Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0015672 (fatigue)
 51,768 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Subjects maintained an isometric contraction of the quadriceps femoris muscle at two-thirds maximal voluntary contraction (m.v.c.) force for 5 s (5.0 +/- 0.3 s; mean +/- S.E. of mean; n = 6) or until fatigue (52 +/- 4 s; n = 13). Muscle biopsies were obtained at rest, immediately after the contractions and also at 1 and 4 min of recovery after contraction to fatigue. In all subjects 5 s isometric contraction resulted in an increase of muscle NADH (0.084 +/- 0.012 at rest to 0.203 +/- 0.041 mmol/kg dry wt.) and a decrease of phosphocreatine (PC; change in concentration = -17.3 +/- 3.8 mmol/kg dry wt.). Glucose-6-phosphate concentration was more than doubled whereas lactate increased in only four of the six subjects. The two subjects who did not show any increase in lactate also had the lowest increase in NADH. At fatigue NADH increased to 0.226 +/- 0.032 mmol/kg dry wt. which was not significantly different from the value after 5 s contraction. Muscle PC was nearly depleted and lactate increased 12-fold above resting levels. The major part (65%) of the NADH increase at fatigue had reverted after 1 min recovery but only a slight further decrease occurred between 1 and 4 min of recovery. In relative terms the time course of the changes in muscle NADH during the first minute of recovery was similar to that of PC resynthesis, suggesting a common regulator such as O2 availability. In contrast to the delayed return of NADH concentration, PC resynthesis continued during the later part of the recovery period and PC concentration was almost fully restored after 4 min of recovery. It is concluded that muscle NADH is already maximally increased in the first seconds of muscle contraction at two-thirds m.v.c. Indirect evidence indicates that this increase reflects a reduction of the mitochondrial NAD-NADH redox couple. The rapid establishment of a reduced mitochondrial redox state at the start of muscle contraction will probably lead to a reduction of the redox state in the cytoplasm also and therefore be important for enhancing lactate formation.
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PMID:Redox state changes in human skeletal muscle after isometric contraction. 361 70

Mitochondrial myopathies are a clinical condition characterized by muscle weakness and fatigue in which the primary defect is localized at the level of the mitochondria. Microscopic examination shows accumulations of mitochondria at the fibre periphery (ragged red fibres) and in some cases mitochondrial paracrystalline inclusions. The spectrum of different mitochondrial defects so far described is reviewed and data from cases investigated in this laboratory are described. The first case was a 17-year-old boy with a multisystem disorder whose muscle mitochondria showed low respiratory activity with all substrates, which doubled in the presence of uncoupler. Further investigation showed that the mitochondrial ATPase activity was only 6% of normal. The next cases were a mother and daughter who showed a typical lipid storage myopathy. The latter was treated successfully with oral carnitine but the myopathy persisted. Mitochondrial investigations indicated a low respiratory activity with NAD-linked substrates but normal activity with succinate and ascorbate + TMPD. A defect in the NADH-CoQ reductase section of the respiratory chain was pinpointed possibly at an iron-sulphur centre. The fourth and fifth cases were two sisters who exhibited no lipid storage myopathy but whose mitochondrial activity was low with NAD-linked substrates but normal with succinate. Again a defect in the NADH-CoQ reductase (complex I) of the respiratory chain was determined. They were also investigated using 31P-NMR. It was found after exercise that their muscle creatine phosphate levels took seven times longer to return to pre-exercise concentrations than control subjects. These results are discussed with respect to the synthesis of mitochondrial proteins and the influence that both the mitochondrial and nuclear DNA have on this process.
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PMID:Mitochondrial myopathies: disorders of the respiratory chain and oxidative phosphorylation. 643 47

Uremia is associated with decreased brain oxygen consumption in humans and with decreased brain energy consumption in rodent models of acute renal failure. We measured the levels of high-energy phosphates and glycolytic intermediates in the brain of dogs with acute or chronic renal failure. We used methods of rapid brain tissue fixation that trap these labile metabolites at their in vivo levels. Creatine phosphate, ATP, and glucose were normal in the brain of animals with renal failure, indicating a normal brain energy reserve. The brain energy charge, which is the fraction of the total adenine nucleotide pool that contains high-energy phosphates, (ATP + 1/2ADP)/(ATP + ADP + AMP), was also normal despite an 8% decrease in the total adenine nucleotide pool. Mild hypoxia failed to alter the level of any of these metabolites. The brain redox state, (NAD+)/(NADH), was normal to high in acute renal failure, suggesting that oxygen supply was not limiting oxygen consumption. In the face of normal brain energy reserves, energy charge, and redox state, the decreased energy consumption of uremic brain probably results from decreased demand rather than limited supply.
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PMID:Uremic encephalopathy: role of brain energy metabolism. 647 28

