The role of Schwann cells and basal lamina tubes in the regeneration of axons through long lengths of freeze-killed nerve grafts

The ability of long acellular nerve grafts to support axonal regeneration was examined using inbred rats. Grafts (40 mm long) of tibial/plantar nerves were used either as live grafts or after freeze-drying to render the grafts acellular. The grafts were sutured to the proximal stump of severed tibial nerves in host animals which were then killed 1-12 weeks later. Axons rapidly regenerated through the living grafts but only extended 10-20 mm into the acellular grafts. This distance was achieved by 6 weeks and thereafter no significant further axonal extension occurred in the acellular grafts. A few naked axons lacking Schwann cell contact were identified in all acellular grafts, but became more numerous near the distal extent of axonal penetration into 6-12 week grafts. These axons contained large numbers of neurofilaments. When the distal 20 mm of 6 week acellular grafts (segments into which axons had not penetrated) were sutured to freshly severed tibial nerves, axons grew readily into the grafted tissue to a maximum distance of 9 mm. It is therefore likely that the limits to axonal regeneration through initially acellular grafts were set by factors intrinsic to the severed nerve. It is suggested that the limited migratory powers of Schwann cells may be one such factor. The concept that basal lamina tubes are not essential for axonal regeneration but may act as low resistance pathways for both axonal elongation and Schwann cell migration is discussed.     

Nerve Regeneration in Predegenerated Basal Lamina Graft: The Effect of Duration of Predegeneration on Axonal Extension

We used predegenerated acellular grafts to bridge proximal and distal stumps of transected nerves and studied how the duration of predegeneration might affect axonal regeneration. Predegenerated acellular grafts were prepared by transecting the tibial nerve of donor rats and, after a period of degeneration, freeze-thawing a 40-mm long segment of the distal stump. Five degeneration periods were used: 0 days (for fresh grafts), 3 days, 1 week, 4 weeks, and 8 weeks. Fresh cellular grafts not treated with freeze-thawing were also used for comparison. Each graft was then transplanted to an isogeneic recipient rat, in which it was used to bridge the proximal stump of the transected left tibial nerve and the distal stamp of the transected right tibial nerve. Six weeks were allowed for the regeneration of axons in all grafts. The regeneration was then assessed by studying transverse sections of the grafts, to determine the maximum length that the axons had regenerated, and the packing density of axons (percentage of sampled areas occupied by axons). The results show that axons had grown to the maximum length in the 4-week predegenerated grafts, and had the highest packing density in the 1-week predegenerated grafts. Regeneration in the fresh acellular (0-day predegenerated) and 8-week predegenerated grafts, especially the latter, was poor. We examine the results with reference to time-dependent events of Wallerian degeneration and propose that there are beneficial effects of multiple factors on the grafts during the first 4 weeks of predegeneration, causing a slow but significant improvement in their capability to support axonal growth. The subsequent rapid deterioration of such capability may be related to structural changes in the extracellular scaffold.     

A double-transgenic mouse used to track migrating Schwann cells and regenerating axons following engraftment of injured nerves

We propose that double-transgenic thy1-CFP(23)/S100-GFP mice whose Schwann cells constitutively express green fluorescent protein (GFP) and axons express cyan fluorescent protein (CFP) can be used to serially evaluate the temporal relationship between nerve regeneration and Schwann cell migration through acellular nerve grafts. Thy1-CFP(23)/S100-GFP and S100-GFP mice received non-fluorescing cold preserved nerve allografts from immunologically disparate donors. In vivo fluorescent imaging of these grafts was then performed at multiple points. The transected sciatic nerve was reconstructed with a 1-cm nerve allograft harvested from a Balb-C mouse and acellularized via 7 weeks of cold preservation prior to transplantation. The presence of regenerated axons and migrating Schwann cells was confirmed with confocal and electron microscopy on fixed tissue. Schwann cells migrated into the acellular graft (163+/-15 intensity units) from both proximal and distal stumps, and bridged the whole graft within 10 days (388+/-107 intensity units in the central 4-6 mm segment). Nerve regeneration lagged behind Schwann cell migration with 5 or 6 axons imaged traversing the proximal 4 mm of the graft under confocal microcopy within 10 days, and up to 21 labeled axons crossing the distal coaptation site by 15 days. Corroborative electron and light microscopy 5 mm into the graft demonstrated relatively narrow diameter myelinated (431+/-31) and unmyelinated (64+/-9) axons by 28 but not 10 days. Live imaging of the double-transgenic thy1-CFP(23)/S100-GFP murine line enabled serial assessment of Schwann cell-axonal relationships in traumatic nerve injuries reconstructed with acellular nerve allografts.     

