Superoxide anion can modulate vascular smooth muscle tone and potentially affect the growth response in vascular disease. The present studies were undertaken to characterize the source of superoxide in rabbit aorta. Rings of aorta (5 mm) were incubated in physiological salt solution (PSS) for 30 min at 37 degrees C in the presence of 10 mM diethyldithiocarbamate (DDC) with or without inhibitors of superoxide-generating systems. Rings were then placed in PSS containing 250 microM lucigenin at 37 degrees C in the presence or absence of inhibitors, and changes in amounts of superoxide were determined by measuring chemiluminescence (units). The inhibitors of xanthine oxidase, oxypurinol (300 microM), and of mitochondrial NADH dehydrogenase, rotenone (50 microM), had no significant effect on superoxide levels. An inhibitor of NADPH oxidase, iodonium thiophen, caused a concentration-dependent inhibition of superoxide anion (12.49 +/- 1.48 vs 5.27 +/- 1.81 and 2.30 +/- 0.36 units, control vs 7 microM and 70 microM iodonium thiopen, respectively). A structurally related iodonium compound, diphenyleneiodonium (20 microM), caused a 78% reduction in basal and DDC-evoked superoxide levels. In the presence or absence of DDC, exogenous administration of NADPH (10 microM-1 mM), but not NADP (1 mM), elicited a concentration-dependent rise in superoxide levels that was inhibited by iodonium thiophen. Particulate fractions of whole aortic tissue exhibited NADPH-dependent superoxide production that was inhibited by 1 microM diphenyleneiodonium.(ABSTRACT TRUNCATED AT 250 WORDS)
Abstract-Glycolysis increases in hypertrophied hearts but the mechanisms are unknown. We studied the regulation of glycolysis in hearts with pressure-overload LV hypertrophy (LVH), a model that showed marked increases in the rates of glycolysis (by 2-fold) and insulin-independent glucose uptake (by 3-fold). Although the V max of the key glycolytic enzymes was unchanged in this model, concentrations of free ADP, free AMP, inorganic phosphate (P i ), and fructose-2,6-bisphosphate (F-2,6-P 2 ), all activators of the rate-limiting enzyme phosphofructokinase (PFK), were increased (up to 10-fold). Concentrations of the inhibitors of PFK, ATP, citrate, and H ϩ were unaltered in LVH. Thus, our findings show that increased glucose entry and activation of the rate-limiting enzyme PFK both contribute to increased flux through the glycolytic pathway in hypertrophied hearts. Moreover, our results also suggest that these changes can be explained by increased intracellular free [ADP] and [AMP], due to decreased energy reserve in LVH, activating the AMP-activated protein kinase cascade. This, in turn, results in enhanced synthesis of F-2,6-P 2 and increased sarcolemma localization of glucose transporters, leading to coordinated increases in glucose transport and activation of PFK. Key Words: cardiac function Ⅲ hypertrophy Ⅲ protein kinases Ⅲ cardiac metabolism Ⅲ cyclic AMP G lucose utilization is increased in hypertrophied and failing hearts, 1-4 but the underlying mechanisms are poorly understood. Increased glycolytic flux in the hypertrophied myocardium is important because ATP synthesis via glucose utilization may compensate for decreased capacity for ATP synthesis via other pathways. 5,6 In hearts with chronic pressure overload hypertrophy, it was recently reported that chronic depletion of the energy reserve compound PCr coupled with large changes in the ratio of PCr to free creatine led to activation of AMP-activated protein kinase (AMPK) by elevated AMP concentrations. 7 AMPK acts as a low-on-fuel sensor and, when the cytosolic AMP concentration increases, AMPK activates enzymes in pathways that synthesize ATP and inhibits enzymes in pathways that use ATP. 8,9 Among the many consequences of activated AMPK is increased localization of glucose transporters in the sarcolemma and hence increased glucose uptake by an insulinindependent mechanism. 10,11 In addition, in a study of acute myocardial ischemia, AMPK was found to phosphorylate and thereby activate heart phosphofructokinase-2 (PFK-2), leading to increased production of fructose-2,6-bisphosphate (F-2,6-P 2 ), a potent activator of the rate-limiting glycolytic enzyme phosphofructokinase (PFK). 12 In the present study, we tested the hypothesis that increased glycolysis in hypertrophied hearts occurs as a consequence of chronic decreases in the energy reserve and activation of AMPK.Using a model of pressure overload left ventricular hypertrophy (LVH) of the rat heart, in which reduced energy reserve, increased AMPK activity, and increased insulin-independent glucose upt...
