Axotomy-induced alterations in the synthesis and transport of neurofilaments and microtubules in dorsal root ganglion cells

Changes in the synthesis and axonal transport of neurofilament (NF) proteins and tubulin were examined after various selective axotomies of adult rat DRG cells. For axonal transport studies, DRGs were labeled by microinjection of 35S-methionine 14 d after axonal injuries, and nerves were retrieved 7 or 14 d after labeling. Slowly transported proteins were examined by quantitative PAGE/fluorography. After distal peripheral nerve crush (50-55 mm from the DRG), the cytoskeleton that entered undamaged regions of peripheral branch DRG axons by slow axonal transport differed from normal, while the cytoskeleton that entered dorsal root axons did not. Specifically, smaller-than-normal ratios of labeled NF protein/tubulin were transported in peripheral DRG axons after distal peripheral nerve crush. This change was almost entirely due to a selective decrease in the output of labeled NF proteins rather than to an increase in the amount of tubulin transported with NF proteins. Since the efficiency of axonal regeneration is known to be lower after cut injury than after nerve crush, we compared the effect of cut versus crush axotomy of peripheral DRG axons on cytoskeletal protein output. A more substantial reduction in the labeled NF/tubulin transport resulted in peripheral DRG axons if the distal sciatic nerve was cut rather than crushed but, even under these axotomy conditions, the labeled NF/tubulin ratios in dorsal root axons were not reduced. Peripheral cut axotomy did result in a lag in the advance of the labeling peak of the NF/microtubule protein wave in dorsal root axons, suggesting either that these proteins were delayed in exiting the cell body or that a slowing of the rate of their transport occurred. Pulse-labeling DRGs in vitro using 35S-methionine, and analysis of labeled proteins by 2-dimensional PAGE-fluorography demonstrated that the incorporation of radioactivity into NF proteins was significantly reduced, while the labeling of tubulins was unchanged 14 d after distal peripheral axotomy. In contrast to the results of peripheral axotomy, dorsal root crushes made close to the DRG (2-3 mm) or considerably distal (at the CNS entry zone 28-30 mm from the DRG) did not produce detectable changes in the amount of labeled NF or tubulin transport in central or peripheral branch axons. These findings indicate that the down-regulation of NF production/output that is exhibited at 14 d after peripheral branch axotomy is not present after central branch injury.(ABSTRACT TRUNCATED AT 400 WORDS)     

Synthesis of myelin proteins and ultrastructural investigations in regenerating rat sciatic nerve

Myelin protein synthesis, as well as ultrastructural and morphometric changes in regenerating peripheral nerve, was studied. Sciatic nerves of rats were crushed unilaterally; sham-operated nerves of the contralateral side served as controls. For the in vivo experiments, rats were killed at selected periods after the nerves were crushed (30, 60, 90, and 120 days); seven days prior to killing, the animals were injected intravenously with L-[4,5-3H]leucine. For the in vitro experiments, proximal and distal segments of sciatic nerve and equivalent sham-operated nerves were labeled with 3H-amino acid mixture 90 days after axotomy. Purified myelin was isolated from nerve segments; specific radioactivity and gel electrophoretic patterns of proteins were analyzed. Cross-sectional electron microscope (EM) preparations of proximal, distal, and contralateral segments of nerves also were examined. Results showed that the incorporation of labeled amino acids into total myelin proteins was enhanced significantly in the distal segment of sciatic nerves at all of the periods of regeneration studied. The yield of myelin protein per mm distal nerve segment increased as regeneration proceeded. The remyelination of fibers early after nerve crush was weak, whereas it gradually attained the normal range 90-120 days after axotomy. Morphometric analysis of myelin sheath thickness of regenerating axons was consistent with the data obtained for myelin protein synthesis.     

Diisopropyl phosphorofluoridate (DFP) treatment alters calcium-activated proteinase activity and cytoskeletal proteins of the hen sciatic nerve

Diisopropyl phosphorofluoridate (DFP) produces delayed neurotoxicity (OPIDN) in hens that is characterized by peripheral and central axonal degeneration. DFP administration resulted in mCANP activity inhibition in sciatic nerve and significant decrease in total NF-H, phosphorylated NF-H, vimentin, GFAP, tubulin, and tau. The degradation of cytoskeletal proteins even in the presence of decreased CANP activity may be ascribed to the release of intracellular Ca²⁺, elevation of other proteinase activity, or modification of cytoskeletal proteins resulting in their increased susceptibility in OPIDN.     

