Degeneration and regeneration of some mechanoreceptors. An ultrastructural study. IV. Ultrastructure of reinnervated Pacinian corpuscles

The first signs of reinnervation of the Pacinian corpuscles have been established at the middle of the second month after nerve crush. The regenerative process pass through two periods. During the first period the progressive increase of the Schwann receptor cells has been observed parallel to the reduction of the regenerating nerve branches. During the second period the reorganization and renewal of the regenerated organelles takes place. Some organelles as dense core vesicles, coated vesicles and microtubules of the receptor nerve fibre show noticeable dynamics. The regeneration has been established only in the preexisting after denervation capsulated remnants of the receptors. After nerve transection the regeneration is prolonged one month later and the less of quantity reinnervated receptors have been observed.     

Leukemia Inhibitory Factor Is an Autocrine Survival Factor for Schwann Cells

Abstract: Schwann cells play a major role in promoting nerve survival and regeneration after injury. Their activities include providing neurotrophic factors and increasing the production of extracellular matrix components and cell surface adhesion molecules to promote axon regeneration. Following nerve transection, leukemia inhibitory factor (LIF) is up-regulated by Schwann cells at the injury site. LIF receptors are also up-regulated at the nerve injury site, but their cellular localization and function have not been fully characterized. We demonstrate that Schwann cells express mRNAs for LIF and the LIF receptor components LIF receptor subunit β and glycoprotein 130 in vitro. We also show that although LIF is not required for the genesis of Schwann cells, it can potentiate the survival of differentiated Schwann cells in the context of neuregulin support. Not only does exogenous LIF promote survival under these conditions, but addition of the soluble LIF receptor (LIF binding protein) and anti-LIF antibodies significantly reduced cell survival, suggesting that LIF exerts autocrine effects. These results suggest that Schwann cell survival following nerve injury is potentially modulated by LIF.     

Study of regeneration in the garfish olfactory nerve

Previous studies of the olfactory nerve, mainly in higher vertebrates, have indicated that axonal injury causes total degeneration of the mature neurons, followed by replacement of new neuronal cells arising from undifferentiated mucosal cells. A similar regeneration process was confirmed in the garfish olfactory system. Regeneration of the nerve, crushed 1.5 cm from the cell bodies, is found to produce three distinct populations of regenerating fibers. The first traverses the crush site 1 wk postoperative and progresses along the nerve at a rate of 5.8 +/- 0.3 mm/d for the leading fibers of the group. The second group of fibers traverses the crush site after 2 wk postcrush and advances at a rate of 2.1 +/- 0.1 mm/d for the leading fibers. The rate of growth of this group of fibers remains constant for 60 d but subsequently falls to 1.6 +/- 0.2 for the leading population of fibers. The leading fibers in the third group of regenerating axons traverse the crush site after 4 wk and advance at a constant rate of 0.8 +/- 0.2 mm/d. The multiple populations of regenerating fibers with differing rates of growth are discussed in the context of precursor cell maturity at the time of nerve injury and possible conditioning effects of the lesion upon these cells. Electron microscopy indicates that the number of axons decreases extensively after crush. The first two phases of regenerating axons represent a total of between 6 and 10% of the original axonal population and are typically characterized by small fascicles of axons surrounded by Schwann cells and large amounts of collagenous material. The third phase of fibers represents between 50 and 70% of the original axonal population.     

