UMLS:C0015672 - FACTA Search

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Query: UMLS:C0015672 (fatigue)
51,768 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A broadly held opinion is that fatigue is not due to an insufficient supply of ATP to the energy consuming mechanisms because tissue [ATP] always remains at least one order of magnitude higher than Km for ATP of any ATPase. In general these findings also suggest that ATP consumption is well balanced with ATP regeneration even in the fatigued muscles. This balance is achieved by down-regulation of ATP consumption. Potentially this down-regulation could be accomplished by any product of the ATPase reaction and the role of Pi and H+ accumulation in this regulation has been discussed in the literature. The purpose of this paper is to describe known compartmentalization of ATP regeneration systems in muscle cell, their importance in the regulation of [adenine nucleotide] in the vicinity of ATPases and how such local ATP regeneration maybe important in the etiology of muscle fatigue. Available experimental evidence suggests that the binding of creatine kinase and glycolytic enzymes in the vicinity of sites where ATP is hydrolyzed and functional coupling between these ATP regenerating mechanisms and ATPase can generate ATPase microenvironments that have an important role in the regulation of ATPase function. Main function of this ATP regeneration is to keep the local ADP/ATP ratios favorable for ATPase function, which seems to be especially important when ATPase turnover is high. Unfortunately, the maximum rate of local ATP regeneration relative to that of ATP hydrolysis in vivo is not known, mainly because in vitro determinations underestimate this value due to a decrease in the fractional of loosely abound enzyme to the preparation during isolation procedure.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The importance of ATPase microenvironment in muscle fatigue: a hypothesis. 764 8

1. ADP inhibits the maximum shortening velocity (V0) in skeletal muscle. [ADP] may increase considerably during contractions and reduce V0 in the absence of energy buffering by phosphocreatine (PCr). We have tested this hypothesis by comparing V0 in long and short tetani produced in situations where PCr buffering is absent. 2. Single, intact muscle fibres were dissected from toe muscles of Xenopus and stimulated by current pulses at 20 degrees C. The test sequence consisted of a 400 ms tetanus, followed after 3 s by a 1400 ms tetanus and after an additional 4 s by a 400 ms tetanus. V0 was measured with slack tests at 200 and 1200 ms, respectively. 3. The PCr system was inactivated in three ways: (i) fatiguing fibres with repeated short tetani; (ii) inhibition of the creatine kinase (CK) reaction with dinitrofluorobenzene; and (iii) inhibition of energy metabolism with iodoacetic acid and cyanide. 4. Under control conditions V0 was similar in all three test tetani. With inactive PCr buffering V0 was about 30% lower in the long tetanus. This slowing recovered fully in the second short tetanus in fatigue and with CK inhibition. 5. Calculations suggest that [ADP] can reach very high levels (about 3 mM) during prolonged contractions in the absence of PCr buffering.
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PMID:Reduced maximum shortening velocity in the absence of phosphocreatine observed in intact fibres of Xenopus skeletal muscle. 771 29

To directly assess the possible role of ADP in muscle fatigue, we have studied the effect of physiological MgADP levels on maximum Ca(2+)-activated isometric force and unloaded shortening velocity (Vus) of single skinned fiber segments from rabbit fast-twitch (psoas) and slow-twitch (soleus) muscles. MgADP concentration was changed in a controlled and well-buffered manner by varying creatine (Cr) in solutions, which also contained MgATP, phosphocreatine (PCr), and creatine kinase (CK). To quantify ADP as a function of Cr added, we determined the apparent equilibrium constant (K') of CK for the conditions of our experiments (pH 7.1, 3 mM Mg2+, 12 degrees C): K' = (sigma [Cr]. sigma [ATP])/(sigma [PCr]. sigma [ADP]) = 260 +/- 3 (SE). In this manner, ADP was altered essentially as occurs during stimulation in vivo but without the concomitant changes in pH and P(i), which affect force and Vus. As ADP (and Cr) was increased, force and Vus decreased in both fiber types; at the highest ADP level used, 200 microM, normalized force was 96.6 +/- 1.7% for psoas (n = 6) and 93.7 +/- 2.8% for soleus (n = 6), and Vus was 80.4 +/- 2.4% for psoas and 91.3 +/- 7.7% for soleus. Diffusion-reaction calculations indicated that radial gradients of metabolite concentrations within fibers could not explain the small effects of ADP on fiber mechanics, and experiments verified that metabolite levels were well buffered within fibers by the CK reaction. Exogenous CK was added to bathing solutions at 290 U/ml, threefold above that necessary to maintain Vus independent of CK concentration; in the absence of PCr and exogenous CK, at least a fourfold increased MgATP was necessary to maintain Vus at the control level. Adenylate kinase activity was not detectable; thus myofibrillar adenosine-triphosphatase and exogenous CK activities were the major determinants of nucleotide levels within activated cells. Cr alone (in absence of PCr and exogenous CK) also decreased force and Vus, presumably by a nonspecific mechanism. Over the physiological range, altered ADP had little or no effect on force or Vus in well-buffered conditions. It is therefore likely that other factors decrease force and Vus during muscular fatigue.
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PMID:Effect of physiological ADP concentrations on contraction of single skinned fibers from rabbit fast and slow muscles. 786 87

