The physiology of phyletic dwarfi sm in Cheirogaleidae

doi:10.1017/CBO9781139871822.017

16 - The physiology of phyletic dwarfi sm in Cheirogaleidae

from Part III - Cheirogaleidae: behavior and ecology

Published online by Cambridge University Press: 05 March 2016

Fabien Génin and

Edited by

Ute Radespiel and

Fabien Génin: Affiliation:
University of Fort Hare, South Africa
Judith C. Masters: Affiliation:
University of Fort Hare, South Africa
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

Introduction

Hill's (1953, p. 28) multivolume monograph, Primates: Comparative Anatomy and Taxonomy, presented a phylogenetic tree of living primates in which cheirogaleids occupied a position at the base of the Malagasy “lemuroid” radiation, 40–45 Ma if the time scale is read literally. Some years later, Charles-Dominique and Martin (1970) sought to provide evidence to support this view of cheirogaleid archaism. They pooled their expert knowledge of dwarf galagos and mouse lemurs to derive an extensive list of characters shared by the smallest representatives of the Afro-Asian and Malagasy strepsirrhine lineages, which they then interpreted as plesiomorphic retentions from the common strepsirrhine ancestor. The list included small size, nocturnal habit, occupation of a “fine branch and creeper” microhabitat, omnivorous but partly insectivorous diet, use of woven, globular nests and oral transport for the protection of altricial infants, and a “noyau” social system mediated largely by urine washing and other scent marking behaviours. Cartmill (1974) elaborated his model of the adaptive origins of the primate clade and its diagnostic characters (forward-facing and convergent orbits; grasping hands and feet; claws transformed into nails) from a similar scenario. In Cartmill's view, the primate ancestor was primarily a predator of flying insects, anchoring itself to a branch with its grasping feet, and launching its body with grasping hands outstretched to capture passing prey, its manual dexterity guided by its forward-facing eyes and consequent stereoscopic vision. The scenario found ready acceptance among many primate evolutionary biologists, and other evidence in its support was rapidly adduced. Mouse lemurs, with their large numbers of small acrocentric chromosomes (2n = 66), were perfect ancestors for a model of karyotypic evolution that favoured Robertsonian fusions (Dutrillaux, 1979). Small fossil teeth from Eocene and Oligocene sediments were declared to resemble those of cheirogaleids (Marivaux et al., 2001; Godinot, 2006). Models of the evolution of primate sociality were grounded in cheirogaleid (especially Microcebus) social systems (Kappeler, 1998).

Cheirogaleids have an additional feature, unique among primates, to recommend them as model ancestors: they use energy-saving strategies similar to those of other small mammals like rodents and insectivores. Cheirogaleids accumulate fat stores which they draw on in periods of food scarcity. This energetic facility offered an appealing resolution to the conundrum of early primate biogeography. Primates are currently distributed on various landmasses which are separated by substantial tracts of ocean.

Type: Chapter
Information: The Dwarf and Mouse Lemurs of Madagascar
Biology, Behavior and Conservation Biogeography of the Cheirogaleidae
, pp. 317 - 334

DOI: https://doi.org/10.1017/CBO9781139871822.017 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2016

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References

Aslam, H, Schneiders, A, Perret, M, Weinbauer, GF, Hodges, JK. 2002. Quantitative assessment of testicular germ cell production and kinematic and morphological parameters of ejaculated spermatozoa in the grey mouse lemur, Microcebus murinus. Reproduction 123:323–332.Google Scholar

Bakker, J, Kelliher, KR, Baum, MJ. 2001. Mating induces gonadotropin-releasing hormone neuronal activation in anosmic female ferrets. Biology of Reproduction 64:1100–1105.Google Scholar

Bartness, TJ. 1996. Photoperiod, sex, gonadal steroids, and housing density affect body fat in hamsters. Physiology and Behavior 60:517–529.Google Scholar

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.Google Scholar

Bobe, R. 2006. The evolution of arid ecosystems in eastern Africa. Journal of Arid Environments 66:564–584.Google Scholar

Brown, JH, Marquet, PA, Taper, ML. 1993. Evolution of body size: consequences of an energetic definition of fitness. The American Naturalist 142(4):573–584.Google Scholar

Canale, CI, Perret, M, Théry, HP. 2010. Physiological flexibility and acclimation to food shortage in a heterothermic primate. Journal of Experimental Biology 214:551–560.Google Scholar

Carlquist, S. 1974. Island Biology. Columbia University Press, New York.

