Torpor

Torpor is a state of decreased physiological activity in an animal, usually by a reduced body temperature and metabolic rate. Torpor enables animals to survive periods of reduced food availability.[1] The term "torpor" can refer to the time a hibernator spends at low body temperature, lasting days to weeks, or it can refer to a period of low body temperature and metabolism lasting less than 24 hours, as in "daily torpor".

Animals that undergo daily torpor include birds (even tiny hummingbirds, notably Cypselomorphae)[2][3] and some mammals, including many marsupial species,[4] rodent species (such as mice), and bats.[5] During the active part of their day, such animals maintain normal body temperature and activity levels, but their metabolic rate and body temperature drop during a portion of the day (usually night) to conserve energy. Torpor is often used to help animals survive during periods of colder temperatures, as it allows them to save the energy that would normally be used to maintain a high body temperature.

Some animals seasonally go into long periods of inactivity, with reduced body temperature and metabolism, made up of multiple bouts of torpor. This is known as hibernation if it occurs during winter or aestivation if it occurs during the summer. Daily torpor, on the other hand, is not seasonally dependent and can be an important part of energy conservation at any time of year.

Torpor is a well-controlled thermoregulatory process and not, as previously thought, the result of switching off thermoregulation.[6] Marsupial torpor differs from non-marsupial mammalian (eutherian) torpor in the characteristics of arousal. Eutherian arousal relies on a heat-producing brown adipose tissue as a mechanism to accelerate rewarming. The mechanism of marsupial arousal is unknown, but appears not to rely on brown adipose tissue.[7]

Evolution

The evolution of torpor likely accompanied the development of homeothermy.[8] Animals capable of maintaining a body temperature above ambient temperature when other members of its species could not would have a fitness advantage. Benefits of maintaining internal temperatures include increased foraging time and less susceptibility to extreme drops in temperature.[8] This adaptation of increasing body temperature to forage has been observed in small nocturnal mammals when they first wake up in the evening.[9][10][11]

Although homeothermy lends advantages such as increased activity levels, small mammals and birds maintaining an internal body temperature spend up to 100 times more energy in low ambient temperatures compared to ectotherms.[12] To cope with this challenge, these animals maintain a much lower body temperature, staying just over ambient temperature rather than at normal operating temperature. This reduction in body temperature and metabolic rate allows the prolonged survival of animals capable of entering torpid states.

Functions

Slowing metabolic rate to conserve energy in times of insufficient resources is the primarily noted purpose of torpor.[13] This conclusion is largely based on laboratory studies where torpor was observed to follow food deprivation.[14] There is evidence for other adaptive functions of torpor where animals are observed in natural contexts:

Circadian rhythm during torpor

Animals that can enter torpor rely on biological rhythms such as torpor to continue natural functions. Different animals will manage their circadian rhythm differently, and in some species it's seen to completely stop (such as in European hamsters). Other organisms like black bear enter torpor and switch to multi-day cycles rather than rely on a circadian rhythm. However, it is seen that both captive and wild bears express similar circadian rhythms when entering torpor. Bears entering torpor in a simulated den with no light expressed normal but low functioning rhythms. The same was observed in wild bears denning in natural areas. The function of circadian rhythms in black, brown, and polar bears suggest that their system of torpor is evolutionarily advanced. [15]

Fat conservation observed in small birds

Torpor has been shown to be a strategy of small migrant birds to increase their body fat. Hummingbirds, resting at night during migration, were observed to enter torpor which helped conserve fat stores for the rest of their migration.[14]

This strategy of using torpor to increase body fat has also been observed in wintering chickadees.[16] Black-capped chickadees, living in temperate forests of North America, do not migrate south during winter. The chickadee can maintain a body temperature 12 °C lower than normal. This reduction in metabolism allows it to conserve 30% of fat stores amassed from the previous day. Without using torpor the chickadee would not be able to conserve its fat stores to survive winter.

