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2 results

  • 28 - Transplantation of Schwann cells and olfactory ensheathing cells to promote regeneration in the CNS

  • from Section B3 - Promotion of regeneration in the injured nervous system
    • By Mary Bartlett Bunge, The Miami Project to Cure Paralysis, University of Miami Miller School of Medicine, Miami, FL, USA, Patrick M. Wood, The Miami Project to Cure Paralysis, University of Miami Miller School of Medicine, Miami, FL, USA
  • Edited by Michael Selzer, University of Pennsylvania, Stephanie Clarke, Université de Lausanne, Switzerland, Leonardo Cohen, National Institute of Mental Health, Bethesda, Maryland, Pamela Duncan, University of Florida, Fred Gage, Salk Institute for Biological Studies, San Diego
  • Book:
    Textbook of Neural Repair and Rehabilitation
    Published online:
    05 March 2012
    Print publication:
    16 February 2006, pp 513-531

  • Summary

    This chapter provides an overview of the efficacy of Schwann cell (SC) and olfactory ensheathing cell (OEC) transplantation to repair the central nervous system (CNS). Remyelination of CNS axons by SCs has been observed in many studies of experimentally induced and naturally occurring pathologic processes. Axons are remyelinated by either endogenous SCs that have migrated into the demyelinated site or by transplanted SCs. Restoration of conduction properties has been studied following remyelination by transplanted SCs. Using the microtransplantation technique to minimize disturbance of the tract architecture, cultured SCs placed into either the cervical corticospinal or ascending dorsal column tracts cause sprouting of both types of axons. A combination strategy involved the transplantation of OECs into the stumps beside the SC bridge after complete transaction. Although OECs do not normally form myelin in the olfactory system, numerous studies have demonstrated that SC-like myelin is produced following the transplantation of OECs.

  • The neurofilament antibody RT97 recognises a developmentally regulated phosphorylation epitope on microtubule-associated protein 1B

  • MANDY JOHNSTONE, ROBERT G. GOOLD, ITZHAK FISCHER, PHILLIP R. GORDON-WEEKS
  • Journal:
    The Journal of Anatomy / Volume 191 / Issue 2 / August 1997
    Published online by Cambridge University Press:
    01 August 1997, pp. 229-244
    Print publication:
    August 1997

  • Microtubules are important for the growth and maintenance of stable neuronal processes and their organisation is controlled partly by microtubule-associated proteins (MAPs). MAP 1B is the first MAP to be expressed in neurons and plays an important role in neurite outgrowth. MAP 1B is phosphorylated at multiple sites and it is believed that the function of the protein is regulated by its phosphorylation state. We have shown that the monoclonal antibody (mAb) RT97, which recognises phosphorylated epitopes on neurofilament proteins, fetal tau, and on Alzheimer's paired helical filament-tau, also recognises a developmentally regulated phosphorylation epitope on MAP 1B. In the rat cerebellum, Western blot analysis shows that mAb RT97 recognises the upper band of the MAP 1B doublet and that the amount of this epitope peaks very early postnatally and decreases with increasing age so that it is absent in the adult, despite the continued expression of MAP 1B in the adult. We confirmed that mAb RT97 binds to MAP 1B by showing that it recognises MAP 1B immunoprecipitated from postnatal rat cerebellum using polyclonal antibodies to recombinant MAP 1B proteins. We established that the RT97 epitope on MAP 1B is phosphorylated by showing that antibody binding was abolished by alkaline phosphatase treatment of immunoblots. Epitope mapping experiments suggest that the mAb RT97 site on MAP 1B is near the N-terminus of the molecule. Despite our immunoblotting data, immunostaining of sections of postnatal rat cerebellum with mAb RT97 shows a staining pattern typical of neurofilaments with no apparent staining of MAP 1B. For instance, basket cell axons and axons in the granule cell layer and white matter stained, whereas parallel fibres did not. These results suggest that the MAP 1B epitope is masked or lost under the immunocytochemical conditions in which the cerebellar sections are prepared. The upper band of the MAP 1B doublet is believed to be predominantly phosphorylated by proline-directed protein kinases (PDPKs). PDPKs are also good candidates for phosphorylating neurofilament proteins and tau and therefore we postulate that the sites recognised by RT97 on these neuronal cytoskeletal proteins may be phosphorylated by similar kinases. Important goals are to determine the precise location of the RT97 epitope on MAP 1B and the kinase responsible.