ABCMdb

ABCC7 p.Val345Cys

Predicted by SNAP2:	A: N (61%), C: D (59%), D: D (85%), E: D (80%), F: D (85%), G: D (80%), H: D (85%), I: D (53%), K: D (85%), L: D (63%), M: D (80%), N: D (75%), P: D (66%), Q: D (80%), R: D (80%), S: D (59%), T: D (53%), W: D (91%), Y: D (85%),
Predicted by PROVEAN:	A: N, C: D, D: D, E: D, F: N, G: D, H: D, I: N, K: D, L: N, M: N, N: D, P: D, Q: D, R: D, S: N, T: N, W: D, Y: D,

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[hide] Conformational changes in a pore-lining helix coup... J Biol Chem. 2008 Feb 22;283(8):4957-66. Epub 2007 Dec 3. Beck EJ, Yang Y, Yaemsiri S, Raghuram V
Conformational changes in a pore-lining helix coupled to cystic fibrosis transmembrane conductance regulator channel gating.
J Biol Chem. 2008 Feb 22;283(8):4957-66. Epub 2007 Dec 3., 2008-02-22 [PMID:18056267]

Abstract [show]
Cystic fibrosis transmembrane conductance regulator (CFTR), the protein dysfunctional in cystic fibrosis, is unique among ATP-binding cassette transporters in that it functions as an ion channel. In CFTR, ATP binding opens the channel, and its subsequent hydrolysis causes channel closure. We studied the conformational changes in the pore-lining sixth transmembrane segment upon ATP binding by measuring state-dependent changes in accessibility of substituted cysteines to methanethiosulfonate reagents. Modification rates of three residues (resides 331, 333, and 335) near the extracellular side were 10-1000-fold slower in the open state than in the closed state. Introduction of a charged residue by chemical modification at two of these positions (resides 331 and 333) affected CFTR single-channel gating. In contrast, modifications of pore-lining residues 334 and 338 were not state-dependent. Our results suggest that ATP binding induces a modest conformational change in the sixth transmembrane segment, and this conformational change is coupled to the gating mechanism that regulates ion conduction. These results may establish a structural basis of gating involving the dynamic rearrangement of transmembrane domains necessary for vectorial transport of substrates in ATP-binding cassette transporters.

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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

[hide] Cystic fibrosis transmembrane conductance regulato... Biochemistry. 2009 Oct 27;48(42):10078-88. Alexander C, Ivetac A, Liu X, Norimatsu Y, Serrano JR, Landstrom A, Sansom M, Dawson DC
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.
Biochemistry. 2009 Oct 27;48(42):10078-88., 2009-10-27 [PMID:19754156]

Abstract [show]
The sixth transmembrane segment (TM6) of the CFTR chloride channel has been intensively investigated. The effects of amino acid substitutions and chemical modification of engineered cysteines (cysteine scanning) on channel properties strongly suggest that TM6 is a key component of the anion-conducting pore, but previous cysteine-scanning studies of TM6 have produced conflicting results. Our aim was to resolve these conflicts by combining a screening strategy based on multiple, thiol-directed probes with molecular modeling of the pore. CFTR constructs were screened for reactivity toward both channel-permeant and channel-impermeant thiol-directed reagents, and patterns of reactivity in TM6 were mapped onto two new, molecular models of the CFTR pore: one based on homology modeling using Sav1866 as the template and a second derived from the first by molecular dynamics simulation. Comparison of the pattern of cysteine reactivity with model predictions suggests that nonreactive sites are those where the TM6 side chains are occluded by other TMs. Reactive sites, in contrast, are generally situated such that the respective amino acid side chains either project into the predicted pore or lie within a predicted extracellular loop. Sites where engineered cysteines react with both channel-permeant and channel-impermeant probes occupy the outermost extent of TM6 or the predicted TM5-6 loop. Sites where cysteine reactivity is limited to channel-permeant probes occupy more cytoplasmic locations. The results provide an initial validation of two, new molecular models for CFTR and suggest that molecular dynamics simulation will be a useful tool for unraveling the structural basis of anion conduction by CFTR.

