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J. Biol. Chem., Vol. 258, Issue 16, 9657-9661, 08, 1983
W Rouslin
Ischemic myocardium was produced by occluding the left circumflex coronary
artery in anesthetized dogs for 10 or 20 min. Autolyzed myocardium was
produced by incubating transmural samples of canine left ventricle at 37
degrees C for 5, 10, 15, 20, 40, or 60 min. Tissue pH was recorded
continuously in each model using a microcombination pH electrode impaled
into the midmyocardium. Mitochondria isolated from both ischemic and
autolyzed tissue exhibited marked parallel depressions of
oligomycin-sensitive ATPase activity, Km ATP, and Vmax. All of these
parameters dropped more markedly during the zero flow autolytic process
than during the low flow ischemia characteristic of the canine left
circumflex occlusion model. The changes in the ATPase kinetic parameters
paralleled closely the drop in tissue pH in each model. These ATPase
kinetic changes were then reproduced in vitro both quantitatively and
qualitatively by incubating isolated control mitochondria at the same pH
values under nonenergizing conditions. It thus became evident that we had,
in effect, utilized the oligomycin- sensitive ATPase as an in situ
indicator of cell acidosis. Reperfusion of 15-min ischemic myocardium was
accompanied by a complete reversal of the acidosis and of the ATPase
activity inhibition. The ATPase inhibition demonstrable in vitro in
isolated mitochondria occurred when the pH was lowered, but only when there
was a concomitant dissipation of the transmembrane electrochemical
gradient. The ATPase inhibition was then reversed completely during a
subsequent state 4 incubation by a carbonyl cyanide
p-trifluoromethoxyphenylhydrazone-sensitive process.
Protonic inhibition of the mitochondrial oligomycin-sensitive adenosine 5'-triphosphatase in ischemic and autolyzing cardiac muscle. Possible mechanism for the mitigation of ATP hydrolysis under nonenergizing conditions
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