Brown AL et al. (2007), Gain-of-function mutations in the MEC-4 DEG/ENa...

XB-ART-35183

J Gen Physiol 2007 Feb 01;1292:161-73. doi: 10.1085/jgp.200609672.

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Gain-of-function mutations in the MEC-4 DEG/ENaC sensory mechanotransduction channel alter gating and drug blockade.

Brown AL , Fernandez-Illescas SM , Liao Z , Goodman MB .

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MEC-4 and MEC-10 are the pore-forming subunits of the sensory mechanotransduction complex that mediates touch sensation in Caenorhabditis elegans (O'Hagan, R., M. Chalfie, and M.B. Goodman. 2005. Nat. Neurosci. 8:43-50). They are members of a large family of ion channel proteins, collectively termed DEG/ENaCs, which are expressed in epithelial cells and neurons. In Xenopus oocytes, MEC-4 can assemble into homomeric channels and coassemble with MEC-10 into heteromeric channels (Goodman, M.B., G.G. Ernstrom, D.S. Chelur, R. O'Hagan, C.A. Yao, and M. Chalfie. 2002. Nature. 415:1039-1042). To gain insight into the structure-function principles that govern gating and drug block, we analyzed the effect of gain-of-function mutations using a combination of two-electrode voltage clamp, single-channel recording, and outside-out macropatches. We found that mutation of A713, the d or degeneration position, to residues larger than cysteine increased macroscopic current, open probability, and open times in homomeric channels, suggesting that bulky residues at this position stabilize open states. Wild-type MEC-10 partially suppressed the effect of such mutations on macroscopic current, suggesting that subunit-subunit interactions regulate open probability. Additional support for this idea is derived from an analysis of macroscopic currents carried by single-mutant and double-mutant heteromeric channels. We also examined blockade by the diuretic amiloride and two related compounds. We found that mutation of A713 to threonine, glycine, or aspartate decreased the affinity of homomeric channels for amiloride. Unlike the increase in open probability, this effect was not related to size of the amino acid side chain, indicating that mutation at this site alters antagonist binding by an independent mechanism. Finally, we present evidence that amiloride block is diffusion limited in DEG/ENaC channels, suggesting that variations in amiloride affinity result from variations in binding energy as opposed to accessibility. We conclude that the d position is part of a key region in the channel functionally and structurally, possibly representing the beginning of a pore-forming domain.

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Species referenced: Xenopus laevis
Genes referenced: plin1 tbx2

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	Figure 1. The peri-TM2 domain of MEC-4, MEC-10, and rat ENaCs. The d position is highlighted in red. In 267 proteins from 36 species in the DEG/ENaC superfamily, the d position is occupied by S > A > G > N in descending order of frequency (Bateman et al., 2004). Residues n after the d position are labeled d + n as referenced in the text. Residue d+7 is indicated with *; mutations at this position in ENaC decrease amiloride Ki' by â¼1,000-fold (Schild et al., 1997).
	Figure 2. Macroscopic amiloride-sensitive current carried by A713X isoforms. (A) Current amplitude vs. side chain volume at the d position. Current was measured at â85 mV. F(6,109) = 8.226, P = 2.38eâ07. (B) Current amplitude at â85 mV vs. reversal potential. The reversal potential was measured from amiloride-sensitive I-V curves derived from voltage ramps. We recorded from at least seven cells harvested from at least two frogs for all isoforms. Marker size is proportional to side chain volume in A and B.
	Figure 3. Steady-state open probability, Po (A), single-channel conductance, Î³ (B), and estimated channel number, N (C), as a function of side-chain volume. Microscopic parameters, Po and Î³, were determined from outside-out patches containing one to two channels. The square root of the probability of not being closed was used as an estimate of Po for two-channel patches. N was estimated as described in the Results. The data are summarized in Table II. One-way ANOVAs for Po, Î³, and N were as follows: F(5,46) = 8.354, P = 1.11e-05; F(5,46) = 6.791, P = 8.12e-05; and F(5, 97) = 12.94, P = 1.2e-09. Pairwise Dunnet's test with respect to wild-type: *, P < 0.01.
	Figure 4. Single-channel recordings of A713X isoforms at â150 mV. Inward current is down and substates are indicated by a horizontal dashed line. To the left of each trace is a segment of the same recording (displayed on a compressed timescale) showing current in the presence (t < 0) and absence (t > 0) of 50 Î¼M amiloride. All-points histograms are to the right of each trace, including fits to the distribution with a sum of Gaussians. The peak corresponding to the closed state is indicated by the vertical dashed line. Similar results were obtained in at least four patches for each isoform.
	Figure 5. Steady-state blockade by amiloride-related compounds. (A) Normalized doseâresponse curves at â60 mV for amiloride (left), benzamil (center), and benzamidine (right). Solid and open circles are data for A713wt and A713T channels, respectively. (B) Effect of mutation on Ki' at â60 mV. (C) Antagonist Ki' vs. voltage. Six A713X isoforms were tested for amiloride blockade: solid circles (A713wt), solid squares (A713V), and solid triangles (A713C); open circles (A713T), open squares (A713D), and open triangles (A713G). Curves were fit to the data according to Woodhull's model of voltage- dependent blockade by charged molecules (Woodhull, 1973). See Table II for fitting parameters and the number of oocytes tested for each isoform and compound.
	Figure 6. Kinetics of blockade by amiloride-related compounds. (A) Time course of the effect of benzamil on A713wt in outside-out macropatches. Vh = â60 mV. Traces corresponding to the effect of 0.1, 0.4, 1.6, and 20 Î¼M benzamil are shown and shaded in proportion to the concentration. (B) On-rates depend on concentration, voltage, and compound. Closed circles are amiloride at Vh = â60 mV (n = 6), open circles are amiloride at Vh = â100 mV (n = 3), hatched circles are benzamil at Vh = â60 mV. (C) Off-rates depend on voltage and compound, but not concentration. All points are mean Â± SEM; lines are fits to averages weighted by the standard deviations.
	Figure 7. Macroscopic current and amiloride block of MEC-4/MEC-10 heteromultimeric channels. (A) Amiloride-sensitive current in wild type, cysteine single-mutant, and cysteine double-mutant heteromeric channels. (B) Amiloride-sensitive current in wild type, aspartate single-mutant, and aspartate double-mutant heteromeric channels. (C) Amiloride-sensitive current in wild type, valine single-mutant, and valine-double mutant heteromeric channels. In AâC, bars are mean Â± SEM for the number of cells indicated above each bar. For ease of comparison, data for wild-type heteromeric channels are repeated in AâC. *, P < 0.01, Student's t test for the indicated comparison. (D) Schematic diagram of the mutant cycle, including Ki' measured at â60 mV for each combination. Values are mean Â± SEM (in Î¼M) for the number of measurements indicated in parenthesis. (E) Coupling energy, RTlnÎ©, for mutations that replace the wild-type alanine with C, T, D, or V in MEC-4 and MEC-10. One-way ANOVA showed that the four Ki values used to calculate each Î© differed from one another at P < 0.0005. See Table S1 for Ki' values and Table S2 for full results of the ANOVA. â , data are from Goodman et al. (2002).

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