Biochemical Foundations of Health and Energy Conservation in Hibernating Free-ranging Subadult Brown Bear Ursus arctos

Brown bears (Ursus arctos) hibernate for 5-7 months without eating, drinking, urinating, and defecating at a metabolic rate of only 25% of the summer activity rate. Nonetheless, they emerge healthy and alert in spring. We quantified the biochemical adaptations for hibernation by comparing the proteo...

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Bibliographic Details
Published in:Journal of Biological Chemistry
Main Authors: Gjesing Welinder, Karen, Hansen, Rasmus, Toft Overgaard, Michael, Brohus, Malene, Sonderkaer, Mads, von Bergen, Martin, Rolle-Kampczyk, Ulrike, Otto, Wolfgang, Lindahl, Tomas, Arinell, Karin, Evans, Alina L., Swenson, Jon E., Revsbech, Inge G., Frobert, Ole
Format: Article in Journal/Newspaper
Language:English
Published: Linköpings universitet, Avdelningen för mikrobiologi och molekylär medicin 2016
Subjects:
coagulation factor
complement system
metabolomics
protein turnover
proteomics
antimicrobial proteins
blood constituents
hibernation physiology
sex hormone-binding globulin (SHBG)
Biochemistry and Molecular Biology
Biokemi och molekylärbiologi
Ursus arctos
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-132848
https://doi.org/10.1074/jbc.M116.742916
Description
Summary:Brown bears (Ursus arctos) hibernate for 5-7 months without eating, drinking, urinating, and defecating at a metabolic rate of only 25% of the summer activity rate. Nonetheless, they emerge healthy and alert in spring. We quantified the biochemical adaptations for hibernation by comparing the proteome, metabolome, and hematological features of blood from hibernating and active free-ranging subadult brown bears with a focus on conservation of health and energy. We found that total plasma protein concentration increased during hibernation, even though the concentrations of most individual plasma proteins decreased, as did the white blood cell types. Strikingly, antimicrobial defense proteins increased in concentration. Central functions in hibernation involving the coagulation response and protease inhibition, as well as lipid transport and metabolism, were upheld by increased levels of very few key or broad specificity proteins. The changes in coagulation factor levels matched the changes in activity measurements. A dramatic 45-fold increase in sex hormone-binding globulin levels during hibernation draws, for the first time, attention to its significant but unknown role in maintaining hibernation physiology. We propose that energy for the costly protein synthesis is reduced by three mechanisms as follows: (i) dehydration, which increases protein concentration without de novo synthesis; (ii) reduced protein degradation rates due to a 6 degrees C reduction in body temperature and decreased protease activity; and (iii) a marked redistribution of energy resources only increasing de novo synthesis of a few key proteins. The comprehensive global data identified novel biochemical strategies for bear adaptations to the extreme condition of hibernation and have implications for our understanding of physiology in general. Funding Agencies|Lundbech Foundation [R126-2012-12408]; Aalborg University

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