Summary
The energy metabolism of rat thymus cells has been investigated using preparations of isolated cells obtained by mechanical treatment of whole organs.
The addition of glycolytic substrates such as glucose, pyruvate and lactate stimulates the endogenous respiration of these cells by 50%. On the other hand, succinate, glutamate and malate do not produce any effect.
Oligomycin (10 µg/ml) inhibits both endogenous and glucose stimulated respiration by about 40%; 2,4-DNP (50 µm) increases by 100% glucose induced respiration.
The results obtained by using mitochondrial and glycolytic inhibitors as well as aminoxyacetic acid (AOA) and following pyridine nucleotides redox changes, support the idea that in thymus cells glucose is able to induce a great enhancement of O2 consumption both by raising the level of endogenous pyruvate and feeding the mitochondrial respiratory chain with cytosolic reducing equivalents, through an active malate-aspartate shuttle.
Thymus cells exhibit a high Pasteur effect (74%). Both AOA and 2,4 DNP are able to stimulate aerobic lactate accumulation by 200% and 100% respectively, indicating that either the redox or phosphate potential do influence the rate of aerobic glycolysis in isolated thymus cells. Similar experiments are also reported on other cells with well known biochemical characteristics.
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Cittadini, A., Bossi, D., Longhi, G. et al. Energy metabolism of isolated rat thymus cells. Mol Cell Biochem 8, 49–57 (1975). https://doi.org/10.1007/BF01731649
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DOI: https://doi.org/10.1007/BF01731649