On the role of phylogeny in determining activity patterns of rodents
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Abstract
Evolutionary plasticity is limited, to a certain extent, by phylogenetic constraints. We asked whether the diel activity patterns of animals reflect their phylogenies by analyzing daily activity patterns in the order Rodentia. We carried out a literature survey of activity patterns of 700 species, placing each in an activity time category: diurnal, nocturnal, or active at both periods (a-rhythmic). The proportion of rodents active at these categories in the entire order, was compared to the activity patterns of species of different families for which we had data for over ten species each: Dipodidae, Echimyidae, Geomyidae, Heteromyidae, Muridae, and Sciuridae. Activity times of rodents from different habitat types were also compared to the ordinal activity time pattern. We also calculated the probability that two random species (from a particular subgroup: family, habitat, etc.) will be active in the same period of the day and compared it to this probability with species drawn from the entire order. Activity patterns at the family level were significantly different from the ordinal pattern, emphasizing the strong relationship between intra-family taxonomic affiliation and daily activity patterns. Large families (Muridae and Sciuridae) analyzed by subfamilies and tribes showed a similar but stronger pattern than that of the family level. Thus it is clear that phylogeny constrains the evolution of activity patterns in rodents, and may limit their ability to use the time niche axis for ecological separation. Rodents living in cold habitats differed significantly from the ordinal pattern, showing more diurnal and a-rhythmic activity patterns, possibly due to physiological constraints. Ground-dwelling rodents differed significantly, showing a high tendency towards a-rhythmic activity, perhaps reflecting their specialized habitat.
Keywords
Activity patterns Habitat Phylogeny Rodents ShiftsPreview
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- Antle, MC, Silver, R 2005Orchestrating time: arrangements of the brain circadian clockTrends Neurosci28145151PubMedCrossRefGoogle Scholar
- Benton, MJ 2000Vertebrate palaeontology2Blackwell Science LtdOxford, EnglandGoogle Scholar
- Daan, S 1981Adaptive daily strategies in behaviorAschoff, J eds. Handbook of behavioral neurobiology 4: biological rhythmsPlenum pressNew York and London275298Google Scholar
- Darwin, C 1859On the origin of species by means of natural selection, or the preservation of favoured races in the struggle for lifeJohn MurrayLondonGoogle Scholar
- Day, T, Abrams, PA, Chase, JM 2002The role of size-specific predation in the evolution and diversification of prey life historiesEvolution56877887PubMedCrossRefGoogle Scholar
- Degen AA (1997) Ecophysiology of small desert mammals. In: Cloudsley-Thompson JL (ed), Springer, BerlinGoogle Scholar
- DeCoursey, PJ 2004The behavioural ecology and evolution of biological timing systemsDunlap, JCLoros, JJDeCoursey, PJ eds. Chronobiology, biological timekeepingSinauer Associates, Inc. PublishersSunderland, Massachusetts2765Google Scholar
- Goldman, BD, Goldman, SL, Riccio, AP, Terkel, J 1997Circadian patterns of locomotor activity and body temperature in blind mole-rats, Spalax ehrenbergi J Biol Rhythm12348361CrossRefGoogle Scholar
- Gould, SJ, Lewontin, RC 1979The spandrels of San Marco and the Panglossian paradigmProc R Soc Lond B Bio205581598CrossRefGoogle Scholar
- Hartenberger, JL 1998Description of the radiation of the Roentia (Mammalia) from the Late Paleocene to the Miocene; phylogenetic consequencesC R Acad Sci II A326439444Google Scholar
- Huchon, D, Madsen, O, Sibbald, MJJB, Ament, K, Stanhope, MJ, Catzeflis, F, Jong, WW, Douzery, EJP 2002Rodent phylogeny and a timescale for the evolution of Glires: evidence from an extensive taxon sampling using three nuclear genesMol Biol Evol1910531065PubMedGoogle Scholar
