Abstract
An electrophoretic survey of allozyme variation revealed substantial genetic differentiation within the eastern Australian population ofActinia tenebrosa. This differentiation appears to reflect the effects of both asexual reproduction and limited gene flow among local populations separated by up to 1050 km. Variation was assessed within groups of 27 to 55 adults sampled between September 1985 and December 1988 collected from small areas of shore within each of 24 local populations. All individuals were collected from stable rock platforms, with the exception of Boulder Bay, where some sea anemones were removed from small mobile boulders. High levels of variability were detected for each of seven enzyme-encoding loci. The patterns of genotypic variation detected imply that local populations are maintained by predominantly asexually generated recruitment. Levels of multi-locus genotypic diversity within samples were consistently less than 50% of the level expected for sexual reproduction with free recombination. This was reflected by the detection of relatively low numbers of multi-locus genotypes and significant departures from expectations for single-locus Hardy-Weinberg equilibria within 17 of the 24 local populations. Standardised genetic variances (F ST ), calculated from the genotypes of all individual adults were typically much greater than those expected for marine organisms with widely dispersed larvae. The former values were reduced, but were still extremely large when “clonal” genotype frequencies were substituted into the calculation. These data imply that although widely dispersed larvae may be an important source of initial colonists, levels of gene flow among established local populations are low. Furthermore, cluster analysis revealed a clear subdivision of the population into northern and southern groups. However, this subdivision was largely explained by strong clinal variation at a GPI-encoding locus. For this locus, allele frequencies ranged from fixation of the A allele in samples from the 12 most northern sites to near fixation of the alternative B allele in southern samples. Subdivision of the eastern Australian population is consistent with the predicted off-shore movement of the Eastern Australian Current close to the border between Victoria and New South Wales. However, the split into northern and southern regions, as evidenced by the variation forGpi, could reflect patterns of gene flow and/or other factors such as natural selection or the recent patterns of colonisation.
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Literature cited
Ayre, D. J. (1983). The effects of asexual reproduction and intergenotypic aggression on the genotypic structure of populations of the sea anemoneActinia tenebrosa. Oecologia 57: 158–165
Ayre, D. J. (1984a). The effects of sexual and asexual reproduction on geographic variation in the sea anemoneActinia tenebrosa. Oecologia 62: 222–229
Ayre, D. J. (1984b). Effects of environment and population density on the sea anemoneActinia tenebrosa. Aust. J. mar. Freshwat. Res. 35: 735–746
Ayre, D. J. (1985). Localized adaptation of clones of the sea anemoneActinia tenebrosa. Evolution 39: 1250–1260
Ayre, D. J. (1988). Evidence for genetic determination of sex inActinia tenebrosa. J. exp. mar. Biol. Ecol. 116: 23–43
Ayre, D. J. (1990). Population subdivision in Australian temperate marine invertebrates: larval connections versus historical factors. Aust. J. Ecol. 15: 403–411
Ayre, D. J., Willis, B. L. (1988). Population structure in the coralPavona cactus: clonal genotypes show little phenotypic plasticity. Mar. Biol. 99: 495–505
Black, R., Johnson, M. S. (1979). Asexual viviparity and population genetics ofActinia tenebrosa. Mar. Biol. 53: 27–31
Bucklin, A., Hedgecock, D., Hand, C. (1984). Genetic evidence of self-fertilization in the sea anemoneEpiactis prolifera. Mar. Biol. 84: 175–182
Chaplin, J. A., Ayre, D. J. (1989). Genetic evidence of variation in the contributions of sexual and asexual reproduction to populations of the freshwater ostracodCandonocypris novaezelandiae. Freshwat. Biol. 22: 275–284
Fadlallah, Y. H. (1982). Reproductive ecology of the coralAstrangia lajollaensis: sexual and asexual patterns in a kelp forest habitat. Oecologia 55: 379–388
Fujii, H. (1987). The predominance of clones in populations of the sea anemoneAnthopleura asiatica (Uchida). Biol. Bull. mar. biol. Lab, Woods Hole 172: 202–211
Hamon, B. V., Godfrey, J. S., Greig, M. A. (1975). The relation between mean sea level, current and wind stress on the east coast of Australia. Aust. J. mar. Freshwat. Res. 26: 389–403
