ABCMdb

ABCC7 p.Ser341Cys

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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

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
218 Finally, the MTSEA reactivity was restricted to only five of twenty-six residues in and flanking TM6 in our study, whereas in the earlier study, residues F337C, S341C, I344C, R347C, T351C, R352C, and Q353C were also shown to be accessible to MTS reagents. Login to comment

PMID: 18167343 [PubMed] Fatehi M et al: "State-dependent access of anions to the cystic fibrosis transmembrane conductance regulator chloride channel pore."

No. Sentence Comment

73 An example is S341C; as shown in Fig. 2A, inclusion of MTS reagents in the pipette solution also gave charge-dependent changes in I-V shape in this mutant, indicating that deposition of charge at this position also alters anion movement in the pore. Login to comment
74 In fact, similar charge-dependent effects were observed in R334C, K335C, T338C, and S341C (Fig. 3). Login to comment
78 Again, results from the example mutant S341C are shown in Fig. 2. Login to comment
105 Modification of S341C-CFTR by external MTS reagents. Login to comment
114 F, wild type (both panels); E, R334C (left); Ⅺ, K335C (left); ‚, F337C (right); ƒ, T338C (right); छ, S341C (right) (mean of data from 3-9 patches). Login to comment
140 Conformational Change in the Pore on Activation of CFTR 6106 JOURNAL OF BIOLOGICAL CHEMISTRY VOLUME 283•NUMBER 10•MARCH 7, each of R334C, K335C, and S341C, like T338C, the apparent degree of Au(CN)2 - modification as determined by the KCN- sensitive component of the current was significantly enhanced by cAMP stimulation (Fig. 7E). Login to comment
154 In the case of MTSET at least, this large organic molecule is able to enter far enough into the pore of nonactivated channels to react with a cysteine substituted for Ser-341, purportedly located in the pore inner vestibule (22). Login to comment
189 E, the mean change in CFTR macroscopic conductance for R334C, K335C, F337C, and S341C following addition of KCN without (white bars) or with (black bars) cAMP pretreatment is shown (mean of data from 4-5 patches). 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
165 That this could reflect the size and/or polarity of the latter reagents is suggested by the observation that S341C, like F337C CFTR, clearly reacts with a smaller MTS compound, MMTS (not shown). Login to comment
166 The results depicted in Figure 4 show that exposure of S341C/ Cys-less CFTR to 100 μM [Ag(CN)2]- produced about 70% inhibition of conductance (gCl), substantially greater than that seen in wt or Cys-less CFTR. Login to comment
176 In contrast, exposure of S341C CFTR to [Au(CN)2]- produced inhibition that was similar to that seen in the wt or Cys-less CFTR and was not altered by KCN, indicating the absence of a ligand exchange reaction. Login to comment
209 Position 332, predicted to reside in the FIGURE 4: Differential reactivity of S341C/Cys-less CFTR toward [Ag(CN)2]- and [Au(CN)2]- . Login to comment
281 Note the lack of consistent results reported for F337C, S341C, I344C, R347C, T351C, R352C, and Q353C (shaded). Login to comment

PMID: 20142516 [PubMed] Zhou JJ et al: "Regulation of conductance by the number of fixed positive charges in the intracellular vestibule of the CFTR chloride channel pore."

No. Sentence Comment

144 In contrast, each of the mutants, K95C, S341C, and S1141C (all in a cys-less background), was strongly sensitive to both MTSES and MTSET. Login to comment
146 In contrast, MTSET inhibited currents carried by cys-less S341C and cys-less S1141C, but potentiated currents carried by cys-less K95C. Login to comment
147 In S341C and S1141C, modification by the bulky MTSET molecule may partly occlude the pore, reducing Cl current. Login to comment
152 The strong reactivity of cys-less K95C, S341C, and S1141C to intracellular MTSES and MTSET is consistent with the cysteine side chains introduced at these positions being exposed within the aqueous inner vestibule of the pore. Login to comment
161 A K95C/S341C double mutant did not yield functional currents in inside-out patches either without or after treatment with 5 mM DTT. Login to comment

PMID: 20805575 [PubMed] Bai Y et al: "Dual roles of the sixth transmembrane segment of the CFTR chloride channel in gating and permeation."

