ABCMdb

ABCC7 p.Thr1134Ala

Predicted by SNAP2:	A: N (53%), C: D (59%), D: D (80%), E: D (85%), F: D (80%), G: D (80%), H: D (85%), I: D (71%), K: D (91%), L: D (75%), M: D (75%), N: D (71%), P: D (85%), Q: D (80%), R: D (91%), S: N (82%), V: D (75%), W: D (85%), Y: D (80%),
Predicted by PROVEAN:	A: N, C: N, D: N, E: N, F: D, G: N, H: D, I: D, K: N, L: D, M: N, N: N, P: D, Q: N, R: N, S: N, V: N, W: D, Y: D,

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[hide] Insight in eukaryotic ABC transporter function by ... FEBS Lett. 2006 Feb 13;580(4):1064-84. Epub 2006 Jan 19. Frelet A, Klein M
Insight in eukaryotic ABC transporter function by mutation analysis.
FEBS Lett. 2006 Feb 13;580(4):1064-84. Epub 2006 Jan 19., 2006-02-13 [PMID:16442101]

Abstract [show]
With regard to structure-function relations of ATP-binding cassette (ABC) transporters several intriguing questions are in the spotlight of active research: Why do functional ABC transporters possess two ATP binding and hydrolysis domains together with two ABC signatures and to what extent are the individual nucleotide-binding domains independent or interacting? Where is the substrate-binding site and how is ATP hydrolysis functionally coupled to the transport process itself? Although much progress has been made in the elucidation of the three-dimensional structures of ABC transporters in the last years by several crystallographic studies including novel models for the nucleotide hydrolysis and translocation catalysis, site-directed mutagenesis as well as the identification of natural mutations is still a major tool to evaluate effects of individual amino acids on the overall function of ABC transporters. Apart from alterations in characteristic sequence such as Walker A, Walker B and the ABC signature other parts of ABC proteins were subject to detailed mutagenesis studies including the substrate-binding site or the regulatory domain of CFTR. In this review, we will give a detailed overview of the mutation analysis reported for selected ABC transporters of the ABCB and ABCC subfamilies, namely HsCFTR/ABCC7, HsSUR/ABCC8,9, HsMRP1/ABCC1, HsMRP2/ABCC2, ScYCF1 and P-glycoprotein (Pgp)/MDR1/ABCB1 and their effects on the function of each protein.

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376 Gupta et al. [178] have examined the effect of T1134A, M1137A, N1138A, S1141A and T1142A and found that, in contrast to those in TM6, mutations in TM12 have little effect on channel permeation properties, suggesting that TM6 and TM12 make highly asymmetric contributions to the pore. Login to comment

[hide] Asymmetric structure of the cystic fibrosis transm... Biochemistry. 2001 Jun 5;40(22):6620-7. Gupta J, Evagelidis A, Hanrahan JW, Linsdell P
Asymmetric structure of the cystic fibrosis transmembrane conductance regulator chloride channel pore suggested by mutagenesis of the twelfth transmembrane region.
Biochemistry. 2001 Jun 5;40(22):6620-7., 2001-06-05 [PMID:11380256]

Abstract [show]
The cystic fibrosis transmembrane conductance regulator (CFTR) Cl(-) channel contains 12 membrane-spanning regions which are presumed to form the transmembrane pore. Although a number of findings have suggested that the sixth transmembrane region plays a key role in forming the pore and determining its functional properties, the role of other transmembrane regions is currently not well established. Here we assess the functional importance of the twelfth transmembrane region, which occupies a homologous position in the carboxy terminal half of the CFTR molecule to that of the sixth transmembrane region in the amino terminal half. Five residues in potentially important regions of the twelfth transmembrane region were mutated individually to alanines, and the function of the mutant channels was examined using patch clamp recording following expression in mammalian cell lines. Three of the five mutations significantly weakened block of unitary Cl(-) currents by SCN(-), implying a partial disruption of anion binding within the pore. Two of these mutations also caused a large reduction in the steady-state channel mean open probability, suggesting a role for the twelfth transmembrane region in channel gating. However, in direct contrast to analogous mutations in the sixth transmembrane region, all mutants studied here had negligible effects on the anion selectivity and unitary Cl(-) conductance of the channel. The relatively minor effects of these five mutations on channel permeation properties suggests that, despite their symmetrical positions within the CFTR protein, the sixth and twelfth transmembrane regions make highly asymmetric contributions to the functional properties of the pore.

