Ca2+ Sparks and Embers of Mammalian Muscle. Properties of the Sources

doi:10.1085/jgp.200308796

Published 30 June 2003. doi:10.1085/jgp.200308796

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© Rockefeller University Press, 0022-1295/2003/7/95/ $5.00
Journal of General Physiology, Volume 122, Number 1, July 2003 95-114
Ca²⁺ Sparks and Embers of Mammalian Muscle. Properties of the Sources

J. Zhou¹, G. Brum², A. González¹, B.S. Launikonis¹, M.D. Stern³ and E. Ríos¹

¹ Department of Molecular Biophysics and Physiology, Rush University, 1750 W. Harrison, St., Chicago, IL 60612
² Departamento de Biofísica, Universidad de la República, Facultad de Medicina, Montevideo, Uruguay
³ Laboratory of Cardiovascular Science, National Institute on Aging, National Institutes of Health, Baltimore, MD 21224

Address correspondence to Eduardo Ríos Professor, Molecular Biophysics and Physiology Rush University School of Medicine, 1750 W. Harrison St. Suite 1279JS, Chicago, IL 60612. Fax: (312) 942-8711; E-mail: erios{at}rush.edu

Ca²⁺ sparks of membrane-permeabilized rat muscle cells wereanalyzed to derive properties of their sources. Most eventsidentified in longitudinal confocal line scans looked like sparks,but 23% (1,000 out of 4,300) were followed by long-lasting embers.Some were preceded by embers, and 48 were "lone embers." Averagespatial width was $~$ 2 µm in the rat and 1.5 µm infrog events in analogous solutions. Amplitudes were 33% smallerand rise times 50% greater in the rat. Differences were highlysignificant. The greater spatial width was not a consequenceof greater open time of the rat source, and was greatest atthe shortest rise times, suggesting a wider Ca²⁺ source. Inthe rat, but not the frog, spark width was greater in scanstransversal to the fiber axis. These features suggested thatrat spark sources were elongated transversally. Ca²⁺ releasewas calculated in averages of sparks with long embers. Releasecurrent during the averaged ember started at 3 or 7 pA (dependingon assumptions), whereas in lone embers it was 0.7 or 1.3 pA,which suggests that embers that trail sparks start with fiveopen channels. Analysis of a spark with leading ember yieldeda current ratio ranging from 37 to 160 in spark and ember, asif 37–160 channels opened in the spark. In simulations,25–60 pA of Ca²⁺ current exiting a point source was requiredto reproduce frog sparks. 130 pA, exiting a cylindric sourceof 3 µm, qualitatively reproduced rat sparks. In conclusion,sparks of rat muscle require a greater current than frog sparks,exiting a source elongated transversally to the fiber axis,constituted by 35–260 channels. Not infrequently, a fewof those remain open and produce the trailing ember.

Key Words: sarcoplasmic reticulum • intracellular channels • excitation-contraction coupling • ryanodine receptors

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