Metabolism of pyruvate and carnitine esters in bovine epididymal sperm mitochondria

Filipin-treated bovine epididymal spermatozoa have been used to study mitochondrial l-acetylcarnitine, l-palmitoylcarnitine, and pyruvate metabolism. The cells were supplemented with malate to allow rapid rates of substrate oxidation. The rate of l-palmitoylcarnitine-supported state 3 respiration was slow. In contrast, pyruvate, acetylcarnitine, or lactate supported rapid and approximately equal respiratory rates. l-Palmitoylcarnitine was a weak inhibitor of pyruvate-supported respiration and pyruvate use and a more potent inhibitor of l-acetylcarnitine. l-Carnitine was an effective inhibitor of l-acetylcarnitine oxidation; however, it did not influence l-palmitoylcarnitine oxidation or inhibit pyruvate utilization. Pyruvate (1.4 m m) disappearance was rapid and was complete within 6–7 min; the lactate produced during pyruvate metabolism was then oxidized. ATP synthesis was constant throughout the 20-min incubation. With pyruvate plus l-acetylcarnitine as substrate, the l-acetylcarnitine concentration initially dropped and then recovered to a level that was dependent on free carnitine addition. Data obtained from experiments using [2- 14C]pyruvate indicated that the 14C label from pyruvate and lactate entered the l-acetylcarnitine pool and labeling was maximal when free l-carnitine was added. The rate of citrate synthesis was maximal when pyruvate was being metabolized; the largest total accumulation occurred when all three substrates were included in the incubation. The data suggest that the high NAD +/ NADH maintained during pyruvate metabolism may restrict flux through the citric acid cycle. The relationships of l-carnitine and the l-carnitine esters to pyruvate metabolism are discussed.