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79 Five alanine-substitution mutations in TM12 were constructed: T1134A, M1137A, N1138A, S1141A, and T1142A (Figure 1B). Login to comment
92 Block of N1138A (Figure 2B), as well as T1134A, M1137A, and T1142A (data not shown), appeared somewhat weaker than for wild-type, whereas block of S1141A actually appeared stronger than for wild-type (Figure 2B). Login to comment
95 Unitary Current Properties. Expression of wild-type, T1134A, M1137A, N1138A, and T1142A-CFTR in CHO cells led to the appearance of unitary PKAand ATP-dependent Cl-channel currents in excised membrane patches (Figure 3A). Login to comment
96 As described above, S1141A could not be expressed in CHO cells; however, unitary S1141A-CFTR Table 1: Relative Anion Permeabilities for Wild-Type and Mutant CFTRa wild-type T1134A M1137A N1138A S1141A T1142A Cl 1.00 ( 0.01 (10) 1.00 ( 0.06 (5) 1.00 ( 0.03 (6) 1.00 ( 0.02 (4) 1.00 ( 0.02 (5) 1.00 ( 0.04 (7) Br 1.37 ( 0.07 (8) 1.42 ( 0.03 (4) 1.61 ( 0.02 (5)* 1.32 ( 0.08 (7) 1.54 ( 0.05 (4) 1.44 ( 0.04 (5) I 0.83 ( 0.03 (6) 0.85 ( 0.04 (4) 0.88 ( 0.02 (3) 0.83 ( 0.03 (4) 0.78 ( 0.01 (3) 0.86 ( 0.03 (3) F 0.103 ( 0.007 (9) 0.077 ( 0.008 (3) 0.107 ( 0.014 (3) 0.089 ( 0.005 (4) 0.053 ( 0.003 (7)** 0.094 ( 0.007 (3) SCN 3.55 ( 0.26 (7) 3.70 ( 0.33 (4) 3.58 ( 0.14 (5) 3.53 ( 0.21 (6) 3.37 ( 0.35 (3) 3.64 ( 0.22 (5) NO3 1.58 ( 0.04 (10) 1.62 ( 0.05 (4) 1.60 ( 0.04 (3) 1.58 ( 0.05 (6) 1.57 ( 0.03 (3) 1.64 ( 0.07 (3) ClO4 0.25 ( 0.01 (8) 0.22 ( 0.00 (3) 0.29 ( 0.02 (3) 0.44 ( 0.05 (5)** 0.22 ( 0.01 (3) 0.30 ( 0.03 (5) formate 0.24 ( 0.01 (9) 0.26 ( 0.01 (3) 0.27 ( 0.03 (3) 0.27 ( 0.01 (4) 0.26 ( 0.02 (4) 0.25 ( 0.03 (3) acetate 0.091 ( 0.003 (10) 0.102 ( 0.021 (3) 0.103 ( 0.011 (3) 0.087 ( 0.022 (3) 0.066 ( 0.007 (4)* 0.086 ( 0.009 (3) a Relative permeabilities (PX/PCl) for different anions present in the intracellular solution under biionic conditions were calculated from macroscopic current reversal potentials according to eq 1 (see Experimental Procedures), as described in detail previously (16, 20, 36). Login to comment
109 Block by SCN- appeared somewhat weakened in N1138A (left), as well as in T1134A, M1137A and T1142A (data not shown, but see Figure 5B), and strengthened in S1141A (right). Login to comment
119 Under steady-state conditions, each of those mutants which could be expressed in CHO cells appeared to have a lower mean channel open probability (PO) than wild-type, although this difference was only statistically significant for T1134A and M1137A (Figure 4B; P < 0.001, two-tailed t-test). Login to comment
128 However, the degree of block was significantly reduced in T1134A, M1137A, and S1141A compared to wild-type (Figure 5). Login to comment
138 For wild-type, T1134A, and M1137A, data from these two different methods are in good agreement, however, for other TM12 mutants there is a significant discrepancy [(†) P < 0.01, (‡) P < 0.001, two-tailed t-test]. Login to comment
143 For wild-type CFTR, as well as for T1134A and M1137A, the inhibitory effects of 10 mM SCN- at -50 mV were the same at the macroscopic and single channel levels (Figure 5B). Login to comment
144 However, for N1138A, S1141A, and T1142A, different degrees of inhibition were observed, suggesting that SCN- has some other effect on these mutants which is both distinct from the observed reduction in unitary current amplitude and absent in wild-type CFTR. Since the single channel results report the isolated effects of SCN- on unitary current amplitude, which is presumably determined by the relative tightness of SCN- binding within the pore, we believe that the reduced apparent SCN- binding affinity suggested by the single channel results with T1134A, M1137A, and S1141A is the best reporter of altered pore function in these mutants. Login to comment
174 Block of unitary Cl- currents by SCN- was significantly weakened in T1134A, M1137A, and S1141A compared to wild-type (Figure 5). Login to comment
184 Mean channel PO under steady-state conditions was reduced to 32% of wild-type levels in T1134A, and to 25% of wild-type in M1137A (Figures 3A and 4B). Login to comment

