Modification of Schwann cell gene expression by electroporation in vivo

Clinical outcomes of nerve grafting are often inferior to those of end-to-end nerve repair. This may be due, in part, to the routine use of cutaneous nerve to support motor axon regeneration. In previous work, we have demonstrated that Schwann cells express distinct sensory and motor phenotypes, and that these promote regeneration in a modality-specific fashion. Intra-operative modification of graft Schwann cell phenotype might therefore improve clinical outcomes. This paper demonstrates the feasibility of electroporating genes into intact nerve to modify Schwann cell gene expression. Initial trials established 70 V, 5 ms as optimum electroporation parameters. Intact, denervated, and reinnervated rat tibial nerves were electroporated with the YFP gene and evaluated serially by counting S-100 positive cells that expressed YFP. In intact nerve, a mean of 28% of Schwann cells expressed the gene at 3 days, falling to 20% at 7 days with little expression at later times. There were no significant differences among the three groups at each time period. Electronmicroscopic evaluation of treated, intact nerve revealed only occasional demyelination and axon degeneration. Intra-operative electroporation of nerve graft is thus a practical means of altering Schwann cell gene expression without the risks inherent in viral transfection.     

The collapsin response mediator protein 5 onconeural protein is expressed in Schwann cells under axonal signals and regulates axon-Schwann cell interactions

Collapsin response mediator protein 5 (CRMP5) is one of the rare peripheral nerve antigens that is a target of autoantibodies in a paraneoplastic peripheral neuropathy. The pattern of axonal and myelin alterations suggests that CRMP5 is involved in axon-Schwann cell interaction. We examined CRMP5 expression and function in primary cultures of Schwann cells and neurons and at various developmental and regenerating stages of rat sciatic nerve and in CRMP5-deficient mice in vivo. Collapsin response mediator protein 5 was strongly expressed during postnatal development and regeneration and decreased with myelination. It was mainly expressed by immature Schwann cells and persisted in Remak cells in the adult; however, a subpopulation of Schwann cells that were induced to myelinate also expressed CRMP5. We identified 2 axonal molecular cues regulating CRMP5 expression: human neuregulin type 1, which induces CRMP5 expression in immature and premyelinating Schwann cells, and cyclic adenosine monophosphate, which inhibits CRMP5 expression when Schwann cells begin myelination. Collapsin response mediator protein 5-deficient mice showed abnormal Schwann process extension resulting in abnormal cell-axon segregation, indicating that CRMP5 is involved in the morphologic adaptation of Schwann cells to surround axons. These results demonstrate the importance of CRMP5 in axon-Schwann cell cooperation during development and regeneration.     

Chronically denervated rat schwann cells respond to GGF in vitro

C-erbB receptor/neuregulin signalling plays a significant role in Schwann cell function. In vivo, Schwann cells up-regulate expression of c-erbB receptors in the first month after injury, but receptor expression is down-regulated with time to levels that are not detectable immunohistochemically. The inability of chronically denervated Schwann cells to respond adequately to signals derived from regenerating axons may be one reason why delayed repair of an injured peripheral nerve frequently fails. We have examined the effects of GGF on denervated Schwann cells in vitro. A modified delayed dissociation technique was used to obtain adult rat Schwann cells from the distal stumps of transected sciatic nerves which had been acutely (7 days) or chronically (2–6 month) denervated. We found that in vitro denervated Schwann cells invariably expressed p75^NTR and c-erbB receptors. There was a progressive decrease in total cell yield and the percentage of cells with Schwann cell phenotype (p75^NTR and/S-100 or/laminin or /GFAP or/c-erbB positive); proliferation rate; migratory potential; and expression of the cell adhesion molecules N-CAM and N-cadherin, with increasing time of denervation. Addition of GGF2 had a significant stimulatory effect upon Schwann cell proliferation and migration, and an increased proportion of Schwann cells expressed N-CAM and N-cadherin, suggesting that these responses were mediated via GGF/c-erbB signalling. Our results support the view that it may be possible to manipulate chronically denervated Schwann cells so that they become more responsive to signals derived from regrowing axons. GLIA 24:290–303, 1998. © 1998 Wiley-Liss, Inc.     

Comparison of Schwann cell and sciatic nerve transcriptomes indicates that mouse is a valid model for the human peripheral nervous system

High-throughput gene expression analyses of murine models of the peripheral nervous system (PNS), and its cellular components, have yielded enormous amounts of expression data of the PNS in various conditions. These data provided clues for future research directions to further decipher this complex organ in relation to acquired and inherited PNS diseases. Various studies addressing the validity of mouse models for human conditions in other tissues and cell types have indicated that in many cases the mouse model only poorly represents the human situation. To determine how well the mouse can serve as model to study the biological processes occurring in the PNS, we compared the gene expression profiles that we generated for mouse and human sciatic nerve and cultured Schwann cells derived thereof. A two-way analysis based on the differentially expressed genes between the sciatic nerve and the cultured Schwann cell, and which takes into account the differential expression between mouse and man, indicates that the human PNS is well represented by that of the mouse in terms of the "biological processes" ontology.