Visualizing Peripheral Nerve Regeneration by Whole Mount Staining

Peripheral nerve trauma triggers a well characterised sequence of events both proximal and distal to the site of injury. Axons distal to the injury degenerate, Schwann cells convert to a repair supportive phenotype and macrophages enter the nerve to clear myelin and axonal debris. Following these events, axons must regrow through the distal part of the nerve, re-innervate and finally are re-myelinated by Schwann cells. For nerve crush injuries (axonotmesis), in which the integrity of the nerve is maintained, repair may be relatively effective whereas for nerve transection (neurotmesis) repair will likely be very poor as few axons may be able to cross between the two parts of the severed nerve, across the newly generated nerve bridge, to enter the distal stump and regenerate. Analysing axon growth and the cell-cell interactions that occur following both nerve crush and cut injuries has largely been carried out by staining sections of nerve tissue, but this has the obvious disadvantage that it is not possible to follow the paths of regenerating axons in three dimensions within the nerve trunk or nerve bridge. To try and solve this problem, we describe the development and use of a novel whole mount staining protocol that allows the analysis of axonal regeneration, Schwann cell-axon interaction and re-vascularisation of the repairing nerve following nerve cut and crush injuries.     

Changes of nerve growth factor synthesis in nonneuronal cells in response to sciatic nerve transection

The intact sciatic nerve contains levels of nerve growth factor (NGF) that are comparable to those of densely innervated peripheral target tissues of NGF-responsive (sympathetic and sensory) neurons. There, the high NGF levels are reflected by correspondingly high mRNANGF levels. In the intact sciatic nerve, mRNANGF levels were very low, thus indicating that the contribution of locally synthesized NGF by nonneuronal cells is small. However, after transection an increase of up to 15-fold in mRNANGF was measured in 4-mm segments collected both proximally and distally to the transection site. Distally to the transection site, augmented mRNANGF levels occurred in all three 4-mm segments from 6 h to 2 wk after transection, the longest time period investigated. The augmented local NGF synthesis after transection was accompanied by a reexpression of NGF receptors by Schwann cells (NGF receptors normally disappear shortly after birth). Proximal to the transection site, the augmented NGF synthesis was restricted to the very end of the nerve stump that acts as a "substitute target organ" for the regenerating NGF-responsive nerve fibers. While the mRNANGF levels in the nerve stump correspond to those of a densely innervated peripheral organ, the volume is too small to fully replace the lacking supply from the periphery. This is reflected by the fact that in the more proximal part of the transected sciatic nerve, where mRNANGF remained unchanged, the NGF levels reached only 40% of control values. In situ hybridization experiments demonstrated that after transection all nonneuronal cells express mRNANGF and not only those ensheathing the nerve fibers of NGF-responsive neurons.     

Terminal Schwann cells guide the reinnervation of muscle after nerve injury

Schwann cells and axons labeled by transgene-encoded, fluorescent proteins can be repeatedly imaged in living mice to observe the reinnervation of neuromuscular junctions. Axons typically return to denervated junctions by growing along Schwann cells contained in the old nerve sheaths or “Schwann cell tubes”. These axons then commonly “escape” the synaptic sites by growing along the Schwann cell processes extended during the period of denervation. These “escaped fibers” grow to innervate adjacent synaptic sites along Schwann cells bridging these sites. Within the synaptic site, Schwann cells, originally positioned above the synaptic site continue to cover the acetylcholine receptors (AChRs) immediately following denervation, but gradually vacate portions of this site. When regenerating axons return, they first deploy along the Schwann cells and ignore sites of AChRs vacated by Schwann cells. In many cases these vacated sites are never reinnervated and are ultimately lost. Following partial denervation, Schwann cells grow in an apparently tropic fashion from denervated to nearby innervated synaptic sites and serve as the substrates for nerve sprouting. These experiments show that Schwann cells provide pathways that stimulate axon growth and insure the rapid reinnervation of denervated or partially denervated muscles.     

