By means of in vivo 31P nuclear magnetic resonance (NMR) we measured energy stores and intracellular pH at 10-min intervals in the myotome of unanesthetized carp and goldfish before, during, and after a period of anoxia (1 h for carp and 4 h for goldfish). The fish were mounted in a modified bioprobe, and their gills were irrigated with a constant flow of aerated or anoxic water. Anoxia caused a steep decline of phosphocreatine and intracellular pH in carp muscle. After the phosphocreatine stores had been exhausted by greater than 85%, [ATP] fell, whereas IMP and phosphodiesters accumulated. In goldfish muscle, initial changes followed the same pattern, but after 20 min a steady state of high-energy phosphates was reached and the development of acidosis was dampened. The resistance of goldfish to anoxia is due to metabolic suppression and a switch from lactate to ethanol and CO2 as the anaerobic end products. In both species, recovery was complete within 3 h. The fast pH recovery seems to be mainly caused by H+ and lactic acid efflux.
Three fish species were exposed to graded hypoxia levels and allowed to recover. Levels of high-energy phosphate compounds in epaxial white muscle were monitored by in vivo 31P nuclear magnetic resonance (NMR) spectroscopy. Furthermore, O2 consumption of the animals was measured. With increasing hypoxia load, metabolic parameters started to change in the following order: phosphocreatine (PCr)-to-Pi ratio (decrease), O2 consumption (decrease), [PCr] (decrease), intracellular pH (pHi; decrease), Pi (increase), free ADP concentration ([ADP]free; increase), [ATP] (decrease). PCr levels fell with the PO2. After each increment, the [PCr] reached a stable plateau value while, in some cases, a recovery was observed. This recovery could be explained because the balance between anaerobic and aerobic metabolism is continuously fluctuating during hypoxia as a consequence of changes in the activity of the fish. Consequently the [ADP]free are fluctuating, resulting in an activation of the creatine kinase reaction and the anaerobic glycolysis. In all three species, anaerobic glycolysis was activated, but in contrast to anoxia exposure, metabolic suppression was absent. The changes of [ADP]free and [H+] (which influences the position of the creatine kinase equilibrium) are species dependent. Species differences observed in the other parameters were small. It is concluded that the pattern of the activation of anaerobic metabolism under deep hypoxia is different from that under anoxia.
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