Improved sciatic nerve regeneration by local thyroid hormone treatment in adult rat is accompanied by increased expression of SCG10

Thyroid hormone plays an important role in regulating the development and regeneration of the nervous system. Our previous work showed that local administration of triiodothyronine (T3) at the level of transected rat sciatic nerve increased the number and diameter of regenerated axons, but the mechanism underlying the improved regeneration is still unclear. Here, we have investigated the effect of T3 on the expression of SCG10, a regulator of microtubule dynamics in growth cones. After transection of adult rat sciatic nerves, silicone tubes were implanted and filled with T3 or phosphate-buffered solution. At various time points following surgery, the expression of SCG10 protein and mRNA was analyzed. Semi-quantitative Western blot analysis revealed that sciatic nerve transection induced a more than 20-fold upregulation of SCG10 protein in proximal nerve segments at 1 day post-lesion, while at this time point, SCG10 mRNA in dorsal root ganglion neurons was not increased yet. The increase in SCG10 protein and mRNA could be observed over 30 days. Local T3 treatment significantly enhanced the increase in SCG10 protein levels about two-fold in the different segments of transected nerve during the regeneration period. Also SCG10 mRNA levels in lumbar ganglia were enhanced. Immunohistochemical analysis showed that T3 treatment not only increased the number of SCG10 positive axons but also the intensity of their staining. These results suggest that SCG10 is involved in the regulation of regeneration. The stimulating effect of T3 on SCG10 expression could provide a mechanism by which T3 enhances peripheral nerve regeneration.     

A decline in glial cell-line-derived neurotrophic factor expression is associated with impaired regeneration after long-term Schwann cell denervation.

In the peripheral nervous system, regeneration of motor and sensory axons into chronically denervated distal nerve segments is impaired compared to regeneration into acutely denervated nerves. In order to find possible causes for this phenomenon we examined the changes in the expression pattern of the glial cell-line-derived neurotrophic factor (GDNF) family of growth factors and their receptors in chronically denervated rat sciatic nerves as a function of time with or without regeneration. Among the GDNF family of growth factors, only GDNF mRNA expression was rapidly upregulated in Schwann cells as early as 48 h after denervation. This upregulation peaked at 1 week and then declined to minimal levels by 6 months of denervation. The changes in the protein expression paralleled the changes in the expression of the GDNF mRNA. The mRNAs for receptors GFRalpha-1 and GFRalpha-2 were upregulated only after maximal GDNF upregulation and remained elevated as late as 6 months. There were no significant changes in the expression of GFRalpha-3 or the tyrosine kinase coreceptor, RET. When we examined the expression of GDNF in a delayed regeneration paradigm, there was no upregulation in the distal chronically denervated tibial nerve even when the freshly axotomized peroneal branch of the sciatic nerve was sutured to the distal tibial nerve. This study suggests that one of the reasons for impaired regeneration into chronically denervated peripheral nerves may be the inability of Schwann cells to maintain important trophic support for both motor and sensory neurons.     

Acute treatment with pulsed electromagnetic fields and its effect on fast axonal transport in normal and regenerating nerve

