Gain-of-function Mutations Reveal Expanded Intermediate States and a Sequential Action of Two Gates in MscL

doi:10.1085/jgp.200409118

Published online Jan 31 2005. doi:10.1085/jgp.200409118
The Rockefeller University Press, 0022-1295 $8.00
JGP, Volume 125, Number 2, 155-170

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Gain-of-function Mutations Reveal Expanded Intermediate States and a Sequential Action of Two Gates in MscL

Andriy Anishkin, Chien-Sung Chiang, and Sergei Sukharev

Department of Biology, University of Maryland, College Park, MD 20742

Correspondence to Sergei Sukharev: sukharev{at}umd.edu

The tension-driven gating transition in the large mechanosensitivechannel MscL proceeds through detectable states of intermediateconductance. Gain-of-function (GOF) mutants with polar or chargedsubstitutions in the main hydrophobic gate display altered patternsof subconducting states, providing valuable information aboutgating intermediates. Here we present thermodynamic analysisof several GOF mutants to clarify the nature and position oflow-conducting conformations in the transition pathway. Unlikewild-type (WT) MscL, which predominantly occupies the closedand fully open states with very brief substates, the mild V23TGOF mutant frequently visits a multitude of short-lived subconductingstates. Severe mutants V23D and G22N open in sequence: closed(C) $->$ low-conducting substate (S) $->$ open (O), with the first subtransitionoccurring at lower tensions. Analyses of equilibrium state occupanciesas functions of membrane tension show that the C $->$ S subtransitionin WT MscL is associated with only a minor conductance increment,but the largest in-plane expansion and free energy change. TheGOF substitutions strongly affect the first subtransition byreducing area ( ${Delta}$ A) and energy ( ${Delta}$ E) changes between C and S statescommensurably with the severity of mutation. GOF mutants alsoexhibited a considerably larger ${Delta}$ E associated with the second(S $->$ O) subtransition, but a ${Delta}$ A similar to WT. The area changesindicate that closed conformations of GOF mutants are physicallypreexpanded. The tension dependencies of rate constants forchannel closure (k_off) predict different positions of rate-limitingbarriers on the energy-area profiles for WT and GOF MscL. Thedata support the two-gate mechanism in which the first subtransition(C $->$ S) can be viewed as opening of the central (M1) gate, resultingin an expanded water-filled "leaky" conformation. Strong facilitationof this step by polar GOF substitutions suggests that separationof M1 helices associated with hydration of the pore in WT MscLis the major energetic barrier for opening. Mutants with a stabilizedS1 gate demonstrate impeded transitions from low-conductingsubstates to the fully open state, whereas extensions of S1–M1linkers result in a much higher probability of reverse O $->$ S transitions.These data strongly suggest that the bulk of conductance gainin the second subtransition (S $->$ O) occurs through the openingof the NH₂-terminal (S1) gate and the linkers are coupling elementsbetween the M1 and S1 gates.

Key Words: mechanosensitive channel • tension • thermodynamics • subconducting states • hydration

A. Anishkin and C.-S. Chiang contributed equally to this work.

Abbreviations used in this paper: GOF, gain-of-function; WT,wild type.

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