Cartmill, M. 1974. Rethinking primate origins. Science 184: 436–443.Google Scholar

Charles-Dominique, P, Martin, RD. 1970. Evolution of lemurs and lorises. Nature 227:257–260.Google Scholar

Chatterjee, HJ, Ho, SYW, Barnes, I, Groves, C. 2009. Estimating the phylogeny and divergence times of primates using a supermatrix approach. BMC Evolutionary Biology 9:259 doi: 10.1186/1471-2148-9-259.Google Scholar

Daniels, HL. 1984. Oxygen consumption in Lemur fulvus: deviation from the ideal model. Journal of Mammalogy 65:584–592.Google Scholar

Dausmann, KH, Glos, J, Ganzhorn, JU, Heldmaier, G. 2004. Hibernation in a tropical primate. Nature 429:825–826.Google Scholar

Dewar, RE, Richard, AF. 2007. Evolution in the hypervariable environment of Madagascar. Proceedings of the National Academy of Sciences of the United States of America 104:13723–13727.Google Scholar

Dröscher, I, Kappeler, PM. 2013. Defining the low end of primate social complexity: the social organization of the nocturnal white-footed sportive lemur (Lepilemur leucopus). International Journal of Primatology doi: 10.1007/s10764-013-9735-3.Google Scholar

Dutrillaux, B. 1979. Chromosomal evolution in primates: tentative phylogeny from Microcebus murinus (prosimian) to man. Human Genetics 48:251–314.Google Scholar

Eberle, M, Perret, M, Kappeler, PM. 2007. Sperm competition and optimal timing of matings in Microcebus murinus. International Journal of Primatology 28:1267–1278.Google Scholar

Fabre, P-H, Rodrigues, A, Douzery, EJP. 2009. Patterns of macroevolution among Primates inferred from a supermatrix of mitochondrial and nuclear DNA. Molecular Phylogenetics and Evolution 53:808–825.Google Scholar

Fedorov, AV, Brierley, CM, Emanuel, K. 2010. Tropical cyclones and permanent El Niño in the early Pliocene epoch. Nature 463:1066–1070.Google Scholar

Geiser, F, Ruf, T. 1995. Hibernation versus daily torpor in mammals and birds: physiological variables and classification of torpor patterns. Physiological Zoology 68:935–966.Google Scholar

Génin, F. 2007. Energy-dependent plasticity of grey mouse lemur social systems: lessons from field and captive studies. Revue d'Écologie (La Terre et la Vie) 62:245–256.Google Scholar

Génin, F. 2008. Life in unpredictable environments: first investigation of the natural history of Microcebus griseorufus. International Journal of Primatology 29:303–321.Google Scholar

Génin, F. 2013. Venus in fur: female power in mouse lemurs Microcebus murinus and M. griseorufus. In Masters, JC, Gamba, M, Génin, F (eds.), Leaping Ahead: Advances in Prosimian Biology (pp. 121–126). Springer, New York.

Génin, F, Masters, JC. 2011. Le mythe du microcèbe primitif. Revue de Primatologie 3:1–17.Google Scholar

Génin, F, Perret, M. 2000. Photoperiod-induced changes in energy balance in gray mouse lemurs. Physiology and Behavior 71:315–321.Google Scholar

Génin, F, Perret, M. 2003. Daily hypothermia in captive grey mouse lemurs (Microcebus murinus): effects of photoperiod and food restriction. Comparative Biochemistry and Physiology B 136:71–81.Google Scholar

