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PLOS ONE 2012

Low Rate of Between-Population Seed Dispersal Restricts Genetic Connectivity and Metapopulation Dynamics in a Clonal Shrub

DOI: 10.1371/journal.pone.0050974

Laura Merwin, Tianhua He, Byron B. Lamont, Neal J. Enright, Siegfried L. Krauss

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Abstract:

Clonal species normally have low seed production, low recruitment rates and long lifespans, and it is expected that the rates of long-distance dispersal (LDD) of seeds will be low as well. Banksia candolleana is a clonal shrub in Mediterranean-type, fire-prone sclerophyll shrublands of southwestern Australia, whose reproductive biology and population dynamics contrast with those of co-occurring nonclonal congeneric species, all of which are restricted to a mosaic of sand dunes set within a matrix of inhospitable swales. Using microsatellite markers, we genotyped 499 plants in all 15 populations of B. candolleana within a 12-km2 area, assessed population genetic differentiation, and quantified the effective rate of interpopulation seed dispersal through genetic assignment of individuals to populations. We measured life history, reproductive and demographic attributes, and compared these with two co-occurring Banksia species, a non-clonal resprouter and a nonsprouter. B. candolleana has much higher levels of population genetic differentiation, and one-third the rate of interpopulation seed migration, as the other two species (2.2% vs 5.5？6.8% of genotyped plants inferred to be immigrants), though distances reached by LDD are comparable (0.3？2.3 km). The low rate of interpopulation dispersal was supported by an analysis of the age structure of three populations that suggests a mean interdune migration rate of <800 m in 200 years, and 60% of suitable dunes remain uninhabited. Thus, B. candolleana has poor properties for promoting long-distance dispersal. It is unclear if these are idiosyncratic to this species or whether such properties are to be expected of clonal species in general where LDD is less critical for species survival.

