ABCMdb

ABCC7 p.Leu333Cys

[switch to full view]
Comments [show]

None has been submitted yet.

Publications

PMID: 18056267 [PubMed] Beck EJ et al: "Conformational changes in a pore-lining helix coupled to cystic fibrosis transmembrane conductance regulator channel gating."

No. Sentence Comment

93 Both Cd2ϩ and MTSEA had significant effects on the conductances of only five (I331C, L333C, R334C, K335C, and T338C) of the 26 Cys-substituted channels examined. Login to comment
100 The oocytes 750 500 250 0 µS 180012006000 s IBMX MTSEA Cd 2+ DTT 200 100 0 µS 180012006000 s IBMX DTT Cd 2+ MTSEA A B C -100 -80 -60 -40 -20 0 20 40 % Change in conductance Y325C A326C L327C I328C K329C G330C I331C I332C L333C R334C K335C I336C F337C T338C T339C I340C S341C F342C WT I344C V345C R347C M348C A349C V350C T351C Q353C * * * * * Cd 2+ 1mM MTSEA 1mM D FIGURE 1. Login to comment
127 For example, whereas L333C in the Glu1371 (WT) channel was inhibited by either Cd2ϩ or MTSEA, neither reagent was particularly effective when this mutation was present in the Gln1371 background 200 150 100 50 0 µS 15001000500 s IBMX Cd 2+ MTSEA DTT -80 -60 -40 -20 0 % Change in conductance I331C L333C R334C K335C T338C Cd 2+ aM Cd 2+ bM Cd 2+ uM A B FIGURE 2. Login to comment
131 B, summary of effects of Cd2ϩ on MTSEA-modified I331C, L333C, R334C, K335C, and T338C channels. Login to comment
135 MTSEA 1371Q 600 400 200 µS 200150100500 s Cd 2+ 1371E -40 0 40 % Change in conductance I331C L333C R334C K335C T338C 1371E 1371Q * * * -80 -60 -40 -20 0 % Change in conductance I331C L333C R334C K335C T338C * * * 1371Q 800 600 400 µS 2001000 s MTSEA 1371E B D E 1 2 30 s1 pAWT; Po=0.18 A 3 1 2 100 s1 pAE1371Q; Po=0.94 C FIGURE 3. Login to comment
142 B, effect of Cd2ϩ on whole cell conductance of L333C-CFTR in 1371E (WT; blue) and in 1371Q (red) backgrounds. Login to comment
153 The differences between Glu1371 and Gln1371 backgrounds in the effects of Cd2ϩ and MTSEA on I331C, L333C, R334C, K335C, and T338C channels are summarized in Fig. 3 (C and E), respectively. Login to comment
159 In contrast, I331C, L333C, and K335C reacted faster in the Glu1371 background (Fig. 4, B and C). Login to comment
160 These results reveal clearly that modification of I331C, L333C, and K335C by both these reagents was much slower in the Gln1371 mutational background than in the WT Glu1371 channels. Login to comment
163 L333C showed a relatively smaller 10-fold 100 75 50 4803602401200 s 1371E; 100 µM 1371Q; 100 µM 100 90 80 70 240180120600 s 1371E; 1 mM 1371Q; 1 mM 120 100 80 120600 s 1371E; 10 µM 1371Q; 1 mM 100 75 50 25 180120600 s 1371Q; 10 µM 1371E; 10 µM 100 90 80 180120600 s 1371Q; 1 mM 1371E; 1 mM 100 75 50 4803602401200 s 1371E; 100 µM 1371Q; 100 µM 9060300 s 1371E; 10 µM 1371Q; 1 mM 180120600 s 1371E; 10 µM 1371Q; 10 µM 100 75 50 25 180120600 s 1371E; 10 µM 1371Q; 10 µM 140 130 120 110 100 4530150 s 1371Q; 10 µM 1371E; 10 µM FIGURE 4. Login to comment
178 All of the residues except L333C had varying but significant differences in the magnitude of the functional effect by MTS reagents. Login to comment
185 However, I331C and L333C channels had a significantly faster modification rate, when minimally active. Login to comment
186 When stimulated by 0.02 mM IBMX, both I331C and L333C reacted nearly 25 times faster with MTSEA and nearly 10-20 times faster with MTSES. Login to comment