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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

[hide] Dual roles of the sixth transmembrane segment of t... J Gen Physiol. 2010 Sep;136(3):293-309. Bai Y, Li M, Hwang TC
Dual roles of the sixth transmembrane segment of the CFTR chloride channel in gating and permeation.
J Gen Physiol. 2010 Sep;136(3):293-309., [PMID:20805575]

Abstract [show]
Cystic fibrosis transmembrane conductance regulator (CFTR) is the only member of the adenosine triphosphate-binding cassette (ABC) transporter superfamily that functions as a chloride channel. Previous work has suggested that the external side of the sixth transmembrane segment (TM6) plays an important role in governing chloride permeation, but the function of the internal side remains relatively obscure. Here, on a cysless background, we performed cysteine-scanning mutagenesis and modification to screen the entire TM6 with intracellularly applied thiol-specific methanethiosulfonate reagents. Single-channel amplitude was reduced in seven cysteine-substituted mutants, suggesting a role of these residues in maintaining the pore structure for normal ion permeation. The reactivity pattern of differently charged reagents suggests that the cytoplasmic part of TM6 assumes a secondary structure of an alpha helix, and that reactive sites (341, 344, 345, 348, 352, and 353) reside in two neighboring faces of the helix. Although, as expected, modification by negatively charged reagents inhibits anion permeation, interestingly, modification by positively charged reagents of cysteine thiolates on one face (344, 348, and 352) of the helix affects gating. For I344C and M348C, the open time was prolonged and the closed time was shortened after modification, suggesting that depositions of positive charges at these positions stabilize the open state but destabilize the closed state. For R352C, which exhibited reduced single-channel amplitude, modifications by two positively charged reagents with different chemical properties completely restored the single-channel amplitude but had distinct effects on both the open time and the closed time. These results corroborate the idea that a helix rotation of TM6, which has been proposed to be part of the molecular motions during transport cycles in other ABC transporters, is associated with gating of the CFTR pore.

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186 Instead, we will focus on the four other positive hits (i.e., I344C, V345C, M348C, and Q353C). Login to comment
212 Similar results were obtained with the cysless/V345C and cysless/ M348C channels. Login to comment
240 A representative experimental result with the cysless/V345C construct is shown in Fig. 11 A. Login to comment
256 (A and B) Macroscopic recordings of cysless/ V345C and cysless/M348C showing modification by 1 mM MTSES when the membrane potential is held at 50 mV (left) and 100 mV (right). Login to comment

[hide] Functional arrangement of the 12th transmembrane r... Pflugers Arch. 2011 Oct;462(4):559-71. Epub 2011 Jul 28. Qian F, El Hiani Y, Linsdell P
Functional arrangement of the 12th transmembrane region in the CFTR chloride channel pore based on functional investigation of a cysteine-less CFTR variant.
Pflugers Arch. 2011 Oct;462(4):559-71. Epub 2011 Jul 28., [PMID:21796338]

Abstract [show]
The membrane-spanning part of the cystic fibrosis transmembrane conductance regulator (CFTR) Cl(-) channel comprises 12 transmembrane (TM) alpha-helices, arranged into two pseudo-symmetrical groups of six. While TM6 in the N-terminal TMs is known to line the pore and to make an important contribution to channel properties, much less is known about its C-terminal counterpart, TM12. We have used patch clamp recording to investigate the accessibility of cytoplasmically applied cysteine-reactive reagents to cysteines introduced along the length of TM12 in a cysteine-less variant of CFTR. We find that methanethiosulfonate (MTS) reagents irreversibly modify cysteines substituted for TM12 residues N1138, M1140, S1141, T1142, Q1144, W1145, V1147, N1148, and S1149 when applied to the cytoplasmic side of open channels. Cysteines sensitive to internal MTS reagents were not modified by extracellular [2-(trimethylammonium)ethyl] MTS, consistent with MTS reagent impermeability. Both S1141C and T1142C could be modified by intracellular [2-sulfonatoethyl] MTS prior to channel activation; however, N1138C and M1140C, located deeper into the pore from its cytoplasmic end, were modified only after channel activation. Comparison of these results with previous work on CFTR-TM6 allows us to develop a model of the relative positions, functional contributions, and alignment of these two important TMs lining the CFTR pore. We also propose a mechanism by which these seemingly structurally symmetrical TMs make asymmetric contributions to the functional properties of the channel pore.