Advantage in environments with unpredictable food sources

Torpor can be a strategy of animals with unpredictable food supplies.[17] For example, high-latitude living rodents use torpor seasonally when not reproducing. These rodents use torpor as means to survive winter and live to reproduce in the next reproduction cycle when food sources are plentiful, separating periods of torpor from the reproduction period. Some animals use torpor during their reproductive cycle, as seen in unpredictable habitats.[17] They experience the cost of a prolonged reproduction period but the payoff is survival to be able to reproduce at all.[17]

The eastern long-eared bat uses torpor during winter and is able to arouse and forage during warm periods.[18]

Survival during mass extinctions

It is suggested that this daily torpor use may have allowed survival through mass extinction events.[19] Heterotherms make up only four out of 61 mammals confirmed to have gone extinct over the last 500 years.[19] Torpor enables animals to reduce energy requirements allowing them to better survive harsh conditions.

Inter-species competition

Interspecific competition occurs when two species require the same resource for energy production.[20] Torpor increases fitness in the case of inter-specific competition with the nocturnal common spiny mouse.[20] When the golden spiny mouse experiences reduced food availability by diet overlap with the common spiny mouse it spends more time in a torpid state.

Parasite resistance by bats

A drop in temperature from torpor has been shown to reduce the ability of parasites to reproduce.[21] Ectoparasites of bats in temperate zones have reduced reproductive rates when bats enter torpor. Where bats do not enter torpor the parasites reproduce at a constant rate throughout the year.

NASA deep sleep option for a mission to Mars

In 2013, SpaceWorks Engineering began researching a way to dramatically cut the cost of a human expedition to Mars by putting the crew in extended torpor for 90 to 180 days. Traveling while hibernating would reduce astronauts' metabolic functions and minimize requirements for life support during multi-year missions.[22]

gollark: +>markov 258639553357676545 2
gollark: +>markov 258639553357676545 2
gollark: +>markov 258639553357676545 2
gollark: Excellent!
gollark: +>markov 258639553357676545 2