The influence of cultured Schwann cells on regeneration through acellular basal lamina grafts

Acellular basal lamina grafts have been shown to be less immunogenic in comparison to cellular grafts, but possess a limited potential for supporting axonal regeneration through them. The present study describes the effect of cultured Schwann cells on enhancing regeneration through acellular grafts. 2 cm long acellular grafts, and in vitro Schwann cell populated acellular grafts were used to repair a surgically created gap in the host peroneal nerve. The transplants were analyzed at 1, 2, 4 and 8 weeks to determine their ability to support axonal regeneration. Host axonal regeneration through Schwann cell cocultured acellular grafts occurred rapidly and was significantly better as compared to non-cultured acellular grafts. The results demonstrate a beneficial effect of Schwann cell culture pretreatment on regeneration through acellular grafts and an improved recovery of the target muscle. The procedure of first preparing acellular grafts with subsequent coculture with Schwann cells offers a novel approach for the repair of injured nervous tissue.     

Neurite-promoting influences of proliferating Schwann cells and target-tissues are not prerequisite for rapid axonal elongation after nerve crush

An important role in peripheral nerve regeneration has been ascribed to humoral trophic and tropic agents arising from the nonneuronal cells in the distal nerve stump and the denervated targets. In order to estimate their contribution to axonal elongation after crush injury to the rat sciatic nerve, an in vivo model was designed in which local cellular and target-derived influences were eliminated by 1) freeze-thawing of a long nerve segment distal to the crush site and 2) cutting the nerve far distally to the crush site, but within the frozen-thawed segment, and deflecting the frozen-thawed nerve stump in the opposite direction from its natural course. The sensory and motor axon elongation rate was estimated from the results of the nerve pinch test and choline acetyltransferase distribution along the nerve segment distal to the crush. The elongation rate of regenerating axons in deflected nerve segments, either non-treated or frozen-thawed, was close in magnitude to that obtained when target-derived influences were not eliminated. Neurotropism of axonal targets is therefore of little importance for axon elongation after nerve crush. In the absence of Schwann cells along the axonal path in frozen-thawed nerve segments, the elongation rate of both sensory and motor axons declined by about 40%. This implies that interactions between viable Schwann cells and growth cones of regenerating axons are not prerequisite for rapid axon elongation when Schwann cell basal lamina constitutes the growth substratum. Nevertheless, Schwann cells in Bungner bands possibly enhance the axon elongation rate by humoral or cell surface-mediated mechanisms.     

