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Confocal laser scanning light microscopy of the extra-thecal epithelia of undecalcified scleractinian corals

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Abstract

The extra-thecal epithelia of cryofixed undecalcified, freeze-substituted polyps of the scleractinian corals Galaxea fascicularis and Tubastrea faulkneri and axial and basal polyps of Acropora formosa have been examined, in anhydrously prepared thick slices, by confocal laser scanning light microscopy. The avoidance of chemical fixation and decalcification makes it possible to determine whether previously seen structures are real or artefactual products of swelling, shrinkage and distortion. All of the epithelia of all the corals examined are characterised by well defined intercellular spaces. Mucocytes are present in all cell layers in Galaxea and Tubastrea but are not present in any cell layers in the axial polyp of Acropora although they are abundant in the oral ectoderm of the basal polyps in this coral. Zooxanthellae are absent in Tubastrea, the epithelia of the exert septa of Galaxea and the axial polyp of Acropora. The calicoblastic ectoderm is generally composed of thin squamous cells with large intercellular spaces. At rapidly calcifying regions such as the tips of the exert septa of Galaxea, the calicoblastic cells are elongated with extensive arborisation of the basal regions of the cells. They are separated by large intercellular spaces and contain numerous fluorescent granules. The apical regions of these cells appear to be closely applied to the surface of the skeleton. There is no evidence of a space between the apical region of the calicoblastic cells and the skeleton.

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References

  • Amerongen HM, Peteya DJ (1980) Ultrastructure study of two kinds of muscle in sea anenomes: the existence of fast and slow muscles. J Morphol 166:145–154

    Google Scholar 

  • Barnes DJ, Chalker BE (1990) Calcification and photosynthesis in reef-building corals and algae. In: Dubinsky Z (ed) Coral Reefs. Elsevier, Amsterdam, pp 109–132

    Google Scholar 

  • Batham EJ (1960) The fine structure of epithelium and mesogloea in a sea anenome. Q Jl Microsc Sci 101:481–485

    Google Scholar 

  • Benos DJ, Kirk RG, Barba WP, Goldner MM (1977) Hyposmotic fluid formation in Hydra. Tissue Cell 9:11–22

    Google Scholar 

  • Bourne GC (1887a) The anatomy of the madreporatian coral Fungia. Q Jl Microsc Sci 27:293–324

    Google Scholar 

  • Bourne GC (1887b) On the anatomy of Mussa and Euphyllia and the morphology of the madreporarian skeleton. Q Jl Microsc Sci 28:21–52

    Google Scholar 

  • Bourne GC (1899) Studies on the structure and formation of the calcareous skeleton of the anthozoa. Q Jl Microsc Sci 41:499–547

    Google Scholar 

  • Burnett AL (1973) Biology of Hydra. Academic Press, New York

    Google Scholar 

  • Chalker BE (1976) Calcium transport during skeletogenesis in hermatypic corals. Comp Biochem Physiol [A] 54:455–459

    Google Scholar 

  • Chapman DM (1974) Cnidarian histology. In: Muscatine L, Lenhoff HM (eds) Coelenterate biology. Academic Press, New York, pp 1–92

    Google Scholar 

  • Dietrich HF, Fontaine AR (1975) A decalcification method for ultrastructure of echioderm tissues. Stain Technol 50:351–354

    Google Scholar 

  • Duerden JE (1904) Recent results on the morphology and development of coral polyps. Smithson Misc Collns 47:93–111

    Google Scholar 

  • Fowler GH (1885) The anatomy of the madreporaria: I. Jl Microsc Sci 25:577–597

    Google Scholar 

  • Fowler GH (1886) The anatomy of the madreporaria: II. Q Jl Microsc Sci 27:1–16

    Google Scholar 

  • Fowler GH (1887a) The anatomy of the madreporaria: III. Q Jl Microsc Sci 28:1–17

    Google Scholar 

  • Fowler GH (1887b) The anatomy of the madreporaria: IV. Q Jl Microsc Sci 28:413–430

    Google Scholar 

  • Fowler GH (1889) The anatomy of the madreporaria: V. Q Jl Microsc Sci 30:405–419

    Google Scholar 

  • Goldberg WM, Taylor GT (1989a) Cellular structure and ultrastructure of the black coral Antipathes aperta. 1. Organisation of the tentacular epidermis and nervous system. J Morphol 202:239–253

    Google Scholar 

  • Goldberg WM, Taylor GT (1989b) Cellular structure and ultrastructure of the black coral Antipathes aperta. 2. The gastrodermis and its collar cells. J Morphol 202:255–269

    Google Scholar 

  • Grimstone AV, Horne RW, Pantin CFA, Robson EA (1958) The fine structure of the mesenteries of the sea anemone Metridium senile. Q Jl Microsc Sci 99:523–540

    Google Scholar 

  • Holley MC (1982) The control of anthozoan cilia by the basal apparatus. Tissue Cell 14:607–620

