Metabolic compartmentalization in neonatal swine myocytes.

The transport of metabolites across the mitochondrial membrane is regulated by specific exchange and shuttle systems that are often dependent on the mitochondrial membrane potential. Thus, metabolite concentrations in the cytosol and mitochondrial compartments are largely determined by the energy state of the cardiac muscle cell. The purpose of this study was to investigate metabolic compartmentalization in ventricular myocytes isolated from newborn (< 24 h) swine hearts. Furthermore, the effect of respiratory inhibition on these distribution patterns was examined. Freshly isolated cells contained 33 nmol of ATP and 37 nmol of total adenine nucleotides (AN) per mg of myocyte protein. Rapid digitonin fractionation indicated that 95% of ATP and 86% of AN were cytosolic, whereas > 50% of the pyridine nucleotides were mitochondrial. With 11 mM added glucose, myocytes treated with the respiratory inhibitor, rotenone, maintained ATP at 88% of that of aerobic myocytes, but phosphocreatine declined by 50% over 30 min. Rotenone treatment caused the mitochondrial NAD/NADH ratio to decline from 1.2 to 0.06, whereas the cytosolic pyridine nucleotides remained > 90% oxidized. Total adenine and pyridine nucleotide content and their compartmentalization were unaffected by respiratory inhibition. Comparisons of metabolite content and respiratory activity between isolated piglet mitochondria and the mitochondrial compartment of piglet myocytes indicated that mitochondria account for approximately 30% of total myocyte protein. A similar value (29%) was obtained for the aqueous volume fraction of the in situ mitochondrial matrix using the 4000 Mr 14C-labeled polyethylene glycol-impermeable 3H2O spaces of intact and lysed myocytes. These results are comparable to literature values for myocardium from other species and age groups.

Cultured AIDS-related Kaposi's sarcoma (AIDS-KS) cells demonstrate impaired bioenergetic adaptation to oxidant challenge: implication for oxidant stress in AIDS-KS pathogenesis.

Despite its recognition as the most prevalent HIV associated cancer, speculation still abounds regarding the pathogenesis of AIDS-related Kaposi's sarcoma (AIDS-KS). However, it has been established that both cytokines, e.g. IL-6, and HIV-associated products, e.g., Tat, are integral in AIDS-KS cellular proliferation. Further, both experimental and clinical evidence is accumulating to link reactive oxygen intermediates (ROI) with both cytokine induction (primarily via nuclear factor-kappa B[NF-kappa B] dependent routes) as well as the subsequent cytokine, tumor necrosis factor alpha (TNF alpha) stimulation of HIV replication. Features of AIDS-KS patients, such as retention of phagocytes, presence of sustained immunostimulation, and a frequent history of KS lesions arising at traumatized sites, make oxidant stress a viable clinical factor in AIDS-KS development. Time course nucleotide profile analyses show that AIDS-KS cells have an inherent, statistically significant, biochemical deficit, even prior to oxidant stress, due to 1) a more glycolytic bioenergetic profile, resulting in lower levels of high energy phosphates (impairing capacity for glutathione [GSH] synthesis and DNA repair); 2) lower levels of NADPH (compromising the activities of GSSG reductase and peroxidase function of catalase); and 3) reduced levels of GSH (impeding both GSH peroxidase and GSH-S-transferases). Following exposure to physiologically relevant levels of H2O2, only the human microvascular endothelial cells (a putative AIDS-KS progenitor cell) responded with bioenergetic adaptations that reflected co-ordination of energy generating and cytoprotective pathways, e.g., retention of the cellular energy charge, increased NAD+, and an accentuation of the ATP, NADPH, and total adenine nucleotide differences relative to AIDS-KS cells. Also, some of the AIDS-KS strains retained intracellular GSSG subsequent to oxidant challenge, inviting the formation of deleterious protein mixed disulfides. While the results of our study address some AIDS-KS issues, they also raise an etiological question, i.e., Does the inability to tolerate oxidant stress arise in conjunction with AIDS-KS neoplastic development, or is it pre-existing in the population at risk? Regardless, use of antioxidant therapy (low risk/ potentially high benefit) in both the "at risk" population as well as in those individuals with active disease may prove a useful preventative and/or treatment modality.