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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
207 However, charge-conservative mutations in the analgous part of TM6-for example, in I344C, V345C, M348C, and A349C-also failed to significantly alter Cl-conductance [4]. Login to comment

[hide] Conformational change opening the CFTR chloride ch... Biochim Biophys Acta. 2012 Mar;1818(3):851-60. Epub 2012 Jan 2. Wang W, Linsdell P
Conformational change opening the CFTR chloride channel pore coupled to ATP-dependent gating.
Biochim Biophys Acta. 2012 Mar;1818(3):851-60. Epub 2012 Jan 2., [PMID:22234285]

Abstract [show]
Opening and closing of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel are controlled by ATP binding and hydrolysis by its nucleotide binding domains (NBDs). This is presumed to control opening of a single "gate" within the permeation pathway, however, the location of such a gate has not been described. We used patch clamp recording to monitor access of cytosolic cysteine reactive reagents to cysteines introduced into different transmembrane (TM) regions in a cysteine-less form of CFTR. The rate of modification of Q98C (TM1) and I344C (TM6) by both [2-sulfonatoethyl] methanethiosulfonate (MTSES) and permeant Au(CN)(2)(-) ions was reduced when ATP concentration was reduced from 1mM to 10muM, and modification by MTSES was accelerated when 2mM pyrophosphate was applied to prevent channel closure. Modification of K95C (TM1) and V345C (TM6) was not affected by these manoeuvres. We also manipulated gating by introducing the mutations K464A (in NBD1) and E1371Q (in NBD2). 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. These results suggest that access from the cytoplasm to K95 and V345 is similar in open and closed channels. In contrast, modifying ATP-dependent channel gating alters access to Q98 and I344, located further into the pore. We propose that ATP-dependent gating of CFTR is associated with the opening and closing of a gate within the permeation pathway at the level of these pore-lining amino acids.

