ABCMdb

ABCC7 p.Lys329Ala

Predicted by SNAP2:	A: N (53%), C: D (66%), D: N (57%), E: D (59%), F: D (66%), G: N (72%), H: N (82%), I: D (71%), L: D (53%), M: D (66%), N: N (82%), P: D (66%), Q: N (72%), R: N (66%), S: N (72%), T: N (72%), V: D (53%), W: D (85%), Y: D (59%),
Predicted by PROVEAN:	A: N, C: N, D: N, E: N, F: N, G: N, H: N, I: N, L: N, M: N, N: N, P: N, Q: N, R: N, S: N, T: N, V: N, W: D, Y: N,

[switch to compact view]
Comments [show]

None has been submitted yet.

Publications
[hide] Molecular determinants of Au(CN)(2)(-) binding and... J Physiol. 2002 Apr 1;540(Pt 1):39-47. Gong X, Burbridge SM, Cowley EA, Linsdell P
Molecular determinants of Au(CN)(2)(-) binding and permeability within the cystic fibrosis transmembrane conductance regulator Cl(-) channel pore.
J Physiol. 2002 Apr 1;540(Pt 1):39-47., 2002-04-01 [PMID:11927667]

Abstract [show]
Lyotropic anions with low free energy of hydration show both high permeability and tight binding in the cystic fibrosis transmembrane conductance regulator (CFTR) Cl(-) channel pore. However, the molecular bases of anion selectivity and anion binding within the CFTR pore are not well defined and the relationship between binding and selectivity is unclear. We have studied the effects of point mutations throughout the sixth transmembrane (TM6) region of CFTR on channel block by, and permeability of, the highly lyotropic Au(CN)(2)(-) anion, using patch clamp recording from transiently transfected baby hamster kidney cells. Channel block by 100 microM Au(CN)(2)(-), a measure of intrapore anion binding affinity, was significantly weakened in the CFTR mutants K335A, F337S, T338A and I344A, significantly strengthened in S341A and R352Q and unaltered in K329A. Relative Au(CN)(2)(-) permeability was significantly increased in T338A and S341A, significantly decreased in F337S and unaffected in all other mutants studied. These results are used to define a model of the pore containing multiple anion binding sites but a more localised anion selectivity region. The central part of TM6 (F337-S341) appears to be the main determinant of both anion binding and anion selectivity. However, comparison of the effects of individual mutations on binding and selectivity suggest that these two aspects of the permeation mechanism are not strongly interdependent.

Comments [show]

None has been submitted yet.

Sentences [show]
No. Sentence Comment
12 Channel block by 100 mM Au(CN)2 _ , a measure of intrapore anion binding affinity, was significantly weakened in the CFTR mutants K335A, F337S, T338A and I344A, significantly strengthened in S341A and R352Q and unaltered in K329A. Login to comment
78 Currents carried by the CFTR mutants K329A, K335A, T338A, S341A and I344A were also stimulated an average of 2_3-fold by PPi (Fig. 2B). Login to comment
86 However, for all mutants studied except K329A, the blocking effects of 100 mM Au(CN)2 _ at _100 mV were significantly altered relative to wild-type (P < 0.05 in each case, Student`s two-tailed t test). Login to comment
87 Comparison between different channel variants at _100 mV reveals the sensitivity to this concentration of Au(CN)2 _ is R352Q > S341A > wild-type, K329A > I344A > K335A = F337S > T338A. Login to comment
95 Results for K329A were indistinguishable from wild-type (not shown). Login to comment
123 At this voltage, block by 100 mM Au(CN)2 _ was significantly weakened in K335A, F337S, T338A and I334A, significantly strengthened in S341A and R352Q and unaffected in K329A (Fig. 3). Login to comment
124 The sequence of relative sensitivity to block by 100 mM Au(CN)2 _ at _100 mV (R352Q > S341A > wild-type, K329A > I344A > K335A = F337S > T338A) suggests that T338 normally makes the strongest contribution to Au(CN)2 _ binding within the pore, with nearby residues K335 and F337 also making large contributions. Login to comment

[hide] Identification of positive charges situated at the... Pflugers Arch. 2008 Nov;457(2):351-60. Epub 2008 May 1. Zhou JJ, Fatehi M, Linsdell P
Identification of positive charges situated at the outer mouth of the CFTR chloride channel pore.
Pflugers Arch. 2008 Nov;457(2):351-60. Epub 2008 May 1., [PMID:18449561]