Adult male rats were exposed to 3.8-km altitude for intervals ranging from 1 h-60 d. Liver samples were taken under light ether anesthesia and were examined by enzymatic analyses. Within 1-6 h of hypoxic exposure, ATP levels decreased while ADP and AMP levels increased, producing a fall in calculated ATP/ADP and adenylate charge ratios. Concurrently, lactate/pyruvate and alpha-glycerophosphate/dihydroxyacetone phosphate ratios increased markedly. Direct measurements of cellular pyridine nucleotides indicated increased NADH/NAD and NADPH/NADP ratios. Levels of total adenosine phosphates and pyridine nucleotides decreased in a significant accompanying response. Many metabolite levels and calculated ratios returned to near-normal values within 1 week of exposure, indicating secondary intracellular adjustments to hypoxic stress; however, persistence of that stress is reflected in lactate concentrations and both substrate redox ratios. Results support and explore concepts that increased oxidation-reduction status and decreased energy status are primary events during hypoxia.
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PMID:Energy status and oxidation-reduction status in rat liver at high altitude (3.8 km). 738 68

Adult male rats were exposed to 3.8-km altitude for intervals ranging from 1 h-60 d. Liver samples were taken under light ether anesthesia and were examined by enzymatic analyses. Within 1-6 h of hypoxic exposure, ATP levels decreased while ADP and AMP levels increased, producing a fall in calculated ATP/ADP and adenylate charge ratios. Concurrently, lactate/pyruvate and alpha-glycerophosphate/dihydroxyacetone phosphate ratios increased markedly. Direct measurements of cellular pyridine nucleotides indicated increased NADH/NAD and NADPH/NADP ratios. Levels of total adenosine phosphate and pyridine nucleotides decreased in a significant accompanying response. Many metabolite levels and calculated ratios returned to near-normal values within 1 week of exposure, indicating secondary intracellular adjustments to hypoxic stress; however, persistence of that stress is reflected in lactate conentrations and both substrate redox ratios. Results support and explore concepts that increased oxidation-reduction status and decreased energy status are primary events during hypoxia.
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PMID:Energy status and oxidation-reduction status in rat liver at high altitude (3.8 km). 741 22

Fatigue development was investigated in five adult female rhesus monkeys, 9-11 yr old (mean weight, 4.6 kg). After sedation and anaesthesia, silver electrodes were implanted in the anterior and posterior parts of the right masseter; the contralateral muscle was used as a control. The bite force was monitored. Muscle biopsies were obtained from the central part of the masseter and were immediately frozen in liquid nitrogen. After freeze-drying a fluorometric analysis using enzymatic methods for measuring levels of glycogen, glucose, lactate, pyruvate, creatine phosphate, creatine, NADH and NAD was made. The masseters were stimulated for 3 min (100 V, 4 Hz and 2 ms). After a 5-min rest period the stimulation was repeated with the same voltage, frequency and duration. The rhesus monkey masseters were easy to fatigue. After the stimulations 25% of the initial bite force remained. A marked substrate depletion was evident. The precontraction values of glycogen, glucose and phosphocreatine were reduced. The NADH concentration increased and the NAD content decreased. An accumulation of waste products was observed; the pyruvate increased by 92% and the lactate increased by a factor of 3. The substantial substrate depletion in combination with a prominent metabolic waste-product accumulation may induce a decrease in bite-force production.
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PMID:Fatigue development during electrical stimulation in the masseter muscle of rhesus monkeys (Macaca mulatta). 806 Feb 65

In Alzheimer's disease (AD) brain increased lipid peroxidation and decreased energy utilization are found. Mitochondria membranes contain a significant amount of arachidonic and linoleic acids, precursors of lipid peroxidation products, 4-hydroxynonenal (HNE) and 2-propen-1-al (acrolein), that are extremely reactive. Both alkenals are increased in AD brain. In this study, we examined the effects of nanomolar levels of acrolein on the activities of pyruvate dehydrogenase (PDH) and Alpha-ketoglutarate dehydrogenase (KGDH), both reduced nicotinamide adenine dinucleotide (NADH)-linked mitochondrial enzymes. Acrolein decreased PDH and KGDH activities significantly in a dose-dependent manner. Using high performance liquid chromatography coupled to mass spectrometry (HPLC-MS), acrolein was found to bind lipoic acid, a component in both the PDH and KGDH complexes, most likely explaining the loss of enzyme activity. Acrolein also interacted with oxidized nicotinamide adenine dinucleotide (NAD(+)) in such a way as to decrease the production of NADH. Acrolein, which is increased in AD brain, may be partially responsible for the dysfunction of mitochondria and loss of energy found in AD brain by inhibition of PDH and KGDH activities, potentially contributing to the neurodegeneration in this disorder.
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PMID:Acrolein inhibits NADH-linked mitochondrial enzyme activity: implications for Alzheimer's disease. 1471 35

