Force development, energy state and ATP production of cardiac muscle from turtles and trout during normoxia and severe hypoxia

doi:10.1242/jeb.00975

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First published online April 23, 2004
Journal of Experimental Biology 207, 1915-1924 (2004)
Published by The Company of Biologists 2004
doi: 10.1242/jeb.00975

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Force development, energy state and ATP production of cardiac muscle from turtles and trout during normoxia and severe hypoxia

Johannes Overgaard and Hans Gesser^*

Department of Zoophysiology, Institute of Biological Sciences, University of Aarhus, DK 8000 Aarhus, Denmark

^* Author for correspondence (e-mail: hans.gesser{at}biology.au.dk)

Accepted 10 March 2004

The effects of hypoxia on energy economy of cardiac muscle werecompared between the hypoxia-tolerant freshwater turtle at 20°Cand the hypoxia-sensitive rainbow trout at 15°C. Isolatedventricular preparations were left either at rest or stimulatedat 30 min^-1 to develop isometric twitch force. Under oxygenatedconditions, twitch force and oxygen consumption were similarfor the two species. Overall metabolism was reduced during severehypoxia in both resting and stimulated preparations and under theseconditions most of the ATP production was derived from anaerobic metabolism.During hypoxia, a metabolic depression of approximately 2/3 occurredfor non-contractile processes in both turtle and trout preparations. Duringhypoxia, lactate production and residual oxygen consumptionwere similar in turtle and trout. Cellular energy state andphosphorylation potential decreased during severe hypoxia inboth species and this reduction was more severe in preparationsstimulated to contraction. However, in turtle ventricular preparationsthe energy state and phosphorylation potential stabilised athigher levels than in trout, and turtle preparations also maintaineda higher twitch force throughout the hypoxic period. Moreover, twitchforce relative to total ATP hydrolysis was markedly increasedduring hypoxia in turtle while this ratio was unchanged fortrout. The main findings of this study are: (1) cellular energyliberation and the energy demand of non-contractile processesdecreased to similar levels in hypoxic turtle and trout myocardium;(2) turtle myocardium maintained a substantially higher cellularenergy state and twitch force development than trout myocardium duringhypoxia and (3) the ratio of twitch force to ATP hydrolysisincreased during hypoxia in turtle but was unchanged in trout.It is possible that this superior economy of the contractingturtle myocardium contributes to the remarkable hypoxia toleranceof freshwater turtles.

Key words: oxygen consumption, lactate production, cellular energy state, phosphorylation potential, cost of contraction, twitch force, metabolic depression, Trachemys scripta, Oncorhynchus mykiss

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