Abstract [show]
We have used site-directed mutagenesis and functional analysis to identify positively charged amino acid residues in the cystic fibrosis transmembrane conductance regulator (CFTR) Cl(-) channel that interact with extracellular anions. Mutation of two positively charged arginine residues in the first extracellular loop (ECL) of CFTR, R104, and R117, as well as lysine residue K335 in the sixth transmembrane region, leads to inward rectification of the current-voltage relationship and decreased single channel conductance. These effects are dependent on the charge of the substituted side chain and on the Cl(-) concentration, suggesting that these positive charges normally act to concentrate extracellular Cl(-) ions near the outer mouth of the pore. Side chain charge-dependent effects are mimicked by manipulating charge in situ by mutating these amino acids to cysteine followed by covalent modification with charged cysteine-reactive reagents, confirming the location of these side chains within the pore outer vestibule. State-independent modification of R104C and R117C suggests that these residues are located at the outermost part of the pore. We suggest that ECL1 contributes to the CFTR pore external vestibule and that positively charged amino acid side chains in this region act to attract Cl(-) ions into the pore. In contrast, we find no evidence that fixed positive charges in other ECLs contribute to the permeation properties of the pore.

Comments [show]

None has been submitted yet.

Sentences [show]
No. Sentence Comment
122 Considering the data at +80 mV, where the inhibitory effects of Pt(NO2)4 2- are strongest, suggests that Pt(NO2)4 2- inhibition is significantly weakened in R104Q, K335A, and (to a lesser extent) R1128Q but not significantly altered in K114C, R117Q, K329A, K829Q, or R899Q (Fig. 8c). Login to comment

[hide] Evidence that extracellular anions interact with a... Can J Physiol Pharmacol. 2009 May;87(5):387-95. doi: 10.1139/y09-023. Zhou JJ, Linsdell P
Evidence that extracellular anions interact with a site outside the CFTR chloride channel pore to modify channel properties.
Can J Physiol Pharmacol. 2009 May;87(5):387-95. doi: 10.1139/y09-023., [PMID:19448737]

Abstract [show]
Extracellular anions enter into the pore of the cystic fibrosis transmembrane conductance regulator (CFTR) Cl- channel, interacting with binding sites on the pore walls and with other anions inside the pore. There is increasing evidence that extracellular anions may also interact with sites away from the channel pore to influence channel properties. We have used site-directed mutagenesis and patch-clamp recording to identify residues that influence interactions with external anions. Anion interactions were assessed by the ability of extracellular Pt(NO2)42- ions to weaken the pore-blocking effect of intracellular Pt(NO2)42- ions, a long-range ion-ion interaction that does not appear to reflect ion interactions inside the pore. We found that mutations that remove positive charges in the 4th extracellular loop of CFTR (K892Q and R899Q) significantly alter the interaction between extracellular and intracellular Pt(NO2)42- ions. These mutations do not affect unitary Cl- conductance or block of single-channel currents by extracellular Pt(NO2)42- ions, however, suggesting that the mutated residues are not in the channel pore region. These results suggest that extracellular anions can regulate CFTR pore properties by binding to a site outside the pore region, probably by a long-range conformational change. Our findings also point to a novel function of the long 4th extracellular loop of the CFTR protein in sensing and (or) responding to anions in the extracellular solution.

Comments [show]

None has been submitted yet.

Sentences [show]
No. Sentence Comment
67 Similar weakening of block by internal Pt(NO2)4 2-was also observed in K114C, K329A, K335A, and R1128Q (Fig. 2), as well as R334Q (Zhou et al. 2007). Login to comment

[hide] The cystic fibrosis transmembrane conductance regu... Pflugers Arch. 2015 Aug;467(8):1783-94. doi: 10.1007/s00424-014-1618-8. Epub 2014 Oct 4. Broadbent SD, Ramjeesingh M, Bear CE, Argent BE, Linsdell P, Gray MA
The cystic fibrosis transmembrane conductance regulator is an extracellular chloride sensor.
Pflugers Arch. 2015 Aug;467(8):1783-94. doi: 10.1007/s00424-014-1618-8. Epub 2014 Oct 4., [PMID:25277268]

Abstract [show]
The cystic fibrosis transmembrane conductance regulator (CFTR) is a Cl(-) channel that governs the quantity and composition of epithelial secretions. CFTR function is normally tightly controlled as dysregulation can lead to life-threatening diseases such as secretory diarrhoea and cystic fibrosis. CFTR activity is regulated by phosphorylation of its cytosolic regulatory (R) domain, and ATP binding and hydrolysis at two nucleotide-binding domains (NBDs). Here, we report that CFTR activity is also controlled by extracellular Cl(-) concentration ([Cl(-)]o). Patch clamp current recordings show that a rise in [Cl(-)]o stimulates CFTR channel activity, an effect conferred by a single arginine residue, R899, in extracellular loop 4 of the protein. Using NBD mutants and ATP dose response studies in WT channels, we determined that [Cl(-)]o sensing was linked to changes in ATP binding energy at NBD1, which likely impacts NBD dimer stability. Biochemical measurements showed that increasing [Cl(-)]o decreased the intrinsic ATPase activity of CFTR mainly through a reduction in maximal ATP turnover. Our studies indicate that sensing [Cl(-)]o is a novel mechanism for regulating CFTR activity and suggest that the luminal ionic environment is an important physiological arbiter of CFTR function, which has significant implications for salt and fluid homeostasis in epithelial tissues.

