Genetic diversity is essential for persistence of animal populations over both the short- and long-term. Previous studies suggest that genetic diversity may decrease with population decline due to genetic drift or inbreeding of small populations. For oscillating populations, there are some studies on the relationship between population density and genetic diversity, but these studies were based on short-term observation or in low-density phases. Evidence from rapidly expanding populations is lacking. In this study, genetic diversity of a rapidly expanding population of the Greater long-tailed hamsters during 1984–1990, in the Raoyang County of the North China Plain was studied using DNA microsatellite markers. Results show that genetic diversity was positively correlated with population density (as measured by % trap success), and the increase in population density was correlated with a decrease of genetic differentiation between the sub-population A and B. The genetic diversity tended to be higher in spring than in autumn. Variation in population density and genetic diversity are consistent between sub-population A and B. Such results suggest that dispersal is density- and season-dependent in a rapidly expanding population of the Greater long-tailed hamster. For typically solitary species, increasing population density can increase intra-specific attack, which is a driving force for dispersal. This situation is counterbalanced by decreasing population density caused by genetic drift or inbreeding as the result of small population size. Season is a major factor influencing population density and genetic diversity. Meanwhile, roads, used to be considered as geographical isolation, have less effect on genetic differentiation in a rapidly expanding population. Evidences suggest that gene flow (Nm) is positively correlated with population density, and it is significant higher in spring than that in autumn.
References
[1]
Berthier K, Galan M, Foltete JC, Charbonnel N, Cosson JF (2005) Genetic structure of the cyclic fossorial water vole (Arvicola terrestris): landscape and demographic influences. Molecular Ecology 14: 2861–2871.
[2]
Cena CJ, Morgan GE, Malette MD, Heath DD (2006) Inbreeding, outbreeding and environmental effects on genetic diversity in 46 walleye (Sander vitreus) populations. Molecular Ecology 15: 303–320.
[3]
Nielsen EE, Hansen MM, Loeschcke V (1999) Genetic variation in time and space: microsatellite analysis of extinct and extant populations of Atlantic salmon. Evolution 53: 261–268.
[4]
Hansson B, Bensch S, Hasselquist D, Lillandt BG, Wennerberg L, et al. (2000) Increase of genetic variation over time in a recently founded population of great reed warblers (Acrocephalus arundinaceus) revealed by microsatellites and DNA fingerprinting. Molecular Ecology 9: 1529–1538.
[5]
Charlesworth D, Wright SI (2001) Breeding system and genome evolution. Current Topics in Developmental Biology 11: 685–690.
[6]
C?té SD, Dallas JF, Marshall F, Langvatn R, Alson SD (2002) Microsatellite DNA evidence for genetic drift and philoparty in Svalbard reindeer. Molecular Ecology 11: 1923–1930.
[7]
Planes S, Lenfant P (2002) Temporal change in the genetic structure between and within cohorts of a marine fish, Diplodus sargus, induced by a large variance in individual reproductive success. Molecular Ecology 11: 1515–1524.
[8]
Stenson AG, Malhotra A, Thorpe RS (2002) Population differentiation and nuclear gene flow in the Dominican anole (Anolis oculatus). Molecular Ecology 11: 1679–1688.
[9]
Slatkin M (1993) Isolation by distance in equilibrium and nonequilibrium populations. Evolution 47: 264–279.
[10]
Shikano T, Chiyokubo T, Taniguchi N (2001) Temporal changes in allele frequency, genetic variation and inbreeding depression in small populations of the guppy, Poecilia reticulata. Heredity 86: 153–160.
[11]
Aspi J, Roininen E, Ruokonen M, Kojola I, Vila C (2006) Genetic diversity, population structure, effective population size and demographic history of the Finnish wolf population. Molecular Ecology 15: 1561–1576.
[12]
Estoup A, Angers B (1998) Microsatellites and minisatellites for molecular ecology: theoretical and experimental considerations. In: Advances in Molecular Ecology (ed. Carvhalo GR), 55–86. IOS Press, The Netherlands.
[13]
Dong JP, Li CH, Zhang ZB (2010) Density-dependent genetic variation in dynamic populations of the Greater long-tailed hamster (Tscherskia triton). Journal of Mammalogy 91: 200–207.
[14]
Xie J, Zhang ZB (2006) Genetic diversity decreases as population density declines: Implications of temporal variation in mitochondrial haplotype frequencies in a natural population of Tscherskia triton. Integrative Zoology 1: 188–193.
[15]
Irene K, Carlo RL (2003) Recent habitat fragmentation caused by major roads leads to reduction of gene flow and loss of genetic variability in ground beetles, Proceedings of the Royal Soceity B. 270: 417–423.
