC7 p.Lys464Ala 11882668:131:32
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ABCC7 p.Lys464Ala 11882668:131:170
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133 B, survivor plots of closed (left-hand panels) and open dwell times (right-hand panels) at 2.75 m (top panels) and 100 µ MgATP (bottom panels) for the single CFTR-K464A channel shown in A (cf. wild type distributions in Zeltwanger et al. 1999).
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ABCC7 p.Lys464Ala 11882668:133:184
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135 hand, a comparison of closing rates for K464A and wild type at 2.75 m ATP does reveal a difference (3.6 ± 0.3 s_1 , n = 18 versus 2.1 ± 0.3 s_1 , n = 6, respectively; P < 0.005; Fig. 3B).
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ABCC7 p.Lys464Ala 11882668:135:40
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136 Thus, K464A appears to abolish the ATP dependence of the closing rate seen in wild type.
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ABCC7 p.Lys464Ala 11882668:136:6
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137 From this result, we suspected that K464A might affect the second functional site for ATP, which is presumed responsible for prolonging open time in wild type channels at millimolar [ATP] (Zeltwanger et al. 1999).
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ABCC7 p.Lys464Ala 11882668:137:36
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138 Since this second functional site for ATP is thought to be the site for AMP-PNP action (Hwang et al. 1994; Carson et al. 1995; Mathews et al. 1998b; Zeltwanger et al. 1999), we examined whether K464A affected AMP-PNP`s prolongation of channel opening.
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ABCC7 p.Lys464Ala 11882668:138:194
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144 Prolonged openings can also be seen in K464A channels exposed to AMP-PNP, but with lower frequency and shorter duration.
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ABCC7 p.Lys464Ala 11882668:144:39
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145 For example, Fig. 4A (lower trace) shows a single K464A channel activated by PKA (40 U ml_1 ) and ATP (250 µ), then exposed to AMP-PNP (1 m).
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ABCC7 p.Lys464Ala 11882668:145:50
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146 Unlike the wild type example, the K464A channel took much longer to become locked open.
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ABCC7 p.Lys464Ala 11882668:146:34
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148 These two examples suggest that the K464A mutation A. C. Powe, Jr, L. Al-Nakkash, M. Li and T.-C. Hwang338 J. Physiol. 539.2 Figure 3.
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ABCC7 p.Lys464Ala 11882668:148:36
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149 Dependence of CFTR-K464A closing and opening rates on [ATP] A, plot of mean opening rates (reciprocals of mean closed times; 0) and closing rates (reciprocals of mean opened times; ª) versus [ATP] for CFTR-K464A.
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ABCC7 p.Lys464Ala 11882668:149:19
status: NEW
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ABCC7 p.Lys464Ala 11882668:149:211
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151 B, comparison of opening and closing rates for CFTR-K464A and wild type at 2.75 m ATP.
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ABCC7 p.Lys464Ala 11882668:151:52
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152 Asterisks indicate a significant difference between closing rates for wild type and K464A (P < 0.005).
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ABCC7 p.Lys464Ala 11882668:152:84
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154 AMP-PNP weakly locks open CFTR-K464A A, representative sweeps from experiments with wild type (top trace) and CFTR-K464A single channels (bottom trace) exposed first to PKA (40 U ml_1 ) and MgATP (250 µ), then with the addition of AMP-PNP (1 m).
X
ABCC7 p.Lys464Ala 11882668:154:31
status: NEW
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ABCC7 p.Lys464Ala 11882668:154:115
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155 Arrows indicate the baseline, downward deflections channel openings. B, survivor plot of open dwell times for CFTR-K464A.
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ABCC7 p.Lys464Ala 11882668:155:115
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158 reduces the ability to become locked open and to stay locked open by AMP-PNP, further substantiating the idea that K464A affects the second functional site for ATP.
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ABCC7 p.Lys464Ala 11882668:158:115
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160 The opening of K464A channels is slowed by AMP-PNP as well.
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ABCC7 p.Lys464Ala 11882668:160:15
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161 The mean closed time for K464A channels exposed to 250 µ ATP and 1 m AMP-PNP was 1366 ± 260 ms (n = 6), approximately threefold longer than in 250 µ ATP alone (~465 ms; Fig. 3A).
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ABCC7 p.Lys464Ala 11882668:161:25
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163 To quantify the extent to which K464A affects the second functional site, we first estimated the duration of AMP-PNP-dependent locked open events using current relaxation time courses upon removal of AMP-PNP.
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ABCC7 p.Lys464Ala 11882668:163:32
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165 Figure 5A shows a comparison of relaxations from wild type (top trace) and K464A channels (bottom trace).
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ABCC7 p.Lys464Ala 11882668:165:75
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167 Wild type channels close slowly, while K464A channels rapidly shut, indicating a shortened locked open duration in the mutant. On average, wild type channels show a mean relaxation time constant of 105 ± 22 s (n = 5) and K464A channels 12 ± 3 s (n = 5; P < 0.01) (Fig. 5B).
X
ABCC7 p.Lys464Ala 11882668:167:39
status: NEW
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ABCC7 p.Lys464Ala 11882668:167:226
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168 However, given that the solution exchange in our system is relatively slow (~5 s; cf. Zeltwanger et al. 1999), relaxation times for K464A are probably rate limited more by nucleotide removal than actual channel closing.
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ABCC7 p.Lys464Ala 11882668:168:132
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170 To obtain a more accurate estimate for locked open event duration in K464A channels, we analysed the open time distribution from patches with one or two channels in the presence of PKA, ATP and AMP-PNP (Fig. 4B; see Methods).
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ABCC7 p.Lys464Ala 11882668:170:69
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172 One component was ~300 ms, consistent with the mean open time for K464A channels in 250 µ ATP alone (Fig. 4B; cf. Fig. 3).
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ABCC7 p.Lys464Ala 11882668:172:66
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178 In addition to reducing the time spent locked open, the K464A mutation also impairs the ability to become locked open, as exemplified by Fig. 4A.
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ABCC7 p.Lys464Ala 11882668:178:56
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179 In that example, the K464A channel opens and shuts many times before being locked open, while wild type opens and shuts only a few times before locking open.
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ABCC7 p.Lys464Ala 11882668:179:21
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181 K464A enhances the dissociation of AMP-PNP A, representative traces from experiments with macroscopic currents from CFTR-wild type (top trace) and CFTR-K464A channels (bottom trace) exposed to PKA (40 U ml_1 ), MgATP (250 µ) and AMP-PNP (1 m).
X
ABCC7 p.Lys464Ala 11882668:181:0
status: NEW
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ABCC7 p.Lys464Ala 11882668:181:152
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183 For the traces shown, the mean relaxation time constant for wild type is 64.8 ± 0.1 s and for CFTR-K464A is 9.1 ± 0.1 s. B, mean relaxation time constants (± ...)
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ABCC7 p.Lys464Ala 11882668:183:104
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184 for wild type and K464A channels.
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ABCC7 p.Lys464Ala 11882668:184:18
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185 Asterisks indicate a significant difference between wild type and K464A (P < 0.01).
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ABCC7 p.Lys464Ala 11882668:185:66
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190 Using the open duration data from K464A channels exposed to AMP-PNP (Fig. 4B), we calculated a cut-off of 842 ms; openings longer than 842 ms were L state and shorter ones O.
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ABCC7 p.Lys464Ala 11882668:190:34
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191 This cut-off was used to classify open events for both wild type and K464A channels.
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ABCC7 p.Lys464Ala 11882668:191:69
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193 Figure 6A shows the distributions obtained from two experiments, one with wild type channels and the other with K464A.
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ABCC7 p.Lys464Ala 11882668:193:112
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194 In the experiments shown, the locking rate for wild type (ª) was 1110 ± 70 s_1 _1 (21 events) and for K464A (1) 370 ± 10 s_1 _1 (49 events), qualitatively consistent with the examples in Fig. 4A.
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ABCC7 p.Lys464Ala 11882668:194:120
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195 On average, wild type channels exhibited a faster locking rate (890 ± 140 s_1 _1 , n = 3) than K464A (560 ± 110 s_1 _1 , n = 6; P < 0.05; Fig. 6B), indicating that the mutation impairs AMP-PNP`s ability to lock open CFTR.
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ABCC7 p.Lys464Ala 11882668:195:108
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198 We wondered whether K464A reduces channel open time in K1250A mutants as it does with AMP-PNP.
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ABCC7 p.Lys464Ala 11882668:198:20
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199 To test this idea, we determined the mean open time for both K1250A single mutant and K464A-K1250A double mutant channels using relaxation time courses upon ATP withdrawal (Fig. 7A).
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ABCC7 p.Lys464Ala 11882668:199:86
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200 In the examples shown, the double mutant relaxes more rapidly than the single mutant. On average, K464A-K1250A channel currents decay fivefold morequicklythanK1250A(34 ± 7 s,n = 5versus167 ± 37 s, n = 6, respectively; Fig. 7C; cf. Zeltwanger et al.1999).
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ABCC7 p.Lys464Ala 11882668:200:98
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202 We also examined the open probability of K1250A and K464A-K1250A.
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ABCC7 p.Lys464Ala 11882668:202:52
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204 K464A reduces the apparent on-rate of AMP-PNP A, Semilog plot of a probability function determined by measuring the cumulative time channels spent in the O state before entering the L state (see Methods).
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ABCC7 p.Lys464Ala 11882668:204:0
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205 The dwell times are from individual experiments for CFTR-K464A (1) and CFTR-wild type (ª).
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ABCC7 p.Lys464Ala 11882668:205:57
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207 B, comparison of the mean locking rates for CFTR-wild type and CFTR-K464A.
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ABCC7 p.Lys464Ala 11882668:207:68
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208 Asterisk indicates a significant difference between wild type and K464A (P < 0.05).
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ABCC7 p.Lys464Ala 11882668:208:66
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210 In this example, all four K1250A channels remain open for most of the sweep, whereas only two of the three double mutants channels are open most of the time, suggesting a lower Po for K464A-K1250A.
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ABCC7 p.Lys464Ala 11882668:210:184
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212 Our estimates of Po for both mutants are much higher than previously reported (~ 0.2_0.34 for K1250A and ~ 0.25 for K464A-K1250A; Carson et al. 1995; Ramjeesingh et al. 1999; but cf. ~0.9 for K1250A; Gunderson & Kopito, 1995).
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ABCC7 p.Lys464Ala 11882668:212:116
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214 To see whether the reduced Po of K464A-K1250A mutants arises only from shorter open times, we calculated mean closed times from steady-state Po and relaxation time constants (see Methods).
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ABCC7 p.Lys464Ala 11882668:214:33
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216 Thus, K1250A prolongs closed time >30-fold compared either to wild type or to the K464A single mutant (Fig. 3B).
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ABCC7 p.Lys464Ala 11882668:216:82
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218 The mean closed time for K464A-K1250A (17 ± 4 s, n = 5; Fig. 7B) is similar to that for K1250A (P ∆ 0.42).
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ABCC7 p.Lys464Ala 11882668:218:25
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219 Our results show that the lower Po in the double mutant is mostly due to shortening of K1250A`s long open time by K464A.
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ABCC7 p.Lys464Ala 11882668:219:114
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221 We tested whether K464A-K1250A behaved in a similar manner.
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ABCC7 p.Lys464Ala 11882668:221:18
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222 A typical example of K464A-K1250A`s gating behaviour is shown in Fig. 8A.
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ABCC7 p.Lys464Ala 11882668:222:21
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227 We then examined the open time distribution of K464A-K1250A channels in the presence Functional interaction between nucleotide binding domains of CFTRJ. Physiol. 539.2 341 Figure 7.
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ABCC7 p.Lys464Ala 11882668:227:47
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228 K464A shortens K1250A relaxation A, representative trace of macroscopic current relaxations from CFTR-K1250A (top trace) and CFTR-K464A-K1250A double mutant channels upon withdrawal of PKA (40 U ml_1 ) and ATP (1 m).
X
ABCC7 p.Lys464Ala 11882668:228:0
status: NEW
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ABCC7 p.Lys464Ala 11882668:228:130
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229 Mean relaxation time constant for the CFTR-K1250A trace shown is 110 ± 1 s and for CFTR-K464A-K1250A is 30 ± 1 s. B, few-channel traces of CFTR-K1250A and CFTR-K464A-K1250A at the steady state in 2.75 m ATP.
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ABCC7 p.Lys464Ala 11882668:229:93
status: NEW
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ABCC7 p.Lys464Ala 11882668:229:170
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230 Dashed lines indicate baseline (all channels closed); marks at the left indicate open channel current levels (a total of 4 channels for K1250A and 3 for K464A-K1250A).
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ABCC7 p.Lys464Ala 11882668:230:153
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231 C, comparison of steady-state Po, mean open (relaxation) times and mean closed times for CFTR-K1250A and CFTR-K464A-K1250A.
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ABCC7 p.Lys464Ala 11882668:231:110
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232 Asterisks indicate significant differences between CFTR-K1250A and CFTR-K464A-K1250A (**P < 0.01; ***P < 0.005).
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ABCC7 p.Lys464Ala 11882668:232:72
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234 A single exponential fit to the distribution provides an estimated open time of 241 ± 3 ms, similar to the open time of wild type, K464A and K1250A at 10 µ ATP (~250 ms; Zeltwanger et al. 1999; present study, Fig. 3A).
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ABCC7 p.Lys464Ala 11882668:234:136
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235 Thus, K464A had little effect on brief openings seen in K1250A at micromolar [ATP].
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ABCC7 p.Lys464Ala 11882668:235:6
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241 We demonstrate that K1250A, but not K464A, affects the opening rate.
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ABCC7 p.Lys464Ala 11882668:241:36
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242 We also show that both K464A and K1250A affect closing at millimolar [ATP] but in opposite ways.
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ABCC7 p.Lys464Ala 11882668:242:23
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243 K464A accelerates closing whereas K1250A delays it.
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ABCC7 p.Lys464Ala 11882668:243:0
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249 Ramjeesingh et al. (1999) showed that K464A only partly reduced CFTR`s ATPase activity while K1250A eliminates it altogether.
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ABCC7 p.Lys464Ala 11882668:249:38
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250 Aleksandrov et al. (2001) showed that K1250A had no effect on 8-azido- [a-32 P]-ATP labelling of CFTR whereas K464A drastically reduced it.
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ABCC7 p.Lys464Ala 11882668:250:110
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255 It was further hypothesized that hydrolysis is the main pathway for closing under normal conditions and that blocking hydrolysis with K464A or K1250A permits closing only through the slow unbinding pathway, resulting in prolonged openings.
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ABCC7 p.Lys464Ala 11882668:255:134
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256 Based on that model, one would predict that the double mutant K464A-K1250A should exhibit long openings at all ATP concentrations, since the hydrolysis pathway at both A. C. Powe, Jr, L. Al-Nakkash, M. Li and T.-C. Hwang342 J. Physiol. 539.2 Figure 8.
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ABCC7 p.Lys464Ala 11882668:256:62
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257 K464A-K1250A gating at millimolar and micromolar [ATP] A, representative sweep from experiments with CFTR-K464A-K1250A channels exposed first to 1 m and then to 10 µ MgATP.
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ABCC7 p.Lys464Ala 11882668:257:0
status: NEW
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ABCC7 p.Lys464Ala 11882668:257:106
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258 Arrow indicates the baseline, downward deflections channel openings. B, survivor plot of open dwell times for CFTR-K464A-K1250A at 10 µ MgATP.
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ABCC7 p.Lys464Ala 11882668:258:115
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262 We find, however, that the mean open time for K464A-K1250A is ~250 ms at 10 µ ATP and ~30 s at 2.75 m ATP (Figs 7 and 8B).
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ABCC7 p.Lys464Ala 11882668:262:46
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263 The double mutant open time at 10 µ ATP is similar to that of wild type, K464A and K1250A at the same [ATP] (Zeltwanger et al. 1999; present study).
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ABCC7 p.Lys464Ala 11882668:263:86
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264 This finding, together with the dramatic differences between K464A and K1250A mutants, casts considerable doubt on the idea that the NBDs function identically.
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ABCC7 p.Lys464Ala 11882668:264:61
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270 The frequency and duration of these locked open events in the presence of AMP-PNP are reduced by the NBD1 mutation K464A (Figs 4, 5 and 6).
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ABCC7 p.Lys464Ala 11882668:270:115
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272 The reduction of AMP-PNP`s lock open effect by K464A then suggests that lysine 464 in NBD1 regulates nucleotide action at NBD2.
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ABCC7 p.Lys464Ala 11882668:272:47
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276 Because K464A reduces the apparent on-rate (i.e. locking rate) of AMP-PNP (Fig. 6), we expected that this mutation should also impair ATP`s ability to prolong open time.
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ABCC7 p.Lys464Ala 11882668:276:8
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278 Furthermore, the NBD2 mutation K1250A greatly prolongs CFTR open time ~300-fold; that prolongation is then reduced ~5-fold by addition of the NBD1 mutation K464A (Fig. 7).
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ABCC7 p.Lys464Ala 11882668:278:156
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288 Furthermore, Ramjeesingh et al. (1999) showed that K464A reduces ATPase activity by ~80% and K1250A virtually eliminates it, suggesting that mutating one NBD affects the biochemical activity of the other.
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ABCC7 p.Lys464Ala 11882668:288:51
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299 Channel open times at 10 µ ATP for wild type, K464A, K1250A and K464A-K1250A are all ~250 ms (Zeltwanger et al. 1999; present study, Figs 3 and 8), indicating that the NBD mutations have no effect on brief openings.
X
ABCC7 p.Lys464Ala 11882668:299:59
status: NEW
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ABCC7 p.Lys464Ala 11882668:299:77
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306 On the other hand, the NBD1 mutation K464A shortens openings at millimolar [ATP] (Fig. 3).