The mechanism whereby low-frequency electromagnetic fields accelerate axonal regrowth and regeneration of peripheral nerve after crush lesion is not known. One candidate is an alteration in axonal transport. In this study we exposed unoperated rats for 15 min/day, and rats that had undergone a crush lesion of the sciatic nerve, for 1 hr/day for 2 days, to 2-Hz pulsed electromagnetic fields. To label fast transported proteins, [³H]-proline was microinjected into the spinal cord, and the sciatic nerves were removed 2, 3.5, and 5 hr later. The rates of fast axonal transport were obtained for animals in all groups by counting sequential 2-mm segments of nerves. The following transport rates were found: in unoperated normal sciatic nerve not exposed to PEMF, 373 ± 14 mm/day; in unoperated normal nerve exposed to PEMF, 383 ± 14 mm/day; in sham crush nerves not exposed to PEMF, 379 ± 19 mm/day; in sham crush nerve exposed to PEMF, 385 ± 17 mm/day; in crushed nerves not exposed to PEMF, 393 ± 16 mm/ day; and in crushed nerves exposed to PEMF, 392 ± 15 mm/day. The results of these experiments indicate that (1) a crush injury to the sciatic nerve does not alter the rate of fast axonal transport, and (2) low-frequency pulsed electromagnetic fields do not alter fast axonal transport rates in operated (crush) or unoperated sciatic nerves. © 1995 Wiley-Liss, Inc.     

Axonal transport of the cytoskeleton in regenerating motor neurons: constancy and change

We have examined slow axonal transport in regenerating motor neurons of the rat sciatic nerve. Using SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) we previously found that the slow component is the vehicle for the axonal cytoskeletal proteins, i.e. the neurofilament triplet proteins, tubulin and actin. When these proteins are pulse-labeled by injecting [3H]- or [35S]-amino acids into the spinal cord, they are transported distally in the nerve as two distinguishable waves of radioactivity, SCa and SCb. In normal motor neurons, the neurofilament triplet proteins and the tubulin are transported in SCa at an average velocity of 1.7 mm/day; the less heavily labeled SCb which moves at 2-5 mm/day is the primary vehicle for actin. We now find that during regeneration the velocity of SCa is unchanged in the region of the axon between the cell body and the lesion, but the amount of labeled neurofilament triplet and associated tubulin transported in the axon is decreased in neurons which had been labeled 20 days post-lesion. In contrast, the labeling of the slowly transported proteins moving ahead of the neurofilament triplet is greater in regenerating nerves than in controls. On the basis of our findings, we propose that in motor axons the normal supply of cytoskeletal protein, which is continuously transported in the slow component, is sufficient to support regeneration. Nevertheless, the neuron cell body can alter the supply of these cytoskeletal proteins so as to enhance its regenerative capacity.     

Nanofibrous nerve conduits for repair of 30-mm-long sciatic nerve defects*

It has been confirmed that nanofibrous poly(3-hydroxybutyrate-co-3-hydroxyvalerate) nerve conduit can promote peripheral nerve regeneration in rats. However, its efficiency in repair of over 30-mm-long sciatic nerve defects needs to be assessed. In this study, we used a nanofibrous poly(3-hydroxybutyrate-co-3-hydroxyvalerate) nerve conduit to bridge a 30-mm-long gap in the rat sciatic nerve. At 4 months after nerve conduit implantation, regenerated nerves were macroscopically observed and histologically assessed. In the nanofibrous graft, the rat sciatic nerve trunk had been reconstructed by restoration of nerve continuity and formation of myelinated nerve fiber. There were Schwann cells and glial cells in the regenerated nerves. Masson’s trichrome staining showed that there were no pathological changes in the size and structure of gastrocnemius muscle cells on the operated side of rats. These findings suggest that nanofibrous poly(3-hydroxybutyrate-co-3-hydroxyvalerate) nerve conduit is suitable for repair of long-segment sciatic nerve defects.     

Diffusion tensor imaging to assess axonal regeneration in peripheral nerves

Development of outcome measures to assess ongoing nerve regeneration in the living animal that can be translated to human can provide extremely useful tools for monitoring the effects of therapeutic interventions to promote nerve regeneration. Diffusion tensor imaging (DTI), a magnetic resonance based technique, provides image contrast for nerve tracts and can be applied serially on the same subject with potential to monitor nerve fiber content. In this study, we examined the use of ex vivo high-resolution DTI for imaging intact and regenerating peripheral nerves in mice and correlated the MRI findings with electrophysiology and histology. DTI was done on sciatic nerves with crush, without crush, and after complete transection in different mouse strains. DTI measures, including fractional anisotropy (FA), parallel diffusivity, and perpendicular diffusivity were acquired and compared in segments of uninjured and crushed/transected nerves and correlated with morphometry. A comparison of axon regeneration after sciatic nerve crush showed a comparable pattern of regeneration in different mice strains. FA values were significantly lower in completely denervated nerve segments compared to uninjured sciatic nerve and this signal was restored toward normal in regenerating nerve segments (crushed nerves). Histology data indicate that the FA values and the parallel diffusivity showed a positive correlation with the total number of regenerating axons. These studies suggest that DTI is a sensitive measure of axon regeneration in mouse models and provide basis for further development of imaging technology for application to living animals and humans.     