See also

Notes

  1. Vuarin, Pauline; Dammhahn, Melanie; Kappeler, Peter M.; Henry, Pierre-Yves (2015). "When to initiate torpor use? Food availability times the transition to winter phenotype in a tropical heterotherm". Oecologia. 179 (1): 43–53. doi:10.1007/s00442-015-3328-0. PMID 25953115.
  2. Hainsworth, F.R.; Wolf, L.L. (1970). "Regulation of oxygen consumption and body temperature during torpor in a hummingbird, Eulampis jugularis". Science. 168 (3929): 368–369. doi:10.1126/science.168.3929.368. PMID 5435893.
  3. "Hummingbirds". Migratory Bird Center, Smithsonian National Zoological Park. Archived from the original on 2008-02-14.
  4. Geiser, Fritz (1994). "Hibernation and Daily Torpor in Marsupials – a Review". Australian Journal of Zoology. 42 (1): 1–16. doi:10.1071/zo9940001.
  5. Bartels, W.; Law, B.S.; Geiser, F. (1998). "Daily torpor and energetics in a tropical mammal, the northern blossom-bat Macroglossus minimus (Megachiroptera)". J. Comp. Physiol. B. 168 (3): 233–239. doi:10.1007/s003600050141. PMID 9591364.
  6. Geiser, Fritz (2004). "Metabolic Rate and Body Temperature Reduction During Hibernation and Daily Torpor". Annu. Rev. Physiol. 66 (66): 239–274. doi:10.1146/annurev.physiol.66.032102.115105. PMID 14977403.
  7. Dawson, T.J., et al. (eds.); Fauna of Australia Vol. 1b – Mammalia; 17. Morphology and Physiology of the Metatheria; pp. 102, p. 30
  8. Geiser, Fritz; Stawski, Clare; Wacker, Chris B.; Nowack, Julia (2017). "Phoenix from the Ashes: Fire, Torpor, and the Evolution of Mammalian Endothermy". Frontiers in Physiology. 8: 842. doi:10.3389/fphys.2017.00842. ISSN 1664-042X. PMC 5673639. PMID 29163191.
  9. Stawski, Clare; Geiser, Fritz (2010-01-01). "Fat and fed: frequent use of summer torpor in a subtropical bat". Naturwissenschaften. 97 (1): 29–35. doi:10.1007/s00114-009-0606-x. ISSN 0028-1042. PMID 19756460.
  10. Warnecke, Lisa; Turner, James M.; Geiser, Fritz (2008-01-01). "Torpor and basking in a small arid zone marsupial". Naturwissenschaften. 95 (1): 73–78. doi:10.1007/s00114-007-0293-4. ISSN 0028-1042. PMID 17684718.
  11. Körtner, Gerhard; Geiser, Fritz (2009). "The key to winter survival: daily torpor in a small arid-zone marsupial". Naturwissenschaften. 96 (4): 525–530. doi:10.1007/s00114-008-0492-7. PMID 19082573.
  12. Batholomew, G. (1982). "Energy Metabolism". Animal Physiology: Principles and Adaptations. Macmillan Publishing Co.
  13. Allaby, Michael (2014). A Dictionary of Zoology. Oxford University Press. p. 963. ISBN 9780199684274.
  14. Carpenter, F. Lynn; Hixon, Mark A. (May 1988). "A New Function for Torpor: Fat Conservation in a Wild Migrant Hummingbird". The Condor. 90 (2): 373–378. doi:10.2307/1368565. JSTOR 1368565.
  15. Jansen, H. T., Leise, T., Stenhouse, G., Pigeon, K., Kasworm, W., Teisberg, J., ... & Robbins, C. T. (2016). The bear circadian clock doesn’t ‘sleep’during winter dormancy. Frontiers in zoology, 13(1), 42.
  16. Chaplin, Susan Budd (1974-12-01). "Daily energetics of the Black-capped Chickadee,Parus atricapillus, in winter". Journal of Comparative Physiology. 89 (4): 321–330. doi:10.1007/BF00695350. ISSN 0340-7594.
  17. McAllan, B. M.; Geiser, Fritz (2014-09-01). "Torpor during Reproduction in Mammals and Birds: Dealing with an Energetic Conundrum". Integrative and Comparative Biology. 54 (3): 516–532. doi:10.1093/icb/icu093. ISSN 1540-7063. PMID 24973362.
  18. Stawski, Clare; Turbill, Christopher; Geiser, Fritz (2009-05-01). "Hibernation by a free-ranging subtropical bat (Nyctophilus bifax)". Journal of Comparative Physiology B. 179 (4): 433–441. doi:10.1007/s00360-008-0328-y. ISSN 0174-1578. PMID 19112568.
  19. Geiser, Fritz; Brigham, R. Mark (2012). Living in a Seasonal World. pp. 109–121. doi:10.1007/978-3-642-28678-0_10. ISBN 978-3-642-28677-3.
  20. Levy, Ofir; Dayan, Tamar; Kronfeld-Schor, Noga (2011-09-01). "Interspecific Competition and Torpor in Golden Spiny Mice: Two Sides of the Energy-Acquisition Coin". Integrative and Comparative Biology. 51 (3): 441–448. doi:10.1093/icb/icr071. ISSN 1540-7063. PMID 21719432.
  21. Lourenço, Sofia; Palmeirim, Jorge Mestre (2008-12-01). "Which factors regulate the reproduction of ectoparasites of temperate-zone cave-dwelling bats?". Parasitology Research. 104 (1): 127–34. doi:10.1007/s00436-008-1170-6. ISSN 0932-0113. PMID 18779978.
  22. Hall, Loura (19 July 2013). "Torpor Inducing Transfer Habitat For Human Stasis To Mars". NASA. Retrieved 20 March 2018.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.