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17 - Possible causes and consequences of different hibernation patterns in Cheirogaleus species – Mitovy fatsy sahala

from Part III - Cheirogaleidae: behavior and ecology

Published online by Cambridge University Press:  05 March 2016

By
Kathrin H. Dausmann  and
Marina B. Blanco
Edited by
Shawn M. Lehman ,
Ute Radespiel  and
Elke Zimmermann
Kathrin H. Dausmann
Affiliation:
University of Hamburg, Germany
Marina B. Blanco
Affiliation:
Duke Lemur Center, USA
Shawn M. Lehman
Affiliation:
University of Toronto
Ute Radespiel
Affiliation:
University of Veterinary Medicine Hannover, Foundation
Elke Zimmermann
Affiliation:
University of Veterinary Medicine Hannover, Foundation
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Summary

Heterothermy in lemurs – flexibility is key

All dwarf lemurs (Cheirogaleus) of Madagascar are obligate hibernators in their natural environments (Petter, 1962, 1978; Petter et al., 1977; Hladik et al., 1980; Petter-Rousseaux et al., 1980; Wright and Martin, 1995; Dausmann, 2008, 2014). Hibernation is an actively suppressed metabolic state of endothermic species to overcome predictable, usually seasonal, metabolic energy and water crises. It is typified by dramatically reduced bodily functions and expressed by lowered metabolic rates and core body temperature (Tb), prolonged pauses between breaths, and lowered heart rates (Carey et al., 2003; Geiser, 2004; Heldmaier et al., 2004). This strategy is especially advantageous for small species, due to the allometric relationship between metabolism and body size (higher mass-specific metabolic rates and greater heat losses over their relatively larger surface areas; Heldmaier et al., 2004; White and Seymour, 2005). The energy needed to sustain vital functions during hibernation is stored as fat deposits or food caches at the end of the active season. Although the ultimate aim – decreasing energy and water demands drastically by using hibernation to survive the harsh conditions of the Malagasy winter – is the same for all Cheirogaleus species, proximate modi operandi differ notably between species inhabiting different habitats.

Biomes in Madagascar can roughly be divided between western dry forests and eastern rainforests (Dufils, 2003). Degree of seasonality (i.e., changes in occurrence and intensity of rainfall, and variation in ambient temperature, Ta) and resource predictability differ markedly between these two regions due to a combination of geographic history (mountains as physical barriers running north to south along central Madagascar), wind systems, and oceanic currents (Donque, 1972; Dufils, 2003; Jury, 2003). In addition, altitudinal gradients also influence environmental conditions and are important in explaining geographic distributions of certain taxa (Raxworthy and Nussbaum, 1994). These differences in environmental conditions not only shape Malagasy taxonomy, but also influence species’ physiological processes.

In lemurs, heterothermy has so far only been confirmed in the Cheirogaleidae, a family of rather small, omnivorous, night-active species. Within this family, individuals have proven flexible in regard to their use and patterns of heterothermy, even within populations inhabiting the same forest areas, or within individuals between different years, depending on environmental seasonality (mainly changes in temperature and precipitation), unpredictability of environmental factors, and individual body condition (Dausmann, 2008, 2014).

Type
Chapter
Information
The Dwarf and Mouse Lemurs of Madagascar
Biology, Behavior and Conservation Biogeography of the Cheirogaleidae
 , pp. 335 - 350
Publisher: Cambridge University Press
Print publication year: 2016