[hide] Identification of a region of strong discriminatio... Am J Physiol Lung Cell Mol Physiol. 2001 Oct;281(4):L852-67. McCarty NA, Zhang ZR
Identification of a region of strong discrimination in the pore of CFTR.
Am J Physiol Lung Cell Mol Physiol. 2001 Oct;281(4):L852-67., [PMID:11557589]

Abstract [show]
The variety of methods used to identify the structural determinants of anion selectivity in the cystic fibrosis transmembrane conductance regulator Cl(-) channel has made it difficult to assemble the data into a coherent framework that describes the three-dimensional structure of the pore. Here, we compare the relative importance of sites previously studied and identify new sites that contribute strongly to anion selectivity. We studied Cl(-) and substitute anions in oocytes expressing wild-type cystic fibrosis transmembrane conductance regulator or 12-pore-domain mutants to determine relative permeability and relative conductance for 9 monovalent anions and 1 divalent anion. The data indicate that the region of strong discrimination resides between T338 and S341 in transmembrane 6, where mutations affected selectivity between Cl(-) and both large and small anions. Mutations further toward the extracellular end of the pore only strongly affected selectivity between Cl(-) and larger anions. Only mutations at S341 affected selectivity between monovalent and divalent anions. The data are consistent with a narrowing of the pore between the extracellular end and a constriction near the middle of the pore.

