Social thermoregulation and torpor in the Siberian hamster

Jefimow, Małgorzata; Głabska, Marta; Wojciechowski, Michał S.

doi:10.1242/jeb.050823

Cited by 31 publications

(23 citation statements)

References 66 publications

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“…Also known as social thermoregulation (Arnold, 1993; Jefimow et al, 2011), huddling represents up to 53% of energy saving during cold, both in birds and mammals (Gilbert et al, 2010). However, how huddling interacts with other energy saving strategies such as torpor (Frey, 1991; Namekata and Geiser, 2009; Jefimow et al, 2011) has been little studied.…”

Section: Introductionmentioning

confidence: 99%

Aerobic power, huddling and the efficiency of torpor in the South American marsupial, Dromiciops gliroides

et al. 2012

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SummaryDuring periods of cold, small endotherms depend on a continuous supply of food and energy to maintain euthermic body temperature (Tb), which can be challenging if food is limited. In these conditions, energy-saving strategies are critical to reduce the energetic requirements for survival. Mammals from temperate regions show a wide arrange of such strategies, including torpor and huddling. Here we provide a quantitative description of thermoregulatory capacities and energy-saving strategies in Dromiciops gliroides, a Microbiotherid marsupial inhabiting temperate rain forests. Unlike many mammals from temperate regions, preliminary studies have suggested that this species has low capacity for control and regulation of body temperature, but there is still an incomplete picture of its bioenergetics. In order to more fully understand the physiological capacities of this “living fossil”, we measured its scope of aerobic power and the interaction between huddling and torpor. Specifically, we evaluated: (1) the relation between basal (BMR) and maximum metabolic rate (MMR), and (2) the role of huddling on the characteristics of torpor at different temperatures. We found that BMR and MMR were above the expected values for marsupials and the factorial aerobic scope (from CO2) was 6.0±0.45 (using CO2) and 6.2±0.23 (using O2), an unusually low value for mammals. Also, repeatability of physiological variables was non-significant, as in previous studies, suggesting poor time-consistency of energy metabolism. Comparisons of energy expenditure and body temperature (using attached data-loggers) between grouped and isolated individuals showed that at 20°C both average resting metabolic rate and body temperature were higher in groups, essentially because animals remained non-torpid. At 10°C, however, all individuals became torpid and no differences were observed between grouped and isolated individuals. In summary, our study suggests that the main response of Dromiciops gliroides to low ambient temperature is reduced body temperature and torpor, irrespective of huddling. Low aerobic power and low time-consistency of most thermoregulatory traits of Dromiciops gliroides support the idea of poor thermoregulatory abilities in this species.

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Section: Introductionmentioning

confidence: 99%

Aerobic power, huddling and the efficiency of torpor in the South American marsupial, Dromiciops gliroides

et al. 2012

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“…Given the high consumption of oxygen required for thermogenesis (Chi and Wang, 2011), this may account for the progressive, regional rewarming noted for the hamster (Osborne et al, 2005). Furthermore, this may in part explain the 'social thermoregulation' previously noted for the Siberian hamster (Jefimow et al, 2011), as grouped animals show narrower ranges of core temperatures during torpor, which may prevent a catastrophic fall in core temperature beyond which cardiovascular control is inadequate. CA may represent an indefinite period of preservation prior to committing to a wholesale transcriptome remodelling during hibernation.…”

Section: Discussionmentioning

confidence: 97%

Is cold acclimation of benefit to hibernating rodents?