188 EvidenceforTM6MovementAssociatedwithChannelGating- The state-dependent reactivity of the MTS reagents with I331C, L333C, and K335C channels could indicate a change in the water accessibility of these residues caused by a conformational change in TM6 or by an alteration in the local environment surrounding these residues. Login to comment
192 For two of the three mutants, I331C and L333C, modification with MTSET profoundly affected channel gating (Fig. 7A). Login to comment
193 The open probabilities of MTSET-modified I331C and L333C channels were significantly smaller than those of unmodified channels. Login to comment
196 These results indicate that MTSET reduces the whole cell conductance of I331C- and L333C-expressing oocytes by inhibiting channel gating and not by affecting channel permeation properties. Login to comment
197 Kinetic analyses of channel gating revealed that the decrease in open probability of MTSET-modified I331C and L333C channels was primarily because of an increase in the mean interburst duration of the A B 1.00.50.0 G0.02/ G1 I331C L333C R334C K335C T338C 200 100 0 µS 8006004002000 s 0.02 1 IBMX (mM) C -100 100 % Change in conductance I331C L333C R334C K335C T338C 0.02 mM IBMX 1 mM IBMX * * * * -80 -60 -40 -20 0 % Change in conductance I331C L333C R334C K335C T338C * * * MTSEA MTSES FIGURE5.EffectsofMTSEA,andMTSESdependonCFTRactivationlevels. Login to comment
216 Although both studies identified I331C, L333C, R334C, and K335C as accessible to MTS reagents, we find that MTSEA increased the conductance of R334C- and K335C-expressing oocytes, whereas it was reported in the previous study to decrease channel currents. Login to comment
223 It is possible that this mutation rather than the open 150 125 100 %G/Gi 600 s K335C I-1.0; 10 µM I-0.02; 10 µM 10 1 10 2 10 3 10 4 Modification rate (M -1 s -1 ) I331C L333C R334C K335C T338C 100 50 %G/Gi 3002001000 s I-1.0; 100 µM I-0.02;10 µM MTSEA I331CL333CR334CK335CT338C 100 75 50 25 0 %G/Gi 180120600 s I-0.02; 10 µM I-1.0; 10 µM 200 150 100 %G/Gi 120600 s I-0.02; 10 µM I-1.0; 10 µM 100 75 50 %G/Gi 3602401200 s I-1.0; 100 µM I-0.02; 10 µM 100 80 60 %G/Gi 9060300 s K335C I-1.0; 10 µM I-0.02; 10 µM 100 50 %G/Gi 180120600 s T338C I-1.0; 10 µM I-0.02; 10 µM 10 1 10 2 10 3 10 4 Modification rate (M -1 s -1 ) I331C L333C R334C K335C T338C MTSES 100 75 50 25 %G/Gi 120600 s I-1.0; 10 µM I-0.02; 10 µM 100 75 50 %G/Gi 3602401200 s I-1.0; 100 µM I-0.02; 10 µM 100 75 %G/Gi 180120600 s I-0.02; 100 µM I-1.0; 1 mM A B FIGURE 6. Login to comment
240 It must be pointed out that under low IBMX concentrations, a 5-fold decrease in CFTR Po cannot account for the entire differences in reactivity of I331C and L333C. Login to comment
242 Hence, a small fraction of the increased reactivity of I331C, and L333C at low IBMX concentrations could be due to a relief from this block, although such an increase in reactivity is not observed for R334C and T338C. Login to comment
258 The openprobabilityandmeanburstandinterbursttimes(meansϮS.E.)forI331C,L333C,K335C,andWTchannels in untreated (-MTSET) and MTSET-treated (ϩMTSET) conditions are shown. Login to comment

PMID: 19381710 [PubMed] Fatehi M et al: "Novel residues lining the CFTR chloride channel pore identified by functional modification of introduced cysteines."

