Increased activities of antioxidant enzymes and decreased ATP concentration in cultured myoblasts with the 3243A-->G mutation in mitochondrial DNA.
(33/2221)
The MELAS syndrome (mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes) is most commonly caused by the 3243A-->G mutation in mitochondrial DNA, resulting in impaired mitochondrial protein synthesis and decreased activities of the respiratory chain complexes. These defects may cause a reduced capacity for ATP synthesis and an increased rate of production of reactive oxygen species. Myoblasts cultured from controls and patients carrying the 3243A-->G mutation were used to measure ATP, ADP, catalase and superoxide dismutase, which was also measured from blood samples. ATP and ADP concentrations were decreased in myoblasts with the 3243A-->G mutation, but the ATP/ADP ratio remained constant, suggesting a decrease in the adenylate pool. The superoxide dismutase and catalase activities were higher than in control cells, and superoxide dismutase activity was slightly, but not significantly higher in the blood of patients with the mutation than in controls. We conclude that impairment of mitochondrial ATP production in myoblasts carrying the 3243A-->G mutation results in adenylate catabolism, causing a decrease in the total adenylate pool. The increase in superoxide dismutase and catalase activities could be an adaptive response to increased production of reactive oxygen species due to dysfunction of the mitochondrial respiratory chain. (+info)
Regulation of skeletal muscle glycogen phosphorylase and PDH during maximal intermittent exercise.
(34/2221)
The time course for the activation of glycogen phosphorylase (Phos) and pyruvate dehydrogenase (PDH) and their allosteric regulators was determined in human skeletal muscle during repeated bouts of maximal exercise. Six subjects completed three 30-s bouts of maximal isokinetic cycling separated by 4-min recovery periods. Muscle biopsies were taken at rest and at 6, 15, and 30 s of exercise during bouts 1 and 3. Phos was rapidly activated within the first 6 s of bout 1 from 12% at rest to 47% at 6 s. The activation of PDH increased from 14% at rest to 48% at 6 s and 95% at 15 s of bout 1. Phos reverted back to basal values at the end of the first bout, whereas PDH remained fully activated. In contrast, in the third bout, PDH was 42% at rest and was activated more rapidly and was nearly completely activated by 6 s, whereas Phos remained at basal levels (range 14-20%). Lactate accumulation was marked in the first bout and increased progressively from 2.7 to 76.1 mmol/kg dry wt with no further increase in bout 3. Glycogen utilization was also marked in the first bout and was negligible in bout 3. The rapid activation of Phos and slower activation of PDH in bout 1 was probably due to Ca(2+) release from the sarcoplasmic reticulum. Lactate accumulation appeared to be due to an imbalance of the relative activities of Phos and PDH. The increase in H(+) concentration may have served to reduce pyruvate production by inhibiting Phos transformation and may have simultaneously activated PDH in the third bout such that there was a better matching between pyruvate production and oxidation and minimal lactate accumulation. As each bout progressed and with successive bouts, there was a decreasing ability to stimulate substrate phosphorylation through phosphocreatine hydrolysis and glycolysis and a shift toward greater reliance on oxidative phosphorylation. (+info)
Internal regulation of ATP turnover, glycolysis and oxidative phosphorylation in rat hepatocytes.
(35/2221)
Previously [Ainscow, E.K. & Brand, M.D. (1999) Eur. J. Biochem. 263, 671-685], top-down control analysis was used to describe the control pattern of energy metabolism in rat hepatocytes. The system was divided into nine reaction blocks (glycogen breakdown, glucose release, glycolysis, lactate production, NADH oxidation, pyruvate oxidation, mitochondrial proton leak, mitochondrial phosphorylation and ATP consumption) linked by five intermediates (intracellular glucose 6-phosphate, pyruvate and ATP levels, cytoplasmic NADH/NAD ratio and mitochondrial membrane potential). The kinetic responses (elasticities) of reaction blocks to intermediates were determined and used to calculate control coefficients. In the present paper, these elasticities and control coefficients are used to quantify the internal regulatory pathways within the cell. Flux control coefficients were partitioned to give partial flux control coefficients. These describe how strongly one block of reactions controls the flux through another via its effects on the concentration of a particular intermediate. Most flux control coefficients were the sum of positive and negative partial effects acting through different intermediates; these partial effects could be large compared to the final control strength. An important result was the breakdown of the way ATP consumption controlled respiration: changes in ATP level were more important than changes in mitochondrial membrane potential in stimulating oxygen consumption when ATP consumption increased. The partial internal response coefficients to changes in each intermediate were also calculated; they describe how steady state concentrations of intermediates are maintained. Increases in mitochondrial membrane potential were opposed mostly by decreased supply, whereas increases in glucose-6-phosphate, NADH/NAD and pyruvate were opposed mostly by increased consumption. Increases in ATP were opposed significantly by both decreased supply and increased consumption. (+info)
Biogenesis of giant mitochondria during insect flight muscle development in the locust, Locusta migratoria (L.). Transcription, translation and copy number of mitochondrial DNA.