Egginton

May

Deveci

et al. 2013

Journal of Experimental Biology

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SUMMARYThe thermal challenge associated with cold acclimation (CA) and hibernation requires effective cardio-respiratory function over a large range of temperatures. We examined the impact of acute cooling in a cold-naïve hibernator to quantify the presumed improvement in cardio-respiratory dysfunction triggered by CA, and estimate the role of the autonomic nervous system in optimising cardiac and respiratory function. Golden hamsters (Mesocricetus auratus) were held at a 12h:12h light:dark photoperiod and room temperature (21°C euthermic control) or exposed to simulated onset of winter in an environmental chamber, by progression to 1h:23h light:dark and 4°C over 4weeks. In vivo acute cooling (core temperature T b =25°C) in euthermic controls led to a hypotension and bradycardia, but preserved cardiac output. CA induced a hypertension at normothermia (T b =37°C) but on cooling led to decreases in diastolic pressure below euthermic controls and a decrease in cardiac output, despite an increase in left ventricular conductance. Power spectral analysis of heart rate variability suggested a decline in vagal tone on cooling euthermic hamsters (T b =25°C). Following CA, vagal tone was increased at T b =37°C, but declined more quickly on cooling (T b =25°C) to preserve vagal tone at levels similar to euthermic controls at T b =37°C. For the isolated heart, CA led to concentric hypertrophy with decreased end-diastolic volume, but with no change in intrinsic heart rate at either 37 or 25°C. Mechanical impairment was noted at 37°C following CA, with peak developed pressure decreased by 50% and peak rate-pressure product decreased by 65%; this difference was preserved at 25°C. For euthermic hearts, coronary flow showed thermal sensitivity, decreasing by 65% on cooling (T=25°C). By contrast, CA hearts had low coronary flow compared with euthermic controls, but with a loss of thermal sensitivity. Together, these observations suggest that CA induced a functional impairment in the myocardium that limits performance of the cardiovascular system at euthermia, despite increased autonomic input to preserve cardiac function. On acute cooling this autonomic control was lost and cardiac performance declined further than for cold-naïve hamsters, suggesting that CA may compromise elements of cardiovascular function to facilitate preservation of those more critical for subsequent rewarming. Supplementary material available online at

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“…Hamsters were held in a ventilated room at the Research Institute of Wildlife Ecology under a natural photoperiod from summer (16 h:8 h light: dark) to winter (9.5 h:14.5 h light:dark; sunrise ∼07:00 h, sunset ∼17:15 h) in February when most measurements were performed and torpor is regularly expressed (Jefimow et al, 2011). Pelage colour of the animals was at stage 4, i.e.…”

Section: Materials and Methods Animal Maintenancementioning

confidence: 99%

Basking hamsters reduce resting metabolism, body temperature and energy costs during rewarming from torpor

Geiser

Gasch

Bieber

et al. 2016

Journal of Experimental Biology

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Basking can substantially reduce thermoregulatory energy expenditure of mammals. We tested the hypothesis that the largely white winter fur of hamsters (Phodopus sungorus), originating from Asian steppes, may be related to camouflage to permit sun basking on or near snow. Winter-acclimated hamsters in our study were largely white and had a high proclivity to bask when resting and torpid. Resting hamsters reduced metabolic rate (MR) significantly (>30%) when basking at ambient temperatures (T a ) of ∼15 and 0°C. Interestingly, body temperature (T b ) also was significantly reduced from 34.7±0.6°C (T a 15°C, not basking) to 30.4±2.0°C (T a 0°C, basking), which resulted in an extremely low (<50% of predicted) apparent thermal conductance. Induced torpor (food withheld) during respirometry at T a 15°C occurred on 83.3±36.0% of days and the minimum torpor MR was 36% of basal MR at an average T b of 22.0±2.6°C; movement to the basking lamp occurred at T b <20.0°C. Energy expenditure for rewarming was significantly reduced (by >50%) during radiant heat-assisted rewarming; however, radiant heat per se without an endogenous contribution by animals did not strongly affect metabolism and T b during torpor. Our data show that basking substantially modifies thermal energetics in hamsters, with a drop of resting T b and MR not previously observed and a reduction of rewarming costs. The energy savings afforded by basking in hamsters suggest that this behaviour is of energetic significance not only for mammals living in deserts, where basking is common, but also for P. sungorus and probably other cold-climate mammals.

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Social thermoregulation and torpor in the Siberian hamster

Cited by 31 publications

References 66 publications

Aerobic power, huddling and the efficiency of torpor in the South American marsupial, Dromiciops gliroides

Aerobic power, huddling and the efficiency of torpor in the South American marsupial, Dromiciops gliroides

Is cold acclimation of benefit to hibernating rodents?

Basking hamsters reduce resting metabolism, body temperature and energy costs during rewarming from torpor

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