Long-term endoneurial changes after nerve transection

Summary Long-term endoneurial changes in the distal stump of transected rat sciatic nerve were examined from 8 to 50 weeks after nerve transection. The morphological alterations were followed both in nerves which were allowed to regenerate and in nerves in which regeneration was prevented by suturing. The nerves prevented from regenerating showed markedly atrophied Schwann cell columns after 20 weeks and a disappearance of some Schwann cell columns after 30 weeks. The surrounding endoneurial fibroblast-like cells gradually lost their delicate cytoplasmic extensions and formed rough fascicles around numerous shrunken Schwann cell columns or around areas from which Schwann cells had apparently disappeared. Inside the fascicles, the Schwann cell loss was replaced by collagen fibrils or occasionally, by a dense accumulation of microfibrils. The loss of endoneurial cytoplasmic processes continued up to 50 weeks, leaving behind patches of thin fibrils around numerous shrunken Schwann cell columns or around collagenous areas where Schwann cells were lost. The endoneurial matrix showed presence of thin 25- to 30-nm collagen fibrils close to shrunken Schwann cell columns up to 50 weeks but in areas with advanced degeneration a shift towards regular 50- to 60-nm collagen fibrils occurred. The degenerated areas resembled those described in Renaut bodies and neurofibromas. Despite suturing of transected nerves to prevent sprouting, occasional regenerating sprouts were noted in the Schwann cell columns. These axons were surrounded in a sheath-like fashion by pre-existing endoneurial cell fascicles covered by a basal lamina. In the reinnervating nerves the endoneurial space gradually lost its compartmentized structures consisting of collagen fibrils and endoneurial fibroblast-like cells. After 20 weeks the endoneurial cells were inconspicuous and the extracelluar matrix consisted mainly of 50- to 60-nm collagen fibrils. During axonal growth and maturation, Schwann cells containing unmyelinated axons surrounded large, myelinated axons in a collar-like fashion. Close to these collars of Schwann cells, thin 25- to 30-nm collagen fibrils were noted in focal areas, even after 50 weeks. Occasionally, numerous clusters of regenerating axonal sprouts were noted in the perineurium. These were surrounded by multiple layers of cells possessing basal lamina. The present results show that after nerve transection the distal stump of the severed nerve shows dynamic changes in the endoneurial space, especially in nerves where reinnervation is prevented. The endoneurial fascicles around occasional axonal sprouts in sutured nerves, representing possibly a delayed type of regeneration, show that axons have a strong ability to grow but on the other hand endoneurial structures are unable to respond normally to axonal growth after advanced degeneration.     

Basic Behavior of Migratory Schwann Cells in Peripheral Nerve Regeneration

In axonal regeneration after a peripheral nerve injury, Schwann cells migrate from the two nerve ends and at last form a continuous tissue cable across the gap which guides the axons toward the bands of Büngner. However, the behavior of migratory Schwann cells and their possible role are obscure. Using a film model in which the proximal stump of a transected nerve in mice was sandwiched between two thin plastic films, we analyzed neural regeneration in the early phase up to the 6th day after axotomy. Regenerating neurites emerged from the nodes of Ranvier adjacent to the axotomized nerve stump within 3 h after axotomy and extended along the parent nerve onto the film. All of the regenerating neurites on the surface of the film consisted of naked axons for at least 2 days after axotomy. Thereafter, Schwann cells from the proximal nerve migrated along a network of the regenerating axons and then closely attached to the axons, ensheathing them. Some of the Schwann cells advanced ahead of the axonal growth cones and were distributed over regions in which axonal extension was not yet present. As calculated from the time course of regenerating neurites, the velocity of axonal regeneration showed two phases: an initial slow phase (77 μm/day) up to the 2nd post-operative day followed by a faster phase (283 μm/day). The first observation of Schwann cells coincided with the onset of the second phase. In addition, the length of regenerating axons on the surface of the film containing many Schwann cells was significantly greater than that on the surface where Schwann cells were not yet present. It meant that migratory Schwann cells stimulated axons to elongate for a longer distance. Furthermore, Schwann cells from a distal stump showed a stronger ability to accelerate the axonal outgrowth than these from a proximal stump.     

Optic axons regenerate into sciatic nerve isografts only in the presence of Schwann cells

Optic axons regenerate into normal but not acellular peripheral nerve (PN) grafts. The first axons penetrate the PN graft before 5 days and grow inside the basal lamina tubes amongst the Schwann cells. By 30 days, 4% of the surviving retinal ganglion cells (RGC) regenerate axons for at least 10 mm into the PN graft. Laminin rich basal lamina tubes persist in the acellular PN transplants but only a few axons penetrate the most proximal parts of the tubes by 5 days and none grow farther into the graft by 30 days. RGC counts demonstrate that 34% of the normal RGC population survive 30 days after anastomosing a normal PN to the transected optic nerve. After anastomosing acellular PN grafts, 25% of RGCs survive compared with 10% after optic nerve section. These findings demonstrate that laminin does not promote regeneration of axons and that Schwann cells play the primary role of offering trophic support and even a substrate for growth. RGC survival is also enhanced by PN grafts even when Schwann cells are absent. This latter result suggests that RGC survival is promoted by a trophic substance released from axons and/or Schwann cells in the PN grafts which survives the thawing/freezing procedure (used to kill the Schwann cells) and is active in the grafts in the immediate post operative period.     

