Summary
The fibrinolytic activity of blood is caused by plasminogen activators (PA) converting plasminogen to plasmin, the active fibrinolytic protease. PA activity in rat neural tissues was studied by Todd's fibrin slide technique. Cryostat sections overlayed with a film of plasminogen and fibrin were incubated for 60–90 min. PA activity was related to the size of the zone of fibrinolysis surrounding the sections. No lysis occurred with fibrin alone. In rats perfused with saline prior to decapitation the size of the zone of lysis was approximately the same as in non-perfused animals. PA activity was compared in the following tissues: adult (2–3 month) cerebellum and 6–14-day postnatal cerebellum; normal sciatic nerve and transected sciatic nerve 1–9 weeks after operation (in these experiments the sciatic nerve was crushed on the left side, on the right side it was transected and the stumps were tightly ligated to prevent regeneration); normal optic nerves and optic nerves undergoing Wallerian degeneration 1–2 weeks after enucleation of the eye. As compared to normal cerebellum PA activity was increased in 6–14-day cerebellum. PA activity was also markedly increased in both crushed and ligated sciatic nerves 1–4 weeks after operation while no differences were observed between normal sciatic nerves and sciatic nerves 9 weeks after ligation. The zone of fibrinolysis surrounding normal optic nerves and the optic nerves of blinded rats was approximately the same. It is proposed that the fibrinolytic system may be relevant to the problem of CNS regeneration.
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References
Aguayo AJ, Dickson R, Trecarten J, Attiwell M, Bray GM, Richardson P (1978) Ensheathment and myelination of regenerating PNS fibers by transplanted optic nerve glia. Neurosci Lett 9:97–104
Bignami A, Chi NH, Dahl D (1981) Centrally cut axons regenerate in peripheral nerve implanted in murine brain. Immunofluorescence study with neurofilament and GFA antisera. In: Gorio A, Millesi H, Mingrino S (eds) Posttraumatic peripheral nerve regeneration. Experimental basis and clinical implication. Raven Press, New York, pp 397–402
Castellino FJ (1981) Recent advances in the chemistry of the fibrinolytic system. Chem Rev 81:431–446
Chi NH, Bignami A, Bich NT, Dahl D (1980) Autologous sciatic nerve grafts to the rat spinal cord: immunofluorescence studies with neurofilament and gliofilament (GFA) antisera. Exp Neurol 68:568–580
David S, Aguayo AJ (1981) Axonal elongation into peripheral nervous system “bridges” after central nervous system injury in adult rats. Science 214:931–933
Deutsch D, Mertz ET (1970) Plasminogen purification from human plasma by affinity chromatography. Science 170:1095–1096
Kao CC, Chang LW, Bloodworth JMB Jr (1977) Axonal regeneration across transected mammalian spinal cords: an electron microscopic study of delayed microsurgical nerve grafting. Exp Neurol 54:591–615
Krystosek A, Seeds NW (1981) Plasminogen activator secretion by granule neurons of developing cerebellum. Proc Natl Acad Sci USA 78:7810–7814
Lang WE (1981) Secretion of plasminogen activators by cultured bovine endothelial cells: partial purification, characterization and evidence for multiple forms. Thromb Haemost 45:219–224
Pandolfi M, Bjernstad A, Nisslen IM (1972) Technical remarks on the microscopical demonstration of tissue plasminogen activator. Thromb Diat Haemorrhag 27:88–98
Reich E (1978) Activation of plasminogen: a widespread mechanism for generating localized extracellular proteolysis. In: Ruddon RW (ed) Biological markers of neoplasia: basic and applied aspects. Elsevier North Holland, Amsterdam, pp 491–500
Richardson PM, McGuinness UM, Aguayo AJ (1981) Axons from CNS neurones regenerate into PNS grafts. Nature 284:264–265
Soreq H, Miskin R (1981) Plasminogen activator in brain. Brain Res 216:361–374
Todd A (1959) The histological localization of fibrinolysin activator. J Pathol 78:281–283
Valinsky JE, Reich E (1981) Plasminogen in chick embryo. Transport and biochemistry. J Biol Chem 256:12470–12475
Weinberg EL, Spencer PS (1979) Studies on the control of myelinogenesis. 3. Signalling of oligodendrocyte myelination by regenerating peripheral axons. Brain Res 162:273–279
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Bignami, A., Cella, G. & Chi, N.H. Plasminogen activators in rat neural tissues during development and in Wallerian degeneration. Acta Neuropathol 58, 224–228 (1982). https://doi.org/10.1007/BF00690805
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DOI: https://doi.org/10.1007/BF00690805