References

[1]	Sork VL, Smouse PE (2006) Genetic analysis of landscape connectivity in tree populations. Landscape Ecol 21: 821–836.
[2]	Holderegger R, Buehler D, Gugerli F, Manel S (2010) Landscape genetics of plants. Trend Plant Sci 15: 675–683.
[3]	Luque S, Saura S, Fortin M-J (2012) Landscape connectivity analysis for conservation: insights from combining new methods with ecological and genetic data. Landscape Ecol 27: 153–157.
[4]	Cain ML, Milligan MG, Strand AE (2000) Long-distance seed dispersal in plant populations. Am J Bot 87: 1217–1227.
[5]	Wang BC, Smith TB (2002) Closing the seed dispersal loop. Trend Ecol Evol 17: 379–386.
[6]	Nathan R (2006) Long-distance dispersal of plants. Science 313: 786–788.
[7]	Nathan R, Perry G, Cronin J, Strand A, Cain M (2003) Methods for estimating long-distance dispersal. Oikos 103: 261–273.
[8]	Hanski I (1998) Metapopulation dynamics. Nature 396: 41–49.
[9]	Levin SA, Muller-Landau HC, Nathan R, Chave J (2003) The ecology and evolution of seed dispersal: a theoretical perspective. Ann Rev Ecol Evol Syst 34: 575–604.
[10]	Segelbacher G, Cushman SA, Epperson BK, Fortin MJ, Francois O, et al. (2010) Applications of landscape genetics in conservation biology: concepts and challenges. Conserv Genet 11: 375–385.
[11]	Nathan R, Schurr FM, Speigel O, Steinitz O, Trakhtenbrot A, et al. (2008) Mechanisms of long-distance seed dispersal. Trend Ecol Evol 23: 238–647.
[12]	Berry O, Tocher MD, Sarre SD (2004) Can assignment tests measure dispersal? Mol Ecol 13: 551–561.
[13]	He T, Krauss SL, Lamont BB, Miller BP, Enright NJ (2004) Long distance dispersal in a metapopulation of Banksia hookeriana inferred by population allocation from AFLP data. Mol Ecol 13: 1099–1109.
[14]	He T, Lamont BB, Krauss SL, Enright NJ, Miller BP (2009) Long-distance dispersal of seeds in the fire-tolerant shrub Banksia attenuata. Ecography 32: 571–580.
[15]	He T, Lamont BB, Krauss SL Enright NJ (2010) Landscape genetics of Banksia hookeriana in a metapopulation system. Ann Bot 106: 547–466.
[16]	Lowe WH, Allendorf FW (2010) What can genetics tell us about population connectivity? Mol Ecol 19: 3038–3051.
[17]	Hopper SD, Gioia P (2004) The southwest Australian floristic region: evolution and conservation of a global hotspot of biodiversity. Ann Rev Ecol Evol Syst 35: 623–650.
[18]	Bell DT (2001) Ecological response syndromes in the flora of southwestern Australia: fire resprouters versus reseeders. Bot Rev 67: 417–440.
[19]	Lamont BB, Wiens D (2003) Are seed set and speciation rates always low among species that resprout after fire, and why? Evol Ecol 17: 277–292.
[20]	Enright NJ, Lamont BB (1989) Seed banks, fire season, safe sites and seedling recruitment in five co-occurring Banksia species. J Ecol 77: 1111–1122.
[21]	Bond WJ, Midgley JJ (2001) Ecology of sprouting in woody plants: the persistence niche. Trend Ecol Evol 16: 45–51.
[22]	Low AB, Lamont BB (1990) Aerial and below-ground phytomass of Banksia scrub-heath at Eneabba, Western Australia. Aust J Bot 38: 351–359.
[23]	Bell TL, Ojeda F (1999) Underground starch storage in Erica species of the Cape Floristic Region - differences between seeders and sprouters. New Phytol 144: 143–152.
[24]	Lamont BB, Enright NJ, He T (2011) Fitness and evolution of resprouters in relation to fire. Plant Ecol 212: 1945–1957.
[25]	Lamont BB, He T, Enright NJ, Krauss SL, Miller BP (2003) Anthropogenic disturbance promotes hybridization between Banksia species by altering their biology. J Evol Biol 16: 551–557.
[26]	Enright NJ, Clarke M, Keith D, Miller BP (2012). Australian sclerophyllous shrubby ecosystems: heathlands, heathy woodlands and mallee woodlands. In: Bradstock R, Gill A, Williams R, editors. Flammable Australia: Fire Regimes and Biodiversity in a Changing World. CSIRO Publishing, Melbourne. 215–234.
[27]	Hanski I, Gaggiotti OE (2004) Ecology, Genetics and Evolution of Metapopulations. Elsevier Academic Press, Amsterdam.
[28]	Doyle JJ (1991) DNA protocols for plants. In: Hewitt GM, editor. Molecular techniques in taxonomy. Springer. 283–293.
[29]	Merwin L, He T, Krauss SL (2010) Isolation and characterization of polymorphic microsatellite DNA markers for Banksia candolleana (Proteaceae). Conserv Genet Resources 2: 345–347.
[30]	Peakall R, Smouse PE (2006) GenAlEx 6: genetic analysis in Excel. Mol Ecol Notes 6: 288–295.
[31]	Rousset F (2008) Genepop '007: a complete reimplementation of the Genepop software for Windows and Linux. Mol Ecol Resources 8: 103–106.
[32]	Oosterhout CV, Hutchinson WF, Wills DPM, Shipley P (2004) Microchecker: software for identifying and correcting genotyping errors in microsatellite data. Mol Ecol Notes 4: 535–538.
[33]	Arnaud-Haond S, Belkhir K (2007) GENCLONE: a computer program to analyse genotypic data, test for clonality and describe spatial clonal organization. Mol Ecol Notes 7: 15–17.