The role of Schwann cells in the regeneration of peripheral nerve axons through muscle basal lamina grafts

Evacuated muscle is a possible substitute for nerve autografts in the repair of damaged peripheral nerves. Previous experiments have shown that killed or evacuated muscle grafts are as effective as nerve autografts for bridging gaps of up to 4 cm between proximal and distal nerve stumps. Evacuated muscle grafts are made of extracellular matrix components, which are good substrates for axon growth in vitro. However, experiments in vivo have generally demonstrated that live Schwann cells are essential for successful axon regeneration. In the present experiments we have used immunohistochemical techniques with anti-S100 and anti-neurofilament antibodies to visualize axon growth and Schwann cell migration into muscle grafts over the first 10 days following grafting. We only saw axons growing into grafts accompanied by Schwann cells, and most though not all Schwann cells were associated with axons. Schwann cell migration from the proximal stump in association with axons was much faster and more extensive than from the distal stump. We examined muscle grafts over the first 20 days after grafting by electron microscopy. Regenerating axons were always associated with Schwann cells, which were mostly in the basal lamina-lined tubes left by the evacuated myofibrils. A comparison between evacuated muscle grafts and grafts in which the muscle had been killed but not evacuated revealed that 7 days after grafting there were more than twice as many regenerated axons in and distal to the evacuated grafts, but that by 20 days the numbers of axons were similar in the two groups.     

Are Schwann cells essential for axonal regeneration into muscle autografts?

When axons regenerate through frozen–thawed (FT) muscle grafts, they are accompanied by co–migrating Schwann cells derived from the nerve stumps. Although acellular, FT muscle grafts contain an internal scaffold of basal laminae rich in components capable of supporting neurite outgrowth in vitro such as laminin and fibronectin: it is not known whether Schwann cells are essential for axonal regrowth within these grafts. In this paper we test the hypothesis that sarcolemmal basal laminae will support axonal regeneration in the absence of Schwann cells. Two groups of 12 adult Wistar rats were used. All rats received a 0.5 cm FT muscle graft, and 12 rats also received a subperineurial injection of the anti–mi to tic agent mitomycin C (400 μg/ml in physiological saline) prior to grafting. Previous studies have shown that this dose effectively depresses cell proliferation within the endoneurium for 3–4 weeks [17, 18, 28]. Rats were killed ( n = 3) 1, 2, 3 or 4 weeks later. The spatio–temporal sequence of axonal regeneration into the grafts was assessed histologically, by immunofluorescence using antibodies against GAP–43; S–100; RT97; laminin and macrophages (EDI), and by transmission electron microscopy. Outgrowth of almost all axons from the mitomycin C–treated proximal stumps was delayed for up to 3 weeks, after which time vigorous regeneration occurred into the persisting tubes of sarcolemmal basal lamina. All axons regenerating within the grafts (irrespective of mitomycin C–treatment) were accompanied by co–migrating Schwann cells. The results suggest that Schwann cells play an important role in axonal regeneration across FT muscle autografts and that sarcolemmal basal laminae alone are insufficient to support axonal regeneration.     

THE EFFECT OF INHIBITING SCHWANN CELL MITOSIS ON THE RE-INNERVATION OF ACELLULAR AUTOGRAFTS IN THE PERIPHERAL NERVOUS SYSTEM OF THE MOUSE

Reactive gliosis in the zone immediately proximal to transection of the sciatic nerve has been inhibited by intraneural injection of mitomycin C, an anti-mitotic agent known to arrest Schwann cell division after transection, crush or demyelination. Mitomycin C-pretreated proximal stumps were subsequently sutured to cellular or acellular autografts (0.5 cm long) and neurite growth into and within the grafts was examined during a 5-week post-operative period. Neurites grew into cellular autografts and became associated with the resident population of Schwann cells within the grafts, to the extent that remyelination was well established in the majority of Schwann cell basal lamina tubes by week 5 post-suture. In marked contrast, very few neurites grew into acellular grafts during this time, and where axons and Schwann cells were seen they tended to be grouped in 'minifascicles'. The results suggest that neurite outgrowth from proximal stumps is dependent upon active Schwann cell participation.     