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ABCC7 p.Lys464Ala 11882668:306:37
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307 K464A also impairs AMP-PNP`s ability to lock open CFTR and the channel`s ability to remain locked open (Figs 4, 5 and 6), which implies that blocking hydrolysis at NBD1 impairs the ability to enter and remain in the longer open state.
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ABCC7 p.Lys464Ala 11882668:307:0
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321 If so, why does the K464A mutation not affect the opening rate?
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ABCC7 p.Lys464Ala 11882668:321:20
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322 There are two possible explanations for this observation: (1) ATP binding, but not hydrolysis at NBD1, opens the channel; or (2) NBD1`s role in channel opening is not revealed by the K464A mutation.
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ABCC7 p.Lys464Ala 11882668:322:183
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323 Although biochemical studies show that K464A does impair ATPase activity in isolated NBD1 (Ko & Pedersen, 1995; King & Sorscher, 1998) as well as in the whole CFTR molecule (Ramjeesingh et al. 1999), the opening rate of K464A may not be affected if opening of CFTR only requires ATP binding.
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ABCC7 p.Lys464Ala 11882668:323:39
status: NEW
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ABCC7 p.Lys464Ala 11882668:323:220
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326 Another possibility is that NBD1 may be involved in channel opening, but the domain`s role is not revealed by the K464A mutation.
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ABCC7 p.Lys464Ala 11882668:326:114
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334 A. C. Powe, Jr, L. Al-Nakkash, M. Li and T.-C. Hwang J. Physiol. 539.2 Conclusions To examine the contribution of NBD1 during CFTR gating, we assessed the kinetic properties of the Walker-A mutant K464A.
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ABCC7 p.Lys464Ala 11882668:334:198
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335 We found that K464A had little effect on the apparent ATP dependence or opening rate of the channel.
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ABCC7 p.Lys464Ala 11882668:335:14
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337 K464A also diminished AMP-PNP`s ability to stabilize channel open state by affecting both apparent on- and off-rates of the non-hydrolysable analogue.
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ABCC7 p.Lys464Ala 11882668:337:0
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338 Finally, K464A reduces the prolongation of open time seen in the NBD2 mutant K1250A at millimolar [ATP], strongly suggesting an interaction between NBD1 and NBD2 during CFTR`s open state.
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ABCC7 p.Lys464Ala 11882668:338:9
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339 Although the NBD1 mutant K464A did not affect opening, the NBD2 mutant K1250A delays opening >30-fold compared to wild type.
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ABCC7 p.Lys464Ala 11882668:339:25
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PMID: 12034762 [PubMed] Dousmanis AG et al: "Distinct Mg(2+)-dependent steps rate limit opening and closing of a single CFTR Cl(-) channel."
No. Sentence Comment
25 Thus, although ATPase activity is diminished 10-20-fold in mutant K464A CFTR, and practically abolished in K1250A CFTR (Ramjeesingh et al., 1999), channel opening rate at millimolar [MgATP] has been reported to be reduced only 2-4-fold in K464A and somewhat more severely (5-10-fold) in K1250A CFTR (Carson et al., 1995; Gunderson and Kopito, 1995; Ramjeesingh et al., 1999); and gating persists even in double mutant K464A/K1250A CFTR channels (Carson et al., 1995).
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ABCC7 p.Lys464Ala 12034762:25:66
status: NEW
X
ABCC7 p.Lys464Ala 12034762:25:239
status: NEW
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ABCC7 p.Lys464Ala 12034762:25:418
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196 Analysis of the temporal asymmetry of changes in character of rapid current blocking events during open bursts of CFTR channels, and their modification by nucleotide analogues and by mutation of NBD2 (K1250A) but not NBD1 (K464A), provided additional evidence that hydrolysis of ATP tightly bound at NBD2 causes the channel to close (Gunderson and Kopito, 1995).
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ABCC7 p.Lys464Ala 12034762:196:223
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246 Nucleotide binding assays (at 0ЊC to prevent hydrolysis) using 8-azidoATP photolabeling show that binding occurs with the same micromolar apparent affinity in wild-type, mutant K1250M, and double mutant K464A/ K1250A, CFTR (Carson et al., 1995).
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ABCC7 p.Lys464Ala 12034762:246:209
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247 These findings, together with the fact that even double mutant K464A/ K1250A CFTR channels open and close at measurable rates (Carson et al., 1995), make it seem unlikely that ATP hydrolysis at either NBD1 or NBD2 is a prerequisite for channel opening.
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ABCC7 p.Lys464Ala 12034762:247:63
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PMID: 12508051 [PubMed] Vergani P et al: "On the mechanism of MgATP-dependent gating of CFTR Cl- channels."
No. Sentence Comment
4 The rate of opening to a burst (1/␶ib) was a saturable function of [MgATP], but apparent affinity was reduced by mutations in either of CFTR`s nucleotide binding domains (NBDs): K464A in NBD1, and K1250A or D1370N in NBD2.
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ABCC7 p.Lys464Ala 12508051:4:185
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9 However, when hydrolysis at NBD2 was impaired, the NBD1 mutation K464A shortened the prolonged open bursts.
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ABCC7 p.Lys464Ala 12508051:9:65
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32 However, in CFTR the Walker A NBD2 mutation K1250A abolished ATP hydrolysis, whereas the NBD1 mutation K464A simply reduced overall hydrolytic activity (Ramjeesingh et al., 1999); and biochemical studies of Walker B aspartate mutations in CFTR (D572N in NBD1, D1370N in NBD2) have not yet been performed.
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ABCC7 p.Lys464Ala 12508051:32:103
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34 Thus, the K1250A mutation dramatically prolonged burst duration, suggesting that hydrolysis at NBD2 might be coupled to burst termination (Carson et al., 1995; Gunderson and Kopito, 1995), whereas the NBD1 mutations K464A, Q552A, and Q552H somewhat slowed channel opening to a burst, suggesting that NBD1 might be a site of ATP interactions governing opening (Carson et al., 1995; Carson and Welsh 1995).
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ABCC7 p.Lys464Ala 12508051:34:216
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41 We studied in detail the dependence of channel gating on [MgATP], gating in the presence of poorly hydrolyzable nucleotide analogs, as well as the effects of mutating residues in the Walker A (K464A and K1250A) and Walker B motifs (in particular, D1370N in NBD2).
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ABCC7 p.Lys464Ala 12508051:41:193
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52 Amounts of cRNA injected were adjusted to vary the level of expression: up to 40 ng/oocyte was required for high expression of K1250A or K464A/K1250A mutant channels, whereas 0.1-0.25 ng/oocyte sufficed for single channel recordings of WT, K464A, or D1370N channels.
X
ABCC7 p.Lys464Ala 12508051:52:137
status: NEW
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ABCC7 p.Lys464Ala 12508051:52:240
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89 T A B L E I Kinetic Parameters of WT and Mutant CFTR Channels WT K464A D1370N mean Ϯ SEM n mean Ϯ SEM n mean Ϯ SEM n (A) 5 mM MgATP ϩ 300 nM PKA ␶b 644 Ϯ 63 30 620 Ϯ 58 21 3,768 Ϯ 499 21 ␶ib 1,671 Ϯ 172 30 2,760 Ϯ 439 21 3,588 Ϯ 414 21 1,552 Ϯ 170 19 2,438 Ϯ 483 12 2,849 Ϯ 491 12 ␶F 19.3 Ϯ 2.0 30 20.8 Ϯ 2.1 21 49.9 Ϯ 4.3 21 nF 0.57 Ϯ 0.06 30 0.50 Ϯ 0.06 21 2.76 Ϯ 0.25 21 rCO 0.75 Ϯ 0.06 30 0.50 Ϯ 0.05 21 0.38 Ϯ 0.05 21 0.77 Ϯ 0.08 19 0.54 Ϯ 0.08 12 0.47 Ϯ 0.07 12 rOC 1.95 Ϯ 0.15 30 1.92 Ϯ 0.15 21 0.43 Ϯ 0.07 21 (B) 5 mM MgATP ␶b 338 Ϯ 22 18 309 Ϯ 23 8 1,748 Ϯ 215 17 ␶ib 4,506 Ϯ 497 18 6,752 Ϯ 1314 8 9,503 Ϯ 1440 17 4,454 Ϯ 1382 5 6,928 Ϯ 1666 6 7,584 Ϯ 1967 9 ␶F 23.5 Ϯ 3.2 18 16.1 Ϯ 2.2 8 51.5 Ϯ 6.0 17 nF 0.42 Ϯ 0.05 18 0.39 Ϯ 0.06 8 1.40 Ϯ 0.13 17 rCO 0.27 Ϯ 0.03 18 0.18 Ϯ 0.03 8 0.16 Ϯ 0.03 17 0.33 Ϯ 0.09 5 0.18 Ϯ 0.03 6 0.22 Ϯ 0.05 9 rOC 3.28 Ϯ 0.21 18 3.43 Ϯ 0.25 8 0.75 Ϯ 0.09 17 (C) 50 ␮M MgATP ␶b 355 Ϯ 44 12 323 Ϯ 136 4 1,433 Ϯ 381 4 ␶F 27.3 Ϯ 5.2 12 22.1 Ϯ 4.4 4 46.2 Ϯ 10.8 4 nF 0.38 Ϯ 0.05 12 0.45 Ϯ 0.11 4 1.91 Ϯ 0.34 4 (D) 5 mM MgAMPPNP ␶b 1,619 Ϯ 232 32 271 Ϯ 52 8 ␶F 59.5 Ϯ 6.6 32 26.8 Ϯ 7.7 8 nF 2.40 Ϯ 0.26 32 0.38 Ϯ 0.10 8 Kinetic parameters were obtained using a maximum likelihood simultaneous fit to dwell-time histograms at all conductance levels (Csanády, 2000).
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ABCC7 p.Lys464Ala 12508051:89:65
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113 (B and C) Representative traces for prephosphorylated K464A and D1370N channels.
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ABCC7 p.Lys464Ala 12508051:113:54
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114 Relative opening (D) and closing (E) rates (mean Ϯ SEM, 2 Յ n Յ 7) from analysis of records as in A-C for WT (blue circles), K464A (red triangles), and D1370N (green squares) channels at 10 ␮M Յ [MgATP] Յ 5 mM, plotted on semilogarithmic axes.
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ABCC7 p.Lys464Ala 12508051:114:143
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116 Curves in D show Michaelis-Menten fits, yielding K0.5 of 56 Ϯ 5, 807 Ϯ 185, 391 Ϯ 118 ␮M, and rCOmax of 1.02, 1.16, and 1.08, for WT, K464A, and D1370N, respectively.
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ABCC7 p.Lys464Ala 12508051:116:159
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123 Compared with WT, both K464A (Walker A lysine in NBD1) and D1370N (Walker B aspartate in NBD2) mutant CFTR channels opened less frequently at low [MgATP] (e.g., 50 ␮M; Figs. 2, A-D), and this defect could be largely overcome by raising the [MgATP], so that, at saturating [MgATP], opening rates of WT, K464A, and D1370N channels differed by less than a factor of two (Table I).
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ABCC7 p.Lys464Ala 12508051:123:23
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ABCC7 p.Lys464Ala 12508051:123:309
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125 As expected (see below) for channels in which opening rate, but not closing rate, is sensitive to [MgATP], the dependence of Po on [MgATP] was not very different from that of rCO, shown in Fig. 2 D, for WT (see Fig. 3 C), K464A, or D1370N channels.
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ABCC7 p.Lys464Ala 12508051:125:222
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151 Catalytic Site Mutations at NBD1 Do Not Alter Channel Closing from Normal, MgATP-elicited Bursts The average rate of closure of K464A mutant CFTR channels from open bursts was closely similar to that of WT CFTR under comparable conditions (Figs. 4, A-F, and 5, A, B, and E); it was likewise approximately independent of [MgATP] (Fig. 2 E, red triangles) and it was similarly reduced roughly twofold by strong phosphorylation (Fig. 4, D and E; Table I).
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ABCC7 p.Lys464Ala 12508051:151:128
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152 Also like WT, the burst duration distributions of K464A mutant channels were well described by single exponential functions (Fig. 4, D-F).
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ABCC7 p.Lys464Ala 12508051:152:50
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157 Burst duration distributions are similar for WT (A-C) and K464A (D-F) channels under comparable conditions, as indicated (PKA present for left column only).
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ABCC7 p.Lys464Ala 12508051:157:58
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160 Only for K464A at ␮M MgATP (F) could the likelihood be significantly increased by including a second component, though with a shorter (but not longer; Ikuma and Welsh, 2000) mean: ␶1 ϭ 30 ms, a1 ϭ 0.17; ␶2 ϭ 263 ms, a2 ϭ 0.83; increase in log likelihood, ⌬LL ϭ 8.3; number of bursts fitted, M ϭ 263; giving (⌬LL - ln(2M) ϭ 2.0).
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ABCC7 p.Lys464Ala 12508051:160:9
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161 The small differences between means at mM and ␮M MgATP (B vs. C, E vs. F) may be only apparent, as the mean ␶b, estimated by multichannel kinetic fits, from these same stretches of record at ␮M MgATP is not significantly different from that during intervening stretches in 5 mM MgATP (for WT: ␶b␮M/␶b5mM ϭ 1.03 Ϯ 0.07, n ϭ 9; for K464A: ␶b␮M/␶b5mM ϭ 0.95 Ϯ 0.13, n ϭ 7).
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ABCC7 p.Lys464Ala 12508051:161:390
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162 (G and H) Representative traces showing gating of K464A and D1370N channels at 15 ␮M MgATP (after PKA removal).
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ABCC7 p.Lys464Ala 12508051:162:50
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163 Prolonged bursts of K464A channels (Ikuma and Welsh, 2000) are not evident.
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ABCC7 p.Lys464Ala 12508051:163:20
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183 Patches contained one WT (A), K464A (B), or S573E (D) channel, or more than one D572N (C) channel.
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ABCC7 p.Lys464Ala 12508051:183:30
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184 (E) Summary of mean (ϮSEM) ␶b values at 5 mM MgATP and 300 nM PKA (n ϭ 30, 21, 9, and 7 for WT, K464A, D572N, and S573E, respectively).
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ABCC7 p.Lys464Ala 12508051:184:115
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218 Closing from Locked-open Bursts Is Faster for K464A Mutants than for WT Channels Although the K464A mutation did not alter open burst duration of channels exposed to MgATP (Figs. 2 E, 4, and 5), regardless of phosphorylation status (Fig. 4; Table I), it did significantly reduce the duration of certain unusually prolonged bursts.
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ABCC7 p.Lys464Ala 12508051:218:46
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ABCC7 p.Lys464Ala 12508051:218:94
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222 For K464A channels, on the other hand (Fig. 10 B), the slow component comprised a somewhat smaller fraction (as ϭ 0.63 Ϯ 0.04, n ϭ 16, Fig. 10 C) of the current Figure 8.
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ABCC7 p.Lys464Ala 12508051:222:4
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227 The smaller fractional amplitude of the slow component for K464A channels can be explained by this observed shortening of their locked-open bursts without the mutation markedly altering the frequency of entry into such bursts.
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ABCC7 p.Lys464Ala 12508051:227:59
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232 The analogous estimate for K464A channels gives an average of 1 locking in every ‫6ف‬ openings.
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ABCC7 p.Lys464Ala 12508051:232:27
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234 The K464A mutation also shortened (Fig. 10, E-G) the similarly prolonged bursts of NBD2 mutant K1250A channels exposed to MgATP alone (Fig. 6 C).
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ABCC7 p.Lys464Ala 12508051:234:4
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242 The K464A mutation speeds exit from locked open burst states.
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ABCC7 p.Lys464Ala 12508051:242:4
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244 (B) Current decay is much faster for the K464A mutant in the same conditions.
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ABCC7 p.Lys464Ala 12508051:244:41
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245 Blue fit lines in A and B show only the slow components of double exponential fits, with ␶s ϭ 67.8s, as ϭ 0.92 for WT, and ␶s ϭ 8.7s, as ϭ 0.79 for K464A.
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ABCC7 p.Lys464Ala 12508051:245:186
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246 (C and D) Summaries of fractional amplitude, as (C), and time constant, ␶s (D), of the slow component from 18 WT and 16 K464A experiments.
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ABCC7 p.Lys464Ala 12508051:246:127
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247 In controls with no MgAMPPNP, closure after exposure to MgATP and PKA yielded ␶ ϭ 1.9 Ϯ 0.2 s (n ϭ 35) for WT and ␶ ϭ 1.0 Ϯ 0.1 s (n ϭ 34) for K464A, and both constructs sometimes showed a small amplitude slower component: for WT, ␶s ϭ 7.6 Ϯ 1.7 s, as ϭ 0.1 Ϯ 0.03 (in 13/35 patches); for K464A, ␶s ϭ 5.9 Ϯ 0.8 s, as ϭ 0.24 Ϯ 0.04 (20/24 patches).
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ABCC7 p.Lys464Ala 12508051:247:193
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ABCC7 p.Lys464Ala 12508051:247:370
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249 (F) The additional K464A mutation accelerates channel closure from bursts: for the traces shown, ␶ ϭ 71.7s (K1250A) and ␶ ϭ 29.7s (K464A/K1250A).
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ABCC7 p.Lys464Ala 12508051:249:19
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ABCC7 p.Lys464Ala 12508051:249:157
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250 (G) Mean time constants of all 9 K1250A and 9 K464A/K1250A relaxations, each well fit by a single exponential.