Nerve Regeneration and Cholesterol Reutilization Occur in the Absence of Apolipoproteins E and A-I in Mice

Abstract: Apolipoproteins have been implicated in the salvage and reutilization of myelin cholesterol during Wallerian degeneration and the subsequent nerve regeneration. Current evidence suggests that myelin cholesterol complexes with apolipoproteins E and A-I to form lipoproteins that are taken up via low-density lipoprotein receptors on myelinating Schwann cells. We recently reported, however, that apolipoprotein E is not required for nerve regeneration or reutilization of myelin cholesterol. We have now investigated nerve regeneration and the reutilization of cholesterol in mutant mice deficient in both apolipoproteins E and A-I. Morphologic examination of nerves 4 and 12 weeks after crush injury revealed that regeneration proceeded at a normal rate in the absence of these apolipoproteins. Autoradiography of regenerating nerves indicated that prelabeled myelin lipid was reutilized in the regenerating myelin. 3-Hydroxy-3-methylglutaryl-CoA reductase, the rate-limiting enzyme in cholesterol synthesis, was down-regulated in the regenerating nerves, indicative of cholesterol uptake via lipoproteins. Prelabeled myelin cholesterol was present in lipoprotein fractions isolated from crushed nerves of mutant mice. These data suggest that there is considerable redundancy in the process of cholesterol reutilization within nerve, and that apolipoproteins other than apolipoproteins E and A-I may be involved in the recycling of myelin cholesterol.     

Evidence for a systemic regulation of neurotrophin synthesis in response to peripheral nerve injury

Up-regulation of neurotrophin synthesis is an important mechanism of peripheral nerve regeneration after injury. Neurotrophin expression is regulated by a complex series of events including cell interactions and multiple molecular stimuli. We have studied neurotrophin synthesis at 2?weeks time-point in a transvertebral model of unilateral or bilateral transection of sciatic nerve in rats. We have found that unilateral sciatic nerve transection results in the elevation of nerve growth factor (NGF) and NT-3, but not glial cell-line derived neurotrophic factor or brain-derived neural factor, in the uninjured nerve on the contralateral side, commonly considered as a control. Bilateral transection further increased NGF but not other neurotrophins in the nerve segment distal to the transection site, as compared to the unilateral injury. To further investigate the distinct role of NGF in regeneration and its potential for peripheral nerve repair, we transduced isogeneic Schwann cells with NGF-encoding lentivirus and transplanted the over-expressing cells into the distal segment of a transected nerve. Axonal regeneration was studied at 2?weeks time-point using pan-neuronal marker NF-200 and found to directly correlate with NGF levels in the regenerating nerve.     

Cholesterol Synthesis Is Down-Regulated During Regeneration of Peripheral Nerve

Abstract: The discovery of apolipoprotein E synthesis and secretion by injured peripheral nerve led to the hypothesis that endoneurial apolipoprotein E serves to salvage degenerating myelin cholesterol. This salvaged cholesterol could then be reutilized by Schwann cells during remyelination via uptake through low-density lipoprotein receptors. As a test of this hypothesis, we measured the rate of cholesterol synthesis in rat sciatic nerve endoneurium during development and at various times following a crush injury at 50 days of age. In control nerves [¹⁴C]acetate incorporation into cholesterol and 3-hydroxy-3-methylglutaryl-CoA reductase activity were closely linked throughout development, indicating that reductase activity in nerve, as in other tissues, is a good indicator of cholesterol's synthetic rate. In the crushed nerves cholesterol synthesis fell to nearly zero during the first week after the crush. There was a partial recovery during the second to fourth weeks, but unlike that of other lipids, cholesterol synthesis remained well below control nerve values throughout most of the 15-week post-crush period examined. Thus, cholesterol synthesis is at very low levels during the myelination of regenerating axons. These results are consistent with a receptor-mediated down-regulation of cholesterol synthesis by lipoproteins, and would be expected if Schwann cells were utilizing an external source of cholesterol as postulated above.     