No. Sentence Comment

177 Effects of external MTS reagents on the gating of CFTR cysteine mutants (I331C, L333C) have been described (Beck et al. 2008) but would presumably not be noticed using our experimental approach. Login to comment

PMID: 19754156 [PubMed] Alexander C et al: "Cystic fibrosis transmembrane conductance regulator: using differential reactivity toward channel-permeant and channel-impermeant thiol-reactive probes to test a molecular model for the pore."

No. Sentence Comment

52 We proposed that these spontaneous changes, that are not seen in either wt or Cys-less CFTR, reflect the coordination of trace Table 1: Percent Change in Oocyte Conductance in the Presence of Compounda MTSETþ MTSES- [Ag(CN)2]- [Au(CN)2]- G330C O O O O I331C -51.6 ( 6.3 -28.9 ( 2.1 -63.1 ( 8.8 O I332C O O O O L333C -58.5 ( 4.8 -47.5 ( 7.6 -83.1 ( 2.2 O R334C þ76.9 ( 11.3 -84.4 ( 1.5 -67.4 ( 7.4 -41.4 ( 3.1 K335C þ10.7 ( 2.4 -37.3 ( 1.5 -29.1 ( 6.4 -54.6 ( 4.7 I336C -54.4 ( 7.9 -75.0 ( 0.6 -81.2 ( 10.5 O F337C O O -89.6 ( 1.9 -90.1 ( 1.3 T338C -37.1 ( 3.3 -85.4 ( 2.5 -75.0 ( 5.2 -88.3 ( 1.6 T339C O O -24.5 ( 7.2 O I340C O O -93.8 ( 1.0 O S341C O O -49.3 ( 4.8 O F342C O O -84.7 ( 1.8 O C343 O O O O I344C O O -66.9 ( 9.3 -77.9 ( 2.1 V345C O O -49.1 ( 9.3 O L346C O O O O R347C O O O O M348C O O -47.9 ( 8.8 -50.1 ( 3.3 A349C O O -19.0 ( 2.0 O V350C O O O O T351C O O O O R352C O O -77.5 ( 1.3 O Q353C O O -72.6 ( 4.5 -76.7 ( 2.8 a Values are means ( SE of three or more oocytes. Login to comment
130 Figure 2 contains an example of results obtained with L333C CFTR on a wt background (L333C/wt). Login to comment
136 FIGURE 2: Functional impact of covalent labeling of L333C CFTR was charge-independent. Login to comment
140 Reactions of MTSETþ and MTSES- with L333C/wt CFTR channels were reversed by exposure to DTT, but the rate of reversal was slower in the case of MTSES- -modified channels, as expected due to the unfavorable electrostatic interaction between the negatively charged adduct and the anionic DTT. Login to comment
271 Beck et al. (9) reported that modification of I331C or L333C CFTR channels results in a profound reduction in open probability, and the authors suggested that these sites may experience significant movement during the gating cycle. Login to comment

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

146 The rate of modification of L333C and K335C, also at the extracellular end of TM6, was also decreased in an E1371Q background, suggesting slower modification of open, compared with closed channels (26). Login to comment
147 However, these cysteines in the outer pore region (L333C, R334C, and K335C) are not modified by intracellular MTS reagents under any conditions (17, 27), suggesting that unlike T338C they cannot move to a position that is accessible to large cytoplasmic substances. Login to comment
152 L102C, like T338C, becomes apparently more accessible to internal cysteine reactive reagents in open channels (Fig. 6B), but is inaccessible to extracellular MTSES (Fig. FIGURE 4. Login to comment
153 Rate of modification of T338C by external MTSES. Login to comment

PMID: 9511930 [PubMed] Akabas MH et al: "Probing the structural and functional domains of the CFTR chloride channel."

No. Sentence Comment

115 The ratio of the reaction rates of MTSES- /MTSET+ with L333C, the most extracellular residue tested, is also 0.08, suggesting that there is no charge selectivity for the movement of the MTS reagents from the extracellular solution to L333C. Login to comment
116 Thus, in order to normalize for the difference in the intrinsic reaction rates of the two MTS reagents we divide the ratio of the rates at a given residue by the ratio of the reaction rates with L333C. Login to comment
148 The lack of significant electrical distance to the residues from L333C to S341C (Fig. 3A) implies that the MTS reagents do not pass through the electrical field to reach these residues. Login to comment

PMID: 9089437 [PubMed] Cheung M et al: "Locating the anion-selectivity filter of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel."