Comparison of different biogenic matrices seeded with cultured Schwann cells for bridging peripheral nerve defects

Tissue-engineering as laboratory based alternative to human autografts and allografts provides "custom made organs" cultured from patient's material. To overcome the limited donor nerve availability different biologic nerve grafts were engineered in a rat sciatic nerve model: cultured isogenic Schwann cells were implanted into acellular autologous matrices: veins, muscles, nerves, and epineurium tubes. Autologous nerve grafts, and the respective biogenic material without Schwann cells served as control. After 6 weeks regeneration was assessed clinically, histologically and morphometrically. The PCR analysis showed that the implanted Schwann cells remain within all the grafts. A good regeneration was noted in the muscle-Schwann cell-group, while regeneration quality in the other groups (with or without Schwann cells) was impaired. The muscle-Schwann cell graft showed a systematic and organized regeneration including a proper orientation of regenerated fibers. All venous and epineurium grafts had a more disorganized regeneration. Seemingly, the lack of endoneural tube like structures in vein grafts lead to impaired regeneration. And, apparently, the beneficial effects of implanted Schwann cells into a large luminal structure can only be demonstrated to a limited extent if endoneural like structures are lacking. A tube offers less area for Schwann cell adhesion and it is more likely to collapse. This underlines the role of the basal lamina, or at least an inner structure acting as scaffold in axonal regeneration. Although the conventional nerve graft remains the gold standard, the implantation of Schwann cells into an acellular muscle provides a biogenic graft with basal lamina tubes as pathway for regenerating axons and the positive effects of Schwann cells producing neurotrophic and neurotropic factors, and thus, supporting axonal regeneration.     

Schwann cell basal lamina and nerve regeneration

Nerve segments approximately 7 mm long were excised from the predegenerated sciatic nerves of mice, and treated 5 times by repetitive freezing and thawing to kill the Schwann cells. Such treated nerve segments were grafted into the original places so as to be in contact with the proximal stumps. The animals were sacrificed 1, 2, 3, 5, 7 and 10 days after the grafting. The grafts were examined by electron microscopy in the middle part of the graft, i.e. 3-4 mm distal to the proximal end and/or near the proximal and distal ends of the graft. In other instances, the predegenerated nerve segments were minced with a razor blade after repetitive freezing and thawing. Such minced nerves were placed in contact with the proximal stumps of the same nerves. The animals were sacrificed 10 days after the grafting. Within 1-2 days after grafting, the dead Schwann cells had disintegrated into fragments. They were then gradually phagocytosed by macrophages. The basal laminae of Schwann cells, which were not attacked by macrophages, remained as empty tubes (basal lamina scaffolds). In the grafts we examined, no Schwann cells survived the freezing and thawing process. The regenerating axons always grew out through such basal lamina scaffolds, being in contact with the inner surface of the basal lamina (i.e. the side originally facing the Schwann cell plasma membrane). No axons were found outside of the scaffolds. One to two days after grafting, the regenerating axons were not associated with Schwann cells, but after 5-7 days they were accompanied by Schwann cells which were presumed to be migrating along axons from the proximal stumps. Ten days after grafting, proliferating Schwann cells observed in the middle part of the grafts had begun to sort out axons. In the grafts of minced nerves, the fragmented basal laminae of the Schwann cells re-arranged themselves into thicker strands or small aggregations of basal laminae. The regenerating axons, without exception, attached to one side of such modified basal laminae. Collagen fibrils were in contact with the other side, indicating that these modified basal laminae had the same polarity in terms of cell attachment as seen in the ordinary basal laminae of the scaffolds.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparison of different biogenic matrices seeded with cultured Schwann cells for bridging peripheral nerve defects