Propranolol, metoprolol, acebutolol, nadolol and atenolol were incubated with isolated rat skeletal muscle mitochondria at 30 degrees C, and the rate of oxygen consumption was measured with an oxygen microelectrode. The potency of these drugs to inhibit state III respiration was correlated with lipid solubility as measured by the octanol/water partition coefficient. The most lipid-soluble beta-blocker, propranolol, had an ED50 of 0.6 mmol/l. The most water-soluble one, atenolol, showed no inhibition at concentrations up to 16 mmol/l. Inhibition of respiratory control ratio, state IV respiration and ADP/O ratio occurred at 2 mmol/l for propranolol, 16 mmol/l for metoprolol and was not consistently observed for the other beta-blockers at the concentrations tested. The inhibition of state III respiration of skeletal muscle mitochondria by lipid-soluble beta-blockers may be one of the causes of the fatigue observed in some patients receiving these drugs.
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PMID:Lipophilic beta-blockers inhibit rat skeletal muscle mitochondrial respiration. 790 63

We have studied the force-velocity relation and the relaxation speed in intact, single fibres from Xenopus during fatigue produced by repeated tetani. Slack tests were used to obtain the shortening velocity at zero load (V0) and ramp shortenings to get the force at intermediate velocities. The relaxation speed was measured as the slope during the initial linear phase of relaxation. During fatiguing stimulation isometric tension declined following a typical pattern with three phases. During the initial 10-15 tetani (phase 1) isometric tension fell to about 80% of the pre-fatigue tension (P0), while V0 showed no significant change. Thereafter V0 fell almost linearly with time, whereas isometric tension first fell very slowly (phase 2) and then rapidly (phase 3). In fatigue V0 was reduced to 46% of the control and isometric tension to 0.34 P0. The force velocity relation seemed less curved during fatigue. The relaxation speed was almost halved during phase 1 and thereafter fell more slowly to less than 10% of the control in fatigue. We suggest changes of isometric tension and shortening velocity during phase 1 and 2 to reflect altered crossbridge function due to changes of intracellular pH, inorganic phosphate and ADP concentration; the additional tension decline during phase 3 would reflect impaired Ca2+ activation of the crossbridges. The rapid slowing of relaxation during phase 1 probably involves Ca2+ saturation of parvalbumin, whereas the additional decline during phase 2 and 3 would reflect the above metabolic changes, acting either on crossbridges or active Ca2+ reuptake into the sarcoplasmic reticulum.
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PMID:Changes of the force-velocity relation, isometric tension and relaxation rate during fatigue in intact, single fibres of Xenopus skeletal muscle. 792 94

This report describes changes of the rate of ATP hydrolysis in single, intact muscle fibres during the development of fatigue induced by intermittent tetanic stimulation. High (type 3) and low (type 1) oxidative muscle fibres dissected from the iliofibularis muscle of Xenopus laevis were studied at 20 degrees C. The rate of ATP hydrolysis was calculated during different time intervals from changes in the content of nucleotides, creatine compounds and lactate, as well as lactate efflux and oxygen uptake. During the first phase of intermittent stimulation, phosphocreatine is fully reduced while the rate of oxygen consumption increases to its maximum, the lactate content increases to a maximum level, and a small amount of IMP is formed; the rate of ATP hydrolysis in type 3 fibres is constant while force decreases, whereas the rate decreases approximately in proportion to force in type 1 fibres. After the first phase, the rate of ATP hydrolysis in type 3 fibres decreases slightly and the fibres reach a steady metabolic state in which the rates of ATP formation and hydrolysis are equal; in type 1 fibres a drastic change of the rate of ATP hydrolysis occurs and a steady metabolic state is not reached. On the basis of the time courses of the metabolic changes, it is concluded that the rate of ATP hydrolysis in type 3 fibres is reduced by acidification and/or a reduced calcium efflux from the sarcoplasmic reticulum, whereas in type 1 fibres inorganic phosphate and/or acidification inhibit the rate initially and ADP is a likely candidate to explain the drastic fall of the rate of ATP hydrolysis during late phases of fatiguing stimulation.
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PMID:ATP formation and ATP hydrolysis during fatiguing, intermittent stimulation of different types of single muscle fibres from Xenopus laevis. 812 21