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4 Modification of K95C (TM1) and V345C (TM6) was not affected by these manoeuvres. Login to comment
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. Login to comment
52 Example timecourses of macroscopic currents (measured at -50 mV during brief voltage excursions from a holding potential of 0 mV) carried by K95C, Q98C, I344C and V345C as indicated, in inside-out membrane patches. Current amplitudes were measured every 6 s following attainment of stable current amplitude after channel activation. Channels were activated with PKA (20 nM) and either a high concentration of ATP (1 mM; in (A) and (C)-(E)) or a low concentration of ATP (10 μM; (B)). Login to comment
55 In each panel, MTSES (20 μM for K95C, I344C and V345C, and 200 μM for Q98C; see Materials and methods) was applied to the cytoplasmic face of the patch at time zero (as indicated by the hatched bar at the bottom of each panel). Login to comment
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. Login to comment
91 As described previously, at K95C and Q98C (TM1) and at I344C and V345C (TM6), current amplitude is decreased by treatment 100 1000 10000 1 mM ATP 10 µM ATP 1 mM ATP + 2 mM PPi K95C Q98C I344C V345C * * ModificationRateConstant(M-1 s-1 )ModificationRateConstant(M-1 s-1 ) A B K95C Q98C I344C V345C 100 1000 10000 Cys-less +K464A +E1371Q * * * * * * Fig. 3. Login to comment
100 Inspection of these example timecourses indicates that, while such manipulations have no effect on the rate of modification in K95C or V345C, the rate of modification is altered in both Q98C and I344C (Fig. 2A-C). Login to comment
101 Quantification of the mean modification rate constant (as described in Materials and methods) demonstrates that decreasing ATP concentration from 1 mM (Fig. 2A) to 10 μM (Fig. 2B) to decrease channel opening rate significantly decreases the rate of modification in Q98C and I344C (~2.0-fold decrease in modification rate constant; Pb0.01), whereas the rate of modification of K95C and V345C was apparently unaffected (P>0.2) (Fig. 3A). Login to comment
102 Conversely, treatment with PPi (2 mM; Fig. 2C) to inhibit channel closure and increase open probability significantly increases the rate of modification in Q98C and I344C (2.5-2.8-fold increase in modification rate constant; Pb0.01) but has no effect on the rate of modification of K95C and V345C (P>0.4) (Fig. 3A). Login to comment
103 These results suggest that pharmacological manipulation of NBD function results in changes in the accessibility of Q98C and I344C-but not K95C or V345C-to cytoplasmic MTSES. Login to comment
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). Login to comment
112 Conversely, the E1371Q mutation significantly increased the rate of MTSES modification at Q98C and I344C (3.0-3.1-fold increase in modification rate constant; Pb0.02) but had no effect on the rate of modification at K95C or V345C (P>0.25) (Fig. 3B). Login to comment
113 These results therefore suggest that altering NBD function non-pharmacologically by mutagenesis alters accessibility of Q98C and I344C to cytoplasmic MTSES, whereas accessibility of K95C and V345C are unaffected by NBD-driven channel gating. Login to comment
149 In contrast, V345C was not sensitive to inhibition by low concentrations of Au(CN)2 - , although it appeared to show the same sensitivity as cys-less to the voltage-dependent blocking effects of higher concentrations of Au(CN)2 - described above (data not shown). Login to comment
165 For two introduced cysteine residues-K95C in TM1 and V345C in TM6-the rate of modification by cytoplasmic reagents was independent of ATP-dependent channel gating (Figs. 3, 6), suggesting that access to these residues is similar both in open channels and in closed channels. Login to comment
173 As pointed out above, the lack of apparent state-dependence of modification in K95C and V345C suggests that the rate of modification at these sites is similar in closed channels. Login to comment
201 While K95C, Q98C and I344C were rapidly inhibited by low concentrations of cytoplasmic Au(CN)2 - (Fig. 6), V345C showed similar Au(CN)2 - sensitivity as cys-less CFTR (data not shown). Login to comment
202 While the reasons why V345C is apparently not modified by Au(CN)2 - are not clear, we have previously found that not all pore-lining cysteine side chains that can be modified by MTS reagents can also be modified by Au(CN)2 - [14]. Login to comment
203 Furthermore, it has been shown that V345C is insensitive to external Au(CN)2 - , although cysteines substituted for other nearby side chains are inhibited under similar conditions [33]. Login to comment

[hide] Cystic fibrosis transmembrane conductance regulato... Biochemistry. 2011 Nov 29;50(47):10311-7. Epub 2011 Nov 4. Liu X, Dawson DC
Cystic fibrosis transmembrane conductance regulator: temperature-dependent cysteine reactivity suggests different stable conformers of the conduction pathway.
Biochemistry. 2011 Nov 29;50(47):10311-7. Epub 2011 Nov 4., [PMID:22014307]

Abstract [show]
Cysteine scanning has been widely used to identify pore-lining residues in mammalian ion channels, including the cystic fibrosis transmembrane conductance regulator (CFTR). These studies, however, have been typically conducted at room temperature rather than human body temperature. Reports of substantial effects of temperature on gating and anion conduction in CFTR channels as well as an unexpected pattern of cysteine reactivity in the sixth transmembrane segment (TM6) prompted us to investigate the effect of temperature on the reactivity of cysteines engineered into TM6 of CFTR. We compared reaction rates at temperatures ranging from 22 to 37 degrees C for cysteines placed on either side of an apparent size-selective accessibility barrier previously defined by comparing reactivity toward channel-permeant and channel-impermeant, thiol-directed reagents. The results indicate that the reactivity of cysteines at three positions extracellular to the position of the accessibility barrier, 334, 336, and 337, is highly temperature-dependent. At 37 degrees C, cysteines at these positions were highly reactive toward MTSES(-), whereas at 22 degrees C, the reaction rates were 2-6-fold slower to undetectable. An activation energy of 157 kJ/mol for the reaction at position 337 is consistent with the hypothesis that, at physiological temperature, the extracellular portion of the CFTR pore can adopt conformations that differ significantly from those that can be accessed at room temperature. However, the position of the accessibility barrier defined empirically by applying channel-permeant and channel-impermeant reagents to the extracellular aspect of the pore is not altered. The results illuminate previous scanning results and indicate that the assay temperature is a critical variable in studies designed to use chemical modification to test structural models for the CFTR anion conduction pathway.