No. Sentence Comment

107 We did not measure the reaction rate constants for the most extracellular residue, I331C, because we thought that it was unlikely that the reaction rates would be voltage dependent given the absence of voltage dependence at the adjacent, more cytoplasmic residues. We also did not measure the reaction rate constants for the mutants I344C and R347C because, although MTSEAϩ reacted with these residues, MTSES- and MTSETϩ did not react with these k ψ( )( )ln k Ψ 0=( )( ) zFδ RT/( )-ln ψ= t a b l e i Second-order Rate Constants for the Reaction of the MTS Reagents with the Water-exposed Cysteine Mutants k ES (M-1s-1) k EA (M-1s-1) k ET (M-1s-1) mutant -25 mV -50 mV -75 mV -25 mV -50 mV -75 mV -25 mV -50 mV -75 mV L333C 71 Ϯ 3(3) 71 Ϯ 20(2) 71 Ϯ 23(3) 320 Ϯ 89(2) 320 Ϯ 128(2) 333 Ϯ 139(3) 952 Ϯ 136(2) 1,000 Ϯ 350(2) 1,053 Ϯ 443(2) R334C 48 Ϯ 14(2) 48 Ϯ 6(3) 44 Ϯ 8(4) 145 Ϯ 32(2) 163 Ϯ 7(2) 182 Ϯ 21(3) 444 Ϯ 49(2) 454 Ϯ 124(2) 588 Ϯ 95(3) K335C 36 Ϯ 20(3) 23 Ϯ 11(3) 27 Ϯ 16(3) 222 Ϯ 80(3) 121 Ϯ 51(4) 107 Ϯ 30(3) 217 Ϯ 111(3) 235 Ϯ 28(3) 217 Ϯ 95(4) F337C 91 Ϯ 17(2) 80 Ϯ 22(3) 71 Ϯ 20(4) 222 Ϯ 74(2) 222 Ϯ 86(3) 285 Ϯ 81(3) 740 Ϯ 246(3) 740 Ϯ 82(2) 714 Ϯ 51(2) S341C 56 Ϯ 18(3) 56 Ϯ 40(2) 43 Ϯ 12(3) 93 Ϯ 6(3) 110 Ϯ 22(3) 138 Ϯ 34(3) 690 Ϯ 356(3) 556 Ϯ 246(3) 800 Ϯ 224(4) T351C 100 Ϯ 25(5) 57 Ϯ 6(3) 26 Ϯ 9(6) 146 Ϯ 30(4) 195 Ϯ 42(4) 296 Ϯ 18(3) 308 Ϯ 47(10) 392 Ϯ 78(6) 769 Ϯ 89(5) R352C 42 Ϯ 4(3) 26 Ϯ 4(5) 21 Ϯ 6(4) 105 Ϯ 76(3) 137 Ϯ 46(3) 205 Ϯ 58(2) 417 Ϯ 138(4) 800 Ϯ 128(2) 952 Ϯ 408(2) Q353C 125 Ϯ 23(4) 51 Ϯ 12(4) 42 Ϯ 8(4) 83 Ϯ 24(4) 116 Ϯ 42(4) 160 Ϯ 92(3) 189 Ϯ 48(6) 220 Ϯ 48(3) 625 Ϯ 273(4) residues and therefore we could not determine the charge selectivity at these positions.2 The reaction rate constants that we have measured are between 10-and 500-fold slower than the rates of reaction with sulfhydryls in free solution (Table II) (Stauffer and Karlin, 1994). Login to comment
112 Furthermore, the voltage dependence of the rates of reaction of MTSES- is opposite to the voltage t a b l e i i Second-order Rate Constants at Holding Potential ϭ 0 mV and Ratios of Rate Constants at V ϭ 0 mV (kmtses/kmtset) 1 2* k0,MTSES 3* k0,MTSET 4‡ k0,MTSES 5§ kES/kET Mutant (M-1 S-1) (M-1 S-1) k0,MTSET L333C 2-MEʈ 4300 51000 0.08 1 L333 68 828 0.08 1 R334 53 376 0.14 2 K335 47 455 0.1 1 F337 96 991 0.1 1 S341 72 727 0.1 1 T351 250 219 1.14 14 R352 48 324 0.15 2 Q353 213 102 2.09 26 *Columns 2, 3 are the rate constants for MTSES- and MTSETϩ at V ϭ 0 mV. Login to comment
115 The same ratio is observed for the rates of reaction with L333C indicating that there is no charge selectivity for the reaction with this residue. Login to comment
116 §Column 5 is the anion to cation selectivity ratio derived by dividing the data in Column 4 by the ratio obtained for the rates of reaction with L333C. Login to comment
117 The ratio of the rate constants (kmtses/kmtset) for reaction with an exposed cysteine relative to the ratio of the rate constants for the reaction with L333C gives a measure of the anion to cation selectivity at the level of an exposed cysteine. Login to comment
134 Note that the electrical distance to the residues from L333C to S341C is close to zero and that the electrical distance to R352C is smaller than the electrical distance to the adjacent residues. Login to comment
155 lar residue tested, L333C, the ratio of the rates of reaction of MTSES-/MTSETϩ is also 0.08 (Table II, column 4); this suggests that there is no charge selectivity for access of the MTS reagents to this residue from the extracellular solution. Login to comment
156 To account for this difference in the intrinsic rates of reaction of the two MTS reagents, we divided the ratio of the rates at a given residue by the ratio of the rates of reaction with L333C. Login to comment