Glucose-induced insulin secretion is associated with inhibition of free fatty acid (FFA) oxidation, increased esterification and complex lipid formation by pancreatic beta-cells. Abundant evidence favors a role for cytosolic long-chain acyl-CoA (LC-CoA), including the rapid rise in malonyl CoA, the inhibitory effect of hydroxycitrate or acetyl CoA carboxylase knockout, both of which prevent malonyl CoA formation, and the stimulatory effect of exogenous FFA. On the other hand, some evidence opposes the concept, including the fall in total LC-CoA levels in response to glucose, the stimulatory effect of LC-CoA on K(ATP) channels and the lack of inhibition of glucose-stimulated secretion either by overexpression of malonyl CoA decarboxylase, which markedly lowers malonyl CoA levels, or by triacsin C, which blocks FFA conversion to LC-CoA. Alternative explanations for these data are presented. A revised model of nutrient-stimulated secretion involving two arms of signal transduction that occur simultaneously is proposed. One arm depends on modulation of the K(ATP) channel evoked by changes in the ATP/ADP ratio. The other arm depends upon anaplerotic input into the tricarboxylic acid cycle, generation of excess citrate, and increases in cytosolic malonyl-CoA. Input from this arm is increased LC-CoA. Signaling through both arms would be required for normal secretion. LC-CoA esters and products formed from them are potent regulators of enzymes and channels. It is hypothesized that their elevations directly modulate the activity of enzymes, genes and various beta-cell functions or modify the acylation state of key proteins involved in regulation of ion channels and exocytosis.
The role of malonyl-CoA, an inhibitor of carnitine palmitoyltransferase I, in regulating the oxidation of fatty acids in rat skeletal (1, 2) and cardiac (3, 4) muscle has been intensively investigated. Recent studies have demonstrated that its concentration in rat muscle is governed, at least in part, by changes in the activity of the muscle isoform of acetyl-CoA carboxylase (ACC  ) 1 (5), the enzyme that catalyzes malonylCoA synthesis. Thus, in keeping with their observed effects on malonyl-CoA concentration and fatty acid oxidation, insulin and glucose appear to activate ACC  in muscle by increasing the cytosolic concentration of citrate, an allosteric activator of ACC  and a precursor of its substrate, cytosolic acetyl-CoA. Conversely, decreases in malonyl-CoA concentration and increases in fatty acid oxidation in muscle during exercise (contraction) have been linked to decreases in ACC  activity, attributable to its phosphorylation and inhibition by the ␣ 2 isoform of AMP-activated protein kinase (AMPK) (5). AMPK can also be activated and the concentration of malonyl-CoA decreased by exposing resting muscle to 5-aminoimidazole-4-carboxamide ribonucleoside (AICAR), which is taken into the muscle and phosphorylated to form the 5Ј-AMP analogue ZMP (6).Whether a change in malonyl-CoA turnover contributes to the alterations in its concentration in muscle during exercise and other conditions is not known. In a lipogenic tissue such as liver, the de novo synthesis of fatty acids is thought to be the major mechanism by which malonyl-CoA is utilized. In contrast, in skeletal muscle fatty acid synthesis occurs at a very low rate, if at all (7), and attention has been focused on malonyl-CoA decarboxylase (MCD) for removal of malonyl-CoA (1). Evidence has been presented that MCD is present in both cardiac (8, 9) and skeletal (1, 10, 11) muscle. In skeletal muscle, its activity is similar to that of ACC (1). In heart, in which MCD activity is substantially greater than in skeletal muscle, a decrease in the K m of MCD for malonyl-CoA has been reported following an increase in its work load (9). On the other hand, no change in activity has been observed following ischemia-reperfusion of the heart, a situation in which AMPK is activated (8). The question of whether MCD is acutely regulated in skeletal muscle and, if so, how has not been studied previously.In this study, we describe the characteristics of purified MCD from rat skeletal muscle and contraction-induced changes in its maximal activity and affinity for malonyl-CoA. In addition, the effects of the AMPK activator 5-aminoimida-
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