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Activation and Inhibition of Succinate-Dependent Ca2+ Transport in Liver Mitochondria during Adaptation

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Abstract

Succinate-dependent Ca2+ accumulation was investigated in rat liver mitochondria and in operation biopsies of patients under states either with prevalence of adrenergic influences (administration of activating doses of adrenaline, acute phase of immobilization stress, initial period after allogenic transplantation, and acute phase of myocardial infarction) or with prevalence of the reciprocal mediator acetylcholine (late period after transplantation, chronic ulcer disease of stomach and duodenum). Adrenaline prevalence leads to increase of succinate-dependent ATP synthesis and Ca2+ accumulation, which is due to known activation of succinate oxidation. However, together with activation, inhibition of these processes was revealed. The inhibition phase prevails under chronic pathology. Therefore, reciprocal regulation of succinate oxidation and succinate-dependent Ca2+ transport in mitochondria occurs in the body in the course of adaptation. The reciprocal regulation of mitochondrial processes is considered as a mechanism of reciprocal regulation of physiological functions.

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Authors and Affiliations

  1. Institute of Theoretical and Experimental Biophysics, Russian Academy of Sciences, Pushchino, Moscow Region, 142290, Russia

    I. R. Saakyan & M. N. Kondrashova

  2. Institute of Surgery, Armenian Ministry of Health, ul. Asratyana 10, Erevan, Armenia

    S. G. Saakyan

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  1. I. R. Saakyan
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  2. S. G. Saakyan
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  3. M. N. Kondrashova
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Saakyan, I.R., Saakyan, S.G. & Kondrashova, M.N. Activation and Inhibition of Succinate-Dependent Ca2+ Transport in Liver Mitochondria during Adaptation. Biochemistry (Moscow) 66, 795–802 (2001). https://doi.org/10.1023/A:1010272914835

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