Temporary colonization of the site of lesion by macrophages is a prelude to the arrival of regenerated axons in injured goldfish optic nerve

Summary. In crushed goldfish optic nerve, regenerating axons cross the site of lesion within 10 days following injury. Some 30 days later, Schwann cells accumulate at the lesion, where they myelinate the new axons. In this study, we have used immunohistochemistry and electron microscopy to examine the cellular environment of the crush site prior to the establishment of Schwann cells in order to learn more about the early events that contribute to axonal regeneration. During the first week following injury, macrophages enter the site of lesion and efficiently phagocytose the debris. The infiltration of macrophages precedes the arrival of regenerating axons that abut and surround these phagocytes. Based on EM morphology and phagocytic capacity, macrophages of the type observed at the site of lesion are not present in the degenerating distal nerve segment, where debris clearance is shared between conventional microglia and astrocytes over a period of several weeks. During this period, axon bundles emerging distally from the injury zone become enwrapped by astrocyte processes, thereby re-establishing the characteristic fascicular cytoarchitecture of the optic nerve. The process of fasciculation also leads to the displacement of myelin debris to the margins of the fiber bundles, where it is trapped by the astrocytes. Our results suggest that the early robust appearance of macrophages at the lesion, and their effectiveness as phagocytes compared with the microglia distally, may contribute to the vigorous axonal regeneration across the crush, beyond which axons<197>excepting the pioneers<197>extend through newly formed debris-free channels delineated by astrocyte processes.     

Basic Fibroblast Growth Factor Promotes Extension of Regenerating Axons of Peripheral Nerve. In Vivo Experiments Using a Schwann Cell Basal Lamina Tube Model

Schwann cell basal lamina tubes serve as attractive conduits for regeneration of peripheral nerve axons. In the present study, by using basal lamina tubes prepared by in situ freeze-treatment of rat saphenous nerve, the effects of exogenously applied basic fibroblast growth (bFGF) on peripheral nerve regeneration was examined 2 and 5 days after bFGF administration. Regenerating axons were observed by light and electron microscopy using PG9.5-immunohistochemistry for specific staining of axons. In addition, the localizations of bFGF and its receptor (FGF receptor-1) were examined by immunohistochemistry using anti-bFGF antibody and anti-FGF receptor-1 antibody, respectively. Regenerating axons extended further in the bFGF-administered segment than the bFGF-untreated control segment. Electron microscopy showed that regenerating axons grew out unaccompanied by Schwann cells. Findings concerning angiogenesis and Schwann cell migration were very similar between the bFGF treated and control nerve segment. bFGF-immunoreactivity was not detected in the control nerve segment. In contrast, bFGF-immunoreactivity was detected on the basal lamina tubes as well as on the plasmalemma of regenerating axons facing the basal lamina in the bFGF treated nerve segment up to 5 days after administration, suggesting that exogenous bFGF can be retained in the basal lamina for several days after administration. FGF receptor was detected on the plasma membrane of regenerating axons where they abutted the basal lamina. These results indicate that bFGF could promote the extension of early regenerating axons by directly influencing the axons, but not via Schwann cells or angiogenesis.     

Profile of adult rat sensory neuron loss, apoptosis and replacement after sciatic nerve crush

Following permanent transection of the adult rat sciatic nerve, sensory neuron apoptosis in the contributing L4 and L5 dorsal root ganglia can be observed for at least 6 months afterwards. To establish the profile of any sensory neuron apoptosis and loss over time when axonal regeneration is allowed, serial sections of L4 and L5 ganglia were examined and the neurons counted using a stereological technique 1, 2 and 3 months after crushing the right sciatic nerve at mid-thigh level. Our results show that an identical degree of sensory neuron loss and apoptosis occurs 1 month after crush as at 1 month after permanent transection. However, at 3 months no neurons undergoing apoptosis could be observed and no significant loss could be detected in the ipsilateral ganglia when compared to unoperated controls. One explanation was a neuronal replacement mechanism, which was investigated by administering bromodeoxyuridine to rats for 1 month after sciatic nerve transection or crush, prior to detection using immunohistochemistry on sections of their ganglia after 2 months. The presence of bromodeoxyuridine in the nuclei of occasional cells that would be counted as neurons on the basis of size and morphology indicates that a process of apparent neurogenesis may underlie the profile of sensory neuron loss after axotomy.     