Stimulating effect of thyroid hormones in peripheral nerve regeneration:research history and future direction toward clinical therapy

Injury to peripheral nerves is often observed in the clinic and severe injuries may cause loss of motor and sensory functions.Despite extensive investigation,testing various surgical repair techniques and neurotrophic molecules,at present,a satisfactory method to ensuring successful recovery does not exist.For successful molecular therapy in nerve regeneration,it is essential to improve the intrinsic ability of neurons to survive and to increase the speed of axonal outgrowth.Also to induce Schwann cell phenotypical changes to prepare the local environment favorable for axonal regeneration and myelination.Therefore,any molecule that regulates gene expression of both neurons and Schwann cells could play a crucial role in peripheral nerve regeneration.Clinical and experimental studies have reported that thyroid hormones are essential for the normal development and function of the nervous system,so they could be candidates for nervous system regeneration.This review provides an overview of studies devoted to testing the effect of thyroid hormones on peripheral nerve regeneration.Also it emphasizes the importance of combining biodegradable tubes with local administration of triiodothyronine for future clinical therapy of human severe injured nerves.We highlight that the local and single administration of triiodothyronine within biodegradable nerve guide improves significantly the regeneration of severed peripheral nerves,and accelerates functional recovering.This technique provides a serious step towards future clinical application of triiodothyronine in human severe injured nerves.The possible regulatory mechanism by which triiodothyronine stimulates peripheral nerve regeneration is a rapid action on both axotomized neurons and Schwann cells.     

A subset of Schwann cells in peripheral nerves contain a 50-kDa protein antigenically related to astrocyte intermediate filaments

Antisera raised to the astrocyte intermediate filament structural protein stained elements in the peripheral nerves of several species. These elements were not associated with myelinated nerve fibers, were more common in splenic and vagus nerves than in the sciatic nerve, and persisted after nerve transection. In teased nerve preparations antigen-positive cells appeared to be the Schwann cells that surround small diameter, unmyelinated axons. Absorption of the antiserum with purified rat spinal cord 50-kDa protein or with bovine splenic nerve cytoskeletal extract blocked the reaction with CNS astrocyte processes or with PNS nerve fibers. Immunoblots of cytoskeletal preparations of bovine splenic nerve or rat sciatic nerve showed that the antigen from peripheral nerves comigrated at 50 kDa with antigen from bovine or rat spinal cord or cultured rat astrocytes. The CNS and PNS 50-kDa proteins from bovine tissues were subjected to limited digestion with Staphylococcus aureus protease V8. After separation on SDS-gels, antigenic peptides were detected by immunoblotting. The pattern of antigenic peptides for the CNS and PNS proteins were identical. We conclude that Schwann cells associated with nonmyelinated axons contain a cytoskeletal protein that is the same size and has the same peptide map as the major structural protein of astrocyte intermediate filaments.     

Selective impairment of slow axonal transport after optic nerve injury in adult rats.

To investigate cellular responses of injured mammalian CNS neurons, we examined the slow transport of cytoskeletal proteins in rat retinal ganglion cell (RGC) axons within the ocular stump of optic nerves that were crushed intracranially. RGC proteins were labeled by an intravitreal injection of 35S-methionine, and optic nerves were examined by SDS PAGE at different times after injury. In one group of rats, the RGC proteins were labeled 1 week after crushing. From 14 to 67 d after axotomy, the labeling of tubulin and neurofilaments was reduced in relation to other labeled proteins and to the labeling of tubulin and neurofilaments in the intact optic nerve of controls. To determine whether this reduction in labeling was due to an alteration in axonal transport after axotomy, we prelabeled RGC proteins 1 week before crushing. In such experiments, the rate of slow axonal transport of tubulin and neurofilaments decreased approximately 10-fold from 6 to 60 d after injury. Our results cannot be due only to the retrograde degeneration of RGCs and injured axons caused by axotomy in the optic nerve, because fast axonal protein transport and the fluorescent labeling of many axons were preserved in the ocular stumps of these optic nerves. This selective failure of the slow axonal transport of tubulin and neurofilaments may affect the renewal of the cytoskeleton and contribute to the gradual degeneration of RGCs that is observed after axotomy. The alterations in slow transport we document here differ from the enhanced rates we previously reported when injured RGC axons regenerated along peripheral nerve segments grafted to the ocular stump of transected optic nerves (McKerracher et al., 1990).     

