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Torpor-arousal cycles in Syrian hamster heart are associated with transient activation of the protein quality control system

Wiersma, M., Beuren, T. M. A., de Vrij, E. L., Reitsema, V. A., Bruintjes, J. J., Bouma, H. R., Brundel, B. J. J. M. & Henning, R. H., Sep-2018, In : Comparative biochemistry and physiology b-Biochemistry & molecular biology. 223, p. 23-28 6 p.

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  • Torpor-arousal cycles in Syrian hamster heart are associated with transient activation of

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DOI

Hibernation consists of torpor, with marked suppression of metabolism and physiological functions, alternated with arousal periods featuring their full restoration. The heart is particularly challenged, exemplified by its rate reduction from 400 to 5-10 beats per minute during torpor in Syrian hamsters. In addition, during arousals, the heart needs to accommodate the very rapid return to normal function, which lead to our hypothesis that cardiac function during hibernation is supported by maintenance of protein homeostasis through adaptations in the protein quality control (PQC) system. Hereto, we examined autophagy, the endoplasmic reticulum (ER) unfolded protein (UPRER) response and the heat shock response (HSR) in Syrian hamster hearts during torpor and arousal. Transition from torpor to arousal (1.5 h) was associated with stimulation of the PQC system during early arousal, demonstrated by induction of autophagosomes, as shown by an increase in LC3B-II protein abundance, likely related to the activation of the UPRER during late torpor in response to proteotoxic stress. The HSR was not activated during torpor or arousal. Our results demonstrate activation of the cardiac PQC system - particularly autophagosomal degradation - in early arousal in response to cardiac stress, to clear excess aberrant or damaged proteins, being gradually formed during the torpor bout and/or the rapid increase in heart rate during the transition from torpor to arousal. This mechanism may enable the large gain in cardiac function during the transition from torpor to arousal, which may hold promise to further understand 'hibernation' of cardiomyocytes in human heart disease.

Original languageEnglish
Pages (from-to)23-28
Number of pages6
JournalComparative biochemistry and physiology b-Biochemistry & molecular biology
Volume223
Early online date9-Jun-2018
Publication statusPublished - Sep-2018

    Keywords

  • Autophagy, ER stress, Heart, Hibernation, Mesocricetus auratus, Protein quality control, Unfolded protein response, BODY-TEMPERATURE GOVERNS, STRESS-INDUCED AUTOPHAGY, MAMMALIAN HIBERNATION, SKELETAL-MUSCLE, GENE-EXPRESSION, PROTEOSTASIS, MYOCARDIUM, METABOLISM, ADAPTATIONS, INHIBITION

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