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References

Arnold, W, Heldmaier, G, Ortmann, S, et al. 1991. Ambient temperatures in hibernacula and their energetic consequences for alpine marmots (Marmota marmota). Journal of Thermal Biology 16:223–226.CrossRefGoogle Scholar
Barnes, BM. 1989. Freeze avoidance in a mammal: body temperatures below 0 degrees C in an Arctic hibernator. Science 244:1593–1595.Google Scholar
Blanco, MB, Godfrey, LR. 2014. Hibernation patterns of dwarf lemurs in the high altitude forest of eastern Madagascar. In Grow, NB, Gursky-Doyen, S, Krzton, A (eds.), High Altitude Primates. Developments in Primatology: Progress and Prospects (pp. 23–42). Springer, New York.
Blanco, MB, Rahalinarivo, V. 2010. First direct evidence of hibernation in an eastern dwarf lemur species (Cheirogaleus crossleyi) from the high-altitude forest of Tsinjoarivo, central-eastern Madagascar. Naturwissenschaften 97:945–950.CrossRefGoogle Scholar
Blanco, MB, Godfrey, LR, Rakotondratsima, M, et al. 2009. Discovery of sympatric Cheirogaleus species in the high-altitude rainforest of Tsinjoarivo, eastern central Madagascar: implications for biogeography and conservation. Folia Primatologica 80:1–17.CrossRefGoogle Scholar
Blanco, MB, Dausmann, KH, Ranaivoarisoa, JF, Yoder, AD. 2013. Underground hibernation in a primate. Scientific Reports 3: doi10.1038/srep01768.Google Scholar
Carey, HV, Andrews, MT, Martin, SL. 2003. Mammalian hibernation: cellular and molecular responses to depressed metabolism and low temperature. Physiological Reviews 83:1153–1181.CrossRefGoogle Scholar
Dausmann, KH. 2005. Measuring body temperature in the field – evaluation of external vs. implanted transmitters in a small mammal. Journal of Thermal Biology 30:195–202.Google Scholar
Dausmann, KH. 2008. Hypometabolism in primates: torpor and hibernation. In Lovegrove, BG, McKechnie, AE (eds.), Hypometabolism in Animals: Torpor, Hibernation and Cryobiology (pp. 327–336). University of KwaZulu-Natal, Pietermaritzburg.
Dausmann, KH. 2013. Spoilt for choice: selection of hibernacula by Cheirogaleus medius. In Masters, J, Gamba, M, Génin, F (eds.), Leaping Ahead: Advances in Prosimian Biology (pp. 205–214). Springer, New York.
Dausmann, KH. 2014. Flexible patterns in energy savings: heterothermy in primates. Journal of Zoology 292:101–111.Google Scholar
Dausmann, KH, Glos, J. 2015. No energetic benefits from sociality in tropical hibernation. Functional Ecology 29:498–505.CrossRefGoogle Scholar
Dausmann, KH, Glos, J, Ganzhorn, JU, Heldmaier, G. 2004. Hibernation in a tropical primate. Nature 429:825–826.CrossRefGoogle Scholar
Dausmann, KH, Glos, J, Ganzhorn, JU, Heldmaier, G. 2005. Hibernation in the tropics: lessons from a primate. Journal of Comparative Physiology B Biochemical Systemic and Environmental Physiology 175:147–155.CrossRefGoogle Scholar
Dausmann, KH, Glos, J, Heldmaier, G. 2009. Energetics of tropical hibernation. Journal of Comparative Physiology B Biochemical Systemic and Environmental Physiology 179:345–357.CrossRefGoogle Scholar
Dausmann, KH, Nowack, J, Kobbe, S. 2012. Afrotropical heterothermy: a continuum of possibilities. In Ruf, T, Bieber, C, Arnold, W, Millesi, E (eds.), Living in a Seasonal World: Thermoregulatory and Metabolic Adaptations (pp. 13–27). Springer, Berlin.
Donque, G. 1972. The climatology of Madagascar. In Battistini, R, Richard-Vindard, G (eds.), Biogeography and Ecology in Madagascar (pp. 87–144). Springer, Dordrecht.
Dufils, J-M. 2003. Forest ecology. In Goodman, SM, Benstead, JP (eds.), The Natural History of Madagascar (pp. 88–96). The University of Chicago Press, Chicago.
Fietz, J. 1999. Monogamy as a rule rather than exception in nocturnal lemurs: the case of the fat-tailed dwarf lemur, Cheirogaleus medius. Ethology 105:255–272.CrossRefGoogle Scholar
Fietz, J, Dausmann, KH. 2006. Big is beautiful – fat storage and hibernation as a strategy to cope with marked seasonality in the fat-tailed dwarf lemur (Cheirogaleus medius). In Gould, L, Sauther, ML (eds.), Lemurs: Ecology and Adaptation (pp. 97–111). Springer, Berlin.
Fietz, J, Ganzhorn, JU. 1999. Feeding ecology of the hibernating primate Cheirogaleus medius: how does it get so fat?Oecologia 121:157–164.Google Scholar
Geiser, F. 2004. Metabolic rate and body temperature reduction during hibernation and daily torpor. Annual Review of Physiology 66:239–274.CrossRefGoogle Scholar
Groeneveld, LF, Blanco, MB, Raharison, J-L, et al. 2010. MtDNA and nDNA corroborate existence of sympatric dwarf lemur species at Tsinjoarivo, eastern Madagascar. Molecular Phylogenetics and Evolution 55(3):833–845.Google Scholar
Heldmaier, G, Ruf, T. 1992. Body temperature and metabolic rate during natural hypothermia in endotherms. Journal of Comparative Physiology B Biochemical Systemic and Environmental Physiology 162:696.Google Scholar