    Google Scholar 

  • Hündgen M (1984) Cnidaria: cell types. In: Bereiter-Hahn J, Matoltsy AG, Richards KS (eds) Biology of the integument. Springer, Berlin, pp 47–57

    Google Scholar 

  • Hyman LH (1940) The invertebrates: protozoa throught ctenophora. McGraw-Hill, New York

    Google Scholar 

  • Ip YK, Lim ALL (1991) Are calcium and strontium transported by the same mechanism in the hermatypic coral Galaxea fascicularis? J Exp Biol 159:507–513

    Google Scholar 

  • Isa Y (1986) An electron microscope study on the mineralisation of the skeleton of the staghorn coral Acropora hebes. Mar Biol 93:91–101

    Google Scholar 

  • Isa Y, Yamazato K (1981) The ultrastructure of calicoblast and related tissues in Acropora hebes (Dana). Proc 4th Int Coral Reef Sym 2:99–105

    Google Scholar 

  • Johnston IS (1980) The ultrastructure of skeletogenesis in hermatypic corals. Int Rev Cytol 67:171–214

    Google Scholar 

  • Kawaguti S (1966) Electron microscopy on the fluorescent green of reef corals with a note on mucous cells. Biol J Okayama Univ 12:11–21

    Google Scholar 

  • Kawaguti S, Sato K (1968) Electron microscopy of the polyp of staghorn corals with special reference to its skeleton formation. Biol J Okayama Univ 14:87–98

    Google Scholar 

  • Kawaguti S, Yokoyama T (1966) Electron microscopy on the polyp and pigment granules of an ahermatypic coral Dendrophyllia cribrosa. Biol J Okayama Univ 12:69–80

    Google Scholar 

  • Kinchington D (1981) Organic-matrix synthesis by scleractinian coral larval and postlarval stages during skeletogenesis. Proc 4th Int Coral Reef Symp 2:107–113

    Google Scholar 

  • LeTissier M D'AA (1988) Diurnal patterns of skeleton formation in Pocillopora damicornis (Linnaeus). Coral Reefs 7:81–88

    Google Scholar 

  • LeTissier M D'AA (1990) The ultrastructure of the skeleton and skeletogenic tissues of the temperate coral Caryophyllia smithii. J Mar Biol Ass UK 70:295–310

    Google Scholar 

  • Marshall AT, Wright OP (1991) Freeze-substitution of scleractinian coral for confocal scanning laser microscopy and X-ray microanalysis. J Microsc 162:341–354

    Google Scholar 

  • Ogilvie MM (1896) Microscopic and systematic study of madreporarian types of corals. Phil Trans B 187:83–345

    Google Scholar 

  • Ogilvie MM (1906) The lime-forming layer of the madreporarian polyp. Q Jl Microsc Sci 49:203–211

    Google Scholar 

  • Ogilvie MM (1907) Note on the formation of the skeleton in the madreporaria. Q Jl Microsc Sci 51:473–482

    Google Scholar 

  • Pearse VB, Muscatine L (1971) Role of symbiotic algae (zooxanthellae) in coral calcification. Biol Bull 141:350–363

    Google Scholar 

  • Robson EA (1957) The structure and hydromechanics of the musculo-epithelium in Metridium. Q Jl Microsc Sci 98:265–279

    Google Scholar 

  • Simkiss K (1986) The processes of biomineralization in lower plants and animals-an overview. In: Leadbeater BS, Riding R (eds) Biomineralization in lower plants and animals. Clarendon Press, Oxford, pp 19–37

    Google Scholar 

  • Tardent P, Tardent R (1979) Developmental and cellular biology of coelenterates. Elsevier-North Holland Press, New York

    Google Scholar 

  • Vandermeulen JH (1974) Studies on reef corals II. Fine structure of planktonic planula larva of Pocillopora damicornis with emphasis on the aboral epidermis. Mar Biol 27:239–249

    Google Scholar 

  • Vandermeulen JH (1975) Studies on reef corals III. Fine structural changes in calicoblast cells in Pocillopora damicornis during settling and calcification. Mar Biol 31:69–77

    Google Scholar 

  • Watson GM, Mariscal RN (1983) Comparative ultrastructure of catch tentacles and feeding tentacles in the sea anenome Haliplanella. Tissue Cell 15:939–953

    Google Scholar 

  • Wright OP, Marshall AT (1991) Calcium transport across the isolated oral epithelium of scleractinian corals. Coral Reefs 10:37–40

    Google Scholar 

Download references

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  1. Analytical Electron Microscopy Laboratory, Department of Zoology, La Trobe University, 3083, Bundoora, Victoria, Australia

    A. T. Marshall & O. P. Wright

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  1. A. T. Marshall
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  2. O. P. Wright
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Marshall, A.T., Wright, O.P. Confocal laser scanning light microscopy of the extra-thecal epithelia of undecalcified scleractinian corals. Cell Tissue Res 272, 533–543 (1993). https://doi.org/10.1007/BF00318560

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  • DOI: https://doi.org/10.1007/BF00318560

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