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ABCC7 p.Lys464Ala 12508051:250:46
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253 However, in double mutant K464A/K1250A CFTR channels (Fig. 10 F) the current relaxation time constant (␶ ϭ 36 Ϯ 4 s, n ϭ 9), and hence the mean open-burst dwell time, was less than half that of channels bearing the K1250A mutation alone (Fig. 10 G).
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ABCC7 p.Lys464Ala 12508051:253:26
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254 Closing from Bursts During Activation by Poorly Hydrolyzable Analogs Alone Is Faster for K464A Mutants than for WT Channels Like WT CFTR (Fig. 7), mutant K464A channels could be opened by millimolar concentrations of the analogs MgAMPPNP or MgATP␥S alone (Fig. 11), with rates of opening to bursts of 1.5 Ϯ 0.2% (n ϭ 4) at 0.5 mM and 2.9 Ϯ 0.3% (n ϭ 4) at 5 mM MgAMPPNP, and 5.0 Ϯ 0.6% (n ϭ 8) at 2 mM MgATP␥S, of the maximal rate at saturating [MgATP], values not very different from those for WT channels under the same conditions.
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ABCC7 p.Lys464Ala 12508051:254:89
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ABCC7 p.Lys464Ala 12508051:254:154
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255 However, the 5-10-fold prolongation of WT bursts by these analogs (Fig. 7 A) was not evident in K464A channels (Fig. 11): for K464A channels opened by MgAMPPNP or MgATP␥S alone, the mean ␶b values were only 1.1 Ϯ 0.2 (n ϭ 8) or 2.2 Ϯ 0.5 (n ϭ 8) times larger, respectively, than at 10 ␮M MgATP.
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ABCC7 p.Lys464Ala 12508051:255:96
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ABCC7 p.Lys464Ala 12508051:255:126
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256 Because this consequence of the K464A mutation is manifest during exposure to essentially nonhydrolyzable ATP analogs it cannot be ascribed to any failure of the mutant channel to hydrolyze nucleotide at the NBD1 catalytic site, but instead must be attributed to the alteration of NBD1 structure per se. D I S C U S S I O N We may draw several conclusions from these analyses of gating kinetics of WT and of NBD mutant CFTR channels, in the presence of MgATP and/or of poorly-hydrolyzable analogs: (a) nucleotide binds at both NBD1 and NBD2 catalytic sites before channel opening; (b) the slow opening transition, after nucleotide binding, is highly sensitive to the structures of the beta-␥ phosphate bridging group and of the ␥ phosphate; (c) no further nucleotide binding is required to terminate an open burst; (d) hydrolysis of the nucleotide at NBD2 precedes normal, rapid closing from bursts; (e) if that hydrolysis is prevented, the structure of the NBD1 catalytic site and of the nucleotide bound there can modulate rate of exit from the resulting prolonged (locked) open burst.
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ABCC7 p.Lys464Ala 12508051:256:32
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266 Our results show that mutations within the Walker motifs of either NBD1 (K464A) or NBD2 (D1370N, Figure 11.
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ABCC7 p.Lys464Ala 12508051:266:73
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267 Gating of prephosphorylated K464A channels by poorly hydrolyzable ATP analogs, as indicated.
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ABCC7 p.Lys464Ala 12508051:267:28
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268 Unlike WT (Fig. 7 A), K464A burst duration was not increased during exposure to MgAMPPNP (A and B, ␶b ϭ 270 Ϯ 50 ms, n ϭ 8), and was only slightly increased during exposure to ATP␥S (C, ␶b ϭ 655 Ϯ 170 ms, n ϭ 8), compared with bursts in MgATP (␶b ϭ 276 Ϯ 21 ms, n ϭ 16) in the same patches.
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ABCC7 p.Lys464Ala 12508051:268:22
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269 Note that, due to the lower apparent affinity of K464A for MgATP (Fig. 2), the relative opening rate of mutant channels at 10 ␮M MgATP averaged only 2.3 Ϯ 0.8% (n ϭ 3) of that in saturating MgATP (compared with ‫%11ف‬ for WT), so the opening rate of K464A channels was similar in the presence of millimolar concentrations of the poorly hydrolyzable analogs or of 10 ␮M MgATP.
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ABCC7 p.Lys464Ala 12508051:269:49
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ABCC7 p.Lys464Ala 12508051:269:289
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270 K1250A) reduce the apparent affinity of the MgATP binding site(s) involved in channel opening (Figs. 2 and 3), but (at least for K464A and D1370N) affect the maximal opening rate little (Table I).
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ABCC7 p.Lys464Ala 12508051:270:129
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275 Accordingly, although no major difference in [␣32P]8-azidoATP photolabeling at 0ЊC was detected between WT and K464A/K1250A (Carson et al., 1995) or K464A CFTR (Vergani et al., 2002), the K464A mutation alone greatly reduced photolabeling of NBD1 by ␮M [␣32P]8-azidoATP at 37ЊC (Aleksandrov et al., 2002) and virtually abolished stable (i.e., surviving extensive post-incubation washing) photolabeling at 30ЊC (unpublished data).
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ABCC7 p.Lys464Ala 12508051:275:124
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ABCC7 p.Lys464Ala 12508051:275:162
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ABCC7 p.Lys464Ala 12508051:275:201
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280 Therefore, the simplest interpretation of the reduced apparent affinity with which MgATP elicits opening of K464A and D1370N (and K1250A) mutants compared with WT is that the mutations impair nucleotide binding at two different sites, such that at subsaturating [MgATP] channel opening is limited by MgATP binding at NBD1 in K464A, but at NBD2 in D1370N (and K1250A).
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ABCC7 p.Lys464Ala 12508051:280:108
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ABCC7 p.Lys464Ala 12508051:280:325
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286 Allosteric interactions between CFTR`s two NBDs (compare Powe et al., 2002) could, therefore, permit the K464A, D1370N, and K1250A mutations to all affect the same binding site.
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ABCC7 p.Lys464Ala 12508051:286:105
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297 However, we cannot rule out that, at low [MgATP], mutant K464A CFTR channels might open to bursts with only NBD2 occupied by nucleotide.
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ABCC7 p.Lys464Ala 12508051:297:57
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298 In fact, although opening rates for WT and D1370N mutant CFTR channels (Fig. 2 D, blue and green symbols) are satisfactorily described by the Michaelis equation (i.e., opening limited by binding to a single site) the opening rates of K464A channels (Fig. 2 D, red symbols) at low (Յ50 ␮M) [MgATP] are slightly higher than expected.
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ABCC7 p.Lys464Ala 12508051:298:234
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299 If confirmed, these results would be consistent with the right-shifted K464A [MgATP]-rCO curve reflecting principally a reduced nucleotide affinity at NBD1 (now lower than the affinity at NBD2) and a low, but nonzero, opening rate of K464A mutant CFTR channels with nucleotide bound only at the unmodified NBD2 site.
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ABCC7 p.Lys464Ala 12508051:299:71
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ABCC7 p.Lys464Ala 12508051:299:234
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300 Therefore, present evidence suggests that nucleotide normally binds to both of WT CFTR`s NBDs before the channel opens, and that opening is limited by nucleotide binding at NBD2 in WT, D1370N, and K1250A CFTR channels, but probably by nucleotide binding at NBD1 in K464A CFTR channels.
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ABCC7 p.Lys464Ala 12508051:300:265
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305 But, by directly comparing gating of the same channels, in the same patch, during exposure to MgAMPPNP, MgAMPPCP, or MgATP␥S, and to MgATP, we find that at concentrations of these analogs expected to be saturating (Figs. 7 and 8; see also Weinreich et al., 1999; Aleksandrov et al., 2001, 2002) the opening rates of WT (Figs. 7-9) and K464A (Fig. 11) channels are only ‫%5ف‬ of that reached at saturating [MgATP].
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ABCC7 p.Lys464Ala 12508051:305:342
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311 Whereas the K464A mutation in NBD1 has been reported to reduce ‫02ف‬ fold the ATPase activity of purified CFTR (Ramjeesingh et al., 1999), we find that the same mutation diminishes maximal opening rate by only Ͻ50%, similar to effects of other NBD1 catalytic site mutations (Figs. 2 and 5).
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ABCC7 p.Lys464Ala 12508051:311:12
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324 We found no clear dependence of burst duration on [MgATP] (10 ␮M to 5 mM) in WT CFTR (Figs. 2 E, 3 A, and 4, B and C) or in K464A, D1370N, or K1250A mutant channels (Figs. 2 E, 3 B, and 4, E-H), indicating that all ATP binding events precede channel opening and no further binding to the open channel is needed to complete the gating cycle.
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ABCC7 p.Lys464Ala 12508051:324:131
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362 However, the scheme as drawn suggests tight coupling between channel gating and ATP hydrolysis, which is inconsistent with the largely unaltered gating of the catalytically impaired K464A mutant (with ATPase Vmax apparently reduced ‫-02ف‬fold; Ramjeesingh et al., 1999).
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ABCC7 p.Lys464Ala 12508051:362:182
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366 Even higher levels of steady state phosphorylation could prolong normal hydrolytic bursts (Table I, WT and K464A), as well as nonhydrolytic locked-open bursts (Table I, D1370N; Fig. 10 A vs. Fig. 9; Fig. 3 B vs. Fig. 10 E), by stabilizing the open burst states more than the transition states for both possible pathways (forward or backward; Fig. 12 A) for terminating the burst.
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ABCC7 p.Lys464Ala 12508051:366:107
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369 But when hydrolysis (at NBD2) was prevented, by supplying nucleotide resistant to hydrolysis (Figs. 9, and 10, A-D; Fig. 7 vs. Fig. 11), by adding VO4 (Vergani et al., 2002), or by mutating the NBD2 Walker A lysine (K1250A; Fig. 10, E-G), the K464A mutation resulted in less prolonged bursts.
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ABCC7 p.Lys464Ala 12508051:369:243
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370 Very similar reduction of locked-open burst duration by the K464A mutation has been described recently in NIH3T3 and CHO cells (Powe et al., 2002).
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ABCC7 p.Lys464Ala 12508051:370:60
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381 The influence of the K464A mutation seen in Fig. 2 D (also on Po) is then mimicked simply by an ‫-05ف‬fold acceleration of the MgATP dissociation rate from NBD1, together with the Ͻ2-fold observed reduction in maximal opening rate (Table IB).
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ABCC7 p.Lys464Ala 12508051:381:21
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646 Effects on CFTR Cl-channel gating of Walker A lysine mutation K464A imply allosteric interaction between NBDs.
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ABCC7 p.Lys464Ala 12508051:646:62
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639 Effects on CFTR Cl- channel gating of Walker A lysine mutation K464A imply allosteric interaction between NBDs.
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ABCC7 p.Lys464Ala 12508051:639:63
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PMID: 12523935 [PubMed] Annereau JP et al: "Cystic fibrosis transmembrane conductance regulator: the NBF1+R (nucleotide-binding fold 1 and regulatory domain) segment acting alone catalyses a Co2+/Mn2+/Mg2+-ATPase activity markedly inhibited by both Cd2+ and the transition-state analogue orthovanadate."
No. Sentence Comment
44 To obtain ht-NBF1jR mutants in the Walker A region (K464H and K464A), cDNA cassettes were exchanged between BamHI and Bst1107I sites with homologous cDNA cassettes excised from the mutant pMALCR1 MBP-NBF1 plasmids, constructed previously in our laboratory [31].
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ABCC7 p.Lys464Ala 12523935:44:62
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48 Overexpression of the recombinant ht-NBF1TR (Gly-404-Lys-830) 'wild-type` and mutant proteins (K464H or K464A) Escherichia coli BL21 (DE3) strain, freshly transformed with the 'wild-type` (i.e. recombinant) and mutant ht-NBF1jR plasmids, were grown in 10 ml of LB medium containing 50 µg\ml kanamycin.
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ABCC7 p.Lys464Ala 12523935:48:104
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103 The Walker A motif is underlined, and Lys-464 within this motif is shown in bold to denote the site of mutations (K464H, K464A) made in this study.
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ABCC7 p.Lys464Ala 12523935:103:121
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105 (C) Expression in E. coli of the 'wild-type` ht-NBF1jR protein and mutant forms K464H and K464A.
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ABCC7 p.Lys464Ala 12523935:105:90
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109 Lanes 2, 4 and 6, E. coli cells transformed with plasmids containing, respectively, cDNA encoding 'wild-type` ht-NBF1jR, mutant-form K464H and mutant-form K464A prior to induction with IPTG; lanes 3, 5 and 7, as for lanes 2, 4 and 6 respectively but after induction with 0.3 mM IPTG.
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ABCC7 p.Lys464Ala 12523935:109:155
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110 (D) SDS/PAGE pattern obtained at different stages of purification of the 'wild-type` ht-NBF1jR protein and mutant forms K464H and K464A.
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ABCC7 p.Lys464Ala 12523935:110:130
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113 SDS/PAGE (10%) was used to analyse 10 µl aliquots at each step as follows: lane 1, molecular-mass markers as defined in (C); lanes 2-4, supernatant from guanidine hydrochloride-extracted E. coli overexpressing the 'wild-type` ht-NBF1jR protein and its mutant forms K464A and K464H respectively; lanes 5-7, flow-through fractions of the same extracts after their application to a Ni-NTA column (note that the $ 50 kDa proteins, i.e. the 'wild-type` ht-NBF1jR protein and its mutant forms, were retained); lanes 8-10, eluates derived from Ni-NTA columns containing, respectively, the 'wild-type` ht-NBF1jR protein and its K464A and K464H mutant forms after including 10 mM imidazole in the elution buffer; lanes 11-13, eluates derived from the same Ni-NTA columns after adding 200 mM imidazole to the elution buffer.
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ABCC7 p.Lys464Ala 12523935:113:270
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ABCC7 p.Lys464Ala 12523935:113:625
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120 E. coli transformed with the pET-28a(T) expression plasmid encoding NBF1TR residues 404-830, and a short His-tagged N-terminal region, markedly overproduce both 'wild-type` and mutant forms (K464H and K464A) of the protein Results presented in Figure 1(C) summarize SDS\PAGE patterns of E. coli cells harbouring the 'wild-type` and mutant ht-NBF1jR-containing plasmids before and after induction with IPTG.
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ABCC7 p.Lys464Ala 12523935:120:201
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122 The same applies to lane 5 (mutant K464H with IPTG) versus lane 4 (mutant K464H without IPTG), and to lane 7 (mutant K464A with IPTG) versus lane 6 (mutant K464A without IPTG).
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ABCC7 p.Lys464Ala 12523935:122:117
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ABCC7 p.Lys464Ala 12523935:122:156
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127 The ht-NBF1TR 'wild-type` protein and its mutant forms can be purified to apparent homogeneity on a Ni-NTA column and show cross-reactivity with a monoclonal antibody to CFTR exhibiting specificity for NBF1 As the overexpressed 'wild-type` and mutant (K464H and K464A) proteins were tagged with six histidines at their N-terminus (see the Materials and methods section and Figure 1B), they were amenable to purification on a column containing bound Ni#+.
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ABCC7 p.Lys464Ala 12523935:127:262
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128 For this reason, the wild-type and mutant E. coli cell pellets derived from the overexpression experiments described above were treated with a buffered solution containing the denaturant guanidine hydrochloride (6 M), and after centri- on the SDS/PAGE gels for the 'wild-type` ht-NBF1jR protein (lane 11) and its mutant forms K464A (lane 12) and K464H (lane 13).
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ABCC7 p.Lys464Ala 12523935:128:326
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129 (E) Cross-reactivity of the purified 'wild-type` ht-NBF1jR protein and mutant form K464A with an anti-CFTR antibody (MATG 1061) with specificity for the NBF1 domain.
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ABCC7 p.Lys464Ala 12523935:129:83
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131 Lanes 1 and 2, purified 'wild-type` ht-NBF1jR protein (0.5 µg) and its K464A mutant (0.5 µg), respectively.
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ABCC7 p.Lys464Ala 12523935:131:76
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142 Data presented in Figure 1(E) show that the purified 'wild-type` ht-NBF1jR protein (lane 1) and its K464A mutant (lane 2) cross-reacted with a monoclonal antibody to CFTR exhibiting specificity for NBF1.
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ABCC7 p.Lys464Ala 12523935:142:100
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152 (B) ATPase activity versus [ATP] plot for the purified renatured 'wild-type` ht-NBF1jR protein and mutant forms K464H and K464A.
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ABCC7 p.Lys464Ala 12523935:152:122
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154 The assay contained, in 75 µl of renaturation buffer, ATP concentrations of 0-100 µM, 5 mM MgCl2 and 0.47 µg of either the 'wild-type` ht-NBF1jR protein (WT) or its mutant forms K464H and K464A, pH 7.5.
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ABCC7 p.Lys464Ala 12523935:154:203
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159 (D) Relative ATPase activities obtained for the 'wild-type` NBF1jR Protein (WT) and mutant forms K464H and K464A using the [32 P]Pi release assay.
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ABCC7 p.Lys464Ala 12523935:159:107
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160 The assay was carried out in 200 µl of renaturation buffer, pH 7.5, containing 3.7 µg of the 'wild-type` ht-NBF1jR protein or its mutant forms (K464H, or K464A), and supplemented with 250 µM [γ-32 P]ATP (1.4i106 c.p.m.) and 1 mM divalent cation.
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ABCC7 p.Lys464Ala 12523935:160:164
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200 Subsequent studies carried out with ht-NBF1jR proteins with mutations in the Walker A consensus region (K464H and K464A) showed that the Vmax was reduced about 50% in each case (Figure 2B).
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ABCC7 p.Lys464Ala 12523935:200:114
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PMID: 12727866 [PubMed] Kogan I et al: "CFTR directly mediates nucleotide-regulated glutathione flux."