Génin, F, Nibbelink, M, Galand, M, Perret, M, Ambid, L. 2003a. Brown fat and nonshivering thermogenesis in the gray mouse lemur (Microcebus murinus). American of Journal of Physiology 284:R811–R818.Google Scholar

Génin, F, Schilling, A, Claustrat, B. 2003b. Melatonin and methimazole mimic short day-induced fattening in gray mouse lemurs. Physiology and Behavior 79:553–559.Google Scholar

Génin, F, Schilling, A, Perret, M. 2005. Social inhibition on seasonal fattening in wild and captive grey mouse lemurs. Physiology and Behavior 86:185–194.Google Scholar

Génin, F, Masters, JC, Ganzhorn, JU. 2010. Gummivory in cheirogaleids: primitive retention or adaptation to hypervariable environments? In Burrows, AM, Nash, LT (eds.), The Evolution of Exudativory in Primates. Developments in Primatology: Progress and Prospects (pp. 123–140). Springer, New York.

Genoud, M, Martin, RD, Glaser, D. 1997. Rate of metabolism in the smallest simian primate, the pygmy marmoset (Cebuella pygmaea). American Journal of Primatology 41:229–245.Google Scholar

Godfrey, LR, Jungers, WL, Reed, KE, Simons, EL, Chatrath, PS. 1997. Subfossil lemurs. In Goodman, SM, Patterson, BD (eds.), Natural Change and Human Impact in Madagascar (pp. 218–256). Smithsonian Institution Press, Washington, DC.

Godinot, M. 2006. Lemuriform origins as viewed from the fossil record. Folia Primatologica 77:446–464.Google Scholar

Gould, SJ. 1977. Ontogeny and Phylogeny. Belknap Press, Cambridge, MA.

Grow, NB, Wirdateti, Nekaris KAI. 2015. Does toxic defence in Nycticebus spp. relate to ectoparasites? The lethal effects of slow loris venom on arthropods. Toxicon 95:1–5.Google Scholar

Harcourt, AH. 2008. Are lemurs' low basal metabolic rates an adaptation to Madagascar's unpredictable climate?Primates 49:292–294.Google Scholar

Hildwein, G, Goffart, M. 1975. Standard metabolism and thermoregulation in a prosimian Perodicticus potto. Comparative Biochemistry and Physiology A 50:201–213.Google Scholar

Hill, WCO. 1953. Primates: Comparative Anatomy and Taxonomy. I – Strepsirhini. Edinburgh University Press, Edinburgh.

Hladik, CM, Charles-Dominique, P, Valdebouze, P, Delort-Laval, J, Flanzy, J. 1971. La caecotrophie chez un Primate phyllophage du genre Lepilemur et les corrélations avec les particularités de son appareil digestif. Compte Rendus de l'Académie des Sciences de Paris 272:3191–3194.Google 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 Charles-Dominique, P, Cooper, HM, Hladik, A, et al. (eds.), Nocturnal Malagasy Primates: Ecology, Physiology, and Behavior (pp. 41–73). Academic Press, New York.

Horvath, JE, Weisrock, DW, Embry, SL, et al. 2008. Development and application of a phylogenomic toolkit: resolving the evolutionary history of Madagascar's lemurs. Genome Research 18: 489–499.Google Scholar

Hrdy, SB. 1977. The Langurs of Abu: Female and Male Strategies of Reproduction. Harvard University Press, Cambridge, MA.

Huchard, E, Canale, CI, Gros, C Le, et al. 2011. Convenience polyandry or convenience polygyny? Costly sex under female control in a promiscuous primate. Proceedings of the Royal Society B 279:1371–1379.Google Scholar

Jolly, A. 1984. The puzzle of female feeding priority. In Small, M (ed.), Female Primates: Studies by Women Primatologists (pp. 197–216). Alan R Liss, New York.

Kappeler, PM. 1998. Nests, tree holes, and the evolution of primate life histories. American Journal of Primatology 46:7–33.Google Scholar

Kappeler, PM. 2000. Lemur origins: rafting by groups of hibernators?Folia Primatologica 71:422–425.Google Scholar

Kayser, C. 1962. The Physiology of Natural Hibernation. Pergamon Press, New York.

