Cell membrane transport of K + stimulates the rate of glycolysis in Ehrlich ascites tumor cells. A study of the characteristics of this relationship indicates that the stimulation occurs under anaerobic as well as under aerobic conditions. The data suggest that glycolysis is stimulated by a K + transport mechanism that is coupled to Na + transport because the effect is blunted or abolished when the principal intracellular ion is lithium or choline. This stimulus to glycolysis is blocked by ouabain and ethacrynic acid, agents that have been shown to inhibit monovalent cation transport in erythrocytes. In contrast to the action of ouabain, glycolysis is inhibited by ethacrynic acid in Ehrlich ascites tumor cells in the absence of cell membrane K + transport. In studies with ghost-free hemolysates of human erythrocytes and with cytosol prepared from Ehrlich ascites tumor cells, ethacrynic acid significantly blocks lactate formation from fructose diphosphate demonstrating the direct inhibitory effect of this agent on one or more enzymes of the Embden-Meyerhof pathway. Since ethacrynic acid has no influence on lactate formation in intact erythrocytes utilizing an endogenous substrate, the presumptive site of inhibition is proximal to the 3-phosphoglycerate level.
Isolated tubules prepared by collagenase treatment of rat renal cortex retained their ultrastructural integrity and responded to added lactate and succinate with an increase in gluconeogenesis and respiration. Inhibition of the mitochondrial respiratory chain with rotenone, or energy conservation sites with oligomycin caused a marked reduction in respiration and ATP content thereby completely inhibiting net gluconeogenesis. Dissociation of gluconeogenesis from respiration was accomplished with quinolinic acid and hydrazine, inhibitors of gluconeogenesis. At 5 times 10(-3) M quinolinic acid, gluconeogenesis from succinate was inhibited approximately 50% and from lactate nearly 100%. This concentration of quinolinic acid did not affect oxygen uptake or the ATP content of tubules in the presence or absence of substrate. Hydrazine at 10(-3) M resulted in approximately 75% inhibition of glucose formation from succinate and complete inhibition from lactate without interfering with respiration or ATP content. The increased mitochondrial energy generation, as manifested by accelerated respiration was independent of gluconeogenesis. The unchanging cell ATP concentration with a higher respiratory rate upon addition of exogenous substrate bespeaks increased ATP turnover. ATP utilization for the substrate-induced enhancement of gluconeogenesis could not account for the increment in ATP hydrolysis.
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