No. Sentence Comment
2 We show that CFTR-expressing membrane vesicles mediate nucleotide-activated GSH ¯ux, which is disrupted in the R347D pore mutant, and in the Walker A K464A and K1250A mutants.
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ABCC7 p.Lys464Ala 12727866:2:155
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94 To assess the nucleotide dependence of GSH permeation through CFTR, we determined the consequences of lysine mutations in the conserved Walker A consensus motifs for ATP binding in NBD1 and NBD2: K464A and K1250A, respectively.
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ABCC7 p.Lys464Ala 12727866:94:196
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96 In Figure 4, we show that both the K464A and K1250A mutants exhibit similar signi®cant reductions in GSH ¯ux.
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ABCC7 p.Lys464Ala 12727866:96:35
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97 We observed that GSH uptake in both the K464A and K1250A membrane vesicles was 3to 4-fold lower than in vesicles expressing wild-type CFTR protein, yielding permeability values of 132 and 120 pmol/mg CFTR/h, respectively (P < 0.001).
X
ABCC7 p.Lys464Ala 12727866:97:40
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102 Membrane vesicles expressing phosphorylated wild-type, K464A or K1250A CFTR were incubated with 20 nM [35S]GSH and 1 mM cold GSH in CFTR transport buffer, in the presence of MgAMPPNP.
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ABCC7 p.Lys464Ala 12727866:102:55
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104 Values shown represent the mean activity (T SEM; for K464A and K1250A, n = 4; for wild-type CFTR, n = 5).
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ABCC7 p.Lys464Ala 12727866:104:53
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105 Inset: expression of CFTR in membranes from Sf9 cells transfected with wild-type, K464A or K1250A CFTR constructs.
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ABCC7 p.Lys464Ala 12727866:105:82
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194 An Sf9 cell pellet (0.5 l) expressing either recombinant CFTR-His proteins (wild type or mutant: R347D, K464A, K1250A) or no CFTR was solubilized in 30 ml of homogenization buffer containing 250 mM sucrose, 50 mM Tris±HCl, 0.25 mM CaCl2 pH 7.5 and protease inhibitors (Roche Diagnostics GmbH, Mannheim, Germany).
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ABCC7 p.Lys464Ala 12727866:194:104
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PMID: 12939393 [PubMed] Basso C et al: "Prolonged nonhydrolytic interaction of nucleotide with CFTR's NH2-terminal nucleotide binding domain and its role in channel gating."
No. Sentence Comment
46 We have previously described pGEMHE-CFTR, pGEMHE-Flag-3-835 (Chan et al., 2000), and pGEMHE-K464A (Vergani et al., 2003).
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ABCC7 p.Lys464Ala 12939393:46:92
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82 Oocytes were injected with 0.1-10 ng of cRNA transcribed from pGEMHE-CFTR (WT or K464A).
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ABCC7 p.Lys464Ala 12939393:82:81
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231 The K464A Mutation Little Influences Binding at 0ЊC, but Diminishes Occlusion at 30ЊC, at Low [Nucleotide] Because the mutation K464A at the Walker A lysine in NBD1 impairs CFTR maturation in mammalian cells (e.g., Aleksandrov et al., 2001), we compared nucleotide interactions with WT and K464A CFTR expressed in oocytes, in which we also compared electrophysiological responses.
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ABCC7 p.Lys464Ala 12939393:231:4
status: NEW
X
ABCC7 p.Lys464Ala 12939393:231:140
status: NEW
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ABCC7 p.Lys464Ala 12939393:231:302
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232 Despite loading twice as much membrane protein in the K464A lanes as in the WT lanes (Fig. 8 A, right) to compensate for diminished K464A expression (Fig. 8 A, left), negligible occlusion of [␣32P]8-N3ATP at 30ЊC was observed for K464A CFTR, either with or without Vi.
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ABCC7 p.Lys464Ala 12939393:232:54
status: NEW
X
ABCC7 p.Lys464Ala 12939393:232:132
status: NEW
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ABCC7 p.Lys464Ala 12939393:232:243
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233 In contrast, simple binding of 5 or 50 ␮M [␣32P]8-N3ATP, assayed by photolabeling in oocyte membranes at 0ЊC, seemed little different for Flag-K464A than for Flag-WT CFTR (Fig. 8 B), even though that binding occurs predominantly at NBD1 (Fig. 3, above), the structurally altered catalytic site.
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ABCC7 p.Lys464Ala 12939393:233:163
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234 The fact that opening of K464A CFTR channels is impaired at low ␮M [MgATP] (Vergani et al., 2003) suggests that channel opening and nucleotide occlusion at NBD1 share a common step that occurs after the simple association with nucleotide.
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ABCC7 p.Lys464Ala 12939393:234:25
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235 The K464A Mutation Virtually Eliminates the Vi-dependent Slowing of CFTR Channel Closing Unlike the slow decline of roughly half of the WT CFTR current (Fig. 4, above), the macroscopic current flowing through K464A channels activated by PKA, MgATP, and Vi decayed relatively rapidly upon nucleotide withdrawal (Fig. 8 C).
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ABCC7 p.Lys464Ala 12939393:235:4
status: NEW
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ABCC7 p.Lys464Ala 12939393:235:209
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236 The current relaxation after exposure to Vi had a double exponential time course (smooth fit line, Fig. 8 C, center): most of the current decayed rapidly (␶fast ϭ 0.9 Ϯ 0.1 s, n ϭ 10) with a time constant like that of closing (␶b ϭ 620 Ϯ 58 ms, n ϭ 24; Vergani et al., 2003) of K464A channels exposed to just PKA and 5 mM MgATP, indicating that the majority of K464A CFTR channels did not respond to the presence of Vi.
X
ABCC7 p.Lys464Ala 12939393:236:328
status: NEW
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ABCC7 p.Lys464Ala 12939393:236:411
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250 K464A CFTR, mutated at the Walker A lysine in NBD1, binds but does not occlude micromolar concentrations of 8-N3ATP, in accord with our conclusion from analyses of channel gating that the mutation lowers the apparent affinity for nucleotide interactions required for the transition to the channel open-burst state.
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ABCC7 p.Lys464Ala 12939393:250:0
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257 Mutation K464A in CFTR impairs occlusion at 30ЊC, but not binding at 0ЊC, at low [nucleotide], and disrupts Vi-induced stabilization of open burst state.
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ABCC7 p.Lys464Ala 12939393:257:9
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258 (A, left) Membranes of oocytes expressing WT or K464A CFTR (without Flag tags) were run on SDS-PAGE gels, transferred to nitrocellulose membranes, and blotted with anti-R-domain antibody.
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ABCC7 p.Lys464Ala 12939393:258:48
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259 WT CFTR was expressed at least twice as well as K464A CFTR in this batch of oocytes (arrow marks mature fully-glycosylated CFTR; lower, sharper band is core-glycosylated CFTR).
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ABCC7 p.Lys464Ala 12939393:259:48
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261 Twice as much membrane was used for K464A samples as for WT samples.
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ABCC7 p.Lys464Ala 12939393:261:36
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262 (B, left) Immunoblots of membranes from Flag-WTand Flag-K464A-expressing oocytes (the Flag tags facilitated immunoprecipitation to enhanced signal-to-noise ratio, as membranes were not washed before photocrosslinking) blotted with anti-R-domain antibody as in A.
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ABCC7 p.Lys464Ala 12939393:262:56
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263 The membranes contained about one third more WT than mutant K464A protein.
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ABCC7 p.Lys464Ala 12939393:263:60
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265 Approximately 30% more membrane was used for Flag-K464A samples as for Flag-WT samples.
X
ABCC7 p.Lys464Ala 12939393:265:50
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266 (C) Macroscopic current in an oocyte patch containing hundreds of K464A CFTR channels.
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ABCC7 p.Lys464Ala 12939393:266:66
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270 (D and E) Mean fit parameters for the time constant (D) and fractional amplitude (E) of the slow component of current decay after activation by 5 mM MgATP plus 300 nM PKA without (white bars) or with 5 mM Vi (black bars) for WT (n ϭ 19) or K464A (n ϭ 10).
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ABCC7 p.Lys464Ala 12939393:270:246
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299 Second, purified NBD1 mutant, K464A, CFTR was reported to hydrolyze MgATP at a maximal rate 10-20-fold lower than that of wild-type CFTR, whereas the equivalent mutation in NBD2, K1250A, essentially abolished hydrolysis (Ramjeesingh et al., 1999).
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ABCC7 p.Lys464Ala 12939393:299:30
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300 Unless the specific activity of that K464A CFTR was greatly underestimated (due to unrecognized nonfunctional K464A protein), if NBD1 is essentially catalytically inactive in intact CFTR as we propose, a possible explanation for the reduced hydrolysis by K464A CFTR is that this mutation somehow impairs MgATP hydrolysis at the NBD2 catalytic site.
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ABCC7 p.Lys464Ala 12939393:300:37
status: NEW
X
ABCC7 p.Lys464Ala 12939393:300:110
status: NEW
X
ABCC7 p.Lys464Ala 12939393:300:255
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301 Gating measurements offer no support for this possibility, as the K464A mutation little affects normal CFTR-channel gating (Carson et al., 1995; Gunderson and Kopito, 1995; Powe et al., 2002; Vergani et al., 2003) other than reducing the apparent affinity for MgATP (Vergani et al., 2003).
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ABCC7 p.Lys464Ala 12939393:301:66
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303 Although this destabilization could reflect loss of an allosteric influence of the wild-type NBD1 catalytic site on the NBD2 catalytic site, if transition to the open burst state involves formation of an NBD1/NBD2 dimer with interfacial catalytic sites (Vergani et al., 2003), then the K464A mutation could act locally within the interface to reduce stability of the NBD dimer.
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ABCC7 p.Lys464Ala 12939393:303:286
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PMID: 14685259 [PubMed] Lewis HA et al: "Structure of nucleotide-binding domain 1 of the cystic fibrosis transmembrane conductance regulator."
No. Sentence Comment
42 A mutated version, K464A, which was expected to have reduced ATP binding, was also cloned and purified in the same manner and was used for ATP-binding measurements (see below).
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ABCC7 p.Lys464Ala 14685259:42:19
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149 ATP binding was significantly reduced by the K464A mutation, presumably because electrostatic interactions with the band g-phosphates of ATP (Figure 4A) are lost.
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ABCC7 p.Lys464Ala 14685259:149:45
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201 Wild type (K), K464A mutant (J), and ATP binding to the filters in the absence of protein (.)
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ABCC7 p.Lys464Ala 14685259:201:15
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PMID: 14745501 [PubMed] Callebaut I et al: "Nucleotide-binding domains of human cystic fibrosis transmembrane conductance regulator: detailed sequence analysis and three-dimensional modeling of the heterodimer."
No. Sentence Comment
235 These results are in agreement with the recent work of Aleksandrov et al. [54] with the Walker A lysine mutants K464A and K1250A, with the finding that NBD2 is a site of rapid nucleotide turnover, while NBD1 is a site of stable nucleotide interaction.
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ABCC7 p.Lys464Ala 14745501:235:112
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PMID: 15284228 [PubMed] Kidd JF et al: "A heteromeric complex of the two nucleotide binding domains of cystic fibrosis transmembrane conductance regulator (CFTR) mediates ATPase activity."
No. Sentence Comment
188 Mutation of the canonical Walker A lysine in either NBD1 (K464A, targeting Site A) or NBD2 (K1250A, targeting Site B) decreased ATPase activity of the whole protein by greater than 50% (39).
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ABCC7 p.Lys464Ala 15284228:188:58
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193 Our data suggest that the nonconventional site to which Lys464 contributes (Site A) also participates in the overall activity, since the K464A mutation causes a significant, albeit partial, decrease in function of the full-length protein.
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ABCC7 p.Lys464Ala 15284228:193:137
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PMID: 15623556 [PubMed] Berger AL et al: "Normal gating of CFTR requires ATP binding to both nucleotide-binding domains and hydrolysis at the second nucleotide-binding domain."
No. Sentence Comment
6 We also studied mutations of the conserved Walker A lysine residues (K464A and K1250A) that prevent hydrolysis.
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ABCC7 p.Lys464Ala 15623556:6:69
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71 The 6% gels revealed that CFTR-A462F and -K464A produced little band C protein, whereas other variants produced predominantly the band C form.
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ABCC7 p.Lys464Ala 15623556:71:42
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123 In CFTR, it has been reported that the K1250A and K464A mutations prevented [␣-32 P]8-N3-ATP photolabeling of the respective NBD (14, 15), whereas another study found that K464A did not prevent [␣-32 P]8-N3-ATP NBD1 photolabeling (36).
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ABCC7 p.Lys464Ala 15623556:123:50
status: NEW
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ABCC7 p.Lys464Ala 15623556:123:179
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124 We found that neither the K1250A nor K464A mutations prevented [␣-32 P]8-N3-ATP photolabeling of the NBDs (Fig. 3A).
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ABCC7 p.Lys464Ala 15623556:124:37
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132 (A) Autoradiogram of [␣-32P]8-N3-ATP labeling of CFTR-K464A and K1250A; labeling of both NBDs was observed for each mutant.
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ABCC7 p.Lys464Ala 15623556:132:61
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164 We found that the K464A mutation did not prevent [␣-32 P]8-N3-ATP photolabeling of NBD1 or NBD2 (Fig. 3A), a finding consistent with some (36) but not all earlier work (14, 15).
X
ABCC7 p.Lys464Ala 15623556:164:18
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165 Our finding indicates that ATP can bind NBD1 bearing the K464A mutation, although for the reasons described above, the ATP binding affinity might have been reduced.
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ABCC7 p.Lys464Ala 15623556:165:57
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166 We reasoned that if ATP binds CFTR-K464A to increase opening, then NEM modification of A462C͞K464A should block binding and reduce activity.
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ABCC7 p.Lys464Ala 15623556:166:35
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167 On the other hand, if the K464A mutation prevents ATP binding (contrary to our labeling results), then NEM modification should have no additional effect on current.
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ABCC7 p.Lys464Ala 15623556:167:26
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169 Therefore, we conclude that ATP binding to NBD1 played an important role in channel activity even when it contained the K464A mutation.
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ABCC7 p.Lys464Ala 15623556:169:120
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172 The S1248F mutation will block NBD2 ATP binding, thereby limiting ATP interactions to NBD1, and the K464A mutation will prevent NBD1 ATP hydrolysis.
X
ABCC7 p.Lys464Ala 15623556:172:100
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177 Thus, when ATP binding to NBD2 was eliminated, we found that the K464A mutation had little effect on gating.
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ABCC7 p.Lys464Ala 15623556:177:65
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205 Third, earlier observations showed that the K464A mutation, which blocks hydrolysis, had relatively minor effects on CFTR gating (16-19, 21).
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ABCC7 p.Lys464Ala 15623556:205:44
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207 For example, our results and those of Basso et al. (36) showed that [␣-32 P]8-N3-ATP labeled the K464A NBD1, although perhaps with a reduced affinity, whereas Aleksandrov et al. (14, 15) reported that it ablated labeling.
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ABCC7 p.Lys464Ala 15623556:207:104
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PMID: 15767296 [PubMed] Bompadre SG et al: "CFTR gating II: Effects of nucleotide binding on the stability of open states."
No. Sentence Comment
11 This binding site likely resides in the NH2-terminal nucleotide binding domain (NBD1) because introducing the K464A mutation, which decreases ATP binding affinity at NBD1, into E1371S-CFTR shortens the relaxation time constant.
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ABCC7 p.Lys464Ala 15767296:11:110
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35 Previous studies suggested that ATP hydrolysis at NBD1 was involved in the opening of the channel since mutations of the Walker A lysine at NBD1 (e.g., K464A) decrease the channel opening rate (Carson et al., 1995; Gunderson and Kopito, 1995; cf.
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ABCC7 p.Lys464Ala 15767296:35:152
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37 However, Powe et al. (2002) reexamined the gating kinetics of K464A mutant CFTR and found little difference in the opening rate between this mutant and WT-CFTR.
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ABCC7 p.Lys464Ala 15767296:37:62
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58 Similarly, the 0.9-kb PflMI-EcoRV fragments were used to replace the corresponding ones in pcDNA 3.1 WT-CFTR or pcDNA 3.1 K464A-CFTR (Powe et al., 2002) to generate pcDNA3.1 D1370N, pcDNA 3.1 E1371S, and pcDNA3.1 K464A/ E1371S CFTR constructs.
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ABCC7 p.Lys464Ala 15767296:58:122
status: NEW
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ABCC7 p.Lys464Ala 15767296:58:213
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247 Current Relaxations of the K464A/E1371S Mutant According to the most recent model (Scheme 2 in the accompanying paper) for CFTR gating (Vergani et al., 2003), NBD1 has little role in the gating transitions since the off rate is extremely slow, and ATP binding at NDB2 precedes channel opening.
X
ABCC7 p.Lys464Ala 15767296:247:27
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262 The K464A mutation shortens the locked-open time of E1371S-CFTR.
X
ABCC7 p.Lys464Ala 15767296:262:4
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263 (A) Sample trace of K464A/E1371S-CFTR channels in the presence of 1 mM ATP ϩ PKA.
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ABCC7 p.Lys464Ala 15767296:263:20
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267 (C) Sample trace of K464A/E1371S-CFTR channels in the presence of 10 ␮M ATP (blue curve).
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ABCC7 p.Lys464Ala 15767296:267:20
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273 Since the K464 mutation has a mild trafficking defect (Cheng et al., 1990; unpublished data), and ⌬R-CFTR already suffers from low expression, we decided to make the K464A/E1371S double mutant construct in the WT background.
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ABCC7 p.Lys464Ala 15767296:273:173
status: NEW
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275 The current decay of the K464A/E1371S-CFTR channel currents is indeed faster than that of E1371S-CFTR, resulting in a shorter relaxation time constant (19.60 Ϯ 0.01 s) upon washout of 1 mM ATP (Fig. 10 B).
