The role of malate in exercise-induced enhancement of mitochondrial respiration.

Liver mitochondria isolated from rats immediately after exercise oxidize substrates more rapidly than do mitochondria from resting animals. In both fed and fasted rats, a 1-h period of exercise resulted in increased concentrations of malate in their livers and in the mitochondria isolated therefrom. This increase occurred in both untrained and exercise-trained rats. Because mitochondrial malate is known to facilitate mitochondrial uptake of other carboxylic substrates, it seems likely that the increased mitochondrial malate is responsible for the increased rate of oxidation. Rats injected with small amounts of malate (4.6 mumol/100 g body wt) yielded liver mitochondria with increased malate concentration and increased rates of oxidation of citrate, alpha-ketoglutarate, and succinate. The beta adrenergic antagonist propranolol (0.25 mg/100 g body wt) and the alpha 1 antagonist prazosin (same dose) did not abolish the effect of exercise on mitochondrial malate concentration or substrate oxidation.

The role of malate in hormone-induced enhancement of mitochondrial respiration.

Shortly after the injection of glucagon, epinephrine, norepinephrine, vasopressin, or angiotensin II into fasted rats, mitochondria isolated from their livers contained elevated concentrations of malate and oxidized citrate, alpha-ketoglutarate, and, in some cases, succinate more rapidly than mitochondria from fasted, control rats. The administration of tryptophan, lactate, or ethanol and refeeding of rats fasted 24 h result in similar elevations of mitochondrial malate concentration and oxidation of added substrates. Treatments that resulted in elevated mitochondrial malate resulted also in increased uptake of added citrate, alpha-ketoglutarate, pyruvate, and, in some cases, succinate. It is postulated that the well-documented effect of gluconeogenic hormones on mitochondrial oxidation of carboxylic substrates may be mediated by malate which not only yields oxalacetate to support the tricarboxylic acid cycle but also facilitates the transport of added substrates, and which is regenerated in the tricarboxylic acid cycle.

Correlation between the malate dependent progesterone and citrate biosynthesis in the mitochondrial fraction of human term placenta. The stimulatory effect of ADP and ATP.

The relationship between malate dependent conversion of cholesterol to progesterone and citrate biosynthesis in human term placental mitochondria has been investigated. It has been shown that ADP and ATP (but not AMP) stimulate, significantly, both progesterone and citrate formation. The stimulatory effect of these adenine nucleotides was dependent on the presence of Mn2+ in the incubation medium. When Mn2+ was omitted or replaced by Mg2+ only negligible stimulatory effect of ADP and ATP was observed. Atractyloside and oligomycin were without effect on ADP and ATP stimulated progesterone and citrate production. Other dinucleotides tested as: GDP, UDP and CDP stimulated both progesterone and citrate formation only slightly. In all the experiments presented the rate of progesterone biosynthesis was found to be significantly correlated with the rate of citrate production. The experimental results presented in this paper suggest that the stimulatory effect of ADP and ATP on malate dependent progesterone biosynthesis is a consequence of an increased conversion of malate to tricarboxylic Krebs cycle intermediates. The possible mechanism by which ATP and ADP stimulate the citrate formation in human placental mitochondria is discussed.

Alterations in some dehydrogenase profiles of sciatectomized toad gastrocnemius muscle-metabolic modifications by malate.

Sciatectomized toad gastrocnemius has shown a progressive loss in lactate (LDH), succinate (SDH) and malate (MDH) dehydrogenase activities and elevation of glutamate dehydrogenase (GDH) activity during post-neurectemic days. The possible role of malate in the restoration of metabolic homeostasis in denervated muscle is discussed.

Kinetic and binding properties of the oxoglutarate translocator of rat-heart mitochondria.

The kinetic study of the oxoglutarateout/malatein exchange through the inner mitochondrial membrane of rat-heart mitochondria has been compelted and extended to higher external-oxoglutarate and to lower internal-malate concentrations. It has been found that the external oxoglutarate inhibits the exchange at high concentration. This excess-substrate inhibition is preceded by four jumps. The kinetic-saturation curve by the internal malate presents an apparent positive cooperativity that may be interpreted in different ways. The independence of the effects of the two substrates on the initial rate has been observed again and supports the conclusions reached in previous work. A method for the determination of oxoglutarate binding to the external face of the inner membrane is described. The binding curve shows four intermediary plateau regions that reflect significant apparent K-effects, alternatively negative and positive. For external-oxoglutarate concentrations below the region of excess-substrate inhibition, the binding-saturation curve and the kinetic-saturation curve are similar, demonstrating that K-effects are predominant. A particularly wide intermediary plateau that seems to correspond to half saturation of the active sites is common to both saturation curves. A clear lack of proportionality between the two curves at low oxoglutarate concentrations seems to indicate that more than one catalytic-rate constant is implied in the exchange kinetics. Two models of the oxoglutarate carrier are presented. Both lead to a minimum degree of 10:10 for the equation of the binding of oxoglutarate to the catalytic sites. In the first model this corresponds to ten subunits associated into a single oligomer while in the second model this results from a mixture of monomeric, dimeric, trimeric and tetrameric associations.