Abstract

Tissue-engineering as laboratory based alternative to human autografts and allografts provides "custom made organs" cultured from patient's material. To overcome the limited donor nerve availability different biologic nerve grafts were engineered in a rat sciatic nerve model: cultured isogenic Schwann cells were implanted into acellular autologous matrices: veins, muscles, nerves, and epineurium tubes. Autologous nerve grafts, and the respective biogenic material without Schwann cells served as control. After 6 weeks regeneration was assessed clinically, histologically and morphometrically. The PCR analysis showed that the implanted Schwann cells remain within all the grafts. A good regeneration was noted in the muscle-Schwann cell-group, while regeneration quality in the other groups (with or without Schwann cells) was impaired. The muscle-Schwann cell graft showed a systematic and organized regeneration including a proper orientation of regenerated fibers. All venous and epineurium grafts had a more disorganized regeneration. Seemingly, the lack of endoneural tube like structures in vein grafts lead to impaired regeneration. And, apparently,the beneficial effects of implanted Schwann cells into a large luminal structure can only be demonstrated to a limited extent if endoneural like structures are lacking. A tube offers less area for Schwann cell adhesion and it is more likely to collapse. This underlines the role of the basal lamina, or at least an inner structure acting as scaffold in axonal regeneration. Although the conventional nerve graft remains the gold standard, the implantation of Schwann cells into an acellular muscle provides a biogenic graft with basal lamina tubes as pathway for regenerating axons and the positive effects of Schwann cells producing neurotrophic and neurotropic factors, and thus, supporting axonal regeneration.     

Laminin molecules in freeze-treated nerve segments are associated with migrating Schwann cells that display the corresponding alpha6beta1 integrin receptor

Isolated acellular nerve segments protected from migration of Schwann cells and the acellular nerve segments joined with the distal nerve stumps were prepared by a repeated freeze-thaw procedure in the rat sciatic nerves. The presence of laminin-1 and -2, as well as alpha6 and beta1 integrin chains, was detected by indirect immunohistochemistry in the sections through acellular nerve segments at 7 and 14 days after cryotreatment. The position of basal laminae and Schwann cells was identified by immunostaining for collagen IV and S-100 protein, respectively. The isolated cryo-treated segment without living Schwann cells (S-100-) did not display immunoreactivity for laminins and integrin chains, while the basal lamina position was verified through the whole segment by immunostaining for collagen IV. The absence of immunostaining for laminin-1 and -2 in cryo-treated nerve segment was verified by Western blot analysis. A crucial diminution of laminin-1 and -2 in the cryo-treated nerve segment of 10-mm length did not abolish the growth and maturation of axons. The greater part of nerve segment connected with the nerve stump displayed no immunohistochemical staining for S-100, corresponding with absence of Schwann cells. The border region of the nerve segment contained Schwann cells (S-100+) migrating from the near-freeze undamaged part of the distal nerve stump. In addition to immunostaining for S-100 protein, the migrating Schwann cells displayed immunostaining for laminins (-1, and -2) and integrin chains (alpha6 and beta1). The results indicate that the presence of laminin molecules in the acellular nerve segments prepared by the repeated freeze-thaw procedure is related with the migrating Schwann cells. The immunostaining for laminins and integrin chains, which constitute one of integrin receptor, suggests an autocrine and/or paracrine utilization of laminin molecules in the promotion of Schwann cell migration.     