PMID: 8744306 [PubMed] Cheung M et al: "Identification of cystic fibrosis transmembrane conductance regulator channel-lining residues in and flanking the M6 membrane-spanning segment."

No. Sentence Comment

91 Effects of MTS reagents on wild-type cysteines RESULTS in CFTR To identify the residues in and flanking the M6 membrane-spanning segment that are on the water-exposed surface of As reported previously (Akabas et al., 1994b), extracellular applications of the MTS reagents to Xenopus oocytes ex- L2j K329C L. _J *G330C 1331C 1332C L333C R334C K335C 1336C F337C T338C T339C 1340C S341C T342C C343,WT 1344C V345C L346C R347C M348C A349C V350C T351C R352C Q353C 0 2000 4000 6000 8000 0 25 50 PEAK CURRENTS (nA) TIME TO REACH PLATEAU (min) FIGURE 2 Peak CFTR-induced currents and time to reach the plateau current after stimulation with cAMP-activating reagents for 24 cysteine-substitution mutants and wild-type CFTR. Login to comment
109 Accessibility of substituted cysteines to MTSES- A 1-min application of 10 mM MTSES- significantly inhibited the CFIR-induced currents of 9 of the 24 cysteine-substituted mutants (Fig. 4 A), L333C, R334C, K335C, F337C, S341C, R347C, T351C, R352C, and Q353C. Login to comment
90 Effects of MTS reagents on wild-type cysteines RESULTS in CFTR To identify the residues in and flanking the M6 membrane-spanning segment that are on the water-exposed surface of As reported previously (Akabas et al., 1994b), extracellular applications of the MTS reagents to Xenopus oocytes ex- L2j K329C L. _J *G330C 1331C 1332C L333C R334C K335C 1336C F337C T338C T339C 1340C S341C T342C C343,WT 1344C V345C L346C R347C M348C A349C V350C T351C R352C Q353C 0 2000 4000 6000 8000 0 25 50 PEAK CURRENTS (nA) TIME TO REACH PLATEAU (min) FIGURE 2 Peak CFTR-induced currents and time to reach the plateau current after stimulation with cAMP-activating reagents for 24 cysteine-substitution mutants and wild-type CFTR. Login to comment
108 Accessibility of substituted cysteines to MTSES- A 1-min application of 10 mM MTSES- significantly inhibited the CFIR-induced currents of 9 of the 24 cysteine-substituted mutants (Fig. 4 A), L333C, R334C, K335C, F337C, S341C, R347C, T351C, R352C, and Q353C. Login to comment