The influence of fibronectin and laminin during Schwann cell migration and peripheral nerve regeneration through silicon chambers

Embryonic fibronectins are up-regulated following peripheral nerve injury in rats

Fibronectin mRNAs that include the alternatively spliced exons EIIIA, EIIIB, and V are prevalent during embryogenesis, and EIIIA and EIIIB reappear during wound healing. Using ribonuclease protection analyses, we found an up-regulation of V120 (containing the alpha 4 beta 1 integrin binding site), as well as EIIIA, and EIIIB in fibronectin mRNAs in the crush-injured adult rat sciatic nerve. In situ hybridization using splice variant-specific probes revealed that cells within endoneurial tubes of the injured nerve synthesize these embryonic forms of fibronectin. Our results suggest that embryonic fibronectins synthesized within the nerve contribute to the permissiveness of the peripheral nervous system to axon regrowth and a mechanism by which alternative splicing of the V region in fibronectin mRNA could enhance nervous system regeneration.

Cryo-immunogold ultrastructural localization of laminin in adult rat peripheral nerve

Elucidation of the functional roles of the extracellular matrix component laminin in adult peripheral nerve has been hindered by differing accounts of its ultrastructural localization. This is the first report applying the advantages of the cryo-immunogold technique to laminin localization in peripheral nerve. Laminin labelling was found over the basal lamina and possibly over the immediately subjacent Schwann cell plasma membrane, but specific labelling appeared to be absent from other membranes (including those of non-myelinated axon/Schwann cell clusters) and from endoneurial collagen fibrils. It would appear that the functional roles played by laminin in normal adult peripheral nerve are likely to be mediated via its localization in the basal lamina, rather than through a more widespread distribution within the endoneurium.

Polyclonal antibodies against NCAM and tenascin delay endplate reinnervation

Experiments were performed to block molecules with antibodies which are upregulated in nerve and muscle following denervation. The delay in endplate reinnervation was taken as a measure for their involvement in regeneration. Gluteus maximus muscles of 86 male CBA/J mice were hemidenervated by freezing the caudal gluteal nerve at a defined position. The degree of reinnervation was evaluated in identified endplates by repeated vital staining of ACh receptors with rhodaminated alpha-bungarotoxin and of axons with 4Di-2ASP. Normally, endplates were completely reinnervated by 13-14 days (108 endplates in seven muscles). After daily application of polyclonal antibodies against NCAM or tenascin, reinnervation was significantly delayed. Preimmune serum, rabbit immunoglobulins or saline did not show this effect. Several monoclonal antibodies against NCAM (H-28) and tenascin (576, 578, 630, 633) showed a tendency but no significant effect. It is concluded that both NCAM and tenascin, upregulated after denervation, are involved in axon guidance and/or endplate reinnervation.

Effects of nerve segment supernatants on cultured Schwann cell proliferation and laminin production

Mouse sciatic nerves were transected and 3 hr to 16 days later proximal segments were removed and homogenized. Supernatants of these segments or of normal sciatic nerves were added to Schwann cells maintained in Dulbecco's modified Eagle's medium (DMEM) + 15% fetal calf serum (FCS). After 6 days, Schwann cells were solubilized and the protein content was measured using a Bio-Rad (Melville, NY) protein assay. Samples containing the same amounts of protein were then applied to microtiter plates and the laminin content was determined by enzyme-linked immunosorbent assay (ELISA). Lysates of cultures treated with 24 hr proximal segment supernatants contained significantly higher levels of laminin than those prepared from other intervals, from distal segments, or from control nerves. Increased surface and cytoplasmic anti-laminin immunoreactivity also was found in Schwann cells treated with 24 hr supernatants. To identify the source(s) of this effect, proximal segments removed 24 hr after transection were bisected; supernatants were prepared from each half and tested. Significant increases in laminin production were produced by supernatants from both halves. When supernatants from proximal and distal halves were compared, the latter produced significantly higher laminin levels. Electron microscopic examination of both halves showed that distal halves contained sprouting neurites and growth cones ensheathed by Schwann cells which had a basal lamina and resembled those seen during development and regeneration. Proximal halves appeared normal. Schwann cell proliferation also was compared in supernatant-treated cultures by using a bromodeoxy-uridine (BrdU) ELISA. The 24 hr and 2 day supernatants increased Schwann cell proliferation significantly; 12 hr, 4 day, and 8 day supernatants produced smaller increases. Our observations suggest that axons undergoing early regenerative changes are one of several possible sources of substance(s) in our proximal segment supernatants which increased Schwann cell proliferation and laminin production.

Nerve growth factor and its low-affinity receptor promote Schwann cell migration

Migrating Schwann cells in developing or regenerating peripheral nerves are known to express dramatically increased levels of nerve growth factor (NGF) and the low-affinity NGF receptor (LNGFR). Schwann cells do not express detectable pp140trk, the NGF-activated receptor tyrosine kinase which is essential for neuronal responses to NGF. The temporal correlation observed in Schwann cells between migration and the enhanced expression of NGF and LNGFR suggests that NGF and LNGFR may promote Schwann cell migration. To test this possibility, we examined the effects of NGF on Schwann cell migration on cryostat sections of biologically relevant NGF-poor and NGF-rich substrates--normal or denervated peripheral (sciatic) nerve, untreated or pretreated with NGF. Results show that Schwann cells migrate more rapidly on denervated than on normal sciatic nerve. Antibodies to NGF or to LNGFR strongly, but incompletely, inhibit enhanced migration on denervated nerves. Pretreatment of denervated nerve sections with NGF increases further the rate of Schwann cell migration. The same antibodies to NGF or to LNGFR abolish this response. These results suggest that one function of the elevated levels of NGF known to be present in embryonic and regenerating peripheral nerves is to promote the migration of Schwann cells. In contrast to neurons, where pp140trk appears to be the functionally critical NGF receptor, NGF responses in Schwann cells depend on LNGFR.