[en] When a globiferous pedicellaria of Sphaerechinus granularis injects its venom, the head autotomizes whereas the stalk remains on the test and enters a regression process with concomitant resorption of its supporting ossicle (i.e. the rod). Scanning electron microscope investigations of the morphological changes undergone by the stereom of resorbing rods show that: (1) resorption proceeds both axially and laterally, and leads to a reduction of approximately 80% of the original length of the rod, (2) secondary growth of new stereom processes occurs concomitantly with resorption but never ensures even a partial regeneration of the rod, and (3) resorption and secondary growth stop before the rod is totally destroyed leaving a static stump that remains in place up to 190 days. Particular resorption figures result from either the axial or the lateral resorption of the rod shaft. These consist chiefly of terraced conical cupules, dense cylinders and concentric lamellae whose walls or edges are typically made of closely piled and/or aligned subprismatic crystallites. Whatever their location along the rod, these crystallites always organize strictly parallel to the rod axis. Whether the crystallites are mosaic blocks composing larger monocrystalline units or discrete monocrystals themselves is for the moment unclear. A growth model, which accounts for the observed resorption figures, is proposed for the shaft of pedicellarial rods. According to this model, the early growth of the shaft would produce elongated, interconnected trabeculae (initial trabeculae) made of densely piled and perfectly aligned crystallites. Thickening and coalescence of adjoining trabeculae would progressively occur by adjunction around the initial trabeculae of successive and concentric layers of similarly arranged crystallites. Coalescent trabeculae would then be cemented together in a perforate stereom layer by the final deposition of larger crystallite layers surrounding the whole shaft periphery. Growth of secondary stereom processes occurs both in the resorbing rod (here the newly formed processes are resorbed soon after they have been produced) and in rods where resorption has stopped. These are always irregular processes that localize near or on the actual sites of resorption. It is suggested these processes result from an uncontrolled activation of the skeleton-forming cells in areas where the concentration of calcium ions increases as a consequence of calcite resorption
Disciplines :
Veterinary medicine & animal health
Author, co-author :
Bureau, Fabrice ; Université de Liège - ULiège > Département de sciences fonctionnelles > GIGA-R : Biochimie et biologie moléculaire
Dubois, Philippe; Université Libre de Bruxelles - ULB > Laboratoire de Biologie marine (C. P. 160)
Ghyoot, M.
Jangoux, M.
Language :
English
Title :
Skeleton resorption in echinoderms : regression of pedicellarial stalks in Sphaerechinus granularis (Echinoidea)
Bischoff W.D., Mackenzie F.T., Bischop F.C. (1987) Stabilities of synthetic magnesian calcites in aqueous solution: comparison with biogenic materials. Geochim Cosmochim Acta 51:1413-1423.
Campbell A.C. (1983) Form and function of pedicellariae. Echinoderm Studies 1 , M., Jangoux, J.M., Lawrence, Balkema, Rotterdam; 139-167.
Devery D.M., Ehlmann A.J. (1981) Morphological changes in a series of synthetic Mg-calcites. Amer Mineral 66:592-595.
Donnay G., Pawson D.L. (1969) X-ray diffraction studies of echinoderm plates. Science, NY 166:1147-1150.
Dubois (1990) Biological control of skeleton properties in echinoderms. Echinoderm Research , C., De Ridder, Ph, Dubois, M.C., Lahaye, M., Jangoux, Balkema, Rotterdam; 17-22.
Dubois, Chen C.P. (1989) Calcification in echinoderms. Echinoderm Studies 3 , M., Jangoux, J.M., Lawrence, Balkema, Rotterdam; 109-178.
Dubois, Hayt S. (1990) Ultrastructure des ossicules d'échinodermes à stéréome non perforé. Echinoderm Research , C., De Ridder, Ph, Dubois, M.C., Lahaye, M., Jangoux, Balkema, Rotterdam; 217-223.
