A comparative study of the inhibitory effects of purine nucleotides and carboxyatractylate on the uncoupling protein-3 and adenine nucleotide translocase.

Uncoupling proteins (UCPs) mediate fatty acid-induced proton cycling in mitochondria, which is stimulated by superoxide and inhibited by GDP. Fatty acid anions can also be transported by adenine nucleotide translocase (ANT), thus resulting in the uncoupling of oxidative phosphorylation. In the present work, an attempt was made to distinguish between the protonophoric activity of UCP3 and that of ANT using inhibition analysis. This study was carried out using mitochondria from skeletal muscles of hibernating Yakut ground squirrel, which have a significant level of UCP3 mRNA. We found that millimolar concentrations of GDP, which is considered to be a specific inhibitor of UCPs, slightly recoupled the mitochondrial respiration and restored the membrane potential. Addition of the specific ANT inhibitor CAT (carboxyatractylate), in micromolar concentration, prior to GDP prevented its recoupling effect. Moreover, GDP and ADP exhibited a competitive kinetic behavior with respect to ANT. In brown adipose tissue, CAT did not prevent the UCP1-iduced increase in chloride permeability and the inhibitory effect of GDP, thus confirming the inability of CAT to affect UCP1. These results allow us to conclude that the recoupling effect of purine nucleotides on skeletal muscle mitochondria of hibernating ground squirrels can be explained by interaction of the nucleotides with ANT, whereas UCP3 is not involved in the process.

Mitochondrial metabolites in tissues as indicators of metabolic alterations during hibernation.

The decrease in metabolism is one of mechanisms for hibernating animals to resist hypoxia and oxidative stress. Assuming that the inhibition of mitochondria; respiration in torpor and its activation upon arousal are accompanied by changes in the content of mitochondrial substrates, we estimated the levels of endogenous metabolites of the tricarboxylic acid (TCA) cycle in the liver, brown adipose tissue, and the brain of the arctic ground squirrels as possible indicators of mitochondrial processes. The level of lactate in the same tissues and serum was determined as marker of hypoxia. It was found that the isocitrate (ISC) concentration in all tissues was one order of magnitude higher than that of alpha-ketoglutarate (KGL), while succinate was not detected in any of tissues, indicating the inhibition at the initial stages of the TCA cycle. During the torpor, the concentrations of ISC, KGL and lactate predominantly decreased in tissues. Serum lactate decreased five-fold in torpor and was restored in a temperature-dependent manner with a long period of persistence of stable concentration in the range of body temperature between 12 and 27°C upon arousal. The data obtained indicate the development of metabolic depression rather than hypoxia in these tissues.