Harris, H., Hopkinson, D. A. (1976). Handbook of electrophoresis in human genetics. North-Holland, Amsterdam
Hedgecock, D. (1986). Is gene flow from pelagic larval dispersal important in the adaptation and evolution of marine invertebrates? Bull. mar. Sci. 39: 550–564
Hoffmann, R. J. (1981). Evolutionary genetics ofMetridium senile. I. Kinetic differences in the phosphoglucose isomerase allozymes. Biochem. Genet. 19: 129–144
Hoffmann, R. J. (1986). Variation in contributions of asexual reproduction to the genetic structure of populations of the sea anemoneMetridium senile. Evolution 40: 357–365
Hunt, A., Ayre, D. J. (1989). Population structure in the sexually reproducing sea anemoneOulactis muscosa. Mar. Biol. 102: 537–544
Jackson, J. B. C. (1986). Modes of dispersal of clonal benthic invertebrates: consequences for the species' distribution and genetic structure of local populations. Bull. mar. Sci. 39: 588–606
Johnson, M. S., Clarke, B., Murray, J. (1988). Discrepancies in the estimation of gene flow inPartula. Genetics, Austin, Tex. 120: 233–238
Johnson, M. S., Threlfall, T. J. (1987). Fissiparity and population genetics ofCoscinasterias calamaria. Mar. Biol. 93: 517–525
Koehn, R. K., Newell, R. E. I., Immerman, F. (1980). Maintenance of an aminopeptidase allele frequency cline by natural selection. Proc. natn. Acad. Sci. U.S.A. 77: 5385–5389
Maxwell, J. G. H., Cresswell, G. R. (1981). Dispersal of tropical marine fauna to the great Australian Bight by the Leeuwin Current. Aust. J. mar. Freshwat. Res. 32: 493–500
Nei, M. (1978). Estimation of average heterozygosity and genetic distance from a small number of individuals. Genetics, Austin, Tex. 89: 583–590
Ottaway, J. R. (1979). Population ecology of the intertidal anemoneActinia tenebrosa. II. Geographical distribution, synonomy, reproductive cycle and fecundity. Aust. J. Zool. 27: 273–290
Selander, R. K., Smith, M. H., Yang, S. Y., Johnson, W. B., Gentry, J. B. (1971). Biochemical polymorphism and systematics in the genusPeromyscus. I. Variation in the old-field mouse (Peromyscus polionotus). Stud. Genet., Austin, Tex. 6: 49–90. (Univ. Tex. Publs, No. 7103)
Shick, J. M., Hoffmann, R. J., Lamb, A. N. (1979). Asexual reproduction, population structure and genotype-environment interactions in sea anemones. Am. Zool. 19: 699–713
Slatkin, M. (1985a). Gene flow in natural populations. A. Rev. Ecol. Syst. 16: 393–430
Slatkin, M. (1985b). Rare alleles as indicators of gene flow. Evolution 39: 53–65
Smith, B. L., Potts, D. C. (1987). Clonal and solitary anemones (Anthopleura) of western North America: population genetics and systematics. Mar. Biol. 94: 537–546
Sokal, R. R., Sneath, P. H. A. (1963). Principles of numerical taxonomy. W. H. Freeman & Co., San Francisco
Stoddart, J. A. (1984a). Genetical structure within populations of the coralPocillopora damicornis. Mar. Biol. 81: 19–30
Stoddart, J. A. (1984b). Genetic differentiation amongst populations of the coralPocillopora damicornis off southwestern Australia. Coral Reefs 3: 149–156
Stoddart, J. A. (1988a). Historecognition and fine-scale spatial genetic structure in sessile benthic invertebrates. In: Grosberg, R. K., Hedgecock, D., Nelson, K. (eds.). Invertebrate historecognition. Plenum Press, New York, p. 111–125
Stoddart, J. A. (1988b). Coral populations fringing islands: larval connections. Aust. J. mar. Freshwat. Res. 39: 109–115
Stoddart, J. A., Taylor, J. F. (1988). Genotypic diversity: estimation and prediction. Genetics, Austin, Tex. 118: 705–711
Swofford, D. L., Selander, R. B. (1981). BIOSYS-1: a FORTRAN program for the comprehensive analysis of electrophoretic data in population genetics and systematics. J. Hered. 72: 281–283
Underwood, A. J., Fairweather, P. G. (1989). Supply-side ecology and benthic marine assemblages. Trends Ecol. Evol. 4: 16–20
Williams, G. C. (1975). Sex and evolution. Princeton University Press, Princeton
Wright, S. (1978). Evolution and the genetics of populations. Vol. 4. Variability within and among natural populations. University of Chicago Press, Chicago
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Communicated by G.F. Humphrey, Sydney
Contribution No. 78 from the Ecology and Genetics Group of the University of Wollongong
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Ayre, D.J., Read, J. & Wishart, J. Genetic subdivision within the eastern Australian population of the sea anemoneActinia tenebrosa . Mar. Biol. 109, 379–390 (1991). https://doi.org/10.1007/BF01313503
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DOI: https://doi.org/10.1007/BF01313503