Heldmaier, G, Ortmann, S, Elvert, R. 2004. Natural hypometabolism during hibernation and daily torpor in mammals. Respiratory Physiology & Neurobiology 141:317–329.CrossRefGoogle Scholar
Hladik, CM, Charles-Dominique, P, Petter, JJ. 1980. Feeding strategies of five nocturnal prosimians in the dry forest of the west coast of Madagascar. In Hladik, CM, Charles-Dominique, P, Petter, JJ, et al. (eds.), Nocturnal Malagasy Primates: Ecology, Physiology, and Behavior (pp. 41–73). Academic Press, New York.
Humphries, MM, Kramer, DL, Thomas, DW. 2003. The role of energy availability in mammalian hibernation: an experimental test in free-ranging eastern chipmunks. Physiological and Biochemical Zoology 76:180–186.CrossRefGoogle Scholar
Jury, MR. 2003 Climate. In Goodman, SM, Benstead, JP (eds.), The Natural History of Madagascar (pp. 75–87). The University of Chicago Press, Chicago.
Kappeler, PM. 2000. Lemur origins: Rafting by groups of hibernators?Folia Primatologica 71:422–425.Google Scholar
Kobbe, S, Dausmann, KH. 2009. Hibernation in Malagasy mouse lemurs as a strategy to counter environmental challenge. Naturwissenschaften 96:1221–1227.Google Scholar
Kobbe, S, Ganzhorn, JU, Dausmann, KH. 2011. Extreme individual flexibility of heterothermy in free-ranging Malagasy mouse lemurs (Microcebus griseorufus). Journal of Comparative Physiology B Biochemical Systemic and Environmental Physiology 181:165–173.Google Scholar
Lahann, P. 2007. Biology of Cheirogaleus major in a littoral rain forest in southeast Madagascar. International Journal of Primatology 28:895–905.CrossRefGoogle Scholar
Lahann, P, Dausmann, KH. 2011. Live fast, die young: flexibility of life history traits in the fat-tailed dwarf lemur (Cheirogaleus medius). Behavioral Ecology and Sociobiology 65:381–390.CrossRefGoogle Scholar
Masters, JC, Lovegrove, BG, Wit, MJ de. 2007. Eyes wide shut: can hypometabolism really explain the primate colonization of Madagascar?Journal of Biogeography 34:21–37.Google Scholar
Nowack, J, Dausmann, KH. 2015. Can heterothermy help the colonization of new habitats?Mammalian Review 45:117–127.Google Scholar
Petter, JJ. 1962. Recherches sur l'écologie et l'éthologie des Lémuriens malagaches. Mémoires du Muséum National d'Histoire Naturelle, Sér A, Zoologie, Paris XXVII:1–146.Google Scholar
Petter, JJ. 1978. Ecological and physiological adaptations of five sympatric nocturnal lemurs to seasonal variations in food production. In Chivers, DJ, Herbert, J (eds.), Recent Advances in Primatology (pp. 211–223). Academic Press, New York.
Petter, JJ, Albignac, R, Rumpler, Y. 1977. Mammifères Lémuriens (Primates Prosimiens). Faune de Madagascar 44. ORSTOM-CNRS, Paris.Google Scholar
Petter-Rousseaux, A, Charles-Dominique, P, Cooper, HM, et al. 1980. Seasonal activity rhythms, reproduction, and body weight variations in five sympatric nocturnal prosimians, in simulated light and climatic conditions. In Nocturnal Malagasy Primates: Ecology, Physiology, and Behavior. Academic Press, New York.
Raxworthy, CJ, Nussbaum, RA. 1994. A rainforest survey of amphibians, reptiles and small mammals at Montagne d'Ambre, Madagascar. Biological Conservation 69:65–73.Google Scholar
Schmid, J. 1999. Sex-specific differences in activity patterns and fattening in the gray mouse lemur (Microcebus murinus) in Madagascar. Journal of Mammalogy 80:749–757.Google Scholar
Schmid, J, Ganzhorn, JU. 2009. Optional strategies for reduced metabolism in gray mouse lemurs. Naturwissenschaften 96:737–741.Google Scholar
Thiele, D, Razafimahatratra, E, Hapke, A. 2013. Discrepant partitioning of genetic diversity in mouse lemurs and dwarf lemurs – biological reality or taxonomic bias?Molecular Phylogenetics and Evolution 69:593–609.Google Scholar
Tøien, O, Blake, J, Edgar, DM, et al. 2011. Hibernation in black bears: Independence of metabolic suppression from body temperature. Science 331:906–909.Google Scholar
Wang, LCH (ed.) 1989. Ecological, physiological, and biochemical aspects of torpor in mammals and birds. In Advances in Comparative and Environmental Physiology. Springer, Berlin.
White, CR, Seymour, RS. 2005. Allometric scaling of mammalian metabolism. Journal of Experimental Biology 208:1611–1619.CrossRefGoogle Scholar
Willis, JS. 1982. The mystery of the periodic arousal. In Lyman, CP, Willis, JS, Malan, A, Wang, L (eds.), Hibernation and Torpor in Mammals and Birds (pp. 92–103). Academic Press, New York.
Wilmé, L, Goodman, SM, Ganzhorn, JU. 2006. Biogeographic evolution of Madagascar's microendemic biota. Science 312:1063–1065.Google Scholar
Wright, PC, Martin, LB. 1995. Predation, pollination and torpor in two nocturnal prosimians: Cheirogaleus major and Microcebus rufus in the rain forest of Madagascar. In Alterman, L, Doyle, GA, Izard, MK (eds.), Creatures of the Dark: The Nocturnal Prosimians (pp. 45–60). Plenum Press, New York.

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