Time course analysis of sensory axon regeneration in vivo by directly tracing regenerating axons

Most current studies quantify axon regeneration by immunostaining regeneration-associated proteins,representing indirect measurement of axon lengths from both sensory neurons in the dorsal root ganglia and motor neurons in the spinal cord.Our recently developed method of in vivo electroporation of plasmid DNA encoding for enhanced green fluorescent protein into adult sensory neurons in the dorsal root ganglia provides a way to directly and specifically measure regenerating sensory axon lengths in whole-mount nerves.A mouse model of sciatic nerve compression was established by squeezing the sciatic nerve with tweezers.Plasmid DNA carrying enhanced green fluorescent protein was transfected by ipsilateral dorsal root ganglion electroporation 2 or 3 days before injury.Fluorescence distribution of dorsal root or sciatic nerve was observed by confocal microscopy.At 12 and 18 hours,and 1,2,3,4,5,and 6 days of injury,lengths of regenerated axons after sciatic nerve compression were measured using green fluorescence images.Apoptosis-related protein caspase-3 expression in dorsal root ganglia was determined by western blot assay.We found that in vivo electroporation did not affect caspase-3 expression in dorsal root ganglia.Dorsal root ganglia and sciatic nerves were successfully removed and subjected to a rapid tissue clearing technique.Neuronal soma in dorsal root ganglia expressing enhanced green fluorescent protein or fluorescent dye-labeled microRNAs were imaged after tissue clearing.The results facilitate direct time course analysis of peripheral nerve axon regeneration.This study was approved by the Institutional Animal Care and Use Committee of Guilin Medical University,China(approval No.GLMC201503010)on March 7,2014.     

Active Src expression is induced after rat peripheral nerve injury

The non-receptor-type Src tyrosine kinases are key components of intracellular signal transduction that are expressed at high levels in the nervous system. To improve understanding of the cascades of molecular events underlying peripheral nerve regeneration, we analyzed active Src expression in the crushed or cut rat sciatic nerves using a monoclonal antibody (clone 28) that recognizes the active form of Src tyrosine kinases, including c-Src and c-Fyn. Western blots showed that active Src expressed in the normal sciatic nerve transiently increased up to threefolds after both types of injury. Immunohistochemistry using clone 28 showed that axonal components are the primary sites of active Src expression in the normal sciatic nerve. Soon after both types of injury, active Src was abundantly expressed in Schwann cells of the segments distal to the injury site. The expression of active Src in the cells decreased with restoration of the axon-Schwann cell relationship and eventually became depleted to very low levels after crushing, but was sustained at high levels in the cut model until the end of the experiment. Regenerated axons consistently expressed active Src throughout nerve regeneration and these eventually became the major sites of active Src expression in the crushed nerve. Among the Src tyrosine kinases, active c-Src selectively increased after crushing according to immunoprecipitation and immunoblotting analyses. Due to its potent biological activity, the increased amounts of the active form of Src probably enhance axonal regrowth, the Schwann cell response, and axon-Schwann cell contact for peripheral nerve regeneration.     