- Jacobs, GH 1993The distribution and nature of color vision among the mammalsBiol Rev Cambridge Philos Soc68413471PubMedCrossRefGoogle Scholar
- Kronfeld, N, Haim, A, Dayan, T, Zisapel, N, Klingenspor, M, Heldmaier, G 2000Seasonal thermogenic acclimation of diurnally and nocturnally active desert spiny micePhysiol Biochem Zool733744CrossRefGoogle Scholar
- Kronfeld-Schor, N, Dayan, T, Elvert, R, Haim, A, Zisapel, N, Heldmaier, G 2001aOn the use of the time axis for ecological separation: diel rhythms as an evolutionary constraintAm Nat158451457CrossRefGoogle Scholar
- Kronfeld-Schor, N, Dayan, T, Jones, ME, Kremer, I, Mandelik, Y, Wollberg, M, Yassur, Y, Gaton, D 2001bRetinal structure and foraging microhabitat use of the golden spiny mouseJ Mammal8210161025CrossRefGoogle Scholar
- Kronfeld-Schor, N, Dayan, T 2003Partitioning of time as an ecological resourceAnnu Rev Ecol Syst34153181CrossRefGoogle Scholar
- Lack, D 1947Darwin’s finchesCambridge University PressCambridge, EnglandGoogle Scholar
- Lawton, JH 1999Are there general laws in ecology?Oikos84177192CrossRefGoogle Scholar
- Lima, SL, Dill, LM 1990Behavioral decisions made under the risk of predation: a review and prospectusCan J Zool68619640CrossRefGoogle Scholar
- Losos, JB, Leal, M, Glor, RE, Queiroz, K, Hertz, PE, Schettino, LR, Lara, AC, Jackman, TR, Larson, A 2003Niche lability in the evolution of a Caribbean lizard communityNature424542545PubMedCrossRefGoogle Scholar
- Morris, D 1965The mammals, a guide to living speciesHodder and StoughtonGreat BritainGoogle Scholar
- Nowak, RM 1999Walker's Mammals of the World6John Hopkins University PressBaltimore, MarylandGoogle Scholar
- Oster, H, Avivi, A, Joel, A 2002A switch from diurnal to nocturnal activity in S. ehrenbergi is accompanied by an uncoupling of light input and the circadian clockCurr Biol1219191922PubMedCrossRefGoogle Scholar
- Pianka, ER, Vitt, LJ 2003LizardsUniversity of California PressBerkeley and Los Angeles, CaliforniaGoogle Scholar
- Riccio, AP, Goldman, BU 2000Circadian rhythms of locomotor activity in naked-mole-rats (Heterocephalus glaber)Physiol Behav71113PubMedCrossRefGoogle Scholar
- Richards, SA 2002Temporal partitioning and aggression among foragers; modelling the effects of stochasticity and individual stateBehav Ecol13427438CrossRefGoogle Scholar
- Saper, CB, Scammell, TE, Lu, J 2005Hypothalamic regulation of sleep and circadian rhythmsNature43712571263PubMedCrossRefGoogle Scholar
- Saper, CB, Lu, J, Chou, TC, Gooley, J 2005The hypothalamic integrator for circadian rhythmsTrends Neurosci28142157CrossRefGoogle Scholar
- Schoener, TW 1974aResource partitioning in ecological communitiesScience1852738CrossRefGoogle Scholar
- Schoener, TW 1974bThe compression hypothesis and temporal resource partitioningProc Natl Acad Sci USA7141694172CrossRefGoogle Scholar
- Simberloff, D 2004Community ecology: is it time to move on?Am Nat163787799PubMedCrossRefGoogle Scholar
- Smale, L, Lee, T, Nunez, AA 2003Mammalian diurnality: some facts and gapsJ Biol Rhythm18356366CrossRefGoogle Scholar
- Tattersall, I 1988Cathemeral activity in primates: a definitionFolia Primatol49200202CrossRefGoogle Scholar
- Webb, CO, Ackerly, DD, McPeek, MA, Donoghue, MJ 2002Phylogenies and community ecologyAnnu Rev Ecol Syst33475505CrossRefGoogle Scholar
- Weinstein M (2003) Spiny arthropods, spiny parasites and spiny mice—availability and ecology in En Gedi. M.Sc. dissertation, Tel Aviv University, Israel (in Hebrew)Google Scholar
- Weins, JA, Addicot, JF, Case, TJ, Diamond, J 1986Overview: the importance of spatial and temporal scale in ecological investigationDiamond, JCase, TJ eds. Community ecologyHarper and RowNew York145153Google Scholar
- Willmer, P, Stone, G, Johnston, I 2000Environmental physiology of animalsBlackwell Science LtdParis, FranceGoogle Scholar
- Wilson, DE, Reeder, DM 1993Mammal species of the world2Smithsonian Institution PressWashington DCGoogle Scholar
- Young, KV, Brodie, ED,Jr, Brodie, ED 2005How the horned lizard got its hornsScience30465CrossRefGoogle Scholar