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60 Mutants K335E, K335F, T338A, T339A, S341A, S341T, T1134A, and T1134F were prepared as previously described (33). Login to comment
143 Relative permeabilities for WT and mutant CFTRs for monovalent anions CFTR n NO3 Br SCN I ClO4 Acetate Isethionate Glutamate Gluconate WT 16 1.35Ϯ0.01 1.19Ϯ0.02 2.42Ϯ0.06 0.36Ϯ0.01 0.10Ϯ0.01 0.15Ϯ0.00* 0.24Ϯ0.01 0.24Ϯ0.01 0.18Ϯ0.01 K335A 5 1.35Ϯ0.01 1.36Ϯ0.03 3.10Ϯ0.11† 0.75Ϯ0.02† 0.12Ϯ0.01 0.06Ϯ0.01† 0.07Ϯ0.01† 0.07Ϯ0.01† 0.08Ϯ0.01† K335F 7 1.51Ϯ0.03† 1.36Ϯ0.02† 2.73Ϯ0.14 0.99Ϯ0.03† 0.20Ϯ0.02† 0.13Ϯ0.01 0.18Ϯ0.03 0.30Ϯ0.02 0.20Ϯ0.02 K335E 5 1.24Ϯ0.04 1.17Ϯ0.02 2.60Ϯ0.06 1.10Ϯ0.03† 0.23Ϯ0.01† 0.10Ϯ0.01† 0.11Ϯ0.01† 0.10Ϯ0.01† 0.11Ϯ0.01† T338A 5 1.74Ϯ0.07† 1.59Ϯ0.02† 4.35Ϯ0.24† 2.56Ϯ0.13† 1.84Ϯ0.08† 0.07Ϯ0.01† 0.06Ϯ0.01† 0.08Ϯ0.01† 0.08Ϯ0.01† T338E 3 3.65Ϯ0.19† 1.94Ϯ0.04† 4.29Ϯ0.13† 2.41Ϯ0.24† 1.18Ϯ0.06† 0.16Ϯ0.03 0.37Ϯ0.05† 0.36Ϯ0.01† 0.22Ϯ0.03 T339A 5 1.47Ϯ0.01 1.29Ϯ0.03 2.65Ϯ0.06 0.57Ϯ0.02† 0.24Ϯ0.04 0.10Ϯ0.02 0.19Ϯ0.02 0.18Ϯ0.01 0.15Ϯ0.01 S341A 6 1.91Ϯ0.02† 1.42Ϯ0.01† 3.10Ϯ0.09† 0.59Ϯ0.00*† 0.09Ϯ0.00* 0.11Ϯ0.01† 0.12Ϯ0.00*† 0.11Ϯ0.00*† 0.12Ϯ0.00*† S341E 12 2.01Ϯ0.10† 1.46Ϯ0.05† 2.81Ϯ0.18 0.84Ϯ0.00*† 0.31Ϯ0.03† 0.20Ϯ0.01 0.23Ϯ0.02 0.19Ϯ0.01 0.19Ϯ0.02 S341T 5 1.81Ϯ0.05† 1.39Ϯ0.03 3.15Ϯ0.15† 0.41Ϯ0.01 0.07Ϯ0.00* 0.05Ϯ0.00*† 0.06Ϯ0.00*† 0.03Ϯ0.01† 0.06Ϯ0.01† T1134A 6 1.43Ϯ0.02 1.30Ϯ0.02 2.66Ϯ0.02 0.46Ϯ0.00*† 0.06Ϯ0.00*† 0.08Ϯ0.01† 0.10Ϯ0.01† 0.11Ϯ0.01† 0.10Ϯ0.00*† T1134F 5 1.31Ϯ0.07 1.17Ϯ0.05 2.50Ϯ0.10 0.63Ϯ0.01† 0.08Ϯ0.00* 0.13Ϯ0.01 0.09Ϯ0.01† 0.18Ϯ0.02 0.13Ϯ0.01 T1134E 4 1.68Ϯ0.02† 1.39Ϯ0.05† 2.37Ϯ0.18 0.19Ϯ0.03† 0.20Ϯ0.03 0.06Ϯ0.01† 0.09Ϯ0.01† 0.08Ϯ0.01† 0.10Ϯ0.01† Values are means Ϯ SE with only data from the hyperpolarizing ramp protocol; n, no. of oocytes. Relative permeability, permeability of anion x to that of Cl. Anions are listed in order of increasing ionic radius. Login to comment
167 Selectivity sequences for WT and mutant CFTRs CFTR Selectivity Sequence by Relative Permeability WT SCNϾϾNO3 ϾBrϾClϾϾIϾisethionateϭglutamateϾgluconateϭacetateϾClO4 K335A SCNϾϾBrϭNO3 ϾClϾIϾϾClO4 Ͼgluconateϭisethionateϭglutamateϭacetate K335F SCNϾϾNO3 ϾBrϾClϭIϾϾglutamateϾgluconateϭClO4 ϭisethionateϾacetate K335E SCNϾϾNO3 ϾBrϭIϾClϾϾClO4 Ͼgluconateϭisethionateϭglutamateϭacetate T338A SCNϾϾIϾϾClO4 ϭNO3 ϾBrϾClϾϾgluconateϭisethionateϭglutamateϭacetate T338E SCNϾNO3 ϾIϾBrϾClO4 ϾClϾϾisethionateϭglutamateϾgluconateϭacetate T339A SCNϾϾNO3 ϾBrϾClϾϾIϾϾClO4 ϭisethionateϭglutamateϭgluconateϾacetate S341A SCNϾNO3 ϾBrϾClϾϾIϾϾgluconateϭisethionateϭglutamateϭacetateϭClO4 S341E SCNϾNO3 ϾBrϾClϾIϾϾClO4 Ͼisethionateϭacetateϭglutamateϭgluconate S341T SCNϾϾNO3 ϾBrϾClϾϾIϾϾClO4 ϭisethionateϭgluconateϭacetateϭglutamate T1134A SCNϾϾNO3 ϾBrϾClϾϾIϾϾglutamateϭisethionateϭgluconateϭacetateϭClO4 T1134F SCNϾϾNO3 ϾBrϾClϾϾIϾϾglutamateϾacetateϭgluconateϾisethionateϭClO4 T1134E SCNϾNO3 ϾBrϾClϾϾClO4 ϭIϾgluconateϭisethionateϭglutamateϭacetate L856 A REGION OF STRONG DISCRIMINATION IN THE CFTR PORE AJP-Lung Cell Mol Physiol • VOL 281 • OCTOBER 2001 • www.ajplung.org out propagation to distant sites. Login to comment