Axonal Regeneration after Sciatic Nerve Lesion Is Delayed but Complete in GFAP- and Vimentin-Deficient Mice

Peripheral axotomy of motoneurons triggers Wallerian degeneration of injured axons distal to the lesion, followed by axon regeneration. Centrally, axotomy induces loss of synapses (synaptic stripping) from the surface of lesioned motoneurons in the spinal cord. At the lesion site, reactive Schwann cells provide trophic support and guidance for outgrowing axons. The mechanisms of synaptic stripping remain elusive, but reactive astrocytes and microglia appear to be important in this process. We studied axonal regeneration and synaptic stripping of motoneurons after a sciatic nerve lesion in mice lacking the intermediate filament (nanofilament) proteins glial fibrillary acidic protein (GFAP) and vimentin, which are upregulated in reactive astrocytes and Schwann cells. Seven days after sciatic nerve transection, ultrastructural analysis of synaptic density on the somata of injured motoneurons revealed more remaining boutons covering injured somata in GFAP^–/–Vim^–/– mice. After sciatic nerve crush in GFAP^–/–Vim^–/– mice, the fraction of reinnervated motor endplates on muscle fibers of the gastrocnemius muscle was reduced 13 days after the injury, and axonal regeneration and functional recovery were delayed but complete. Thus, the absence of GFAP and vimentin in glial cells does not seem to affect the outcome after peripheral motoneuron injury but may have an important effect on the response dynamics.     

Time Course and Characteristics of the Capacity of Sensory Nerves to Reinnervate Skin Territories outside Their Normal Innervation Zones

Factors involved in the outcome of regeneration of the saphenous nerve after a cut or crush lesion were studied in adult rats with electrophysiological recordings of low-threshold mechanoreceptor activity and plasma extravasation of Evans blue after electrical nerve stimulation that activated C fibers.

In the first series of experiments, saphenous and sciatic nerve section was combined with anastomosis of the transected proximal end of the saphenous nerve to the distal end of the cut tibial nerve. Regeneration of saphenous nerve fibers involved in plasma extravasation and low-threshold mechanoreceptor activity in the glabrous skin was observed 13 weeks after nerve anastomosis. Substance P-, calcitonin gene-related peptide-, and protein gene product 9.5 (PGP-9.5)-immunoreactive (IR) thin epidermal and dermal nerve endings, as well as coarse dermal PGP-9.5-IR nerve fibers and Meissner corpuscles and Merkel cell-neurite-like complexes, were observed in the reinnervated glabrous skin at this time.

In a second series of experiments, the time course of the regeneration of saphenous nerve axons to the permanently sciatic-nerve-denervated foot sole was examined. Saphenous-nerve-induced plasma extravasation and low-threshold mechanoreceptor activity in the saphenous nerve were found in the normal saphenous nerve territory 2, 3, 4, and 6 weeks after sciatic nerve cut combined with saphenous nerve crush in the left hindlimb. Saphenous-nerve-induced plasma extravasation was also present in the glabrous skin normally innervated by the sciatic nerve 3, 4, and 6 weeks after the sciatic cut/saphenous crush lesion. However, no low-threshold mechanoreceptor activity was detected in the saphenous nerve when the glabrous skin area was stimulated.

In a third series of experiments, the fate of the expansion of the saphenous nerve territory after saphenous nerve crush was examined when the crushed sciatic nerve had been allowed to regenerate. Nerve fibers involved in plasma extravasation were observed in the glabrous skin of the hindpaw after saphenous nerve, as well as after tibial nerve, C-fiber stimulation 3, 12, and 43 weeks after the saphenous crush/sciatic crush lesion.