[16]
Mader HJ (1984) Animal habitat isolation by roads and agricultural fields. Biology Conservation 29: 81–96.
[17]
Magnus W, Arnd S (2001) The impact of habitat fragmentation and social structure on the population genetics of roe deer (Capreolus capreolus L.) in Central Europe. Heredity 86: 703–715.
[18]
Zhang ZB, Wang Z (1998) Ecology and Management of Rodent Pests in Agriculture Ocean Press, Beijing, China.
[19]
Xu LX, Zhang ZB, Song MJ, Cao XP, Wang FS, et al. (2002) A method of extracting genomic DNA from animal specimen preserved in formalin. Acta Zoologica Sinica 48: 264–269.
[20]
Xu LX, Song MJ, Guo Y, Kong FH, Zhang ZB (2007) The highly polymorphic microsatellite markers for the Greater long-tailed hamster (Tscherskia triton). Molecular Ecology Notes 7: 617–619.
[21]
Francis C, Yeh Yang R, Boyle T (1999) Popgene version 1.31: Microsoft window-based freeware for population genetic analysis.
[22]
Kimura M, Crow JF (1964) The number of alleles that can be maintained in a finite population. Genetics 49: 725–738.
[23]
Lewontin R (1972) The Apportionment of Human Diversity. Evolutionary Biology 6: 391–398.
[24]
Levene H (1949) On a matching problem in genetics. The Annals of Mathematical Statistics 20: 91–94.
[25]
Slatkin M, Barton NH (1989) A comparison of three indirect methods for estimating average levels of gene flow. Evolution 43: 1349–1368.
[26]
Wang YQ, Zhang ZB, Xu LX (2000) The genetic diversity of central and peripheral populations of Greater long-tailed hamster (Cricetulus triton). Chinese Science Bulletin 47: 201–206.
[27]
North A, Cornell S, Ovaskainen O (2011) Evolutionary responses of dispersal distance to landscape structure and habitat loss. Evolution 65: 1739–1751.
[28]
Nowicki P, Vrabec V (2011) Evidence for positive density-dependent emigration in butterfly metapopulations. Oecologia 167: 657–665.
[29]
P?rn H, Ringsby TH, Jensen H, S?ther BE (2011) Spatial heterogeneity in the effects of climate and density-dependence on dispersal in a house sparrow metapopulation. Proceedings of Biological Sciences 279: 144–152.
[30]
Andreassen HP, Ims RA (2001) Dispersal in patchy vole populations: role of patch configuration, density dependence, and demography. Ecology 82: 2911–2926.
[31]
Lin YTK, Batzli GO (2001) The influence of habitat quality on dispersal demography, and population dynamics of voles. Ecological Monograph 71: 241–275.
[32]
Aars J, Dallas JF, Piertney SB, Marshall F, Gow JL, et al. (2006) Widespread gene flow and high genetic variability in populations of water voles Arvicola terrestris in patchy habitats. Molecular Ecology 15: 1455–66.
[33]
Waser PM, Busch JD, McCormick CR, DeWoody JA (2006) Parentage analysis detects cryptic precapture dispersal in a philopatric rodent. Molecular Ecology 15: 1929–1937.
[34]
Hanski I (1999) Metapopulation Ecology. OxfordUniversity Press, New York.
[35]
Ims RA, Hjermann D (2001) Condition-dependent dispersal. In Dispersal: 203–216. Clobert J, Danchin E, Dhondt AA & Nichols JD (Eds). Oxford: Oxford University Press.
[36]
Ranta E, Fowler MS, Kaitala V (2008) Population synchrony in small-world networks. Proceedings of Biological Sciences 275: 435–42.
[37]
Ims RA, Andreassen HP (2005) Density-dependent dispersal and spatial population dynamics. Proceedings of Biological Sciences 272: 913–8.
[38]
Bowler DE, Benton TG (2005) Causes and consequences of animal dispersal strategies: relating individual behaviour to spatial dynamics. Biological Reviews 80: 205–225.
[39]
Clobert J, Ims RA, Rousset F (2004) Causes, mechanisms and consequences of dispersal. In: Haski I, Gaggiotti OE (eds) Ecology, genetics and evolution of metapopulations. Academic, London, 307–335.
[40]
Song MJ, Zhang ZB, Neumann K, Gattermann R (2005) Sex-biased dispersal of Greater long-tailed hamster (Tscherskia triton) revealed by microsatellites. Canadian Journal of Zoology 83: 773–779.