191 Relative conductances for WT and mutant CFTRs for monovalent anions CFTR n NO3 Br SCN I ClO4 Acetate Isethionate Glutamate Gluconate WT 16 0.87Ϯ0.01 0.77Ϯ0.01 0.18Ϯ0.01 0.25Ϯ0.01 0.23Ϯ0.01 0.55Ϯ0.01 0.50Ϯ0.01 0.57Ϯ0.02 0.56Ϯ0.02 K335A 5 0.88Ϯ0.04 0.77Ϯ0.02 0.30Ϯ0.02† 0.35Ϯ0.02 0.24Ϯ0.02 0.33Ϯ0.01† 0.32Ϯ0.02† 0.37Ϯ0.02† 0.38Ϯ0.02† K335F 7 1.21Ϯ0.05† 0.87Ϯ0.02† 0.55Ϯ0.02† 0.36Ϯ0.01† 0.19Ϯ0.01 0.34Ϯ0.01† 0.34Ϯ0.01† 0.41Ϯ0.01† 0.37Ϯ0.01† K335E 5 1.16Ϯ0.05† 0.91Ϯ0.02† 0.59Ϯ0.02† 0.51Ϯ0.02† 0.28Ϯ0.01 0.22Ϯ0.01† 0.25Ϯ0.01† 0.22Ϯ0.01† 0.24Ϯ0.01† T338A 5 1.20Ϯ0.13† 1.03Ϯ0.06† 0.98Ϯ0.12† 0.82Ϯ0.02† 0.50Ϯ0.04† 0.18Ϯ0.05† 0.08Ϯ0.01† 0.31Ϯ0.05† 0.29Ϯ0.05† T338E 3 3.66Ϯ0.36† 1.53Ϯ0.09† 1.80Ϯ0.12† 1.39Ϯ0.11† 0.87Ϯ0.03† 0.36Ϯ0.04† 0.56Ϯ0.17 0.44Ϯ0.03† 0.48Ϯ0.03† T339A 5 1.01Ϯ0.02† 0.77Ϯ0.03 0.22Ϯ0.01 0.31Ϯ0.03 0.23Ϯ0.01 0.38Ϯ0.02† 0.48Ϯ0.01 0.48Ϯ0.01 0.52Ϯ0.01 S341A 6 1.67Ϯ0.01† 1.08Ϯ0.01† 0.63Ϯ0.03† 0.26Ϯ0.00* 0.15Ϯ0.01† 0.63Ϯ0.01† 0.54Ϯ0.02 0.63Ϯ0.01 0.63Ϯ0.01 S341E 12 1.74Ϯ0.11† 1.14Ϯ0.02† 1.81Ϯ0.06† 0.48Ϯ0.01† 0.35Ϯ0.02† 0.28Ϯ0.01† 0.69Ϯ0.02† 0.65Ϯ0.01† 0.68Ϯ0.01† S341T 5 0.85Ϯ0.02 0.82Ϯ0.01 0.29Ϯ0.01† 0.22Ϯ0.01 0.13Ϯ0.01† 0.48Ϯ0.01 0.45Ϯ0.02 0.43Ϯ0.02 0.55Ϯ0.01 T1134A 6 0.83Ϯ0.02 0.78Ϯ0.01 0.24Ϯ0.01† 0.21Ϯ0.01 0.09Ϯ0.01† 0.39Ϯ0.01† 0.38Ϯ0.01† 0.39Ϯ0.01† 0.40Ϯ0.01 T1134F 5 0.68Ϯ0.03† 0.69Ϯ0.03† 0.36Ϯ0.01† 0.07Ϯ0.01† 0.16Ϯ0.01 0.48Ϯ0.02 0.30Ϯ0.02† 0.22Ϯ0.01† 0.32Ϯ0.02† T1134E 4 0.99Ϯ0.02† 1.00Ϯ0.02† 0.50Ϯ0.02† 0.20Ϯ0.03 0.26Ϯ0.02 0.32Ϯ0.03† 0.34Ϯ0.01† 0.34Ϯ0.03† 0.34Ϯ0.03† Values are means Ϯ SE with only data from the hyperpolarizing ramp protocol; n, no. of oocytes. Relative conductance, conductance of anion x to that of Cl. Anions are listed in order of increasing ionic radius. Login to comment
197 The shape of the I-V curve between -80 and ϩ60 mV was not affected by the K335A, T338A, T339A, or T1134A mutations, whereas S341A CFTR exhibited less outward rectification than WT CFTR. Login to comment
203 K335A and T1134A CFTR exhibited decreased Gx/GCl values for most anions, with radii as large as or larger than acetate. Login to comment
204 However, neither Px/PCl nor Gx/GCl values for the smallest anions (NO3 - and Br- ) were altered in K335A CFTR or T1134A CFTR compared with WT CFTR. Login to comment
213 Vrev Cl in ND96 bath solution for WT and mutant CFTRs CFTR n Vrev Cl WT 16 -21.24Ϯ0.59 K335A 5 -22.12Ϯ0.35 K335F 7 -21.92Ϯ0.90 K335E 5 -22.88Ϯ0.36 T338A 5 -26.97Ϯ0.79* T338E 3 -20.58Ϯ1.07 T339A 5 -22.21Ϯ0.98 S341A 6 -21.21Ϯ0.56 S341E 12 -28.77Ϯ1.36* S341T 5 -26.62Ϯ1.43* T1134A 6 -28.33Ϯ1.23* T1134F 5 -19.74Ϯ0.73 T1134E 4 -27.54Ϯ1.27* Values are means Ϯ SE; n, no. of oocytes. Login to comment
218 T1134F CFTR exhibited a similar pattern except that GNO3/GCl and GBr/GCl were decreased and GSCN/GCl was increased compared with T1134A CFTR. Login to comment
255 The one exception to this pattern is the decreased GClO4/GCl in T1134A CFTR. Login to comment
268 Px/PCl and Gx/GCl values for each anion x in each mutant were calculated for T1134A, K335A, T338A, T339A, and S341A CFTRs and normalized to Px/PCl and Gx/GCl values for WT CFTR. Login to comment
316 The overall discriminating power was approximately the same for WT, K335A, T339A, and T1134A CFTR. Login to comment
388 Selectivity between Cl- and the divalent anion S2O3 2CFTR n GS2O3/GCl WT 16 0.39Ϯ0.01 K335A 5 0.37Ϯ0.01 K335F 7 0.39Ϯ0.01 K335E 5 0.34Ϯ0.01* T338A 5 0.38Ϯ0.01 T338E 3 0.70Ϯ0.08* T339A 5 0.39Ϯ0.02 S341A 6 0.27Ϯ0.01* S341E 12 0.54Ϯ0.01* S341T 5 0.38Ϯ0.01 T1134A 6 0.34Ϯ0.02 T1134F 5 0.33Ϯ0.01* T1134E 4 0.44Ϯ0.05 Values are means Ϯ SE; n, no. of oocytes. Login to comment
464 However, our data show that mutations K335A and T1134A had nearly identical effects on selectivity patterns between large and small anions, as if these amino acids occupy nearly homologous positions in TM6 and TM12. Login to comment