X
ABCC7 p.Lys464Ala 15767296:275:25
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276 This relaxation time constant is even shorter when the K464A/E1371S-CFTR channel is opened with 10 ␮M ATP (13.95 Ϯ 0.02 s).
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ABCC7 p.Lys464Ala 15767296:276:55
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277 Since the number of K464A/E1371S-CFTR channels is relatively low due to a moderate trafficking defect, it is easier to observe microscopic channel behavior at 10 ␮M ATP (Fig. 10 C).
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ABCC7 p.Lys464Ala 15767296:277:20
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278 As shown previously for ⌬R/E1371S-CFTR (Fig. 5), the current trace reveals that K464A/E1371S-CFTR channels also exhibit numerous brief openings that last for tens to hundreds of milliseconds in the presence of 10 ␮M ATP.
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ABCC7 p.Lys464Ala 15767296:278:87
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366 Powe et al. (2002) showed that the K464A mutation shortens the open time by 40% at high [ATP].
X
ABCC7 p.Lys464Ala 15767296:366:35
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367 Interestingly, introducing the K464A mutations into the K1250A construct significantly decreases the locked-open time (Powe et al., 2002; Vergani et al., 2003).
X
ABCC7 p.Lys464Ala 15767296:367:31
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368 An equivalent observation is also made in the current report for K464A/E1371S mutants.
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ABCC7 p.Lys464Ala 15767296:368:65
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371 As mentioned above, Powe et al. (2002) showed that the K464A mutant exhibits a normal opening rate despite a lower ATP binding affinity at NBD1 for this mutant.
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ABCC7 p.Lys464Ala 15767296:371:55
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380 This hypothesis is based on the observation that mutations that affect ATP binding at NBD1 (e.g., K464A) alter the stability of the open state of K1250A, suggesting an interaction between two ATP-binding sites.
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ABCC7 p.Lys464Ala 15767296:380:98
status: NEW
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405 Although we proposed that ATP binding at NBD2 plays a critical role in channel opening (see above), this idea is based more on default since we observed that the K464A mutation, which decreases ATP binding affinity at NBD1 (Basso et al., 2003), does not affect the opening rate (Powe et al., 2002).
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ABCC7 p.Lys464Ala 15767296:405:162
status: NEW
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PMID: 16223764 [PubMed] Zhou Z et al: "High affinity ATP/ADP analogues as new tools for studying CFTR gating."
No. Sentence Comment
220 Our earlier studies show that a mutation (i.e. K464A) that causes a decrease of ATP binding affinity at the NBD1 site (Basso et al. 2003) does not affect the opening rate or the ATP dose-response relationship (Powe et al. 2002; cf. Vergani et al. 2003), suggesting ATP binding at the NBD1 site may not be absolutely required for channel opening (also see Bompadre et al. 2005b).
X
ABCC7 p.Lys464Ala 16223764:220:47
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222 The proposition that P-ATP acts on the NBD1 site to modulate channel closing is also based on our earlier studies with the K464A mutant.
X
ABCC7 p.Lys464Ala 16223764:222:123
status: NEW
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223 Although this mutation does not affect channel opening, K464A-CFTR exhibits a shorter open time (Powe et al. 2002).
X
ABCC7 p.Lys464Ala 16223764:223:56
status: NEW
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224 In addition, K464A mutation decreases the locked open time of hydrolysis-deficient mutants K464A/K1250A and K464A/E1371S (Powe et al. 2002; Vergani et al. 2003; Bompadre et al. 2005b), supporting the idea that the strength of ligand binding at the NBD1 site affects the stability of the open state.
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ABCC7 p.Lys464Ala 16223764:224:13
status: NEW
X
ABCC7 p.Lys464Ala 16223764:224:91
status: NEW
X
ABCC7 p.Lys464Ala 16223764:224:108
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PMID: 16227620 [PubMed] Zhang ZR et al: "State-dependent chemical reactivity of an engineered cysteine reveals conformational changes in the outer vestibule of the cystic fibrosis transmembrane conductance regulator."
No. Sentence Comment
6 In contrast, modification was faster in R334C/K464A-CFTR channels, which exhibit prolonged interburst closed states.
X
ABCC7 p.Lys464Ala 16227620:6:46
status: NEW
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45 R334C-, R334C/ K464A-, and R334C/K1250A-CFTR channels were activated by excision into intracellular solution containing 300 mM NMDG-Cl, 1.1 mM MgCl2, 2 mM Tris-EGTA, 1 mM MgATP, 10 mM TES (pH 7.4), 50 units/ml PKA.
X
ABCC7 p.Lys464Ala 16227620:45:15
status: NEW
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145 Mutation K464A in NBD1 leads to a great reduction in the channel opening rate.
X
ABCC7 p.Lys464Ala 16227620:145:9
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146 We studied outside-out macropatches from oocytes expressing R334C/K1250A- or R334C/K464A-CFTR to determine the effects of these gating domain mutations on the kinetics of modification, using experimental procedures similar to those described above.
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ABCC7 p.Lys464Ala 16227620:146:83
status: NEW
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165 MTSET؉ -induced modification of R334C/K1250A-CFTR and R334C/ K464A-CFTR.
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ABCC7 p.Lys464Ala 16227620:165:67
status: NEW
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166 Shown are outside-out macropatches from oocytes expressing either R334C/K1250A-CFTR (A and C) or R334C/K464A-CFTR (B).
X
ABCC7 p.Lys464Ala 16227620:166:103
status: NEW
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171 In contrast, the kinetics of modification of R334C/K464A-CFTR by MTSETϩ were fit best with a first-order exponential function, with ␶ ϭ 1.92 s in this experiment.
X
ABCC7 p.Lys464Ala 16227620:171:51
status: NEW
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191 Therefore, we recorded from giant outside-out patches pulled from oocytes expressing R334C/ K464A-CFTR, which would reduce Po considerably by prolonging the interburst closed durations (21-23) (Fig. 5B).
X
ABCC7 p.Lys464Ala 16227620:191:92
status: NEW
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192 The macroscopic current of R334C/K464A-CFTR was increased rapidly upon application of 10 ␮M MTSETϩ .
X
ABCC7 p.Lys464Ala 16227620:192:33
status: NEW
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194 The modification rate coefficient for MTSETϩ in R334C/K464A-CFTR was 41,864 Ϯ 4,229 M -1 s-1 , which is roughly 2-fold higher than that in R334C-CFTR under identical conditions (p ϭ 0.007).
X
ABCC7 p.Lys464Ala 16227620:194:60
status: NEW
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234 Under conditions that decrease channel activity (R334C/K464A-CFTR), the rate of modification was increased dramatically.
X
ABCC7 p.Lys464Ala 16227620:234:55
status: NEW
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PMID: 16246032 [PubMed] Vergani P et al: "Control of the CFTR channel's gates."
No. Sentence Comment
39 To determine which of the two composite sites in the NBD1-NBD2 dimer is involved in channel opening, we introduced mutations at residues seen to interact directly with the bound nucleotide in the solved crystal structures, in the head of either NBD1 [K464A (Lys464 → Ala)] or NBD2 (D1370N).
X
ABCC7 p.Lys464Ala 16246032:39:251
status: NEW
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PMID: 16361259 [PubMed] Gross CH et al: "Nucleotide-binding domains of cystic fibrosis transmembrane conductance regulator, an ABC transporter, catalyze adenylate kinase activity but not ATP hydrolysis."
No. Sentence Comment
240 Next, we wanted to examine three key CFTR residues in mNBD1 (K464A, G551D, and ⌬F508) to determine what effect these mutations had on their ability to form homodimers or alter AK activity.
X
ABCC7 p.Lys464Ala 16361259:240:61
status: NEW
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241 All three mutant proteins overexpressed, however, during their purifications two mutants (⌬F508 and K464A) were problematic.
X
ABCC7 p.Lys464Ala 16361259:241:107
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244 Because of the chaperone contamination we were forced to abandon our analysis of the K464A and ⌬F508 proteins.
X
ABCC7 p.Lys464Ala 16361259:244:85
status: NEW
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PMID: 16554808 [PubMed] Gadsby DC et al: "The ABC protein turned chloride channel whose failure causes cystic fibrosis."
No. Sentence Comment
139 But they are 11 22 11 2 a b ATP ATP ATP ATP C2 Open Concentration of MgATP in µM Relativeopeningrate K1250A K464A C1C0 101 1.0 WT K464A K1250A 0.5 0 102 103 104 Figure 3 | The conserved Walker A lysine is critical for ATP binding in each NBD.
X
ABCC7 p.Lys464Ala 16554808:139:113
status: NEW
X
ABCC7 p.Lys464Ala 16554808:139:135
status: NEW
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144 ATP first binds to the non-mutant site, that is to the NBD2 site (blue) in K464A channels (upper row), but to the NDB1 site (green) in K1250A channels (lower row).
X
ABCC7 p.Lys464Ala 16554808:144:75
status: NEW
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PMID: 17700963 [PubMed] Bompadre SG et al: "Cystic fibrosis transmembrane conductance regulator: a chloride channel gated by ATP binding and hydrolysis."
No. Sentence Comment
133 [51] showed that, in contrast to previous studies[25,27] , the K464A mutation does not affect the channel opening rate, but it shortens the mean open time.
X
ABCC7 p.Lys464Ala 17700963:133:63
status: NEW
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135 In addition, introducing the K464A mutation into the K1250A mutant whose ATP hydrolysis at NBD2 is diminished[25,27] dramatically shortens the stable open state seen in the K1250A mutation (Fig.3).
X
ABCC7 p.Lys464Ala 17700963:135:29
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160 This conclusion was reached after finding that the ATP dose-response relationships of the Walker A mutants K464A and K1250A and the Walker B mutant D1370N were shifted towards higher [ATP] com- paredto theATPdose-response curvefor wild-typechannels.
X
ABCC7 p.Lys464Ala 17700963:160:107
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164 The K464A mutation shortens current relaxation of K1250A-CFTR.
X
ABCC7 p.Lys464Ala 17700963:164:4
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165 A: Representative traces for the current relaxation of K1250A-CFTR and K464A/K1250A-CFTR upon withdrawal of ATP and PKA.
X
ABCC7 p.Lys464Ala 17700963:165:71
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183 This same effect was observed previously for K464A by Powe et al[51] .
X
ABCC7 p.Lys464Ala 17700963:183:45
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PMID: 18391167 [PubMed] Chen TY et al: "CLC-0 and CFTR: chloride channels evolved from transporters."
No. Sentence Comment
732 They showed that purified K464A-CFTR exhibits a nearly identical opening rate as wild-type channels at 1 mM ATP.
X
ABCC7 p.Lys464Ala 18391167:732:26
status: NEW
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734 (237) not only confirmed this result, but also showed that the relationship between [ATP] and the opening rate is not affected by the K464A mutation, thus casting serious doubt on the role of ATP binding at ABP1 in channel opening.
X
ABCC7 p.Lys464Ala 18391167:734:134
status: NEW
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794 Although the mutations that presumably decrease ATP affinity at the ABP1 (K464A and W401G) have questionable effects on the ability of ATP to increase the opening rate of CFTR, both mutants show a shortened open time, suggesting a destabilization of the open state by the mutations (237, 360).
X
ABCC7 p.Lys464Ala 18391167:794:74
status: NEW
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795 The effect of K464A on the open time was seen even in early studies (42, 251).
X
ABCC7 p.Lys464Ala 18391167:795:14
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796 The shortened opening bursts of K464A-CFTR, compared with wild-type channels, are visually discernable in Ramjeesingh et al.
X
ABCC7 p.Lys464Ala 18391167:796:32
status: NEW
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800 (324) reported that the open time for K464A-CFTR is not significantly different from that of wild-type channels.
X
ABCC7 p.Lys464Ala 18391167:800:38
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802 It is, however, important to note that the K464A mutation does shorten the locked open time of hydrolysis-deficient mutants in two different studies (237, 324), suggesting that this effect on the open time is not due to a potential allosteric action of the mutations at the ABP1 on the ATP hydrolysis rate at the ABP2, which normally determines the rate of channel closing.
X
ABCC7 p.Lys464Ala 18391167:802:43
status: NEW
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804 Thus a reduction of the free energy of ATP binding could be reported as a decreased open-time constant as seen with the K464A and W401G mutants.
X
ABCC7 p.Lys464Ala 18391167:804:120
status: NEW
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PMID: 18957373 [PubMed] Muallem D et al: "Review. ATP hydrolysis-driven gating in cystic fibrosis transmembrane conductance regulator."
No. Sentence Comment
61 For both mutants (K464A in site 1 and D1370N in site 2), opening rate was reduced at low [ATP], but fast opening could be restored by increasing [ATP] (figure 2b, open symbols).
X
ABCC7 p.Lys464Ala 18957373:61:18
status: NEW
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86 (b) Hyperbolic relationship between [ATP] and opening rates (apparent dissociation constants are 56G5, 807G185, 391G118 mM for WT (filled circles), K464A (open triangles) and D1370N (open squares), respectively).
X
ABCC7 p.Lys464Ala 18957373:86:148
status: NEW
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84 (b) Hyperbolic relationship between [ATP] and opening rates (apparent dissociation constants are 56G5, 807G185, 391G118 mM for WT (filled circles), K464A (open triangles) and D1370N (open squares), respectively).
X
ABCC7 p.Lys464Ala 18957373:84:148
status: NEW
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PMID: 19332621 [PubMed] Tsai MF et al: "State-dependent modulation of CFTR gating by pyrophosphate."
No. Sentence Comment
433 Echoing this observation, the lock-open duration of MgPPi is reduced by mutations that decrease the ATP binding affinity to NBD1, K464A, and W401G, but can be partially restored by a high affinity ATP analogue, P-ATP (unpublished data; compare Powe et al., 2002; Zhou et al., 2006).
X
ABCC7 p.Lys464Ala 19332621:433:130
status: NEW
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PMID: 19837660 [PubMed] Chen JH et al: "Direct sensing of intracellular pH by the cystic fibrosis transmembrane conductance regulator (CFTR) Cl- channel."
No. Sentence Comment
6 Because these data suggest that pHi modulates the interaction of MgATP with the nucleotide-binding domains (NBDs) of CFTR, we examined the pHi dependence of site-directed mutations in the two ATP-binding sites of CFTR that are located at the NBD1:NBD2 dimer interface (site 1: K464A-, D572N-, and G1349D-CFTR; site 2: G551D-, K1250M-, and D1370N-CFTR).
X
ABCC7 p.Lys464Ala 19837660:6:277
status: NEW
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47 To study the CFTR variants K464A, D572N, and D1370N, we employed the vaccinia virus/bacteriophage T7 hybrid expression system to transiently express CFTR variants in HeLa cells as described previously (17, 18).
X
ABCC7 p.Lys464Ala 19837660:47:27
status: NEW
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229 At pHi 7.3, bursts of K464A-CFTR channel openings were separated by prolonged channel closures, whereas dramatically prolonged bursts of K1250M-CFTR channel openings were separated by very long-lived channel closures (Figs. 7, E and G, and 8).
X
ABCC7 p.Lys464Ala 19837660:229:22
status: NEW
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230 Although Po values of K464A-CFTR were less than those of wild-type CFTR at all pHi values tested, the effects of acidic and alkaline pHi on K464A- and wild-type CFTR were similar (Fig. 7, E and F).
X
ABCC7 p.Lys464Ala 19837660:230:22
status: NEW
X
ABCC7 p.Lys464Ala 19837660:230:140
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231 This suggests that K464A-CFTR does not change the pHi sensitivity of CFTR.
X
ABCC7 p.Lys464Ala 19837660:231:19
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246 A, C, E, and G, representative recordings show the effects of pHi on the activity of G551D-, G1349D-, K464A-, and K1250M-CFTR Cl-channels in the presence of ATP (1 mM).
X
ABCC7 p.Lys464Ala 19837660:246:102
status: NEW
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247 Dotted lines indicate where channels are closed, and downward deflections correspond to channel openings. B, D, F, and H, effects of pHi on the NPo of G551Dand G1349D-CFTR and Po of K464A- and K1250M-CFTR.
X
ABCC7 p.Lys464Ala 19837660:247:182
status: NEW
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311 Third, Hϩ ions potentiate the gating behavior of CFTR constructs bearing site-directed mutations in ATP-binding site 1 (K464A- and D572N-CFTR).
X
ABCC7 p.Lys464Ala 19837660:311:126
status: NEW
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PMID: 19966305 [PubMed] Csanady L et al: "Strict coupling between CFTR's catalytic cycle and gating of its Cl- ion pore revealed by distributions of open channel burst durations."
No. Sentence Comment
7 We show that the wild-type CFTR channel gating cycle is essentially irreversible and tightly coupled to the ATPase cycle, and that this coupling is completely destroyed by the NBD2 Walker B mutation D1370N but only partially disrupted by the NBD1 Walker A mutation K464A.
X
ABCC7 p.Lys464Ala 19966305:7:265
status: NEW
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60 (B-D) Histograms of open burst durations for prephosphorylated WT (B), D1370N (C), and K464A (D) CFTR channels; 30-s segments of representative single-channel current recordings are shown above each panel.
X
ABCC7 p.Lys464Ala 19966305:60:87
status: NEW
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65 ATP was 2 mM for WT and D1370N, but 5 mM for K464A.
X
ABCC7 p.Lys464Ala 19966305:65:45
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66 Burst Duration Distribution of K464A Mutant Reveals Profoundly Altered Gating Mechanism.
