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J Appl Physiol 66: 2231-2238, 1989;
8750-7587/89 $5.00
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Journal of Applied Physiology, Vol 66, Issue 5 2231-2238, Copyright © 1989 by American Physiological Society

ARTICLES

Glycogen synthesis from lactate in a chronically active muscle

R. J. Talmadge, J. I. Scheide and H. Silverman
Department of Zoology and Physiology, Louisiana State University, Baton Rouge 70803.

In response to neural overactivity (pseudomyotonia), gastrocnemius muscle fibers from C57Bl/6Jdy2J/dy2J mice have different metabolic profiles compared with normal mice. A population of fibers in the fast-twitch superficial region of the dy2J gastrocnemius stores unusually high amounts of glycogen, leading to an increased glycogen storage in the whole muscle. The dy2J muscle also contains twice as much lactate as normal muscle. A [14C]lactate intraperitoneal injection leads to preferential 14C incorporation into glycogen in the dy2J muscle compared with normal muscle. To determine whether skeletal muscles were incorporating lactate into glycogen without body organ (liver, kidney) input, gastrocnemius muscles were bathed in 10 mM [14C]lactate with intact neural and arterial supply but with impeded venous return. The contralateral gastrocnemius serves as a control for body organ input. By using this in situ procedure, we demonstrate that under conditions of high lactate both normal and dy2J muscle can directly synthesize glycogen from lactate. In this case, normal whole muscle incorporates [14C] lactate into glycogen at a higher rate than dy2J whole muscle. Autoradiography, however, suggests that the high-glycogen-containing muscle fibers in the dy2J muscle incorporate lactate into glycogen at nearly four times the rate of normal or surrounding muscle fibers.


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