[hide] Point mutations in the pore region directly or ind... Pflugers Arch. 2002 Mar;443(5-6):739-47. Epub 2001 Dec 8. Gupta J, Linsdell P
Point mutations in the pore region directly or indirectly affect glibenclamide block of the CFTR chloride channel.
Pflugers Arch. 2002 Mar;443(5-6):739-47. Epub 2001 Dec 8., [PMID:11889571]

Abstract [show]
The sulfonylurea glibenclamide is a relatively potent inhibitor of the CFTR Cl(-) channel. This inhibition is thought to be via an open channel block mechanism. However, nothing is known about the physical nature of the glibenclamide-binding site on CFTR. Here we show that mutations in the pore-forming 6th and 12th transmembrane regions of CFTR affect block by intracellular glibenclamide, confirming previous suggestions that glibenclamide enters the pore in order to block the channel. Two mutations in the 6th transmembrane region, F337A and T338A, significantly weakened glibenclamide block, consistent with a direct interaction between glibenclamide and this region of the pore. Interestingly, two mutations in the 12th transmembrane region (N1138A and T1142A) significantly strengthened block. These two mutations also abolished the dependence of block on the extracellular Cl(-) concentration, which in wild-type CFTR suggests an interaction between Cl(-) and glibenclamide within the channel pore that limits block. We suggest that mutations in the 12th transmembrane region strengthen glibenclamide block not by directly altering interactions between glibenclamide and the pore walls, but indirectly by reducing interactions between Cl(-) ions and glibenclamide within the pore. This work demonstrates that glibenclamide binds within the CFTR channel pore and begins to define its intrapore binding site.