X
ABCC7 p.Lys464Ala 19966305:66:31
status: NEW
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67 Although the K464A mutation lowers CFTR ATPase turnover rate ~10-fold (21), τb was essentially unaffected by this mutation (Fig. 1D Inset).
X
ABCC7 p.Lys464Ala 19966305:67:13
status: NEW
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68 However, the shape of the distribution of K464A burst durations (Fig. 1D; reconstructed from 2,327 events) clearly differed from that of WT CFTR.
X
ABCC7 p.Lys464Ala 19966305:68:42
status: NEW
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70 However, because the K464A mutant does carry out some ATP hydrolysis, albeit slowly (21), we also evaluated a partially hydrolytic mechanism by leaving k-1 in scheme 2 as a free parameter.
X
ABCC7 p.Lys464Ala 19966305:70:21
status: NEW
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73 The rate estimates from this fit suggest that in K464A CFTR, the rate of the ATP hydrolysis step (k1) is slowed by only ~4-fold compared with WT, consistent with the fact that this mutation is not in the composite NBD2 site, where ATP hydrolysis occurs.
X
ABCC7 p.Lys464Ala 19966305:73:49
status: NEW
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74 But this analysis also indicates that the K464A mutation greatly destabilizes the prehydrolytic dimer (k-1 is increased).
X
ABCC7 p.Lys464Ala 19966305:74:42
status: NEW
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84 Acceleration of Nonhydrolytic Channel Closure by the K464A Mutation Supports Microscopic Burst Duration Analysis.
X
ABCC7 p.Lys464Ala 19966305:84:53
status: NEW
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85 Assuming k-1 = 0.22 s-1 for WT, the ML fit of scheme 2 to the K464A burst distribution (Fig. 1D) suggests that rate k-1 is increased by ~15-fold in K464A CFTR.
X
ABCC7 p.Lys464Ala 19966305:85:62
status: NEW
X
ABCC7 p.Lys464Ala 19966305:85:148
status: NEW
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86 This conclusion from the distribution of microscopic burst durations is corroborated by the fact that closure of nonhydrolytic CFTR mutants and of WT channels "locked" in open bursts by nonhydrolyzable ATP analogs or by orthovanadate is greatly accelerated by the K464A mutation (16, 18, 30, 32).
X
ABCC7 p.Lys464Ala 19966305:86:264
status: NEW
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87 For instance, closure of the catalytically incompetent NBD2 Walker A mutant K1250A is accelerated ~10-fold in the double-mutant K464A/K1250A, as reported by the rate of macroscopic current decay upon ATP removal (Fig. 2B; red line is a single-exponential fit; Fig. 2C, red bar).
X
ABCC7 p.Lys464Ala 19966305:87:128
status: NEW
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97 Slow nonhydrolytic closing rate and its acceleration by the K464A mutation.
X
ABCC7 p.Lys464Ala 19966305:97:60
status: NEW
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98 (A and B) Macroscopic currents of prephosphorylated K1250A (A) and K464A/K1250A (B) CFTR channels were activated by application of 10 mM ATP.
X
ABCC7 p.Lys464Ala 19966305:98:67
status: NEW
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100 (C) Mean (±SEM) closing rates estimated as the inverses of the current relaxation time constants (τrelax), for K1250A (blue) and K464A/K1250A (red).
X
ABCC7 p.Lys464Ala 19966305:100:140
status: NEW
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104 Fig. 4 A-C compares such average parameters for fully (navy blue) and partially (royal blue) phosphorylated WT, and partially phosphorylated D1370N (green) and K464A (red) CFTR channels.
X
ABCC7 p.Lys464Ala 19966305:104:160
status: NEW
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105 Consistent with previous reports, for D1370N CFTR channels gating in near-saturating ATP (2 mM) (16), τb is ~4-fold longer than, but τib is like, that of WT (Fig. 4 B and C, green bars) (cf. refs. 9, 16, 30), whereas for prephosphorylated K464A CFTR channels in saturating ATP (5 mM) (16), τb is comparable to, but τib is at least ~2-fold longer than, that of WT (Fig. 4 B and C, red bars) (9, 14, 16 but cf. ref. 32).
X
ABCC7 p.Lys464Ala 19966305:105:251
status: NEW
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115 However, the fit for K464A provides additional support for this assignment.
X
ABCC7 p.Lys464Ala 19966305:115:21
status: NEW
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117 Thus, the set k1' = 15.4 s-1 , k2' = 4.30 s-1 , k-1' = 3.39 s-1 fits the observed pdf for K464A just as well as the set displayed in Fig. 4E (k1 = 0.91 s-1 , k2 = 18.8 s-1 , k-1 = 3.39 s-1 ).
X
ABCC7 p.Lys464Ala 19966305:117:90
status: NEW
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118 But this alternative set can be ruled out as it would yield an essentially hydrolytic mechanism for K464A (with a coupling ratio of ~82%) in contradiction of the observed severe defect in ATPase turnover rate (21).
X
ABCC7 p.Lys464Ala 19966305:118:100
status: NEW
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120 The NBD1 Walker A mutant K464A has received much previous attention.
X
ABCC7 p.Lys464Ala 19966305:120:25
status: NEW
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121 That this mutation, in a catalytically inactive binding site (17, 18), affects channel gating only slightly (Fig. 4D; cf. refs. 16, 21, 32) contrasts with its substantial suppression of the rate of ATP hydrolysis of purified K464A CFTR protein (to <10% of WT) (21).
X
ABCC7 p.Lys464Ala 19966305:121:225
status: NEW
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122 The altered shape of the distribution of K464A burst durations (Fig. 1D) now provides a satisfying explanation for this dissociation between channel cycle time and ATPase rate.
X
ABCC7 p.Lys464Ala 19966305:122:41
status: NEW
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123 The ratio k1/(k1 + k-1) estimated from the scheme 2 fit (Fig.4E Left and Right, red bars) suggests that in K464A approximately one out of every five bursts proceeds through the normal irreversible hydrolytic pathway (Fig. 4F).
X
ABCC7 p.Lys464Ala 19966305:123:107
status: NEW
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124 This "coupling ratio" between channel opening and ATP hydrolysis of ~21% for K464A CFTR contrasts with that of ≥95% for WT channels (blue bars, Fig. 4E Left and Right and Fig. 4F).
X
ABCC7 p.Lys464Ala 19966305:124:77
status: NEW
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125 Because the cycle time of K464A channels is prolonged ~2-fold compared with WT (Fig. 4D), the predicted overall ATPase turnover rate is on the order of 10% of WT, which is in very reasonable agreement with the measured value (21).
X
ABCC7 p.Lys464Ala 19966305:125:26
status: NEW
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161 (A-D) Open probabilities (A), mean burst (B), and interburst (C) durations obtained from multichannel fits, and calculated channel cycle times (D) for fully (navy blue) and partially (royal blue) phosphorylated WT, and partially phosphorylated D1370N (green) and K464A (red) CFTR.
X
ABCC7 p.Lys464Ala 19966305:161:263
status: NEW
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162 [ATP] was 2 mM for WT and D1370N, but 5 mM for K464A.
X
ABCC7 p.Lys464Ala 19966305:162:47
status: NEW
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164 (E) ML estimates of rates k1 (Left), k2 (Center), and k-1 (Right) for fully (navy blue) and partially (royal blue) phosphorylated WT, and partially phosphorylated D1370N (green) and K464A (red) CFTR channels.
X
ABCC7 p.Lys464Ala 19966305:164:182
status: NEW
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169 Probabilities for exiting state O1 (Top Right) in either of two possible directions are printed in color for partially phosphorylated WT (blue), K464A (red), and D1370N (green).
X
ABCC7 p.Lys464Ala 19966305:169:145
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184 Therefore, although both methods yielded qualitatively similar results, we used the distributions obtained using method (i) for WT and K464A (Figs. 1 B and D, 3B, and 4), and that obtained using method (ii) for D1370N (Fig. 1C).
X
ABCC7 p.Lys464Ala 19966305:184:135
status: NEW
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PMID: 20667826 [PubMed] Thibodeau PH et al: "The cystic fibrosis-causing mutation deltaF508 affects multiple steps in cystic fibrosis transmembrane conductance regulator biogenesis."
No. Sentence Comment
200 Mutations of the Walker A lysine (K464A and K1250A in NBD1 and NBD2, respectively) have been shown to dramatically decrease ATP affinity (40).
X
ABCC7 p.Lys464Ala 20667826:200:34
status: NEW
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206 The NBD1 K464A mutation also failed to rescue ⌬F508 trafficking.
X
ABCC7 p.Lys464Ala 20667826:206:9
status: NEW
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207 However, when introduced into the wild type background, the K464A reduced CFTR maturation, as evidenced by a decrease in band C.
X
ABCC7 p.Lys464Ala 20667826:207:60
status: NEW
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280 B, mutation of the composite ATP-binding site in NBD1, K464A, adversely affects the trafficking of wild type CFTR.
X
ABCC7 p.Lys464Ala 20667826:280:55
status: NEW
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330 In contrast, the K464A NBD1 ATP-binding mutant decreased wild type CFTR maturation.
X
ABCC7 p.Lys464Ala 20667826:330:17
status: NEW
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PMID: 21419343 [PubMed] Khushoo A et al: "Ligand-driven vectorial folding of ribosome-bound human CFTR NBD1."
No. Sentence Comment
114 In addition, mutations that inhibit ATP binding to NBD1 in full-length CFTR (W401A, A462F, and K464A [Berger et al., 2005]) also inhibited binding to truncated NBD1 (Figures 5E and 5F).
X
ABCC7 p.Lys464Ala 21419343:114:95
status: NEW
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205 The CFP-NBD1 ATP-binding mutant contained W401A, A462F, and K464A mutations in the ATP-binding site as predicted by the crystal structure (2BBO).
X
ABCC7 p.Lys464Ala 21419343:205:60
status: NEW
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PMID: 21576373 [PubMed] Szollosi A et al: "Mutant cycles at CFTR's non-canonical ATP-binding site support little interface separation during gating."
No. Sentence Comment
59 A mutation in the conserved Walker A lysine of NBD1, K464A, reduced channel opening rate at low [ATP] (Vergani et al., 2003), suggesting that ATP binding at site 1 can be made rate limiting for channel opening.
X
ABCC7 p.Lys464Ala 21576373:59:53
status: NEW
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61 In other studies, neither the K464A mutation (Powe et al., 2002) nor mutation of an aromatic residue (W401), which is seen to stack against the adenine moiety of ATP in some crystals of CFTR NBD1 (Lewis et al., 2005, but cf.
X
ABCC7 p.Lys464Ala 21576373:61:30
status: NEW
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PMID: 9922375 [PubMed] Sheppard DN et al: "Structure and function of the CFTR chloride channel."
No. Sentence Comment
375 This is consistent with the finding that in the absence predicted to decrease the rate of hydrolysis at NBD1, for example, K464A and Q552A, would thus increase the in-of ATP, the channel does not open.
X
ABCC7 p.Lys464Ala 9922375:375:123
status: NEW
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PMID: 9922377 [PubMed] Gadsby DC et al: "Control of CFTR channel gating by phosphorylation and nucleotide hydrolysis."
No. Sentence Comment
558 First,be sequential, although the precise nature and mechanism of the ordering remain to be determined. In keeping with they noted that the opening rate of mutant K464A CFTR channels was only approximately twofold lower than thatthe proposed role of PKA-mediated phosphorylation, presumably largely within the R domain, in modulating the of wild-type CFTR, whereas the equivalent mutation in other nucleoside triphosphatases (NTPases) reduces thefunction of NBD2, it has recently been shown that neither AMP-PNP nor PPi (both of which are believed to bind hydrolysis rate by several orders of magnitude.
X
ABCC7 p.Lys464Ala 9922377:558:163
status: NEW
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560 Recent analyses of the dependence on temperature K464A in purified CFTR slows ATP hydrolysis only less than twofold (159).
X
ABCC7 p.Lys464Ala 9922377:560:49
status: NEW
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PMID: 9931011 [PubMed] Ramjeesingh M et al: "Walker mutations reveal loose relationship between catalytic and channel-gating activities of purified CFTR (cystic fibrosis transmembrane conductance regulator)."
No. Sentence Comment
21 While it was determined that the K464A mutation abrogated ATPase activity of the CFTR-NBF1 fusion protein (15), the effect of the K1250A mutation in the context of the CFTR-NBF2 fusion protein is not known.
X
ABCC7 p.Lys464Ala 9931011:21:33
status: NEW
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32 A small cassette containing the specific mutation, i.e., a BspE1/SphI fragment for the K464A mutation or a Pm1I/Tth111I fragment for the K1250A mutation was subcloned into a new pBQ6.2 and then sequenced to confirm the introduction of the mutations.
X
ABCC7 p.Lys464Ala 9931011:32:87
status: NEW
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33 Ultimately, K464A (as an XbaI/SphI fragment) or K1250A (as a Pm1I/Tth111I fragment) was subcloned into pBlueBac4 (Invitrogen, Carlsbad, CA) for baculovirus expression.
X
ABCC7 p.Lys464Ala 9931011:33:12
status: NEW
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123 Disruption of the Chloride Channel ActiVity of the Intact Purified CFTR Protein by Mutation of the Walker A Lysine in either NBF1 or NBF2. We assessed the consequences of each of the Walker lysine mutations, K464A and K1250A, on the chloride channel activity of CFTR using two assays.
X
ABCC7 p.Lys464Ala 9931011:123:208
status: NEW
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PMID: 9521779 [PubMed] Urbatsch IL et al: "Mutations in either nucleotide-binding site of P-glycoprotein (Mdr3) prevent vanadate trapping of nucleotide at both sites."
No. Sentence Comment
254 In the cystic fibrosis transmembrane conductance regulator (CFTR), mutations of the conserved Walker A lysine altered the conductive properties of the Cl- channel: the K464A mutation in NB1 decreased the frequency of channel openings, whereas K1250A or K1250M in NB2 prolonged the open state of the channel (59).
X
ABCC7 p.Lys464Ala 9521779:254:168
status: NEW
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PMID: 22303012 [PubMed] Wang W et al: "Alternating access to the transmembrane domain of the ATP-binding cassette protein cystic fibrosis transmembrane conductance regulator (ABCC7)."
No. Sentence Comment
52 These two reporter cysteine substitutions were combined with mutations in the NBDs that affect ATP-dependent channel gating: K464A (NBD1) and E1371Q (NBD2).
X
ABCC7 p.Lys464Ala 22303012:52:125
status: NEW
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53 As discussed in detail in our recent study (22), these NBD mutations are expected either to decrease (K464A) or increase (E1371Q) overall CFTR channel activity via well characterized effects on ATP-dependent channel gating.
X
ABCC7 p.Lys464Ala 22303012:53:102
status: NEW
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77 Specifically, following the lead of other groups (25, 26), we used the NBD1 mutation K464A to decrease overall channel activity, and the NBD2 mutation E1371Q to increase channel activity.
X
ABCC7 p.Lys464Ala 22303012:77:85
status: NEW
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78 Previously we showed that these mutations mimic the effects of decreasing channel activity with low cytoplasmic ATP concentrations (K464A) or by "locking" channels in the open state by treatment with 2 mM sodium pyrophosphate (E1371Q) (22).
X
ABCC7 p.Lys464Ala 22303012:78:132
status: NEW
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88 In both cases, the rate of modification by MTSES was significantly decreased by the K464A mutation and significantly increased by the E1371Q mutation, effects that are quantified in Fig. 1C.
X
ABCC7 p.Lys464Ala 22303012:88:84
status: NEW
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89 For modification of T338C, the mean modification rate constant was decreased ϳ2.4-fold in a K464A background and increased ϳ3.9-fold in E1371Q, whereas the modification rate constant for L102C was decreased by ϳ26% in K464A and increased ϳ2.0-fold in E1371Q.
X
ABCC7 p.Lys464Ala 22303012:89:98
status: NEW
X
ABCC7 p.Lys464Ala 22303012:89:236
status: NEW
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93 As shown in Fig. 2, application of a low concentration of Au(CN)2 - (2 ␮M) caused a rapid inhibition of current carried by both T338C and L102C.
X
ABCC7 p.Lys464Ala 22303012:93:84
status: NEW
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94 As with MTSES, the rate of modification by Au(CN)2 - was significantly decreased by the K464A mutation (by ϳ1.8-fold for T338C and ϳ3.4-fold for L102C) and significantly increased by the E1371Q mutation (by ϳ5.6-fold for T338C and ϳ1.8-fold for L102C), as well as by pyrophosphate treatment (by ϳ6.0-fold for T338C and ϳ2.0-fold for L102C; data not shown).
X
ABCC7 p.Lys464Ala 22303012:94:88
status: NEW
X
ABCC7 p.Lys464Ala 22303012:94:98
status: NEW
X
ABCC7 p.Lys464Ala 22303012:94:236
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99 Expression of all E1371Q-CFTR constructs led to the appearance of constitutive, cAMP-insensitive but GlyH-101-inhibited whole cell currents (supplemental Fig. S2).
X
ABCC7 p.Lys464Ala 22303012:99:94
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104 Fig. 4A shows examples of the rate of current inhibition in response to application of a common concentration of MTSES (1 ␮M) in T338C, T338C/K464A, and T338C/E1371Q.
X
ABCC7 p.Lys464Ala 22303012:104:149
status: NEW
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109 The decline in current amplitude following Au(CN)2 - application has been fitted by a single exponential function. C, average modification rate constants(k)forAu(CN)2 - ,calculatedfromfitstodatasuchasthoseshowninAandB.AsterisksindicateasignificantdifferencefromthecysteinemutantsT338C and L102C (black bars) (p Ͻ 0.02).
