The Conformation of Calsequestrin Determines Its Ability to Regulate Skeletal Ryanodine Receptors
Loading...
Date
Authors
Wei, Lan
Varsányi, Magdolna
Dulhunty, Angela F.
Beard, Nicole A.
Journal Title
Journal ISSN
Volume Title
Publisher
Biophysical Society
Abstract
Ca2+ efflux from the sarcoplasmic reticulum decreases when store Ca2+ concentration falls, particularly in skinned fibers and isolated vesicles where luminal Ca2+ can be reduced to very low levels. However ryanodine receptor activity in many single channel studies is higher when the luminal free Ca2+ concentration is reduced. We investigated the hypothesis that prolonged exposure to low luminal Ca2+ causes conformational changes in calsequestrin and deregulation of ryanodine receptors, allowing channel activity to increase. Lowering of luminal Ca2+ from 1 mM to 100 microM for several minutes resulted in conformational changes with dissociation of 65-75% of calsequestrin from the junctional face membrane. The calsequestrin remaining associated no longer regulated channels. In the absence of this regulation, ryanodine receptors were more active when luminal Ca2+ was lowered from 1 mM to 100 microM. In contrast, when ryanodine receptors were calsequestrin regulated, lowering luminal Ca2+ either did not alter or decreased activity. Ryanodine receptors are regulated by calsequestrin under physiological conditions where calsequestrin is polymerized. Since depolymerization occurs slowly, calsequestrin can regulate the ryanodine receptor and prevent excess Ca2+ release when the store is transiently depleted, for example, during high frequency activity or early stages of muscle fatigue.
Description
Keywords
animals, binding sites, calcium, calsequestrin, cells, cultured, dose-response relationship, drug, ion channel gating, male, muscle, skeletal, protein binding, protein conformation, rabbits, ryanodine receptor calcium release channel, sarcoplasmic reticulum, signal transduction, structure-activity relationship
Citation
Collections
Source
Biophysical Journal