The development of acidosis during intense exercise has traditionally been explained by the increased production of lactic acid, causing the release of a proton and the formation of the acid salt sodium lactate. On the basis of this explanation, if the rate of lactate production is high enough, the cellular proton buffering capacity can be exceeded, resulting in a decrease in cellular pH. These biochemical events have been termed lactic acidosis. The lactic acidosis of exercise has been a classic explanation of the biochemistry of acidosis for more than 80 years. This belief has led to the interpretation that lactate production causes acidosis and, in turn, that increased lactate production is one of the several causes of muscle fatigue during intense exercise. This review presents clear evidence that there is no biochemical support for lactate production causing acidosis. Lactate production retards, not causes, acidosis. Similarly, there is a wealth of research evidence to show that acidosis is caused by reactions other than lactate production. Every time ATP is broken down to ADP and P(i), a proton is released. When the ATP demand of muscle contraction is met by mitochondrial respiration, there is no proton accumulation in the cell, as protons are used by the mitochondria for oxidative phosphorylation and to maintain the proton gradient in the intermembranous space. It is only when the exercise intensity increases beyond steady state that there is a need for greater reliance on ATP regeneration from glycolysis and the phosphagen system. The ATP that is supplied from these nonmitochondrial sources and is eventually used to fuel muscle contraction increases proton release and causes the acidosis of intense exercise. Lactate production increases under these cellular conditions to prevent pyruvate accumulation and supply the NAD(+) needed for phase 2 of glycolysis. Thus increased lactate production coincides with cellular acidosis and remains a good indirect marker for cell metabolic conditions that induce metabolic acidosis. If muscle did not produce lactate, acidosis and muscle fatigue would occur more quickly and exercise performance would be severely impaired.
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PMID:Biochemistry of exercise-induced metabolic acidosis. 1676 Mar 35

Acute Renal Failure (ARF) is the most costly kidney disease in hospitalized patients and remains as a serious problem in clinical medicine. The mortality rate among ARF patients remains around 50% and no pharmaceutical agents are currently available to improve its clinical outcome. Although several successful therapeutic approaches have been developed in animal models of the disease, translation of the results to clinical ARF remains elusive. Understanding the cellular and molecular mechanisms of vascular and tubular dysfunction in ARF is important for developing acceptable therapeutic interventions. Following an ischemic episode, cells of the affected nephron undergo necrotic and/or apoptotic cell death. Necrotic cell death is widely considered to be a futile process that cannot be modulated by pharmacological means as opposed to apoptosis. However, recent reports from various laboratories including ours indicate that inhibition or absence of poly(ADP)-ribose polymerase (PARP), one of the molecules involved in cell death, provides remarkable protection in disease models such as stroke, myocardial infarction and renal ischemia which are characterized predominantly by necrotic type of cell death. Overactivation of PARP in conditions such as ischemic renal injury leads to cellular depletion of its substrate NAD+ and consequently ATP. The severely compromised cellular energetic state induces acute cell injury and diminishes renal functions. PARP activation also enhances the expression of proinflammatory agents and adhesion molecules in ischemic kidneys. Pharmacological inhibition and gene ablation of PARP-1 decreased energy depletion, inflammatory response and improved renal functions in the setting renal ischemia/reperfusion injury. The biochemical pathways and the cellular and molecular mechanisms mediated by PARP-1 activation in eliciting the energy depletion and inflammatory responses in ischemic kidney are not fully elucidated. Dissecting the molecular mechanisms by which PARP activation contributes to oxidant-induced cell death will provide new strategies to interfere in those pathways to modulate cell death in renal ischemia. The current review evaluates the experimental evidences in animal and cell culture models implicating PARP as a pathophysiological modulator of acute renal failure with particular emphasis on ischemic renal injury.
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PMID:Poly(ADP-ribose) polymerase-mediated cell injury in acute renal failure. 1591 33

The concentration- and time-dependent effects of sulphur mustard on cultured human epidermal keratinocyte function were investigated with respect to cell proliferation, DNA and protein synthesis, the level of NAD(+) and ATP, and the intracellular activity of lactate dehydrogenase. If human epidermal keratinocytes were stimulated to proliferate by replating following exposure to sulphur mustard, inhibition of cell growth was observed after treatment of cells with 0.5 mum-sulphur mustard or more. Similarly, DNA synthesis was reduced in a concentration-dependent manner following exposures to 0.5 mum-sulphur mustard or higher. Inhibition of protein synthesis was observed only on exposure to concentrations higher than 10 mum. These effects could be detected immediately after exposure and were constant for at least 24 hr. In contrast, parameters for cellular energy decreased with time following exposure. At 24 hr post-exposure a concentration-dependent depletion of NAD(+) and ATP was observed, starting at exposure levels of 50 mum-sulphur mustard. Decrease of intracellular lactate dehydrogenase activity also occurred with exposures to 50 mum-sulphur mustard or more, although it was not possible to cause a reduction of more than 50% of control values. Furthermore, the results showed that sulphur mustard induces either persistent damage or damage that develops within 24 hr following treatment. The concurrent inhibition of DNA and protein synthesis combined with a decreased energy supply may have an important role in sulphur mustard-induced blister formation in skin.
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PMID:Concentration- and time-related effects of sulphur mustard on human epidermal keratinocyte function. 2073 20


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