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

Welinder, Karen G.; Hansen, Rasmus; Overgaard, Michael Toft; Brohus, Malene; Sønderkær, Mads; Bergen, Martin von; Rolle-Kampczyk, Ulrike; Otto, Wolfgang; Lindahl, Tomas; Arinell, Karin; Evans, Alina L.; Swenson, Jon E.; Revsbech, Inge G.; Fröbert, Ole

doi:10.1074/jbc.m116.742916

Cited by 40 publications

(64 citation statements)

References 54 publications

(68 reference statements)

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“…Again, we consider that better understanding of modulations within the mechanisms of the clotting cascade in black bears may introduce opportunities for employing novel clinical mechanisms for anti-coagulation therapy and targeted treatments. It should be noted that in a very recent publication the clotting behavior in hibernating brown bears (Ursus arctos) has been described to elicit similar responses (Welinder et al, 2016).…”

Section: Discussionmentioning

confidence: 93%

Blood clotting behavior is innately modulated in Ursus Americanus during early and late denning relative to summer months

Iles

Laske

Garshelis

et al. 2016

Journal of Experimental Biology

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Remarkably, American black bears (Ursus americanus) are capable of varying their heart rates to coincide with their breathing, creating pauses of 30 s or more, yet they do not appear to suffer from embolic events. We evaluated some features of the clotting cascade of black bears, providing novel insights into the underlying mechanisms they evoke for embolic protection during hibernation. We measured activated clotting time, prothrombin time and activated partial thromboplastin time during early denning (December), late denning (March) and summer (August). Activated clotting time during early hibernation was ∼3 times longer than that observed among non-hibernating animals. Clotting time was reduced later in hibernation, when bears were within ∼1 month of emerging from dens. Prothrombin time was similar for each seasonal time point, whereas activated partial thromboplastin time was highest during early denning and decreased during late denning and summer. We also examined D-dimer concentration to assess whether the bears were likely to have experienced embolic events. None of the nonparturient bears exceeded a D-dimer concentration of 250 ng ml −1 (considered the clinical threshold for embolism in mammals). Our findings suggest there is unique expression of the clotting cascade in American black bears during hibernation, in which extrinsic pathways are maintained but intrinsic pathways are suppressed. This was evaluated by a significant difference between the activated clotting time and activated partial thromboplastin time during the denning and non-denning periods. These changes are likely adaptive, to avoid clotting events during states of immobilization and/or periods of asystole. However, an intact extrinsic pathway allows for healing of external injuries and/or foreign body responses.

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Section: Discussionmentioning

confidence: 93%

Blood clotting behavior is innately modulated in Ursus Americanus during early and late denning relative to summer months

Iles

Laske

Garshelis

et al. 2016

Journal of Experimental Biology

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“…Brown bears hibernate for several months during which they do not eat, drink, defecate or urinate, thus reducing the use of the bladder, kidneys, and digestive tract (Folk, Folk, & Minor, 1972;Hissa, 1997;Stenvinkel, Fröbert, et al, 2013). Hibernation adaptations allow bears to overcome anuria, hyperlipidemia, and immobilization (Welinder et al, 2016), preserve muscles and bones avoiding osteoporosis or sarcopenia (Fröbert, Frøbert, Kindberg, Arnemo, & Overgaard, 2020;Vestergaard et al, 2011) and prevent diseases such as metabolic syndrome, diabetes, and cardiovascular pathologies (Arinell et al, 2012;Fröbert et al, 2020;Nelson & Robbins, 2015). The physiological modifications that occur in bears during hibernation, and which are summarized below, might be the result of ultimate factors such as metabolic dietary-related needs and energy conservation, which brown bears have to deal with to survive the winter (Table 1).…”

Section: Hibernation Physiology and The Potential Energetic Costsmentioning

confidence: 99%

“…The hibernating induction trigger (HIT), a compound present in the blood, might initiate physiological and metabolic changes that lead to hibernation (Hellgren, 1998;Hissa et al, 1994;Jørgensen et al, 2014;Welinder et al, 2016), although it has also been suggested than more than a single substance could trigger all these changes (Hissa, 1997). For example, the sex hormone-binding globulin protein, which increases its concentration 45-fold during hibernation, might also help trigger hibernation (Welinder et al, 2016).…”