Low-threshold mechanoreceptors from the regenerated saphenous nerve, which primarily innervates hairy skin, seem to be functional in the glabrous skin if the axons are guided by the transected tibial nerve by anastomosis. Furthermore, the results indicate that fibers from the regenerating saphenous nerve that have extended into denervated glabrous skin areas can exist even if sciatic nerve axons are allowed to grow back to their original territory.     

Polysialyltransferase overexpression in Schwann cells mediates different effects during peripheral nerve regeneration

The polysialic acid (PSA) moiety of the neural cell adhesion molecule (NCAM) has been shown to support dynamic changes underlying peripheral nerve regeneration. Using transgenic mice expressing polysialyltransferase ST8SiaIV under control of a glial-specific (proteolipid protein, PLP) promoter (PLP-ST8SiaIV-transgenic mice), we tested the hypothesis that permanent synthesis of PSA in Schwann cells impairs functional recovery of lesioned peripheral nerves. After sciatic nerve crush, histomorphometric analyses demonstrated impaired remyelination of regenerated axons at the lesion site and in target tissue of PLP-ST8SiaIV-transgenic mice, though the number and size of regenerating unmyelinated axons were not changed. This was accompanied by slower mechanosensory recovery in PLP-ST8SiaIV-transgenic mice. However, the proportion of successfully mono-(re)innervated motor endplates in the foot pad muscle was significantly increased in PLP-ST8SiaIV-transgenic mice when compared with wild-type littermates, suggesting that long-term increase in PSA levels in regenerating nerves may favor selective motor target reinnervation. The combined negative and positive effects of a continuous polysialyltransferase overexpression observed during peripheral nerve regeneration suggest that an optimized time- and differentiation-dependent control of polysialyltransferase expression in Schwann cells may further improve recovery after peripheral nerves injury.     

Cholesterol Synthesis in Regenerating Peripheral Nerve Is Not Influenced by Serum Cholesterol Levels

Abstract: Following a nerve crush, cholesterol from degenerating myelin is retained within the nerve and reutilized for new myelin synthesis during nerve regeneration, apparently via a lipoprotein-mediated process. Because at least some serum components have access to the endoneurium of injured nerve, it has been suggested that serum lipoproteins are also significant contributors of cholesterol to Schwann cells during nerve regeneration. To test this hypothesis, serum cholesterol levels were reduced by >90% with 4-aminopyrazolopyrimidine, followed by measurement of the activity of the key regulatory enzyme in cholesterol synthesis, 3-hydroxy-3-methylglutaryl-CoA reductase. Treatment with 4-aminopyrazolopyrimidine caused a sevenfold increase in 3-hydroxy-3-methylglutaryl-CoA reductase activity in kidney but had no effect on the activity of this enzyme in either intact or regenerating sciatic nerve. These data indicate that serum-derived cholesterol is neither necessary for nor contributes significantly to myelin synthesis in regenerating nerve.     

Faster nerve regeneration after sciatic nerve injury in mice over-expressing basic fibroblast growth factor

Basic fibroblast growth factor (FGF-2) is expressed in the peripheral nervous system and is up-regulated after nerve lesion. It has been demonstrated that administration of FGF-2 protects neurons from injury-induced cell death and promotes axonal regrowth. Using transgenic mice over-expressing FGF-2 (TgFGF-2), we addressed the importance of endogenously generated FGF-2 on sensory neuron loss and sciatic nerve regeneration. After sciatic nerve transection, wild-type and transgenic mice showed the same degree of cell death in L5 spinal ganglia. Also, the number of chromatolytic, eccentric, and pyknotic sensory neurons was not changed under elevated levels of FGF-2. Morphometric evaluation of intact nerves from TgFGF-2 mice revealed no difference in number and size of myelinated fibers compared to wild-type mice. One week after crush injury, the number of regenerated axons was doubled and the myelin thickness was significantly smaller in transgenic mice. After 2 and 4 weeks, morphometric analysis and functional tests revealed no differences in recovery of sensory and motor nerve fibers. To study the role of FGF-2 over-expression on Schwann cell proliferation during the early regeneration process, we used BrdU-labeling to mark dividing cells. In transgenic mice, the number of proliferating cells was significantly increased distal to the crush site compared to wild-types. We propose that endogenously synthesized FGF-2 influences early peripheral nerve regeneration by regulating Schwann cell proliferation, axonal regrowth, and remyelination.     

