A Mutation Linked with Bartter's Syndrome Locks Kir 1.1a (Romk1) Channels in a Closed State

doi:10.1085/jgp.114.5.685

Published online 1 November 1999.

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Original Article

A Mutation Linked with Bartter's Syndrome Locks Kir 1.1a (Romk1) Channels in a Closed State

Thomas P. Flagg^a, Margaret Tate^a, Jean Merot^b, and Paul A. Welling^a

^a From the Department of Physiology, University of Maryland School of Medicine, Baltimore, Maryland 21201
^b Department de Biologie Cellulaire et Moleculaire, Centre d'Etudes Saclay, Gif sur Yvette, France 91191
Department of Physiology, University of Maryland School of Medicine, 655 W. Baltimore St., Baltimore, MD 21201.Fax: 410-706-8341;

pwelling{at}umaryland.edu

Mutations in the inward rectifying renal K⁺ channel, Kir 1.1a(ROMK), have been linked with Bartter's syndrome, a familialsalt-wasting nephropathy. One disease-causing mutation removesthe last 60 amino acids (332–391), implicating a previouslyunappreciated domain, the extreme COOH terminus, as a necessaryfunctional element. Consistent with this hypothesis, truncatedchannels (Kir 1.1a 331X) are nonfunctional. In the present study,the roles of this domain were systematically evaluated. Whencoexpressed with wild-type subunits, Kir 1.1a 331X exerted anegative effect, demonstrating that the mutant channel is synthesizedand capable of oligomerization. Plasmalemma localization ofKir 1.1a 331X green fluorescent protein (GFP) fusion constructwas indistinguishable from the GFP–wild-type channel,demonstrating that mutant channels are expressed on the oocyteplasma membrane in a nonconductive or locked-closed conformation.Incremental reconstruction of the COOH terminus identified aminoacids 332–351 as the critical residues for restoring channelactivity and uncovered the nature of the functional defect.Mutant channels that are truncated at the extreme boundary ofthe required domain (Kir 1.1a 351X) display marked inactivationbehavior characterized by frequent occupancy in a long-livedclosed state. A critical analysis of the Kir 1.1a 331X dominantnegative effect suggests a molecular mechanism underlying theaberrant closed-state stabilization. Coexpression of differentdoses of mutant with wild-type subunits produced an intermediatedominant negative effect, whereas incorporation of a singlemutant into a tetrameric concatemer conferred a complete dominantnegative effect. This identifies the extreme COOH terminus asan important subunit interaction domain, controlling the efficiencyof oligomerization. Collectively, these observations providea mechanistic basis for the loss of function in one particularBartter's-causing mutation and identify a structural elementthat controls open-state occupancy and determines subunit oligomerization.Based on the overlapping functions of this domain, we speculatethat intersubunit interactions within the COOH terminus mayregulate the energetics of channel opening.

Key Words: potassium • channel • gate • subunit oligomerization • green fluorescent protein

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