[34]	Piry S, Alapetite A, Cornuet J-M, Paetkau D, Baudouin L, et al. (2004) GeneClass2: a software for genetic assignment and first-generation migrant detection. J Hered 95: 536–539.
[35]	Paetkau D, Slade R, Burden M, Estoup A (2004) Genetic assignment methods for the direct, real-time estimation of migration rate: a simulation-based exploration of accuracy and power. Mol Ecol 13: 55–65.
[36]	Rannala B, Mountain JL (1997) Detecting immigration by using multilocus genotypes. Proc Natl Acad Sci USA 94: 9197–9201.
[37]	Roques S, Duchesne P, Bernatchez L (1999) Potential of microsatellites for individual assignment: the North Atlantic redfish (genus Sebastes) species complex as a case study. Mol Ecol 8: 1703–1717.
[38]	Campbell D, Duchesne P, Bernatchez L (2003) AFLP utility for population assignment studies: analytical investigation and empirical comparison with microsatellites. Mol Ecol 12: 979–991.
[39]	Robledo-Arnucio JJ (2012) Joint estimation of contemporary seed and pollen dispersal rates among plant populations. Mol Ecol Resources 12: 299–311.
[40]	Wilson GA, Rannala B (2003) Bayesian inference of recent migration rates using multilocus genotypes. Genetics 163: 1177–1191.
[41]	Enright NJ, Lamont BB (1992) Recruitment variability in the resprouting shrub Banksia attenuata and non-sprouting congeners in the northern sandplain heaths of south-western Australia. Acta Oecologica 13: 727–741.
[42]	Enright NJ, Marsula R, Lamont BB, Wissel C (1998a) The ecological significance of canopy seed storage in fire-prone environments: a model for nonsprouting shrubs. J Ecol 86: 946–959.
[43]	Enright NJ, Marsula R, Lamont BB, Wissel C (1998b) The ecological significance of canopy seed storage in fire-prone environments: a model for resprouting shrubs. J Ecol 86: 960–973.
[44]	Lamont BB, Enright NJ, Witkowski ETF, Groeneveld J (2007) Conservation biology of banksias: insights from natural history to simulation modeling. Aust J Bot 55: 280–292.
[45]	He T, Lamont BB, Krauss SL, Enright NJ, Miller BP (2008) Covariation between intraspecific genetic diversity and species diversity within a plant functional group. J Ecol 96: 956–961.
[46]	Groeneveld J, Enright NJ, Lamont BB (2008) Simulating the effects of different spatio-temporal fire regimes on plant metapopulation persistence in a Mediterranean-type region. J Appl Ecol 45: 1477–1485.
[47]	Clements HB (1977) Lift-off of forest firebrands USDA Forest Service Research Paper SE-159.
[48]	Krauss SL, He T, Barrett L, Lamont BB, Miller BP, et al. (2009) Contrasting impacts of pollen and seed dispersal on spatial genetic structure in the bird-pollinated Banksia hookeriana. Heredity 102: 274–285.
[49]	Manel S, Schwartz M, Luikart G, Taberlet P (2003) Landscape genetics: combining landscape ecology and population genetics. Trends Ecol Evol 18: 189–197.
[50]	Krauss SL, He T, Lamont BB, Miller BP, Enright NJ (2006) Late Quaternary climate change and spatial genetic structure in the shrub Banksia hookeriana. Mol Ecol 15: 1125–1137.
[51]	Midgley GF, Thuiller W, Higgins SI (2007) Plants species migration as a key uncertainty in predicting future impacts of climate change on ecosystems: progress and challenges. In. Canadell J, editor. Terrestrial Ecosystems in a Changing World. Springer-Verlag, Berlin. 149–160.
[52]	Witkowski ETF, Lamont BB (2006) Resilience of two Banksia species to global change: Comparing results of bioclimatic modelling, demographic and translocation studies. Int J Biodivers Sci Managem 2: 1–14.
[53]	Garb J, Kotler BP, Brown JS (2000) Foraging and community consequences of seed size for coexisting Negev Desert granivores. Oikos 88: 291–300.
[54]	Rafferty CM, Lamont BB, Hanley ME (2010) Herbivore feeding preferences in captive and wild populations. Austral Ecol 35: 257–263.
[55]	Lamont BB, Witkowski ETF, Enright NJ (1993) Post-fire litter microsites: safe for seeds, unsafe for seedlings. Ecology 74: 501–512.
[56]	Leishman MR, Westoby M (1994) The role of seed size in seedling establishment in dry soil conditions ？ experimental evidence from semi-arid species. J Ecol 82: 249–258.
[57]	Lamont BB, Witkowski ETF (1995) A test for lottery recruitment among four Banksia species based on their demography and biological attributes. Oecologia 101: 299–308.
[58]	Lamont BB, Groom PK (2002) Green cotyledons of two Hakea species control seedling mass and morphology by supplying mineral nutrients rather than organic compounds. New Phytol 153: 101–110.
[59]	Lamont BB, Barrett GJ (1988) Constraints on seed production and storage in a root-suckering Banksia. J Ecol 76: 1069–1082.
[60]	Lamont BB (1989) Sexual versus vegetative reproduction in Banksia elegans. Bot Gaz 149: 370–375.
[61]	Tautz D, Ellegren H, Weigel D (2010) Next generation molecular ecology. Mol Ecol 19: 1–3.

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