Peripheral nerve regeneration through optic nerve grafts

Summary Grafts of optic nerve were placed end-toend with the proximal stumps of severed common peroneal nerves in inbred mice. It was found that fraying the proximal end of adult optic nerve grafts to disrupt the glia limitans increased their chances of being penetrated by regenerating peripheral nerve fibres. Suturing grafts to the proximal stump also enhanced their penetration by axons. The maximum distance to which the axons grew through the CNS tissue remained about 1.5 mm from 2–12 weeks after grafting. Schwann cells were seldom identified in the grafts. Varicose and degenerating nerve fibres were often seen within the grafts. Some varicose profiles were shown to be the terminal parts of axons within the grafts. Axons containing clusters of organelles resembling synaptic vesicles became more abundant in the longerterm grafts. Immunohistochemical studies performed on sutured grafts using a polyclonal antiserum to neurofilaments confirmed the impressions given by the electron microscopical observations. Grafts of neonatal optic nerve lacked myelin debris but were not usually penetrated by regenerating peripheral axons within a 6-week period. Sixty minutes after the intravenous injection of horseradish peroxidase, reaction product could be detected in the extracellular spaces around blood vessels in all types of living optic nerve graft. This indicates that blood-borne macromolecules could penetrate the grafts. However the profiles of axons which were found within living optic nerve grafts had no obvious relationship to blood vessels and were usually surrounded by astrocytic processes. These results suggest that living astrocytes, rather than the absence of serum-derived trophic factors or the presence of CNS myelin, constitute the major barrier to the extension of axons and the migration of Schwann cells into CNS tissue.Supported by a grant from the Wellcome Trust     

Multipotentiality of Schwann cells in cross-anastomosed and grafted myelinated and unmyelinated nerves: quantitative microscopy and radioautography.

Cross-anastomoses and autogenous grafts of unmyelinated and myelinated nerves were examined by electron microscopy and radioautography to determine if Schwann cells are multipotential with regard to their capacity to produce myelin or to assume the configuration seen in unmyelinated fibres. Two groups of adult white mice were studied. (A) In one group, the myelinated phrenic nerve and the unmyelinated cervical sympathetic trunk (CST) were cross-anastomosed in the neck. From 2 to 6 months after anastomosis, previously unmyelinated distal stumps contained many myelinated fibres while phrenic nerves joined to proximal CSTs became largely unmyelinated. Radioautography of distal stumps indicated that proliferation of Schwann cells occurred mainly in the first few days after anastomosis but was also present to a similar extent in isolated stumps. (B) In other mice, CSTs were grafted to the myelinated sural nerves in the leg. One month later, the unmyelinated CSTs became myelinated and there was no radioautographic indication of Schwann cell migration from the sural nerve stump to the CST grafts. Thus, Schwann cell proliferation in distal stumps is an early local response independent of axonal influence. At later stages, axons from the proximal stumps cause indigenous Schwann cells in distal stumps from the previously unmyelinated nerves to produce myelin while Schwann cells from the previously unmyelinated nerves to produce myelin while Schwann cells from the previously myelinated nerves become associated with unmyelinated fibres. Consequently, the regenerated distal nerve resembled the proximal stump. It is suggested that this change is possible because Schwann cells which divide after nerve injury reacquire the developmental multipotentiality which permits them to respond to aoxonal influences.     

Effects of short- and long-term Schwann cell denervation on peripheral nerve regeneration, myelination, and size

Poor functional recovery after peripheral nerve injury has been generally attributed to inability of denervated muscles to accept reinnervation and recover from denervation atrophy. However, deterioration of the Schwann cell environment may play a more vital role. This study was undertaken to evaluate the effects of chronic denervation on the capacity of Schwann cells in the distal nerve stump to support axonal regeneration and to remyelinate regenerated axons. We used a delayed cross-suture anastomosis technique in which the common peroneal (CP) nerve in the rat was denervated for 0-24 weeks before cross-suture of the freshly axotomized tibial (TIB) and chronically denervated CP nerve stumps. Motor neurons were backlabeled with either fluoro-ruby or fluorogold 12 months later, to identify and count TIB motor neurons that regenerated axons into chronically denervated CP nerve stumps. Number, size, and myelination of regenerated sensory and motor axons were determined using light and electron microscopy. We found that short-term denervation of < or =4 weeks did not affect axonal regeneration but more prolonged denervation profoundly reduced the numbers of backlabeled motor neurons and axons in the distal nerve stump. Yet, atrophic Schwann cells retained their capacity to remyelinate regenerated axons. In fact, the axons were larger and well myelinated by long-term chronically denervated Schwann cells. These findings demonstrate a progressive inability of chronically denervated Schwann cells to support axonal regeneration and yet a sustained capacity to remyelinate the axons which do regenerate. Thus, axonal interaction can effectively switch the nonmyelinating phenotype of atrophic Schwann cells back into the myelinating phenotype.     