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63 While block of the TM12 mutants S1141A (Fig. 1) and T1134A and M1137A (data not shown) was indistinguishable from wild-type, block was significantly weakened in the TM6 mutants F337A and T338A, and significantly strengthened in the TM12 mutants N1138A and T1142A (Fig. 1). Login to comment
71 In contrast, I/I0 was not altered in T1134A, M1137A or S1141A at any voltage (data not shown). Login to comment
116 This does not appear to be a nonspecific effect of mutagenesis within TM12, since three other mutations in this region (T1134A, M1137A, S1141A) had no effect on glibenclamide block (Fig. 3). Login to comment
135 Interestingly, these two mutations did not affect SCN- block, although other TM12 mutants (T1134A, M1137A, S1141A) did [10], suggesting that Cl- and SCN- binding may be controlled by different structural features within TM12. 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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212 In contrast, mutations in the analogous part of TM12 have been found to have little effect on conductance, which was reported as being unaltered in T1134A and M1137A [15] and slightly decreased in the less conservative T1134F [31]. Login to comment

[hide] Differential contribution of TM6 and TM12 to the p... Pflugers Arch. 2012 Mar;463(3):405-18. Epub 2011 Dec 13. Cui G, Song B, Turki HW, McCarty NA
Differential contribution of TM6 and TM12 to the pore of CFTR identified by three sulfonylurea-based blockers.
Pflugers Arch. 2012 Mar;463(3):405-18. Epub 2011 Dec 13., [PMID:22160394]

Abstract [show]
Previous studies suggested that four transmembrane domains 5, 6, 11, 12 make the greatest contribution to forming the pore of the CFTR chloride channel. We used excised, inside-out patches from oocytes expressing CFTR with alanine-scanning mutagenesis in amino acids in TM6 and TM12 to probe CFTR pore structure with four blockers: glibenclamide (Glyb), glipizide (Glip), tolbutamide (Tolb), and Meglitinide. Glyb and Glip blocked wildtype (WT)-CFTR in a voltage-, time-, and concentration-dependent manner. At V (M) = -120 mV with symmetrical 150 mM Cl(-) solution, fractional block of WT-CFTR by 50 muM Glyb and 200 muM Glip was 0.64 +/- 0.03 (n = 7) and 0.48 +/- 0.02 (n = 7), respectively. The major effects on block by Glyb and Glip were found with mutations at F337, S341, I344, M348, and V350 of TM6. Under similar conditions, fractional block of WT-CFTR by 300 muM Tolb was 0.40 +/- 0.04. Unlike Glyb, Glip, and Meglitinide, block by Tolb lacked time-dependence (n = 7). We then tested the effects of alanine mutations in TM12 on block by Glyb and Glip; the major effects were found at N1138, T1142, V1147, N1148, S1149, S1150, I1151, and D1152. From these experiments, we infer that amino acids F337, S341, I344, M348, and V350 of TM6 face the pore when the channel is in the open state, while the amino acids of TM12 make less important contributions to pore function. These data also suggest that the region between F337 and S341 forms the narrow part of the CFTR pore.