Körtner, G, Geiser, F. 2000. Torpor and activity patterns in free-ranging sugar gliders Petaurus breviceps (Marsupiala). Oecologia 123:350–357.Google Scholar

Lomolino, MV. 1985. Body size of mammals on islands: the Island Rule reexamined. The American Naturalist 125:310–316.Google Scholar

Lomolino, MV. 2005. Body size evolution in insular vertebrates: generality of the island rule. Journal of Biogeography 32:1683–1699.Google Scholar

Lovegrove, BG. 2001. The evolution of body armor in mammals: plantigrade constraints of large body size. Evolution 55:1464–1473.Google Scholar

Lovegrove, BG 2004. Locomotor mode, maximum running speed and basal metabolic rate in placental mammals. Physiology and Biochemical Zoology 77:916–928.Google Scholar

Lovegrove, BG 2012. The evolution of endothermy in Cenozoic mammals: a plesiomorphic–apomorphic continuum. Biological Reviews 87(1):128–162.Google Scholar

Lovegrove, BG, Génin, F. 2007. Torpor and hibernation in a basal placental mammal, the lesser hedgehog tenrec Echinops telfairi. Journal of Comparative Physiology B 178:691–698.Google Scholar

Marivaux, L, Welcomme, J-L, Antoine, P-O, et al. 2001. A fossil lemur from the Oligocene of Pakistan. Science 294:587–591.Google Scholar

Martin, RD. 1972. Adaptive radiation and behaviour of the Malagasy lemurs. Philosophical Transactions of the Royal Society of London B 264:295–352.Google 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

Masters, JC, Silvestro, D, Génin, F, DelPero, M. 2013. Seeing the wood through the trees: the current state of higher systematics in the Strepsirhini. Folia Primatologica 84:201–219.Google Scholar

Masters, JC, Génin, F, Silvestro, D, Lister, A, DelPero, M. 2014. The red island and the seven dwarfs: body size reduction in Cheirogaleidae. Journal of Biogeography 41:1833–1847.Google Scholar

McCormick, SA. 1980. Oxygen consumption and torpor in the fat-tailed dwarf lemur (Cheirogaleus medius): rethinking prosimian metabolism. Comparative Biochemistry and Physiology A 68:605–610.Google Scholar

McNab, BK. 1986. The influence of food habits on the energetics of eutherian mammals. Ecological Monographs 56:1–19.Google Scholar

McNab, BK. 2002. The Physiological Ecology of Vertebrates. A View from Energetics. Cornell University Press, Ithaca.

Müller, EF. 1979. Energy metabolism, thermoregulation and water budget in the slow loris (Nycticebus coucang, Boddaert 1785). Comparative Biochemistry and Physiology A 64:109–119.Google Scholar

Müller, EF, Jaksche, H. 1980. Thermoregulation, oxygen consumption, heart rate and evaporative water loss in the thick-tailed bushbaby (Galago crassicaudatus, Geoffroy, 1812). Zeitschrift für Säugetierkunde 45:269–278.Google Scholar

Nicholls, DG, Locke, RM. 1984. Thermogenic mechanisms in brown fat. Physiological Reviews 64:1–64.Google Scholar

Perelman, P, Johnson, WE, Roos, C, et al. 2011. A molecular phylogeny of living primates. PLoS Genetics 7:e11342.Google Scholar

Perret, M, Aujard, F. 2001. Regulation by photoperiod of seasonal changes in body mass and reproductive function in gray mouse lemurs (Microcebus murinus): differential responses by sex. International Journal of Primatology 22:5–24.Google Scholar

Petry, VH, Riehl, I, Zucker, H. 1986. Energieumsatzmessungen an weissbüscheläffchen (Callithrix jacchus). Journal of Animal Physiology and Animal Nutrition 55:214–224.Google Scholar