Fatigue and lethargy, common symptoms in uraemia, have been attributed to many factors. To assess possible bioenergetic contributions to this, we examined the forearm muscle of five patients in end-stage renal failure using 31P-magnetic resonance spectroscopy. There was a small increase in the ratio of intracellular inorganic phosphate to ATP in resting muscle, suggesting an increased cytosolic phosphate concentration. During exercise, increased phosphocreatine breakdown was accompanied by rapid intracellular acidification and an increase in calculated lactic acid accumulation in the muscle of the uraemic subjects, suggesting glycolysis dominating over oxidative phosphorylation as a source of ATP. After exercise, the half-time of phosphocreatine (PCr) recovery was longer in the uraemic subjects, suggesting diminished mitochondrial function. The initial rate of PCr resynthesis was not significantly decreased, but when account was taken of the high cytosolic ADP concentration (which drives mitochondrial oxidative ATP synthesis) the calculated maximum oxidative capacity was significantly reduced in the uraemic subjects. Thus there was evidence of mitochondrial dysfunction in uraemia due either to limitation of oxygen supply, reduced mitochondrial content, or an intrinsic mitochondrial defect. This resulted in increased phosphocreatine depletion and increased glycolytic ATP production during exercise and there was partial compensation of the mitochondrial abnormality by increased ADP concentration. In three of these patients studied after elevation of haemoglobin with erythropoeitin (from 8 to 12 g/dl), initial phosphocreatine breakdown and lactic acid accumulation during exercise were normalized, while exercise duration and calculated maximum oxidative capacity remained significantly abnormal. This suggests that anaemia contributes to these metabolic abnormalities but does not fully explain them.
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PMID:Effect of chronic uraemia on skeletal muscle metabolism in man. 838 87

The role of prolonged electrical stimulation on sarcoplasmic reticulum (SR) Ca2+ sequestration measured in vitro and muscle energy status in fast white and red skeletal muscle was investigated. Fatigue was induced by 90 min intermittent 10-Hz stimulation of rat gastrocnemius muscle, which led to reductions (p < 0.05) in ATP, creatine phosphate, and glycogen of 16, 55, and 49%, respectively, compared with non-stimulated muscle. Stimulation also resulted in increases (p < 0.05) in muscle lactate, creatine, Pi, total ADP, total AMP, IMP, and inosine. Calculated free ADP (ADPf) and free AMP (AMPf) were elevated 3- and 15-fold, respectively. No differences were found in the metabolic response between tissues obtained from the white (WG) and red (RG) regions of the gastrocnemius. No significant reductions is SR Ca2+ ATPase activity were observed in homogenate (HOM) or a crude SR fraction (CM) from WG or RG muscle following exercise. Maximum Ca2+ uptake in HOM and CM preparations was similar in control (C) and stimulated (St) muscles. However, Ca2+ uptake at 400 nM free Ca2+ was significantly reduced in CM from RG (0.108 +/- 0.04 to 0.076 +/- 0.02 mumol.mg-1 protein.min-1 in RG - C and RG - St, respectively). Collectively, these data suggest that reductions in muscle energy status are dissociated from changes in SR Ca2+ ATPase activity in vitro but are related to Ca2+ uptake at physiological free [Ca2+ bd in fractionated SR from highly oxidative muscle. Dissociation of SR Ca2+ ATPase activity from Ca2+ uptake may reflect differences in the mechanisms evaluated by these techniques.
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PMID:Effects of prolonged low frequency stimulation on skeletal muscle sarcoplasmic reticulum. 856 84

Mechanical properties and metabolic adaptation to exercise in skeletal muscle of dystrophic hamsters were studied with an in vivo 31P-NMR multistep fatigue test. Three successive 20-min steps with increasing rhythms of tetanic stimulation were followed by a 20-min recovery period. Fatigue in dystrophic hamsters (DH) developed more rapidly and was greater than in normal hamsters (NH); total mechanical performance per min increased step by step in NH while it decreased in DH, showing a progressive mechanical impairment of the dystrophic muscles. ADP and PCr recovery rates were significantly reduced in DH muscles. Acidosis appeared in both DH and NH and persisted in DH throughout the test, suggesting reduced mitochondrial oxidative capacity of the dystrophic muscle. The pH recovery rate was reduced in DH muscles suggesting a reduction in export protons capacity. These results provide evidence of impaired mitochondrial function and intracellular ionic regulation in the dystrophic muscle, associated with the lack of dystrophin and dystrophin-associated glycoproteins in the DH.
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PMID:In vivo evidence of abnormal mechanical and oxidative functions in the exercised muscle of dystrophic hamsters by 31P-NMR. 858 20

Metabolic and mechanical properties of female rat skeletal muscles, submitted to endurance training on a treadmill, were studied by a 60-min in vivo multistep fatigue test. 31P-NMR was used to follow energy metabolism and pH. Mechanical performance was greatly improved in trained muscles. The oxidative capacity of the skeletal muscles was evaluated from the relationship between ADP calculated from the creatine kinase equilibrium and work and from the measure of the rate of phosphocreatine (PCr) resynthesis following exercise. In trained muscles, ADP production was lower per unit of mechanical performance, showing an improvement of oxidative metabolism. However, the PCr resynthesis rate was not modified. Slight acidosis and ATP depletion were observed from the beginning of the fatigue test. These modifications suggest changes of the creatine kinase equilibrium favoring mitochondrial ATP production. Our results indicate that muscle status improvement could be accompanied by ATP depletion and minimal acidosis during contraction; this would be of particular importance for objective evaluation of muscle regeneration processes and of gene therapy in muscle diseases.
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PMID:Improvement of muscular oxidative capacity by training is associated with slight acidosis and ATP depletion in exercising muscles. 860 1

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