Probing the Role of Negatively Charged Amino Acid Residues in Ion Permeation of Skeletal Muscle Ryanodine Receptor

doi:10.1529/biophysj.104.056002

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CHANNELS, RECEPTORS, AND ELECTRICAL SIGNALING

Probing the Role of Negatively Charged Amino Acid Residues in Ion Permeation of Skeletal Muscle Ryanodine Receptor

Ying Wang ¹, Le Xu ¹, Daniel A. Pasek ¹, Dirk Gillespie ² and Gerhard Meissner ¹^*

¹ University of North Carolina
² Rush University

^* To whom correspondence should be addressed. E-mail: meissner{at}med.unc.edu.

Submitted on November 9, 2004
Revised on February 10, 2005
Accepted on 27 April 2005

Abstract
Sequence comparison suggests that the RyRs have pore architecturesimilar to that of the bacterial K+ channel KcsA. The lumenalloop linking the two most C-terminal transmembrane spanningsegments in the RyRs has a predicted pore helix and an aminoacid motif (GGGIG) homologous similar to the selectivity filter(TVGYG) of KcsA identified by x-ray analysis (Doyle et al.,1998). The RyRs have many negatively charged amino acid residuesin the two regions linking the GGGIG motif and predicted porehelix with the two most C-terminal transmembrane spanning segments.We tested the role of these residues by generating single-sitemutants, focusing on amino acid residues conserved among themammalian RyRs. Replacement of two acidic residues immediatelyfollowing the GGGIG motif in skeletal muscle ryanodine receptor(RyR1-D4899 and -E4900) with asparagine and glutamine adjacentto the GGGIG motif profoundly affected ion permeation and selectivity.By comparison, mutagenesis of aspartate and glutamate residuesin the putative linker regions showed a K+ conductance and selectivityfor Ca2+ compared to K+ (PCa/PK) close to wild type. The resultsshow that the negatively charged carboxyl oxygens of D4899 andE4900 side chains are major determinants of RyR ion conductanceand selectivity. A model emphasizing the role of the two aminoacid residues in determining ion permeation of RyR is presentedin (Gillespie et al., (submitted).

Key Words: Ca2+ release channel, ion permeation, ion selectivity, ryanodine receptor, skeletal muscle

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