Richard, AF, Nicoll, ME. 1987. Female social dominance and basal metabolism in a Malagasy primate, Propithecus verreauxi. American Journal of Primatology 12:309–314.Google Scholar

Roos, C, Schmitz, J, Zischler, H. 2004. Primate jumping genes elucidate strepsirrhine phylogeny. Proceedings of the National Academy of Sciences of the United States of America 101:10650–10654.Google Scholar

Rothwell, NJ, Stock, MJ. 1985. Thermogenic capacity and brown adipose tissue activity in the common marmoset. Comparative Biochemistry and Physiology A 81:683–686.Google Scholar

Schmid, J. 2000. Daily torpor in the gray mouse lemur (Microcebus murinus) in Madagascar: energetic consequences and biological significance. Oecologia 123:175–183.Google Scholar

Schmid, J, Kappeler, PM. 1998. Fluctuating sexual dimorphism and differential hibernation by sex in a primate, the grey mouse lemur (Microcebus murinus). Behavioral Ecology and Sociobiology 43:125–132.Google Scholar

Schmid, J, Ruf, T, Heldmaier, G. 2000. Metabolism and temperature regulation during daily torpor in the smallest primate, the pygmy mouse lemur (Microcebus myoxinus) in Madagascar. Journal of Comparative Physiology B 170:59–68.Google Scholar

Schülke, O. 2005. Evolution of pair-living in Phaner furcifer. International Journal of Primatology 26:903–919.Google Scholar

Simmen, B, Bayart, F, Rasamimanana, H, Zahariev, A, Blanc, S, Pasquet, P. 2010. Total energy expenditure and body composition in two free-living sympatric lemurs. PloS ONE 5:e9860 doi: 10.1371/journal.pone.0009860.Google Scholar

Springer, MS, Meredith, RW, Gatesy, J, et al. 2012. Macroevolutionary dynamics and historical biogeography of primate diversification inferred from a species supermatrix. PLoS ONE 7:e49521.Google Scholar

Thompson, SD, Power, ML, Rutledge, CE, Kleiman, DG. 1994. Energy metabolism and thermoregulation in the golden lion tamarin (Leontopithecus rosalia). Folia Primatologica 63:131–143.Google Scholar

Tilden, DC, Oftedal, OT. 1995. The bioenergetics of reproduction in prosimian primates: is it related to female dominance? In Alterman, L, Doyle, GA, Izard, MK (eds.), Creatures of the Dark: The Nocturnal Prosimians (pp. 119–131). Plenum Publishing Corporation, New York.

Loan, M Van, Mayclin, P. 1987. A new TOBEC instrument and procedure for the assessment of body composition: use of the Fourier coefficients to predict lean body mass and total body water. American Journal of Clinical Nutrition 45:131–137.Google Scholar

Wallace, AR. 1892. Island Life. Macmillan and Co., London.

Weston, EM, Lister, AM. 2009. Insular dwarfism in hippos and a model for brain size reduction in Homo floresiensis. Nature 459:85–88.Google Scholar

Whittaker, RJ, Fernández-Palacios, JM. 2007. Island Biogeography: Ecology, Evolution, and Conservation, 2nd edition. Oxford University Press, Oxford.

Wright, PC. 1999. Lemur traits and Madagascar ecology: coping with an island environment. Yearbook of Physical Anthropology 42:31–72.Google Scholar

Wright, PC, Martin, LB. 1995. Predation, pollination and torpor in two nocturnal prosimians: Cheirogaleus major and Microcebus rufus in the rainforest of Madagascar. In Alterman, L, Doyle, GA, Izard, MK (eds.), Creatures of the Dark: The Nocturnal Prosimians (pp. 45–60). Plenum Press, New York.

Yoder, AD. 1996. The use of phylogeny for reconstructing lemuriform biogeography. In Lourenço, WR (ed.), Biogéographie de Madagascar (pp. 245–258). Editions de l'ORSTOM, Paris.

Young, AL, Richard, AF, Aiello, LC. 1990. Female dominance and maternal investment in strepsirrhine primates. The American Naturalist 135:473–488.Google Scholar

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