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No. Sentence Comment
163 Effects on time-dependent block by mutations R334A and K335A Fractional block by Glip200 μM V1153A D1152A I1151A S1150A S1149A N1148A V1147A A1146S W1145A Q1144A L1143A T1142A S1141A M1140A I1139A N1138A M1137A A1136S L1135A T1134A WT 0 0.2 0.4 0.6 0.8 * ** ** ** ** ** ** * V1153A D1152A I1151A S1150A S1149A N1148A V1147A A1146S W1145A Q1144A L1143A T1142A S1141A M1140A I1139A N1138A M1137A A1136S L1135A T1134A WT 0 0.2 0.4 0.6 0.8 1.0 * * * * * ** ** ** ** Fractional block by Glyb50 μM Fig. 4 Alanine-scanning in TM12 to identify amino acids that interact with Glyb and Glip. Login to comment
192 S1141A (-0.83±0.02 pA, n=5) increased and T1134A (-0.59±0.02 pA, n=4) decreased single-channel full open state amplitude compared to WT-CFTR (-0.70±0.03 pA, n=10; Fig. 9). Login to comment
239 Hence, strong time-dependent block of macropatch currents, and the appearance of multiple drug-induced closed states in single-channel recordings, may not arise from 0.4 pA 2 s M348A c f 0.2 pA 2 s F337A c f 0.4 pA 2 s K335A c f 0.4 pA 2 s c s2 f D1152A 0.4 pA 2 s T1134A c f 0.4 pA 2 s S1141A c f s2 0.4 pA 2 s c f WT 2000 4000 #ofevents 0.0 -0.5 -1.0 Current (pA) -1.50.5 3000 9000 #ofevents 0.0 -0.5 -1.0 Current (pA) -1.50.5 6000 400 1200 #ofevents 0.0 -0.5 -1.0 Current (pA) -1.50.5 800 1600 1000 3000 #ofevents 0.0 -0.5 -1.0 Current (pA) -1.50.5 2000 500 #ofevents 0.0 -0.5 -1.0 Current (pA) -1.50.5 1000 4000 12000 #ofevents 0.0 -0.5 -1.0 Current (pA) -1.50.5 8000 200 600 #ofevents 0.0 -0.5 -1.0 Current (pA) -1.50.5 400 Fig. 9 Representative single-channel traces for WT-, K335A-, F337A-, M348A-, T1134A-, S1141A-, and D1152A-CFTR (left) from excised inside-out membrane patches with symmetrical 150 mM Cl- solution, and their all-points amplitude histograms (right). Login to comment

[hide] Novel pore-lining residues in CFTR that govern per... Neuron. 1994 Sep;13(3):623-34. McDonough S, Davidson N, Lester HA, McCarty NA
Novel pore-lining residues in CFTR that govern permeation and open-channel block.
Neuron. 1994 Sep;13(3):623-34., [PMID:7522483]

Abstract [show]
The cystic fibrosis transmembrane conductance regulator (CFTR) is both a member of the ATP-binding cassette superfamily and a Cl(-)-selective ion channel. We investigated the permeation pathway of human CFTR with measurements on conduction and open-channel blockade by diphenylamine-2-carboxylic acid (DPC). We used site-directed mutagenesis and oocyte expression to locate residues in transmembrane domain (TM) 6 and TM 12 that contact DPC and control rectification and single-channel conductances. Thus, TM 12 and the previously investigated TM 6 line the CFTR pore. In each TM, residues in contact with DPC are separated by two turns of an alpha helix. The contributions of TM 6 and TM 12 to DPC block and Cl- permeation, however, are not equivalent. The resulting structural model for the conduction pathway may guide future studies of permeation in other Cl- channels and ATP-binding cassette transporters.

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No. Sentence Comment
78 Affinity and Voltage Dependence for Block of CFTR Variants by DPC Construct TM Ko( - 100) (PM) 0 I-V Relation n Properties Wild type Wild type low [Cl-], (10 mM) K335E 6 K335F 6 T338A 6 T339A 6 S341A 6 S341T 6 S1118A 11 T1134A 12 T1134F 12 S1141A 12 Triple 6,12 276 f 14 181 f 13" 303 -t 14 351 * 15' 220 * 14 284 * 47 1251 f 116a 530 f 80" 243 * 37 230 * 20 74 * 3" 220 * 13 325 * 26b 0.41 f 0.01 0.32 f 0.02" 0.42 f 0.01 0.42 f 0.02 0.36 f 0.02" 0.44 * 0.12 0.49 * 0.03" 0.35 f 0.09 0.40 f 0.02 0.35 * 0.02" 0.41 f 0.01 0.42 f 0.03 0.21 * O.Ol",b Linear, E,,, = -8 f 1 mV Ere\ = +48+2mV Inward rectification Linear Linear Linear Strong inward rectification Inward rectification Linear Linear Linear Linear Strong inward rectification Affinity for DPC was determined empirically at -100 mV, from whole-cell currents measured in the presence of 200 uM DPC (see Experimental Procedures). Login to comment
230 Control mutation T1134A has insignificant effects on DPC binding, as does mutation SIIIBA, in TM 11 at a position homologous to T1134. Login to comment