Abstract
FOR more than a century there has been controversy as to whether Schwann cells are able to synthesise collagen and the collagen-related basement membrane1,2. Recent evidence provides more direct proof that Schwann cells are indeed equipped to synthesise collagen and probably also a basement membrane in the same way as other cells of epithelial and neuroectodermal origin3–5. Observations in various pathological situations, including regeneration after crush injury6,7 and in peripheral nerve ischaemia8 indicate that axon regrowth and Schwann cell migration occur along scaffolding consisting of basement membranes and endoneurial collagen fibres. The role of the basement membrane and the endoneurial collagen in normal myelination has, however, remained largely unknown. It has been generally accepted that these extracellular elements provide not only mechanical support to peripheral nerves, but also that they are partly responsible for the relative lack of developmental faults in peripheral myelination9. A recent report10 suggests that the acquisition of a basement membrane by a Schwann cell occurs at the time that the cell establishes a permanent relationship with an axon. It is not known, however, whether the association of the axon with the Schwann cell induces the latter to synthesise basement membrane, or whether the Schwann cell only establishes a relationship with an axon once the Schwann cell has acquired a basement membrane.
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References
Cytology and Cellular Pathology of the Nervous System (edit. by Penfield, W.), 953–990 (Hoeber, New York, 1932).
Murray, M., and Stout, A. P., Am. J. Path., 18, 585–589 (1942); ibid., 16, 41–60 (1940).
Cohen, A. M., and Hay, E. D., Devl Biol., 26, 578–605 (1971).
Dodson, J. W., and Hay, E. D., Expl Cell Res., 65, 215–220 (1971).
Church, R. L., Panzer, M. L., and Pfeiffer, S. E., Proc. natn. Acad. Sci. U.S.A., 70, 1943–1946 (1973).
Nathaniel, E. J. H., and Pease, D. C., J. Ultrastruct. Res., 9, 550–560 (1963).
Thomas, P. K., J. Cell Biol., 23, 375–382 (1964).
Northals, J. K., and Wisniewski, H. M., J. neurol. Sci., 24, 65–76 (1975).
Peters, A., Palay, S. L., and Webster, H. de F., in The Fine Structure of the Nervous System. The cells and their processes, 95–98 (Harper and Row, NewYork, 1970).
Billings-Gagliardi, S., Webster, H. de F., and O'Connell, M. F., Am. J. Anat., 141, 375–392 (1974).
Bradley, W. G., and Jenkison, M., J. neurol. Sci., 18, 227–247 (1973); ibid., 25, 249–255 (1975).
Biscoe, T. J., Caddy, K. W. T., Pallot, D. J., Pehrson, U. M. M., and Stirling, C. A., Brain Res., 76, 534–536 (1974).
Stirling, C. A., J. Anat., 119, 169–180 (1975).
Huizar, P., Kuno, M., and Miyata, Y., J. Physiol., Lond., 248, 231–246 (1975).
Cravioto, H., J. Ultrastruct. Res., 12, 634–651 (1965).
Gamble, H. M., and Breathnach, A. S., J. Anat., 99, 573–584 (1965).
Ochoa, J., J. Anat., 108, 231–245 (1971).
Webster, H. de F., Cell Biol., 48, 348–367 (1971).
Webster, H. de F., Martin, J. R., and O'Connell, M. F., Devl Biol., 32, 401–416 (1973).
Rumpelt, H. J., Langer, K. H., Scharer, K., Straub, E., and Thoenes, W., Virchows Arch. A. Path. Anat. Histol., 364, 225–233 (1974).
Ashworth, C. T., Stembridge, V. A., and Luibel, F. J., Acta Cytologica, 5, 369–384 (1961).
Frei, J. V., J. Cell Biol., 15, 335–342 (1962).
Frithiof, L., Acta Oto-Laryngol., 73, 323–334 (1972).
Rodrigo, F. G., Br. J. Derm., 86, 348–355 (1972).
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MADRID, R., JAROS, E., CULLEN, M. et al. Genetically determined defect of Schwann cell basement membrane in dystrophic mouse. Nature 257, 319–321 (1975). https://doi.org/10.1038/257319a0
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DOI: https://doi.org/10.1038/257319a0
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