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131 The values at 37 °C (gray bars) from T339C to V345C reflect small changes in conductance in response to the temperature pulse, rather than reactivity toward MTSES- . Login to comment

[hide] Alignment of transmembrane regions in the cystic f... J Gen Physiol. 2011 Aug;138(2):165-78. Epub 2011 Jul 11. Wang W, El Hiani Y, Linsdell P
Alignment of transmembrane regions in the cystic fibrosis transmembrane conductance regulator chloride channel pore.
J Gen Physiol. 2011 Aug;138(2):165-78. Epub 2011 Jul 11., [PMID:21746847]

Abstract [show]
Different transmembrane (TM) alpha helices are known to line the pore of the cystic fibrosis TM conductance regulator (CFTR) Cl(-) channel. However, the relative alignment of these TMs in the three-dimensional structure of the pore is not known. We have used patch-clamp recording to investigate the accessibility of cytoplasmically applied cysteine-reactive reagents to cysteines introduced along the length of the pore-lining first TM (TM1) of a cysteine-less variant of CFTR. We find that methanethiosulfonate (MTS) reagents irreversibly modify cysteines substituted for TM1 residues K95, Q98, P99, and L102 when applied to the cytoplasmic side of open channels. Residues closer to the intracellular end of TM1 (Y84-T94) were not apparently modified by MTS reagents, suggesting that this part of TM1 does not line the pore. None of the internal MTS reagent-reactive cysteines was modified by extracellular [2-(trimethylammonium)ethyl] MTS. Only K95C, closest to the putative intracellular end of TM1, was apparently modified by intracellular [2-sulfonatoethyl] MTS before channel activation. Comparison of these results with recent work on CFTR-TM6 suggests a relative alignment of these two important TMs along the axis of the pore. This alignment was tested experimentally by formation of disulfide bridges between pairs of cysteines introduced into these two TMs. Currents carried by the double mutants K95C/I344C and Q98C/I344C, but not by the corresponding single-site mutants, were inhibited by the oxidizing agent copper(II)-o-phenanthroline. This inhibition was irreversible on washing but could be reversed by the reducing agent dithiothreitol, suggesting disulfide bond formation between the introduced cysteine side chains. These results allow us to develop a model of the relative positions, functional contributions, and alignment of two important TMs lining the CFTR pore. Such functional information is necessary to understand and interpret the three-dimensional structure of the pore.

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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
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

[hide] Identification of cystic fibrosis transmembrane co... Biophys J. 1996 Jun;70(6):2688-95. Cheung M, Akabas MH
Identification of cystic fibrosis transmembrane conductance regulator channel-lining residues in and flanking the M6 membrane-spanning segment.
Biophys J. 1996 Jun;70(6):2688-95., [PMID:8744306]