Section: Hibernation Physiology and The Potential Energetic Costsmentioning

confidence: 99%

“…High concentrations of phospholipids and cholesterol may be due to the shrinking of the membrane of the adipocytes caused by dehydration (Welinder et al, 2016). The high concentrations of free fatty acids (FA) and glycerol might be the result of their release from adipose tissue during hibernation (Welinder et al, 2016), with short chain (easier oxidation) of FAs being released and retained in muscle and tissue adipose than long FA chains, as it occurs in other hibernating mammals (Giroud et al, 2019).…”

Section: Lipid Metabolismmentioning

confidence: 99%

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Denning in brown bears

González-Bernardo

Russo

Valderrábano

et al. 2020

Ecology and Evolution

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Hibernation represents an adaptation for coping with unfavorable environmental conditions. For brown bears Ursus arctos, hibernation is a critical period as pronounced temporal reductions in several physiological functions occur. Here, we review the three main aspects of brown bear denning: (1) den chronology, (2) den characteristics, and (3) hibernation physiology in order to identify (a) proximate and ultimate factors of hibernation as well as (b) research gaps and conservation priorities. Den chronology, which varies by sex and reproductive status, depends on environmental factors, such as snow, temperature, food availability, and den altitude. Significant variation in hibernation across latitudes occurs for both den entry and exit. The choice of a den and its surroundings may affect individual fitness, for example, loss of offspring and excessive energy consumption. Den selection is the result of broad‐ and fine‐scale habitat selection, mainly linked to den insulation, remoteness, and availability of food in the surroundings of the den location. Hibernation is a metabolic challenge for the brown bears, in which a series of physiological adaptations in tissues and organs enable survival under nutritional deprivation, maintain high levels of lipids, preserve muscle, and bone and prevent cardiovascular pathologies such as atherosclerosis. It is important to understand: (a) proximate and ultimate factors in denning behavior and the difference between actual drivers of hibernation (i.e., factors to which bears directly respond) and their correlates; (b) how changes in climatic factors might affect the ability of bears to face global climate change and the human‐mediated changes in food availability; (c) hyperphagia (period in which brown bears accumulate fat reserves), predenning and denning periods, including for those populations in which bears do not hibernate every year; and (d) how to approach the study of bear denning merging insights from different perspectives, that is, physiology, ecology, and behavior.

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“…Proteomes of blood, organs and tissues can be characterised by mass spectrometry (MS), which identifies proteins and determines relative protein quantities by matching the mass of peptide fragments to predicted peptide sequences from databases. The differences between the summer and winter brown bear plasma proteome have been characterised by Welinder et al [30], providing information of the biochemical adaptions for hibernation, as the bloodstream has primary functions in signalling. A number of adaptations specific to hibernation were discovered, including energy conservation by decreased levels of the majority of plasma proteins combined with maintained or moderately increased levels of a few key plasma proteins performing crucial functions in hibernation.…”

Section: A Strategy To Translate From Bears To Humansmentioning

confidence: 99%

The brown bear as a translational model for sedentary lifestyle‐related diseases

et al. 2019

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Sedentary lifestyle accelerates biological ageing, is a major risk factor for developing metabolic syndrome and is associated with cardiovascular disease, diabetes mellitus, kidney failure, sarcopenia and osteoporosis. In contrast to the linear path to worsening health in humans with metabolic syndrome, brown bears have developed a circular metabolic plasticity enabling these animals to tolerate obesity and a ‘sedentary lifestyle’ during hibernation and exit the den metabolically healthy in spring. Bears are close to humans physiology wise, much closer than rodents, the preferred experimental animals in medical research, and may better serve as translational model to develop treatments for lifestyle‐related diseases. In this review, aspects of brown bear hibernation survival strategies are outlined and conceivable experimental strategies to learn from bears are described.

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

Cited by 40 publications

References 54 publications

Blood clotting behavior is innately modulated in Ursus Americanus during early and late denning relative to summer months

Blood clotting behavior is innately modulated in Ursus Americanus during early and late denning relative to summer months

Denning in brown bears

The brown bear as a translational model for sedentary lifestyle‐related diseases

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