Abstract
Allozyme variation at six polymorphic loci was examined in foliose dictyoceratid sponges from isolated reefs in the western Coral Sea. Four major genetic groups corresponding to the species Phyllospongia lamellosa, P. alcicornis, Carterospongia flabellifera and Collospongia auris were examined. A further two rare morphotypes from individual reefs formed genetic outliers to the P. lamellosa group, and may represent further taxa related to P. lamellosa. Gene frequencies in individual reef populations were largely in Hardy-Weinberg equilibrium, suggesting that random mating occurred in local populations of all four common species. Genetic variability was high and observed heterozygosities within populations ranged from 0.13 to 0.40. All four taxa showed significant genetic differentiation among populations (F ST=0.05 to 0.36). Genetic distances (Nei's D) among populations within species ranged from 0 to 0.723 and increased with increasing geographical separation. There was evidence that genetic differentiation between populations to the north and to the south of the southern limit of the South Equatorial Current (SEC) divergence was greater than expected on the basis of their geographical separation. The SEC divergence may form a partial barrier to gene flow among populations of these ecologically important sponges on the submerged Queensland Plateau. Levels of migration among populations of three of the species was less than those required to prevent divergence of the populations through genetic drift (Nm<1). Restricted migration among populations may provide a mechanism to explain the occurrence of highly divergent populations of dictyoceratid sponges whose specific identity is not clear, and may allow them additionally to develop partial reproduction isolation from other populations.
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References
Andrews JC, Clegg S (1989) Coral Sea circulation and transport deduced from modal information models. Deep-Sea Res 36:957–974
Benzie JAH (1991) Genetic relatedness of foraminiferan (Marginopora vertebralis) populations from reefs in the Western Coral Sea and Great Barrier Reef. Coral Reefs 10:29–36
Benzie JAH, Williams ST (1992) Genetic structure of the giant clam (Tridacna maxima) populations from reefs in the Western Coral Sea. Coral Reefs 11:135–141
Bergquist PR, Ayling AM, Wilkinson CR (1988) Foliose Dictyoceratida of the Australian Great Barrier Reef. I. Taxonomy and phylogenetic relationships. Pubbl Staz zool Napoli (I: Mar Ecol) 9: 291–319
Church JA (1987) East Australian Current adjacent to the Great Barrier Reef. Aust J mar Freshwat Res 38:671–683
Elston RC, Forthofer R (1977) Testing for Hardy-Weinberg equilibrium in small samples. Biometrics 33:536–542
Harris H, Hopkinson DA (1976) Handbook for enzyme electrophoresis in human genetics. North Holland, Oxford Looseleaf
Jokiel PL, Hildemann WH, Bigger CH (1982) Frequency of intercolony graft acceptance or rejection as a measure of population structure in the sponge Callyspongia diffusa. Mar Biol 71:135–139
Miller RG (1966) Simultaneous statistical inference. McGraw-Hill, New York
Nei M (1978) Estimation of average heterozygosity and genetic distance from a small number of individuals. Genetics, Austin, Tex 89:583–590
Neigel JE, Avise JC (1985) The precision of histocompatibility response in clonal recognition in tropical marine sponges. Evolution 39:724–732
Neigel JE, Schmahl GP (1984) Phenotypic variation within histocompatibility-defined clones of marine sponges. Science, NY 224:413–415
Pickard GL, Donguy JR, Henin C, Rougerie F (1977) A review of the physical oceanography of the Great Barrier Reef and western Coral Sea. Monogr Ser Aust Inst mar Sci 2:1–134
Richardson BJ, Baverstock PR, Adams M (1986) Allozyme electrophoresis. A handbook for animal systematics and population studies. Academic Press Australia, North Ryde
Shaklee JB, Keenan CP (1986) A practical laboratory guide to the techniques and methodology of electrophoresis and its application to fish fillet identification. CSIRO Marine Laboratories Report 77. CSIRO, Hobart
Solé-Cava AM, Boury-Esnault N, Vacelet J, Thorpe JP (1992). Biochemical genetic divergence and systematics in sponges of the genera Corticium and Oscarella (Desmospongiae: Homoscleromorpha) in the Mediterranean Sea. Mar Biol 113:299–304
Solé-Cava AM, Thorpe JP (1986) Genetic differentiation between morphotypes of the marine sponges Suberites ficus (Desmospongiae: Hadromerida). Mar Biol 93:247–253
Stoddart JA (1989) Foliose Dictyoceratida of the Australian Great Barrier Reef. III. Preliminary electrophoretic systematics. Pubbl Staz zool Napoli (I: Mar Ecol) 10:167–178
Swofford DL, Selander RB (1981) BIOSYS-1: a fortran program for the comprehensive analysis of electrophoretic data in population genetics and systematics. J Hered 72:281–283
Urbaneja M, Lin AL (1981) A preliminary study on the isozyme patterns and taxonomy of tropical sponges. Comp Biochem Physiol 70B:367–373
Waples RS (1987) A multispecies approach to the analysis of gene flow in marine shore fishes. Evolution 41:385–400
Weir BS, Cockerham CC (1984) Estimating F-statistics for the analysis of population structure. Evolution 38:1358–1370
Wilkinson CR (1987) Productivity and abundance of large sponge populations on Flinders Reef flats, Coral Sea. Coral Reefs 5: 183–188
Wilkinson CR (1988) Foliose Dictyoceratida of the Australian Great Barrier Reef. II. Ecology and distribution of these prevalent sponges. Pubbl Staz zool Napoli (I: Mar Ecol) 9:321–327
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Communicated by G. F. Humphrey, Sydney
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Benzie, J.A.H., Sandusky, C. & Wilkinson, C.R. Genetic structure of dictyoceratid sponge populations on the western Coral Sea reefs. Marine Bioliogy 119, 335–345 (1994). https://doi.org/10.1007/BF00347530
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DOI: https://doi.org/10.1007/BF00347530