(36/2221)
The biogenesis of giant mitochondria in flight muscle of Locusta migratoria (L.) was analyzed at the molecular level. During the 2 weeks between the beginning of the last larval stage and the imago capable of sustained flight, individual mitochondria have been shown to enlarge 30-fold and the fractional mitochondrial volume of muscle cells increases fourfold [Brosemer, R.W., Vogell, W. and Bucher, Th. (1963) Biochem. Z. 338, 854-910]. Within the same period, the activity of cytochrome c oxidase, containing subunits encoded on mitochondrial DNA, increased twofold. However, no significant change in mitochondrial DNA copy number, and even a threefold decrease in mitochondrial transcripts, was observed. Mitochondrial translation rate, measured in isolated organelles, was twofold higher in larval muscle, which can be explained only partly by the higher content of mitochondrial RNAs. Thus, rather unusually, in this system of mitochondrial differentiation, the mitochondrial biosynthetic capacity correlates with the rate of organelle biogenesis rather than the steady-state concentration of a marker enzyme. The copy number of mitochondrial DNA does not seem to play a major role in determining either mitochondrial transcript levels or functional mass. (+info)
Dimethylbiguanide inhibits cell respiration via an indirect effect targeted on the respiratory chain complex I.
(37/2221)
We report here a new mitochondrial regulation occurring only in intact cells. We have investigated the effects of dimethylbiguanide on isolated rat hepatocytes, permeabilized hepatocytes, and isolated liver mitochondria. Addition of dimethylbiguanide decreased oxygen consumption and mitochondrial membrane potential only in intact cells but not in permeabilized hepatocytes or isolated mitochondria. Permeabilized hepatocytes after dimethylbiguanide exposure and mitochondria isolated from dimethylbiguanide pretreated livers or animals were characterized by a significant inhibition of oxygen consumption with complex I substrates (glutamate and malate) but not with complex II (succinate) or complex IV (N,N,N',N'-tetramethyl-1, 4-phenylenediamine dihydrochloride (TMPD)/ascorbate) substrates. Studies using functionally isolated complex I obtained from mitochondria isolated from dimethylbiguanide-pretreated livers or rats further confirmed that dimethylbiguanide action was located on the respiratory chain complex I. The dimethylbiguanide effect was temperature-dependent, oxygen consumption decreasing by 50, 20, and 0% at 37, 25, and 15 degrees C, respectively. This effect was not affected by insulin-signaling pathway inhibitors, nitric oxide precursor or inhibitors, oxygen radical scavengers, ceramide synthesis inhibitors, or chelation of intra- or extracellular Ca(2+). Because it is established that dimethylbiguanide is not metabolized, these results suggest the existence of a new cell-signaling pathway targeted to the respiratory chain complex I with a persistent effect after cessation of the signaling process. (+info)
Fluidity in mitochondrial membranes: thermotropic lateral translational motion of intramembrane particles.
(38/2221)
The fracture faces of frozen rat liver mitochondria reveal that intramembrane particles can be induced to under go long-range lateral translational motion and aggregation, which parallel the appearance of large, particle-free smooth patches in the hydrophobic interior of the two mitochondrial membranes. These lateral separations were observed under conditions that induce thermotropic lipid-lipid phase separations. Low temperature-induced lateral separation occurred between the intramembrane particles (integral proteins) and smooth patches (bilayer lipid) at temperatures between about 10 and -12 degrees in the outer membrane and between about -4 and -12 degrees in the inner, energy transducing membrane. (+info)
Charge pair model of bioenergetics: redox enzymes.
(39/2221)
A model of electron transfer between redox enzymes is constructed on the assumption that the apoenzyme contains orientable units, which are tentatively identified with flipping amino acids. The model is based on the entatic state hypothesis, and the rate of electron transfer is derived. (+info)
Ca(2+) activation of heart mitochondrial oxidative phosphorylation: role of the F(0)/F(1)-ATPase.
(40/2221)
Ca(2+) has been postulated as a cytosolic second messenger in the regulation of cardiac oxidative phosphorylation. This hypothesis draws support from the well-known effects of Ca(2+) on muscle activity, which is stimulated in parallel with the Ca(2+)-sensitive dehydrogenases (CaDH). The effects of Ca(2+) on oxidative phosphorylation were further investigated in isolated porcine heart mitochondria at the level of metabolic driving force (NADH or Deltapsi) and ATP production rates (flow). The resulting force-flow (F-F) relationships permitted the analysis of Ca(2+) effects on several putative control points within oxidative phosphorylation, simultaneously. The F-F relationships resulting from additions of carbon substrates alone provided a model of pure CaDH activation. Comparing this curve with variable Ca(2+) concentration ([Ca(2+)]) effects revealed an approximate twofold higher ATP production rate than could be explained by a simple increase in NADH or Deltapsi via CaDH activation. The half-maximal effect of Ca(2+ )at state 3 was 157 nM and was completely inhibited by ruthenium red (1 microM), indicating matrix dependence of the Ca(2+) effect. Arsenate was used as a probe to differentiate between F(0)/F(1)-ATPase and adenylate translocase activity by a futile recycling of ADP-arsenate within the matrix, catalyzed by the F(0)/F(1)-ATPase. Ca(2+) increased the ADP arsenylation rate more than twofold, suggesting a direct effect on the F(0)/F(1)-ATPase. These results suggest that Ca(2+) activates cardiac aerobic respiration at the level of both the CaDH and F(0)/F(1)-ATPase. This type of parallel control of both intermediary metabolism and ATP synthesis may provide a mechanism of altering ATP production rates with minimal changes in the high-energy intermediates as observed in vivo. (+info)