Mesoglea
Mesoglea, also known as mesohyl, is the translucent, non-living, jelly-like substance found between the two epithelial cell layers i.e between ecto and endoderm in the bodies of cnidarians and sponges. Mesoglea refers more correctly to the tissue found in jellyfish and it functions as a hydro-static skeleton. Mesohyl generally refers to tissue found in sponges.
The mesoglea is mostly water. Other than water, the mesoglea is composed of several substances including fibrous proteins like collagen and heparan sulphate proteoglycans.[1] The mesoglea is mostly acellular,[2] but in both cnidaria[3] and ctenophora[4] the mesoglea contains muscle bundles and nerve fibres. Other nerve and muscle cells lie just under the epithelial layers.[2] The mesoglea also contains wandering amoebocytes that play a role in phagocytosing debris and bacteria. These cells also fight infections by producing antibacterial chemicals.[5]
The mesoglea may be thinner than either of the cell layers[6] in smaller coelenterates like a hydra or may make up the bulk of the body in larger jellyfish. The mesoglea serves as an internal skeleton, supporting the body. Its elastic properties help restore the shape after it is deformed by the contraction of muscles.[7] However, without the buoyancy of water to support it, the mesoglea is not stiff enough to bear the weight of the body and coelenterates collapse when they are taken out of water.
In order to differentiate the use of the word mesenchyme in vertebrate embryology (that is, undifferentiated tissue found in embryonic true [ento-]mesoderm from which are derived all connective tissues, blood vessels, blood cells, the lymphatic system, and the heart) and the use in invertebrate zoology (a more-or-less solid but looselly organized tissue consisting of a gel matrix [the mesoglea, in strict sense] with various cellular and fibrous inclusions, located between epidermis and gastrodermis), some authors prefer to use the term mesoglea (in wider sense) in lieu of mesenchyme when referring to the middle layers of sponges and diploblasts, reserving the term mesenchyme for the embryological sense. However, Brusca & Brusca (2003) discourage this usage, using mesoglea in its strict sense, and preferring to maintain both the embryological and zoological senses for the term mesenchyme.[8]
See also
References
- ↑ Sarras, M. P.; Madden, M. E.; Zhang, X.; Gunwar, S.; Huff, J. K.; Hudson, B. G. (1991). "Extracellular matrix (mesoglea) of Hydra vulgaris". Developmental Biology. 148 (2): 481–494. doi:10.1016/0012-1606(91)90266-6. PMID 1743396.
- 1 2 Josephson, R. (2004). "The Neural Control of Behavior in Sea Anemones". Journal of Experimental Biology. 207 (14): 2371–2372. doi:10.1242/jeb.01059. PMID 15184508.
- ↑ Werner, B.; Chapman, D. M.; Cutress, C. E. (1976). "Muscular and nervous systems of the cubopolyp (Cnidaria)". Experientia. 32 (8): 1047–1049. doi:10.1007/BF01933964.
- ↑ Hernandez-Nicaise, M. L. (1973). "The nervous system of ctenophores III. Ultrastructure of synapses". Journal of Neurocytology. 2 (3): 249–263. doi:10.1007/BF01104029. PMID 9224490.
- ↑ Hutton, Danielle M. C.; Smith, Valerie J. (1996). "Antibacterial Properties of Isolated Amoebocytes from the Sea Anemone Actinia equina". Biological Bulletin. 191 (3): 441–451. doi:10.2307/1543017. JSTOR 1543017.
- ↑ Campbell, Richard D. (1976). "Elimination by Hydra interstitial and nerve cells by means of colchicine". Journal of Cell Science. 21 (1): 1–13. PMID 932105.
- ↑ Kier, W. M. (2012). "The diversity of hydrostatic skeletons". Journal of Experimental Biology. 215 (8): 1247–1257. doi:10.1242/jeb.056549. PMID 22442361.
- ↑ Brusca & Brusca (2003), p. 220.