No. Sentence Comment

82 7 out of the 25 mutant channels exhibited a reduced single-channel current amplitude, including, from extracellular to intracellular, R334C, K335C, F337C, T338C, S341C, R347C, and R352C (Fig. 2). Login to comment
83 The single-channel amplitude is unsolv- able in the cases of R334C, S341C, R347C, and R352C due to a limited bandwidth, whereas it is 0.2-0.3 pA for Data analysis Current traces containing fewer than three channel opening levels and lasting for >1 min were selected for single-channel kinetic analysis using a program developed by L. Csanády (2000). Login to comment
128 Although MTSET posed small (<20% for S341C) or negligible inhibition, modification by MTSES drastically reduced the current (e.g., Fig. 4, E and F). Login to comment
185 Because anion conduction was severely perturbed by the mutations R352C and S341C, we were not able to assess the effects of MTSES modification on the single-channel amplitude for these two constructs. Login to comment

PMID: 21796338 [PubMed] Qian F et al: "Functional arrangement of the 12th transmembrane region in the CFTR chloride channel pore based on functional investigation of a cysteine-less CFTR variant."

No. Sentence Comment

140 In this respect, the slow rate of modification observed in N1138C (Fig. 3b) is similar to that we reported for P99C and L102C in TM1 [41] and T338C and S341C in TM6 [9], and the much higher modification rate constant for T1142C, S1141C, and (to a lesser extent) M1140C is closer to that reported for K95C in TM1 [41] and I344C, V345C, and M348C in TM6 [9]. Login to comment

PMID: 22352759 [PubMed] Norimatsu Y et al: "Cystic fibrosis transmembrane conductance regulator: a molecular model defines the architecture of the anion conduction path and locates a "bottleneck" in the pore."

No. Sentence Comment

333 Neither of the channel-impermeant regents, MTSET+ or MTSES- , reacted with S341C when each was applied from the extracelluar side. Login to comment

PMID: 22923500 [PubMed] Norimatsu Y et al: "Locating a Plausible Binding Site for an Open Channel Blocker, GlyH-101, in the Pore of the Cystic Fibrosis Transmembrane Conductance Regulator."

No. Sentence Comment

164 S341C CFTR is reactive toward channel permeant reagents, like [Ag(CN)2]- , but the reactions are not irreversible at this position, a requirement for implementation of the post-GlyH-101 washout protocol. Login to comment
247 The S341C CFTR is reactive toward channel-permeant reagents such as [Ag(CN)2]afa; but the reactions at this position are not irreversible, which is a requirement for implementation of the post-GlyH-101 washout protocol. Login to comment
279 B, time courses of the reactions of the S341C CFTR with 1 mM NEM in the presence and absence of 10 òe;M GlyH-101. Data points represent mean afe; S.E.M. (n afd; 3). Login to comment
280 Covalent labeling of the S341C CFTR with NEM resulted in reductions in conductance. Login to comment
284 The EC50 at 0 mV for GlyH-101 blockade for the S341C CFTR was 0.89 afe; 0.056 òe;M (n afd; 3). Login to comment

PMID: 21746847 [PubMed] Wang W et al: "Alignment of transmembrane regions in the cystic fibrosis transmembrane conductance regulator chloride channel pore."

No. Sentence Comment

139 Our work concerning intracellular MTS reagent modification in TM6 also identified some cysteines that could be modified in both activated and nonactivated channels (e.g., V345C and M348C), and others that could apparently be modified only after channel activation (e.g., T338C, S341C, and I344C), suggesting a state-dependent conformational change that alters access of internally applied MTS reagents into the pore (El Hiani and Linsdell, 2010). Login to comment
181 Unfortunately, the double mutants K95C/V345C and Q98C/V345C did not yield functional currents when expressed in BHK cells, even after treatment with DTT to break any possible disulfide bonds; a similar lack of functional expression was previously reported for K95C/S341C (Zhou et al., 2010). Login to comment
227 Second, whereas cysteines substituted for TM6 residues in the putative narrow pore region-F337C, T338C, and S341C-could be modified by both intracellular and extracellular MTS reagents (El Hiani and Linsdell, 2010), no residues that could be modified from both sides of the membrane were identified in TM1. Login to comment
256 For comparison, the MTSES modification rate constant for P99C and L102C (Fig. 3) was similar to that of T338C and S341C in TM6 (El Hiani and Linsdell, 2010) (all between 100 and 150 M1 s1 ), and the modification rate constant for K95C was comparable to, or slightly greater than, that of I344C, V345C, and M348C (El Hiani and Linsdell, 2010) (all between 2,000 and 4,000 M1 s1 ). Login to comment

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

No. Sentence 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
155 The electrical distance increases dramatically from S341C to T351C (Fig. 3A), suggesting that most of the electrical potential falls in this region of the channel. 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
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

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