Abstract [show]
The cystic fibrosis transmembrane conductance regulator (CFTR) forms a chloride channel that is regulated by phosphorylation and ATP binding. Work by others suggested that some residues in the sixth transmembrane segment (M6) might be exposed in the channel and play a role in ion conduction and selectivity. To identify the residues in M6 that are exposed in the channel and the secondary structure of M6, we used the substituted cysteine accessibility method. We mutated to cysteine, one at a time, 24 consecutive residues in and flanking the M6 segment and expressed these mutants in Xenopus oocytes. We determined the accessibility of the engineered cysteines to charged, lipophobic, sulfhydryl-specific methanethiosulfonate (MTS) reagents applied extracellularly. The cysteines substituted for Ile331, Leu333, Arg334, Lys335, Phe337, Ser341, Ile344, Arg347, Thr351, Arg352, and Gln353 reacted with the MTS reagents, and we infer that they are exposed on the water-accessible surface of the protein. From the pattern of the exposed residues we infer that the secondary structure of the M6 segment includes both alpha-helical and extended regions. The diameter of the channel from the extracellular end to the level of Gln353 must be at least 6 A to allow the MTS reagents to reach these residues.

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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
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

[hide] Metal bridges illuminate transmembrane domain move... J Biol Chem. 2014 Oct 10;289(41):28149-59. doi: 10.1074/jbc.M114.593103. Epub 2014 Aug 20. El Hiani Y, Linsdell P
Metal bridges illuminate transmembrane domain movements during gating of the cystic fibrosis transmembrane conductance regulator chloride channel.
J Biol Chem. 2014 Oct 10;289(41):28149-59. doi: 10.1074/jbc.M114.593103. Epub 2014 Aug 20., [PMID:25143385]

Abstract [show]
Opening and closing of the cystic fibrosis transmembrane conductance regulator are controlled by ATP binding and hydrolysis by the cytoplasmic nucleotide-binding domains. Different conformational changes in the channel pore have been described during channel opening and closing; however, the relative importance of these changes to the process of gating the pore is not known. We have used patch clamp recording to identify high affinity Cd(2+) bridges formed between pairs of pore-lining cysteine residues introduced into different transmembrane alpha-helices (TMs). Seven Cd(2+) bridges were identified forming between cysteines in TMs 6 and 12. Interestingly, each of these Cd(2+) bridges apparently formed only in closed channels, and their formation stabilized the closed state. In contrast, a single Cd(2+) bridge identified between cysteines in TMs 1 and 12 stabilized the channel open state. Analysis of the pattern of Cd(2+) bridge formation in different channel states suggests that lateral separation and convergence of different TMs, rather than relative rotation or translation of different TMs, is the key conformational change that causes the channel pore to open and close.

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51 To investigate potential Cd2af9; bridges formed between pore-lining cysteine side chains exposed in the inner vestibule of the CFTR pore, we combined individual cysteines that we previously found to be accessible to cytoplasmically applied methanethiosulfonate reagents in three important pore-lining TMs: TM1 (K95C, Q98C) (13), TM6 (I344C, V345C, M348C, A349C) (15), and TM12 (M1140C, S1141C, T1142C, Q1144C, W1145C, V1147C, N1148C) (16), to generate a total of 50 double cysteine mutants (8 TM1:TM6; 14 TM1:TM12; 28 TM6:TM12). Login to comment
71 In contrast, the remaining seven double cysteine mutants, namely I344C/S1141C (Fig. 2, C and D), V345C/S1141C, M348C/ S1141C (Fig. 2, C and E), M348C/V1144C, M348C/W1145C, M348C/V1147C, and M348C/N1148C, all showed increased sensitivity to Cd2af9; , leading to a significant decrease in Ki as compared with either of the single cysteine mutants from which they were derived (estimated Ki values b0d; 50 òe;M; Fig. 3). Login to comment
128 Also note that the estimated Ki values for some double mutants were c56;300 òe;M (V345C/M1140C, 316 afe; 38 òe;M, n afd; 3; A349C/M1140C, 345 afe; 58 òe;M, n afd; 3; A349C/T1142C, 231 afe; 68 òe;M, n afd; 3). Login to comment
137 Thus, M348C is able to form Cd2af9; bridges with cysteines at multiple positions in TM12 (S1141C, Q1144C, W1145C, V1147C, N1148C) (Fig. 8B), and S1141C is able to form Cd2af9; bridges with cysteines both in TM1 (K95C) and in TM6 (I344C, V345C, M348C) (Fig. 8C). Login to comment