Comments [show]

None has been submitted yet.

Sentences [show]
No. Sentence Comment
112 To explore the role of phosphorylation further, we studied the effect of deleting the R domain from CFTR (residues 634-836) [12, 7], which removes all the major PKA/PKC Table 1 Summary of the FSK stimulation of whole cell currents and Erev shifts observed with the CFTR constructs used in this study CFTR Construct n FSK Stimulation (%&#b1;SEM) Erev shift (mV&#b1;SEM) WT (50 bc;M ATP) 5 180&#b1;96 15.0&#b1;3.6 WT (100 bc;M ATP) 6 12,000&#b1;6,000 15.2&#b1;3.0 WT (300 bc;M ATP) 8 1,200&#b1;600 17.0&#b1;3.0 WT (1 mM ATP) 24 13,000&#b1;6,000 23.7&#b1;1.8 WT (1.3 mM ATP) 9 1,400&#b1;900 16.7&#b1;2.6 WT (2 mM ATP) 24 6,100&#b1;5,300 16.7&#b1;1.6 WT (5 mM ATP) 7 1,600&#b1;1,000 20.1&#b1;4.4 WT (50 bc;M ATP + 50 bc;M P-ATP) 7 224&#b1;130 15.3&#b1;1.0 WT + Genistein 4 7,600&#b1;5,200 26.1&#b1;5.4 WT + AMP-PNP 5 2,800&#b1;2,500 21.8&#b1;5.5 WT (3 mM MgCl2) 7 28,000&#b1;17,000 18.3&#b1;3.1 R104Q 5 4,600&#b1;1,600 28.6&#b1;4.7 K114C 5 12,000&#b1;6,700 29.2&#b1;3.0 R117Q 4 33,000&#b1;20,000 30.1&#b1;3.4 K329A 5 13,000&#b1;10,000 33.7&#b1;2.1 R334Q 9 13,000&#b1;6,700 27.3&#b1;2.9 K335A 5 3,200&#b1;1,500 20.8&#b1;7.1 W401G 7 2,600&#b1;1,800 18.5&#b1;4.8 Delta-R (No Stim) 5 - 25.1&#b1;2.7 Delta-R (No FSK, Genistein) 5 140&#b1;13 22.7&#b1;3.0 Delta-R (FSK, No Genistein) 4 89&#b1;14 15.6&#b1;6.0 Delta-R (FSK + Genistein) 6 639&#b1;432 25.1&#b1;4.9 Delta-R-E1371S (No FSK) 9 - 21.4&#b1;4.8 Delta-R-E1371S (FSK) 4 2,600&#b1;1,400 15.3&#b1;4.7 K892Q 7 16,000&#b1;9,500 36.8&#b1;4.8 R899E 4 1,200&#b1;400 25.0&#b1;2.7 R899K 4 1,600&#b1;900 26.6&#b1;2.9 R899Q 7 5,400&#b1;2,800 30.0&#b1;1.3 R899Q + AMP-PNP 4 72,000&#b1;50,000 15.2&#b1;2.8 R899Q-E1371Q (No FSK) 4 - 18.4&#b1;5.9 R899Q-E1371Q (FSK) 6 107&#b1;48 15.6&#b1;3.0 R1128Q 6 14,000&#b1;6,100 41.1&#b1;4.2 Y1219G 6 3,200&#b1;2,500 19.2&#b1;3.3 E1371Q (No FSK) 6 - 25.5&#b1;3.5 E1371Q (FSK) 8 -28&#b1;9 22.3&#b1;4.0 E1371Q (FSK, No ATP, No GTP) 8 270&#b1;130 19.4&#b1;4.5 E1371Q + AMP-PNP (No FSK) 4 - 24.7&#b1;6.5 E1371Q + AMP-PNP (FSK) 8 180&#b1;170 17.4&#b1;4.0 Vector Control 4 15&#b1;38 - FSK stimulation was calculated as the percentage increase in current density at -60 mV from the Erev, after 5-min exposure to 10 bc;M FSK. Login to comment