Molecular basis of interactions between regenerating adult rat thalamic axons and Schwann cells in peripheral nerve grafts II. Tenascin-C

Tenascin-C is a developmentally regulated extracellular matrix component. There is evidence that it may be involved in axon growth and regeneration in peripheral nerves. We have used in situ hybridization and immunocytochemistry to investigate the association of tenascin-C with central nervous system axons regenerating through a peripheral nerve autograft inserted into the thalamus of adult rats. Between 3 days and 4 weeks after implantation, tenascin-C immunoreactivity was increased in the grafts, first at the graft/brain interface, then in the endoneurium of the graft, and finally within the Schwann cell columns of the graft. By electron microscopy, reaction product was present around collagen fibrils and basal laminae in the endoneurium, but the heaviest deposits were found at the surface of regenerating thalamic axons within Schwann cell columns. Schwann cell surfaces were not associated with tenascin-C reaction product except where they faced the tenascin-rich basal lamina or were immediately opposite axons surrounded by tenascin-C. By 8 weeks after graft implantation tenascin-C in the endoneurium and around axons of the graft was decreased. In the brain parenchyma aroundthe proximal part of the graft, axonal sprouts associated with tenascin-C could not be identified earlier than 2 weeks after grafting and were sparse at this stage. Larger numbers of such axons were present at 8–13 weeks after grafting and were located predominantly where the glia limitans between brain and graft appeared to be incomplete, suggesting that the tenascin-C may have penetrated the brain parenchyma from the graft. By in situ hybridization, cells expressing tenascin-C mRNA (probably Schwann cells) appeared first at the brain/graft interface 3 days after grafting and thereafter were mainly located within the grafts. Lightly labelled cells containing tenascin-C mRNA (probably glial cells) were scattered in the thalamic parenchyma both ipsilateral and contralateral to the graft and a few heavily labelled cells were located very close to the tip of the graft. These results show that regenerating adult thalamic axons, unlike regenerating peripheral axons, become intimately associated with peripheral nerve graft-derived tenascin-C, suggesting that they express a tenascin-C receptor, as many neurons do during development, and that tenascin-C derived from Schwann cells may play a role in the regenerative growth of such axons through the grafts. © 1995 Wiley-Liss, Inc.     

The role of laminin, a component of Schwann cell basal lamina, in rat sciatic nerve regeneration within antiserum-treated nerve grafts

Regeneration of the sciatic nerve in transplanted nerve grafts in which laminin was inactivated was examined electron microscopically. Nerve grafts for transplantation were obtained from close cloned donor Wistar rats; 1-cm nerve segments of the sciatic nerve were frozen and thawed to kill the Schwann cells. Control recipient rats received grafts treated with normal rabbit serum to repair the artificially-made complete defect of the right sciatic nerve, and the experimental group of rats received grafts doubly treated with normal serum and rabbit anti-laminin antiserum. In the control grafts regenerating axons grew almost completely through the inside of the basal lamina scaffolds (92%) and adhered to the structure, while in the anti-laminin antiserum treated grafts the axons were present outside (52%) and inside (48%) the scaffolds simultaneously. In this case, the adhesion of axons to the scaffolds was obscure. Axons were associated with and without Schwann cells both inside and outside the basal lamina scaffolds. No unassociated Schwann cells were observed. The maximal number of axons in a 2 mm portion of the antiserum-treated grafts was approximately 250 axons per 100 × 100 μm square and 520 in the control at 15 days. At 30 days, almost the same number of axons was found at the distal (8 mm) portion of both groups. The growth in the former was delayed for 3 days. These results indicate that regenerating peripheral nerve axons may enter the basal lamina scaffolds and grow well because of the neurotrophic function of laminin present at the inner side of Schwann cell basal lamina.