Molecular approaches to nerve regeneration.

Current research into regeneration of the nervous system has focused on defining the molecular events that occur during regeneration. One well-characterized system for studying nerve regeneration is the sciatic nerve of rat. Numerous studies have characterized the sequence of events that occur after a crush injury to the sciatic nerve (Cajal 1928; Hall 1989). These events include axon and myelin breakdown, changes in the permeability of the blood vessels, proliferation of Schwann cells, invasion of macrophages, and the phagocytosis of myelin fragments by Schwann cells and macrophages. The distal segment of the injured sciatic nerve provides a supportive environment for the regeneration of the nerve fibres (Cajal 1928; David & Aguayo 1981). Within a period of weeks, the injured sciatic nerve is able to regrow and successfully reinnervate the appropriate targets. Some of the molecules that provide trophic support for the regrowing nerve fibres have been identified, including nerve growth factor (NGF) (Heumann et al. 1987) and glial maturation factor beta (Bosch et al. 1989). Another class of molecules show changes in their rates of synthesis during regeneration, including both proteins (Skene & Shooter 1983; Muller et al. 1986) and mRNA species (Trapp et al. 1988; Meier et al. 1989). To better understand nerve regeneration, we have taken two, parallel molecular approaches to study the events associated with regeneration. The first of these is to study in detail the mechanism of action of a molecule that has been implicated in the regeneration process, nerve growth factor. The second approach is to identify novel gene sequences which are regulated during regeneration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Glial and Neuronal Marker Proteins in the Silicone Chamber Model for Nerve Regeneration

Abstract: In the present study, neuronal and Schwann cell marker proteins were used to biochemically characterize the spatiotemporal progress of degeneration/regeneration in the silicone chamber model for nerve regeneration. Rat sciatic nerves were transected and the proximal and distal stumps were inserted into a bridging silicone chamber with a 10-mm interstump gap. Using dot immunobinding assays, S-100 protein and neuronal intermediate filament polypeptides were measured in different parts of the nerve 0–30 days after transaction. In the most proximal nerve segment, all the measured proteins were transiently increased. In the proximal and distal stumps adjacent to the transection, the studied proteins were decreased indicating degeneration of the nerve. Within the silicone chamber, the regenerating nerve expressed the Schwann cell S-100 protein already at 7 days, whereas the neurofilament polypeptides appeared later. These observations are corroborated by previous morphological studies. The biochemical method described provides a new and fast approach to the study of nerve regeneration.     

Temporal-Spatial Expressions of Spy1 in Rat Sciatic Nerve After Crush

As a novel cell cycle protein, Spy1 enhances cell proliferation, promotes the G1/S transition as well as inhibits apoptosis in response to UV irradiation. Spy1 levels are tightly regulated during mammary development, and overexpression of Spy1 accelerates tumorigenesis in vivo. But little is known about the role of Spy1 in the pathological process of damage and regeneration of the peripheral nervous system. Here we established a rat sciatic nerve crush (SNC) model to examine the spatiotemporal expression of Spy1. Spy1 expression was elevated gradually after sciatic nerve crush and peaked at day 3. The alteration was due to the increased expression of Spy1 in axons and Schwann cells after SNC. Spy1 expression correlated closely with Schwann cells proliferation in sciatic nerve post injury. Furthermore, Spy1 largely localized in axons in the crushed segment, but rarely co-localized with GAP43. These findings suggested that Spy1 participated in the pathological process response to sciatic nerve injury and may be associated with Schwann cells proliferation and axons regeneration.