X
ABCC7 p.Lys464Ala 22303012:109:148
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110 Data are mean from three or four patches. Alternating Access Model of CFTR MARCH 23, 2012ȂVOLUME 287•NUMBER 13 JOURNAL OF BIOLOGICAL CHEMISTRY 10159 fication (Fig. 4B) suggests an increase of ó3.7-fold in T338C/ K464A and a dramatic decrease of ϳ35-fold in T338C/E1371Q compared with T338C alone.
X
ABCC7 p.Lys464Ala 22303012:110:231
status: NEW
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114 Quantification of the rate constant for modification (Fig. 5C) suggests, for modification of T338C, an increase of ϳ5.7-fold in K464A and a decrease of ϳ150-fold in E1371Q, and for modification of L102C, an increase of ϳ2.3-fold in K464A and a decrease of ϳ2.7-fold in E1371Q.
X
ABCC7 p.Lys464Ala 22303012:114:134
status: NEW
X
ABCC7 p.Lys464Ala 22303012:114:250
status: NEW
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116 Changing Patterns of Accessibility Suggest Marker Cysteine Residues "Switch Sides" of Membrane during Gating-The effects of NBD mutations on the rate of modification of T338C and L102C by internal cysteine-reactive reagents (estimated from experiments on inside-out membrane patches) and by external cysteine-reactive reagents (estimated from whole cell current recording experiments) are compared in Fig. 6.
X
ABCC7 p.Lys464Ala 22303012:116:69
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120 In each panel, it can be seen that the rate of modification by internal MTSES and Au(CN)2 - increases in the order K464A Ͻ Cys-less &#x3fd; E1371Q, whereas modification by extracellular MTSES (in T338C) and Au(CN)2 - shows the opposite pattern, K464A Ͼ Cys-less Ͼ E1371Q.
X
ABCC7 p.Lys464Ala 22303012:120:115
status: NEW
X
ABCC7 p.Lys464Ala 22303012:120:134
status: NEW
X
ABCC7 p.Lys464Ala 22303012:120:250
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123 Given the known effects of the K464A and E1371Q mutations on ATP-dependent channel gating, it seems reasonable to us to infer that the factor causing this movement from one side of the membrane to the other is channel gating: when the channel is closed (enriched in the K464A constructs), accessibility of these cysteines from the outside is increased, and when the channel is open (enriched in the E1371Q constructs), their accessibility from the inside is increased.
X
ABCC7 p.Lys464Ala 22303012:123:31
status: NEW
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ABCC7 p.Lys464Ala 22303012:123:270
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178 Each panel illustrates the change in modification rate constant for the same reporter cysteine (T338C in A and C, L102C in B and D) in three different backgrounds (K464A, Cys-less, and E1371Q), for modification by MTSES (A and B) or Au(CN)2 - (C and D) applied to the intracellular (●, inside) or extracellular (E, outside) side of the membrane.
X
ABCC7 p.Lys464Ala 22303012:178:164
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54 These two reporter cysteine substitutions were combined with mutations in the NBDs that affect ATP-dependent channel gating: K464A (NBD1) and E1371Q (NBD2).
X
ABCC7 p.Lys464Ala 22303012:54:125
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55 As discussed in detail in our recent study (22), these NBD mutations are expected either to decrease (K464A) or increase (E1371Q) overall CFTR channel activity via well characterized effects on ATP-dependent channel gating.
X
ABCC7 p.Lys464Ala 22303012:55:102
status: NEW
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80 Specifically, following the lead of other groups (25, 26), we used the NBD1 mutation K464A to decrease overall channel activity, and the NBD2 mutation E1371Q to increase channel activity.
X
ABCC7 p.Lys464Ala 22303012:80:85
status: NEW
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81 Previously we showed that these mutations mimic the effects of decreasing channel activity with low cytoplasmic ATP concentrations (K464A) or by "locking" channels in the open state by treatment with 2 mM sodium pyrophosphate (E1371Q) (22).
X
ABCC7 p.Lys464Ala 22303012:81:132
status: NEW
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126 In each panel, it can be seen that the rate of modification by internal MTSES and Au(CN)2 afa; increases in the order K464A b0d; Cys-less b0d; E1371Q, whereas modification by extracellular MTSES (in T338C) and Au(CN)2 afa; shows the opposite pattern, K464A b0e; Cys-less b0e; E1371Q.
X
ABCC7 p.Lys464Ala 22303012:126:121
status: NEW
X
ABCC7 p.Lys464Ala 22303012:126:263
status: NEW
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129 Given the known effects of the K464A and E1371Q mutations on ATP-dependent channel gating, it seems reasonable to us to infer that the factor causing this movement from one side of the membrane to the other is channel gating: when the channel is closed (enriched in the K464A constructs), accessibility of these cysteines from the outside is increased, and when the channel is open (enriched in the E1371Q constructs), their accessibility from the inside is increased.
X
ABCC7 p.Lys464Ala 22303012:129:31
status: NEW
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ABCC7 p.Lys464Ala 22303012:129:270
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185 Each panel illustrates the change in modification rate constant for the same reporter cysteine (T338C in A and C, L102C in B and D) in three different backgrounds (K464A, Cys-less, and E1371Q), for modification by MTSES (A and B) or Au(CN)2 afa; (C and D) applied to the intracellular (cf;, inside) or extracellular (E, outside) side of the membrane.
X
ABCC7 p.Lys464Ala 22303012:185:164
status: NEW
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PMID: 22234285 [PubMed] Wang W et al: "Conformational change opening the CFTR chloride channel pore coupled to ATP-dependent gating."
No. Sentence Comment
5 We also manipulated gating by introducing the mutations K464A (in NBD1) and E1371Q (in NBD2).
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ABCC7 p.Lys464Ala 22234285:5:56
status: NEW
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6 The rate of modification of Q98C and I344C by both MTSES and Au(CN)2 - was decreased by K464A and increased by E1371Q, whereas modification of K95C and V345C was not affected.
X
ABCC7 p.Lys464Ala 22234285:6:88
status: NEW
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54 In (D) channels also had the NBD1 mutation K464A, and in (E) channels also had the NBD2 mutation E1371Q.
X
ABCC7 p.Lys464Ala 22234285:54:43
status: NEW
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60 Additional mutations were introduced into the cys-less background using the QuikChange site-directed mutagenesis -200 -150 -100 -50 0 I (pA) Time (s) K95C A) 1 mM ATP -180 -120 -60 0 Q98C -400 -300 -200 -100 0 -200 -150 -100 -50 0 I344C -300 -200 -100 0 -500 -400 -300 -200 -100 0 V345C -250 -200 -150 -100 -50 0 -300 -200 -100 0 -600 -400 -200 0 -750 -500 -250 0 -600 -400 -200 0 -800 -600 -400 -200 0 I (pA) Time (s) 20 µM MTSES 20 µM MTSES 20 µM MTSES200 µM MTSES C) 1 mM ATP + 2 mM PPi E) E1371Q (1 mM ATP) I (pA) Time (s) D) K464A (1 mM ATP) B) 10 µM ATP -100 -75 -50 -25 0 -200 -150 -100 -50 0 -80 -60 -40 -20 0 -80 -60 -40 -20 0 -120 -90 -60 -30 0 -80 -60 -40 -20 0 -60 -40 -20 0 -300 -200 -100 0 I (pA) Time (s) I (pA) Time (s) 0 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 system (Agilent Technologies, Santa Clara, CA, USA) and verified by DNA sequencing.
X
ABCC7 p.Lys464Ala 22234285:60:550
status: NEW
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95 In (B), NBD function has been altered by the mutations K464A (NBD1) and E1371Q (NBD2).
X
ABCC7 p.Lys464Ala 22234285:95:55
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105 Indeed, previous studies of pore accessibility changes have taken advantage of NBD mutations K464A and E1371Q [10,11].
X
ABCC7 p.Lys464Ala 22234285:105:93
status: NEW
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106 The NBD1 mutation K464A decreases channel opening rate and has been described as slightly decreasing overall open probability at moderate ATP concentrations [9,28,29], whereas mutagenesis of the key catalytic glutamate residue E1371 in NBD2 prevents ATP hydrolysis to cause dramatic prolongation of CFTR channel open times, presumably leading to an increase in open probability [1,30,31].
X
ABCC7 p.Lys464Ala 22234285:106:18
status: NEW
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107 To alter channel gating by non-pharmacological means, we therefore combined the NBD mutations K464A and E1371Q with each of the four cysteine mutants described above.
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ABCC7 p.Lys464Ala 22234285:107:94
status: NEW
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111 The K464A mutation significantly decreased the rate of MTSES modification at Q98C and I344C (2.5-2.9-fold decrease in modification rate constant; Pb0.005) but had no effect on the rate of modification at K95C or V345C (P>0.5) (Fig. 3B).
X
ABCC7 p.Lys464Ala 22234285:111:4
status: NEW
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150 We therefore compared the rate of Au(CN)2 - inhibition in K95C, Q98C and I344C at two different ATP concentrations (10 μM and 1 mM), as well as in channels also bearing the NBD mutations K464A or E1371Q (Fig. 6).
X
ABCC7 p.Lys464Ala 22234285:150:193
status: NEW
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151 Quantification of the mean modification rate constant demonstrated that decreasing ATP -300 -200 -100 0 -400 -300 -200 -100 0 -200 -150 -100 -50 0 -60 -40 -20 0 -120 -80 -40 0 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 0 60 120 180 -100 -75 -50 -25 0 -90 -60 -30 0 -90 -60 -30 0 -120 -80 -40 0 A) 1 mM ATP I (pA) I (pA) I (pA) Time (s) 200 nM Au(CN)2 C) K464A (1 mM ATP) D) E1371Q (1 mM ATP) 2 µM Au(CN)2 200 nM Au(CN)2 I (pA) Time (s) Time (s) -200 -150 -100 -50 0 -90 -60 -30 0 -120 -80 -40 0 K95C Q98C I344C B) 10 µM ATP Time (s) Fig. 6. Timecourse of modification by Au(CN)2 - .
X
ABCC7 p.Lys464Ala 22234285:151:454
status: NEW
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153 Reporter cysteines (K95C, Q98C, and I344C as indicated) were examined in isolation (A, B) or combined with the NBD mutations K464A (C) or E1371Q (D).
X
ABCC7 p.Lys464Ala 22234285:153:125
status: NEW
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157 In addition, the K464A mutation significantly decreased the rate of Au(CN)2 - modification of Q98C and I344C (1.4-1.5-fold decrease in modification rate constant with 1 mM ATP; Pb0.005) but had no effect on the rate of modification at K95C (P>0.5) (Fig. 7).
X
ABCC7 p.Lys464Ala 22234285:157:17
status: NEW
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167 The rate of modification at these two sites was significantly decreased by lowering ATP concentration (Figs. 3A, 7) and by the K464A mutation (Figs. 3B, 7), and significantly increased by PPi (Fig. 3A) and the E1371Q mutation (Figs. 3B, 7).
X
ABCC7 p.Lys464Ala 22234285:167:127
status: NEW
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180 For example, reducing ATP concentration to 10 μM is expected to decrease open probability around tenfold [25], whereas the K464A mutation is usually reported as having only a minor effect on open probability [9,28,29].
X
ABCC7 p.Lys464Ala 22234285:180:129
status: NEW
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181 Perhaps surprisingly, then, we find the effects of low ATP and the K464A mutation on modification rate constants for Q98C and I344C to be quantitatively similar and in the range of 1.5 to 3-fold (Figs. 3, 7).
X
ABCC7 p.Lys464Ala 22234285:181:67
status: NEW
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PMID: 9530164 [PubMed] Berger HA et al: "Fluoride stimulates cystic fibrosis transmembrane conductance regulator Cl- channel activity."
No. Sentence Comment
230 Effect of increasing F- concentration on current in wild-type CFTR, CFTR-K464A, and CFTR-K1250M.
X
ABCC7 p.Lys464Ala 9530164:230:73
status: NEW
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233 *P Ͻ 0.005 compared with wild-type CFTR and *P Ͻ 0.026 compared with CFTR-K464A.
X
ABCC7 p.Lys464Ala 9530164:233:86
status: NEW
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222 Effect of increasing F2 concentration on current in wild-type CFTR, CFTR-K464A, and CFTR-K1250M.
X
ABCC7 p.Lys464Ala 9530164:222:73
status: NEW
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225 *P , 0.005 compared with wild-type CFTR and *P , 0.026 compared with CFTR-K464A.
X
ABCC7 p.Lys464Ala 9530164:225:74
status: NEW
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PMID: 9463368 [PubMed] Sugita M et al: "CFTR Cl- channel and CFTR-associated ATP channel: distinct pores regulated by common gates."
No. Sentence Comment
131 The residues altered in CFTR∆R-S660A, CFTR S-oct-D, K464A and K1250A mutants are shown.
X
ABCC7 p.Lys464Ala 9463368:131:59
status: NEW
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155 These NBD1 and NBD2 mutants, containing the individual mutations K464A and K1250A, respectively, were expressed in MDCK cells and single-channel currents of CFTR Cl- channels and CFTR-associated ATP channels were analyzed.
X
ABCC7 p.Lys464Ala 9463368:155:65
status: NEW
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161 the K464A mutant exhibited no significant differences in Po (p Ͼ0.05), to (p Ͼ0.05) and the mean closed time (tc) (p Ͼ0.15), although there was a tendency towards increased tc and shorter to (Figure 10B, C, D and E).
X
ABCC7 p.Lys464Ala 9463368:161:4
status: NEW
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163 The K464A mutation similarly had no significant effects on the gating of the CFTR-associated ATP channels (Figure 10B, C, D and E).
X
ABCC7 p.Lys464Ala 9463368:163:4
status: NEW
X
ABCC7 p.Lys464Ala 9463368:163:65
status: NEW
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173 (B) Current traces from a MDCK cell expressing K464A at various membrane potentials (representative of nine independently observed channels).
X
ABCC7 p.Lys464Ala 9463368:173:47
status: NEW
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205 Mutations in the conserved Walker A motif lysines of NBD1 (K464A) and NBD2 (K1250A) are thought to attenuate ATP hydrolysis with minimal effect on ATP binding (Sung et al., 1988; Schneider et al., 1994; Carson et al., 1995).
X
ABCC7 p.Lys464Ala 9463368:205:59
status: NEW
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206 Previous analyses of the K464A mutant indicated that it had a reduced Po due to an increased closed time, although these effects were not pronounced (Carson et al., 1995; Gunderson and Kopito, 1995).
X
ABCC7 p.Lys464Ala 9463368:206:25
status: NEW
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272 Acknowledgements We thank M.Welsh for providing the CFTR∆R-S660A and CFTR S-oct-D mutants, R.Kopito for providing the K1250A and K464A mutants, J.Engelhardt for providing the R347E mutant, U.Patel for her precious technical help and D.Mak for helpful discussions.
X
ABCC7 p.Lys464Ala 9463368:272:136
status: NEW
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138 The residues altered in CFTRƊR-S660A, CFTR S-oct-D, K464A and K1250A mutants are shown.
X
ABCC7 p.Lys464Ala 9463368:138:57
status: NEW
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170 the K464A mutant exhibited no significant differences in Po (p b0e;0.05), to (p b0e;0.05) and the mean closed time (tc) (p b0e;0.15), although there was a tendency towards increased tc and shorter to (Figure 10B, C, D and E).
X
ABCC7 p.Lys464Ala 9463368:170:4
status: NEW
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172 The K464A mutation similarly had no significant effects on the gating of the CFTR-associated ATP channels (Figure 10B, C, D and E).
X
ABCC7 p.Lys464Ala 9463368:172:4
status: NEW
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183 (B) Current traces from a MDCK cell expressing K464A at various membrane potentials (representative of nine independently observed channels).
X
ABCC7 p.Lys464Ala 9463368:183:47
status: NEW
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215 Mutations in the conserved Walker A motif lysines of NBD1 (K464A) and NBD2 (K1250A) are thought to attenuate ATP hydrolysis with minimal effect on ATP binding (Sung et al., 1988; Schneider et al., 1994; Carson et al., 1995).
X
ABCC7 p.Lys464Ala 9463368:215:59
status: NEW
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216 Previous analyses of the K464A mutant indicated that it had a reduced Po due to an increased closed time, although these effects were not pronounced (Carson et al., 1995; Gunderson and Kopito, 1995).
X
ABCC7 p.Lys464Ala 9463368:216:25
status: NEW
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282 Acknowledgements We thank M.Welsh for providing the CFTRƊR-S660A and CFTR S-oct-D mutants, R.Kopito for providing the K1250A and K464A mutants, J.Engelhardt for providing the R347E mutant, U.Patel for her precious technical help and D.Mak for helpful discussions.
X
ABCC7 p.Lys464Ala 9463368:282:134
status: NEW
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PMID: 9558482 [PubMed] Foskett JK et al: "ClC and CFTR chloride channel gating."
No. Sentence Comment
307 In one study, ATP hydrolysis by a recombinant NBD1-maltose-binding protein fusion protein was inhibited by replacement of the Walker A lysine with alanine (K464A) (179), confirming predictions.
X
ABCC7 p.Lys464Ala 9558482:307:156
status: NEW
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308 K464A CFTR channels have reduced Po (135, 145).
X
ABCC7 p.Lys464Ala 9558482:308:0
status: NEW
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314 Activation of D572 and G551 mutants is inhibited (153, 154), and channel gating of Q552 mutants is altered (138) similarly to those for the K464A mutant.
X
ABCC7 p.Lys464Ala 9558482:314:140
status: NEW
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PMID: 9511929 [PubMed] Devidas S et al: "CFTR: domains, structure, and function."
No. Sentence Comment
113 (1995) demonstrated that CFTR variants which contained mutations in the conserved Walker A motif of either NBD1 (K464A) or NBD2 (K1250M and K1250A) decreased the open probability of the channel compared to wt-CFTR.