Dubois, Jangoux M. (1985) The micro structure of the asteroid skeleton (Asterias rubens). Proc Fifth Int Echinoderm Conference, Galway , B.F., Keegan, B.D.S., O'Connor, Balkema, Rotterdam; 507-512.
Dubois, Jangoux M. (1990) Stereom morphogenesis and differentiation during regeneration of adambulacral spines of Asterias rubens (Asteroida: Echinodermata). Zoomorphology 109:263-272.
Ghyoot M., Dubois, Jangoux M. (1990) Ultrastructure and presumed origin of the phagocytic cells involved in the regression of headless stalks of globiferous pedicellariae in the echinoid Sphaerechinus granularis (Echinodermata). Echinoderm Research , C., De Ridder, Ph, Dubois, M.C., Lahaye, M., Jangoux, Balkema, Rotterdam; 239-245.
Gordon I. (1926) The development of the calcareous test of Echinocardium cordatum. Philosophical Transactions of the Royal Society B: Biological Sciences 214:259-312.
Heatfield B.M. (1971) Growth of the calcareous skeleton during regeneration of spines of the sea urchin, Strongylocentrotus purpuratus: A light and scanning electron microscope study. Journal of Morphology 134:57-90.
Hilgers H., Splechtna H. (1982) Zur Steuerung der Ablösung Giftpedizellarien bei Sphaerechinus granularis (Lam.) und Paracentrotus lividus (Lam.) (Echinodermata, Echinoidea). Zool Jb Anat 107:442-457.
Holland L.Z., Holland N.D. (1975) The fine structure of epidermal glands of regenerating and mature globiferous pedicellariae of a sea urchin (Lytechinus pictus). Tissue Cell 7:723-737.
Holland N.D., Grimmer J.C. (1981) Fine structure of syzygial articulations before and after arm autotomy in Florometra serratissima (Echinodermata: Crinoidea). Zoomorphology 98:169-183.
Mann S. (1983) Mineralization in biological systems. Struct Bonding 54:125-174.
Märkel K. (1979) Structure and growth of the cidaroid socket-joint lantern of Aristotle compared to the hinge-joint lanterns of non-cidaroid regular echinoids (Echinodermata, Echinoidea). Zoomorphology 94:1-32.
Märkel K. (1981) Experimental morphology of coronar growth in regular echinoids. Zoomorphology 97:31-52.
Märkel K., Röser U. (1983) Calcite résorption in the spine of the echinoid Eucidaris tribuloides. Zoomorphology 103:43-58.
Mischor B. (1975) Zur Morphologie und Regeneration der Hohlstacheln von Diadema antillarum Philippi und Echinothrix diadema (L) (Echinoidea, Diadematidae). Zoomorphologie 82:243-258.
Okazaki K., Inoué S. (1976) Crystal property of the larval sea urchin spicule. Dev Growth Differ 18:413-434.
Okazaki K., Dillaman R.M., Wilbur K.M. (1981) Crystalline axes of the spine and test of the sea urchin Strongylocentrotus purpuratus: Determination by crystal etching and decoration. Biological Bulletin 161:402-415.
O'Neill P. (1981) Polycrystalline echinoderm calcite and its fracture mechanics. Science, NY 213:646-648.
Pérès J.M. (1950) Recherches sur les pédicellaires glandulaires de Sphaerechinus granularis (Lamarck). Arch Zool Exp Gén 86:118-136.
Raup D.M. (1959) Crystallography of echinoid calcite. The Journal of Geology 67:661-674.
Smith A.B. (1980) Stereom microstructure of the echinoid test. Spec Pap Palaeontol 25:1-81.
Smith A.B. (1990) Biomineralization in echinoderms. Skeletal Biomineralization Patterns, Processes and Evolutionary Trends , J.G., Carter, American Geophysical Union, Washington DC; 117-147.
Towe K.M. (1972) Invertebrate shell structure and the organic matrix concept. Biomineralization 4:1-14.