X
ABCC7 p.Lys464Ala 9511929:113:113
status: NEW
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114 Mutations in NBD1 alone decreased the open probability whereas mutations at NBD2 or simultaneously at both the NBDs (K464A/ K1250A) prolonged the frequency of bursts of activity. These data point out convincingly that the two NBD's cooperate to control channel gating.
X
ABCC7 p.Lys464Ala 9511929:114:117
status: NEW
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PMID: 8702904 [PubMed] Cotten JF et al: "Effect of cystic fibrosis-associated mutations in the fourth intracellular loop of cystic fibrosis transmembrane conductance regulator."
No. Sentence Comment
148 We found that two NBD1 mutants, K464A and G551S, had a normal or increased response to PPi (Fig. 7C).
X
ABCC7 p.Lys464Ala 8702904:148:32
status: NEW
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200 Data are mean Ϯ S.E. of (n) measurements for: wild-type (9), F1052V (3), R1066L (4), A1067T (4), G551S (6), K464A (4), G1349D (5), K1250 M at 5 mM PPi (5), wild-type at 5 mM PPi (16).
X
ABCC7 p.Lys464Ala 8702904:200:114
status: NEW
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147 We found that two NBD1 mutants, K464A and G551S, had a normal or increased response to PPi (Fig. 7C).
X
ABCC7 p.Lys464Ala 8702904:147:32
status: NEW
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199 Data are mean 6 S.E. of (n) measurements for: wild-type (9), F1052V (3), R1066L (4), A1067T (4), G551S (6), K464A (4), G1349D (5), K1250 M at 5 mM PPi (5), wild-type at 5 mM PPi (16).
X
ABCC7 p.Lys464Ala 8702904:199:108
status: NEW
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PMID: 8557666 [PubMed] Sato S et al: "Glycerol reverses the misfolding phenotype of the most common cystic fibrosis mutation."
No. Sentence Comment
95 Processing of mutants K464R and K464A was inefficient by comparison with wild type and was enhanced by incubation in the presence of 10% glycerol, even after accounting for the unequal label present in the immature precursor in the presence of glycerol (Fig. 3B).
X
ABCC7 p.Lys464Ala 8557666:95:32
status: NEW
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122 Interestingly, we observe a strong correlation between the temperature sensitivity of CFTR mutations like ⌬F508, K464R, and K464A (data not shown) and their ability to be remediated by glycerol.
X
ABCC7 p.Lys464Ala 8557666:122:131
status: NEW
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97 Processing of mutants K464R and K464A was inefficient by comparison with wild type and was enhanced by incubation in the presence of 10% glycerol, even after accounting for the unequal label present in the immature precursor in the presence of glycerol (Fig. 3B).
X
ABCC7 p.Lys464Ala 8557666:97:32
status: NEW
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124 Interestingly, we observe a strong correlation between the temperature sensitivity of CFTR mutations like DF508, K464R, and K464A (data not shown) and their ability to be remediated by glycerol.
X
ABCC7 p.Lys464Ala 8557666:124:124
status: NEW
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PMID: 8741733 [PubMed] Wilkinson DJ et al: "CFTR: the nucleotide binding folds regulate the accessibility and stability of the activated state."
No. Sentence Comment
229 The calculated values of k,,~.for K464Q and K464A indicated that the substitutions to alanine or glutamine also increased the off rate under activating conditions, which contributed to the increase in Ka and compensated somewhat for the reduction in relaxation rate caused by the reduced on rate.
X
ABCC7 p.Lys464Ala 8741733:229:44
status: NEW
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281 + kott) (10-3 min-l kon kofr latency *k~m CFTR (mM) n (10-3min-]) mM-1) (10-3min 1) (10-3min-l) n (min) (10 3min i) n wt 0.65 • 0.08 26 664 • 51 118 • 9 558 • 45 76-+ 6 20 6.0 • 0.3 88 • 6 16 K464R 2.6 • 0.1": 4 153 + 20**+ 20 • 3*** 101 • 13''` 52 • 7*: 5 1.3 • 0.2*++ 174 • 14"** 7 K464Q 3.3 • 0.5"* 5 331 • 56*** 40 -+ 7* 199 • 34* 132 • 22*'` 5 1.9 • 0.3"I 142 -+ 19''` 5 K464A 4.6 • 0.7** 6 289 • 49* 30 • 5** 151 • 26*** 139 • 24*: 7 1.1 • 0.1"** 133 • 14"** 8 D572N 9.3 + 0.02*: 6 106 • 7*: 7-+0.5*: 37-+3*** 69 • 5+* 4 0.9 • 0.2*** 245 • 32*: 3 K1250R 0.17 • 0.07*: 5 239 •33*** 46 -+ 6"+* 231 • 32*: 8 • 1": 10 10.4 • 0.8"~ 100 • 7** 6 K1250Q 0.12 • 0.04*** 5 150 • 18''` 29 • 4* 146 -+ 18" 4 + 0.4"I 5 22.3 • 2.4*: 30 •5": 5 K1250A 0.07 + 0.02*: 10 218 • 18" 43 • 4*'` 215 • 18": 3 -+0.3*~* 5 15.6-+ 1.0"** 43 -+5** 5 D1370N 0.16 + 0.04*'` 7 449 - 79*: 87 • 15: 435 +76** 14 - 2*: 5 16.3-4-1.2"" 69-+ 6** 5 The symbols (*) and ('`) indicate significant differences from wild-type CFTR and the analogous mutant, respectively (P < 0.05).
X
ABCC7 p.Lys464Ala 8741733:281:495
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383 Similarly, the mutation K464A increased the interburst interval by fivefold, whereas rate analysis revealed a nearly fourfold slowing of the activation rate (k'o,1).
X
ABCC7 p.Lys464Ala 8741733:383:24
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231 The calculated values of k,,~.for K464Q and K464A indicated that the substitutions to alanine or glutamine also increased the off rate under activating conditions, which contributed to the increase in Ka and compensated somewhat for the reduction in relaxation rate caused by the reduced on rate.
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ABCC7 p.Lys464Ala 8741733:231:44
status: NEW
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283 + kott) (10-3 min-l kon kofr latency *k~m CFTR (mM) n (10-3 min-]) mM-1) (10-3 min 1) (10-3min-l) n (min) (10 3min i) n wt 0.65 ߦ 0.08 26 664 ߦ 51 118 ߦ 9 558 ߦ 45 76 -+ 6 20 6.0 ߦ 0.3 88 ߦ 6 16 K464R 2.6 ߦ 0.1": 4 153 + 20**+ 20 ߦ 3*** 101 ߦ 13''` 52 ߦ 7*: 5 1.3 ߦ 0.2*++ 174 ߦ 14"** 7 K464Q 3.3 ߦ 0.5"* 5 331 ߦ 56*** 40 -+ 7* 199 ߦ 34* 132 ߦ 22*'` 5 1.9 ߦ 0.3"I 142 -+ 19''` 5 K464A 4.6 ߦ 0.7** 6 289 ߦ 49* 30 ߦ 5** 151 ߦ 26*** 139 ߦ 24*: 7 1.1 ߦ 0.1"** 133 ߦ 14"** 8 D572N 9.3 + 0.02*: 6 106 ߦ 7*: 7 -+0.5*: 37 -+3*** 69 ߦ 5+* 4 0.9 ߦ 0.2*** 245 ߦ 32*: 3 K1250R 0.17 ߦ 0.07*: 5 239 ߦ 33*** 46 -+ 6"+* 231 ߦ 32*: 8 ߦ 1": 10 10.4 ߦ 0.8"~ 100 ߦ 7** 6 K1250Q 0.12 ߦ 0.04*** 5 150 ߦ 18''` 29 ߦ 4* 146 -+ 18" 4 + 0.4"I 5 22.3 ߦ 2.4*: 30 ߦ 5": 5 K1250A 0.07 + 0.02*: 10 218 ߦ 18" 43 ߦ 4*'` 215 ߦ 18": 3 -+0.3*~* 5 15.6 -+ 1.0"** 43 -+5** 5 D1370N 0.16 + 0.04*'` 7 449 - 79*: 87 ߦ 15: 435 + 76** 14 - 2*: 5 16.3 -4-1.2"" 69 -+ 6** 5 The symbols (*) and ('`) indicate significant differences from wild-type CFTR and the analogous mutant, respectively (P < 0.05).
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ABCC7 p.Lys464Ala 8741733:283:481
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385 Similarly, the mutation K464A increased the interburst interval by fivefold, whereas rate analysis revealed a nearly fourfold slowing of the activation rate (k'o,1).
X
ABCC7 p.Lys464Ala 8741733:385:24
status: NEW
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PMID: 7543023 [PubMed] Gunderson KL et al: "Conformational states of CFTR associated with channel gating: the role ATP binding and hydrolysis."
No. Sentence Comment
57 These NBF1 and NBF2 mutants, harboring the individual mutations K464A and K1250A, K1250G, K1250M, or K1250T, respectively, were expressed in HEK cells and reconstituted into planar lipid bilayers from which single-channel currents were recorded (Figures 3A and 3B).
X
ABCC7 p.Lys464Ala 7543023:57:64
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59 Compared with wild-type CFTR, the NBF1 mutant K464A exhibited slowed gating kinetics and reduced open probability (Po) in the presence of 1 mM MgATP (Figure 3A; see Figure 5).
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ABCC7 p.Lys464Ala 7543023:59:46
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74 Effect of Mutation of the P Loop Lysine in NBF1 and NBF2 on CFTR Gating (A) Single-channel record of K464A in the absence (top) or presence (bottom)of 2 mM PP~.
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ABCC7 p.Lys464Ala 7543023:74:101
status: NEW
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121 The simplest interpretation of these data is that ATP binding ConformationalStatesof CFTR 09 08 07 06 Oo 05 040.3 * 32 wildtype K464A K1250A G1247D/ D1370N 01249E 6~se' B 2500 20O0 5 1500 1OO0 500 o~ 0 w[Id{ype K464A K1250A C1247D/ Ol 370N G1249E Figure5.
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ABCC7 p.Lys464Ala 7543023:121:130
status: NEW
X
ABCC7 p.Lys464Ala 7543023:121:213
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214 Polymerase Chain Reaction Megaprimer Mutagenesis The following site-directed mutants were constructed by using the megaprimer polymerase chain reaction (PCR)-based mutagenesis protocol (Landt et al., 1990; Sarkar and Sommer, 1990): K464A, K1250A, K1250G, K1250T, and GG1247, 1249DE.
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ABCC7 p.Lys464Ala 7543023:214:232
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122 The simplest interpretation of these data is that ATP binding ConformationalStatesof CFTR 09 08 07 06 Oo 05 040.3 * 32 wildtype K464A K1250A G1247D/ D1370N 01249E 6~se' B 2500 20O0 5 1500 1OO0 500 o ~ 0 w[Id{ype K464A K1250A C1247D/ Ol 370N G1249E Figure5.
X
ABCC7 p.Lys464Ala 7543023:122:130
status: NEW
X
ABCC7 p.Lys464Ala 7543023:122:214
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215 Polymerase Chain Reaction Megaprimer Mutagenesis The following site-directed mutants were constructed by using the megaprimer polymerase chain reaction (PCR)-based mutagenesis protocol (Landt et al., 1990; Sarkar and Sommer, 1990): K464A, K1250A, K1250G, K1250T, and GG1247, 1249DE.
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ABCC7 p.Lys464Ala 7543023:215:232
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PMID: 7534226 [PubMed] Sheppard DN et al: "Mechanism of dysfunction of two nucleotide binding domain mutations in cystic fibrosis transmembrane conductance regulator that are associated with pancreatic sufficiency."
No. Sentence Comment
177 It is interesting to compare the effect that different mutations in NBD1 had on al: P574H decreased a1, A455E did not change al, and K464A (a mutant of the Walker A lysine of NBDl; Carson and Welsh, 1995) appeared to increase the rate of channel closing.
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ABCC7 p.Lys464Ala 7534226:177:133
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PMID: 7505767 [PubMed] Dork T et al: "Exon 9 of the CFTR gene: splice site haplotypes and cystic fibrosis mutations."
No. Sentence Comment
115 Early evidence for a crucial role of exon 9 sequences came from the findings that mutations 71 within or adjacent to the Walker motif A produce a CF phenotype in vivo (A455E, G458V; Kerem et al. 1990; Cuppens et al. 1990) and in vitro (K464A; Anderson and Welsh 1992).
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ABCC7 p.Lys464Ala 7505767:115:236
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PMID: 7694298 [PubMed] Smit LS et al: "Functional roles of the nucleotide-binding folds in the activation of the cystic fibrosis transmembrane conductance regulator."
No. Sentence Comment
89 Alanine and arginine substitutions at lysine-464 and -1250 were associated with sensitivities similar to those observed with the glutamine substitutions (K464A or K464R, Kil2 = 0.8 mM; K1250A or K1250R, K,12 < 0.02 mM).
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ABCC7 p.Lys464Ala 7694298:89:154
status: NEW
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PMID: 11597353 [PubMed] Boucherot A et al: "Role of CFTR's PDZ1-binding domain, NBF1 and Cl(-) conductance in inhibition of epithelial Na(+) channels in Xenopus oocytes."
No. Sentence Comment
38 Using similar PCR techniques, the NBF1 mutants of human CFTR vF508, G551D, S466L, K464A, D572N, KH483/484AA, R487Q, R516A, KR598/600GA, KK611/612AA and K615A were in vitro synthesized (Quickchange, Stratagene).
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ABCC7 p.Lys464Ala 11597353:38:82
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171 We therefore introduced mutations into NBF1 sites which are essential for binding/hydrolysis of ATP and GTP and which have homology to GTP binding proteins such as Walker A (loop L1) (K464A, S466L), switch I motif (KH483/484AA, R487A), switch II motif (loop L4, G551D) and Walker B (D572N) [23].
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ABCC7 p.Lys464Ala 11597353:171:184
status: NEW
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PMID: 14697202 [PubMed] Randak C et al: "An intrinsic adenylate kinase activity regulates gating of the ABC transporter CFTR."
No. Sentence Comment
263 The Walker A mutations (K464A in NBD1 and K1250A in stimulation (Berger et al., 2002).
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ABCC7 p.Lys464Ala 14697202:263:24
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269 Thus, these data begin to discriminate between the ATPase and adenylate kinase effects whereas K464A enhanced Ap5A inhibition (Figures 7E and 7F).
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ABCC7 p.Lys464Ala 14697202:269:95
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288 Data are from 5 (wild-type, K464A, D572N), 9 (K1250A), 10 (D1370N), and 3 (N1303K) membrane patches. Asterisks indicate p b0d; 0.05 compared to wild-type by ANOVA followed by Dunnett`s multiple comparison test.
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ABCC7 p.Lys464Ala 14697202:288:28
status: NEW
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PMID: 23752332 [PubMed] Csanady L et al: "Conformational changes in the catalytically inactive nucleotide-binding site of CFTR."
No. Sentence Comment
29 For instance, the K464A mutation, which-by removing the side chain of the conserved NBD1 Walker A lysine-perturbs the NBD1 side of site 1, dramatically alters the mechanism of gating (Csan&#e1;dy et al., 2010).
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ABCC7 p.Lys464Ala 23752332:29:18
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35 M A T E R I A L S A N D M E T H O D S Molecular biology Human WT CFTR and CFTR segment 433-1480 in the pGEMHE plasmid (Chan et al., 2000) served as templates for mutants H1348A, K1250A, E1371S, K1250A/H1348A, E1371S/H1348A, E1371S/K464A, and 433-1480(K1250A), which were created using the QuikChange kit (Agilent Technologies).
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ABCC7 p.Lys464Ala 23752332:35:231
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66 Fig. S2 shows the effect of the K464A mutation on nonhydrolytic closing rate measured in the E1371S background.
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ABCC7 p.Lys464Ala 23752332:66:32
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219 Interestingly, the K464A mutation, which perturbs site 1 by removing the conserved Walker A lysine, was also shown to affect the energetics of both of the C1࢒O1 and O1࢐O2 gating steps (Csan&#e1;dy et al., 2010), although in a different way: in this mutant, rate k1 decreased approximately fourfold, whereas the rate of nonhydrolytic closure, in a K1250A mutant background, increased by &#e07a;10-fold (this is also replicated in the E1371S background; Fig. S2).
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ABCC7 p.Lys464Ala 23752332:219:19
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220 Thus, although the distortion of the energetic profile by the K464A mutation differs from that seen for the two perturbations studied here, the K464A result is again consistent with movements in site 1 occurring in both of the above gating steps.
X
ABCC7 p.Lys464Ala 23752332:220:62
status: NEW
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ABCC7 p.Lys464Ala 23752332:220:144
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PMID: 23921386 [PubMed] Randak CO et al: "ATP and AMP mutually influence their interaction with the ATP-binding cassette (ABC) adenylate kinase cystic fibrosis transmembrane conductance regulator (CFTR) at separate binding sites."
No. Sentence Comment
275 Error bars, S.E. Nucleotide Interactions with the ABC Adenylate Kinase CFTR 27698 JOURNAL OF BIOLOGICAL CHEMISTRY VOLUME 288ߦNUMBER 38ߦSEPTEMBER 20, 2013 at SEMMELWEIS UNIV OF MEDICINE on December , D1370N, abolished Ap5A inhibition of current, whereas the homologous mutations in ATP-binding site 1, K464A and D572N, did not.
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ABCC7 p.Lys464Ala 23921386:275:314
status: NEW
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303 However, the homologous mutations in ATP-binding site 1 (K464A and D572N) did not (19).
X
ABCC7 p.Lys464Ala 23921386:303:57
status: NEW
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