Changes in cytoskeletal gene expression affect the composition of regenerating axonal sprouts elaborated by dorsal root ganglion neurons in vivo

The effect of a change in neurofilament (NF) and tubulin gene expression on the elongation of axonal sprouts by adult rat sensory neurons was examined. Distal sciatic nerve crush axotomy was used to initiate changes in cytoskeletal gene expression in lumbar dorsal root ganglion (DRG) neurons. In situ hybridization of DRG neurons with 35S-labeled cDNA probes revealed a significant reduction in the level of mRNAs for the low-molecular weight-NF protein and a significant increase in the level of beta tubulin mRNAs by 2 weeks after axotomy. A novel modification of the axonal transport paradigm was used to examine the biochemical composition of the regenerating axons formed by primed and unprimed DRG neurons. Primed neurons (which had sustained a crush axotomy of the distal sciatic nerve 2 weeks earlier) and unprimed (normal) neurons were labeled by microinjection of 35S-methionine and then stimulated to regenerate axons by a crush located very close to the DRG. In this paradigm, axonal sprouts that formed after the proximal crush axotomy incorporated radiolabeled, slow axonally transported proteins as they elongated. Fluorographs of SDS-PAGE revealed that the regenerating axonal sprouts of primed DRG cells incorporated and conveyed significantly less labeled NF protein than did the regenerating axons of unprimed DRG neurons. Electron microscopy revealed that the regenerating axonal sprouts of primed DRG cells contained numerous microtubules but very few identifiable NFs compared with the regenerating sprouts of unprimed DRG neurons.(ABSTRACT TRUNCATED AT 400 WORDS)     

Axonal dependency of the postnatal upregulation in neurofilament expression

A coordinated up-regulation in the expression of all three neurofilament (NF) proteins occurs during postnatal development in the rat (Schlaepfer and Bruce, J Neurosci Res [in press], 1990a). In the present study, sciatic nerves were transected in neonatal rats in order to determine the effects of axotomy on the postnatal upregulation of NF expression in neurons of rat dorsal root ganglia (DRG). Left sciatic nerves were transected at postnatal day 3 (P3), 6 (P6), 8 (P8), or 10 (P10). mRNA and protein levels of the light (NF-L), mid-sized (NF-M), and heavy (NF-H) NF proteins were compared in L4 and L5 DRGs from the transected (left) vs. control (right) sides of the same animals at varying intervals after transection. When nerves were transected at P10, mRNA levels of all three NF proteins declined markedly in the parent DRG neurons, thereby completely interrupting the postnatal upregulation of NF expression. P10 transections also led to widespread chromatolytic changes in axotomized neurons, indistinguishable from those that occur in adult DRG following sciatic nerve transection (Goldstein et al., J Neurosci 7:1586-1594, 1987). Nerve transections at earlier (e.g., P3) neonatal timepoints also led to a decrease of NF expression, but to a lesser extent than that which resulted from a P10 transection. Also, P3 transections caused only minimal chromatolytic changes in the axotomized neurons. Thus, the postnatal upregulation of NF expression is dependent upon axonal continuity and the extent of axonal dependency increases during early postnatal development. These findings support the hypothesis that the postnatal upregulation of NF expression, the axotomy-induced downregulation of NF expression and the chromatolytic reaction to nerve transection are all dependent upon or responsive to axonal- or target cell-derived signals that are acquired during postnatal maturation.     

Altered tubulin and neurofilament expression and impaired axonal growth in diabetic nerve regeneration

Cytoskeletal protein expression in sensory neurons and sciatic nerve axonal growth were examined in type 1 diabetic BB/Wor rats after sciatic nerve crush injury. Diabetic male rats were subjected to sciatic nerve crush at 6 wk of diabetes. L4 and L5 dorsal root ganglia (DRG) mRNA expression of low and medium molecular weight neurofilaments (NF-L, NF-M), betaII- and betaIII-tubulin as well as protein expression of NF-L, NF-M, and beta-tubulin were examined at various time points following crush injury and compared with age- and sex-matched non-diabetic BB/Wor rats. Steady state mRNA expression of NF-L, NF-M, betaII- and betaIII-tubulin were decreased in diabetic DRG. NF-L and NF-M proteins were also decreased in DRG of uncrushed diabetic animals. After crush injury, betaII- and betaIII-tubulin mRNA were upregulated in control animals at day 2 and day 6, respectively, and beta-tubulin protein showed similarly increased expression after crush injury, while such upregulations did not occur in diabetic animals. Conversely, mRNA and protein expressions of NF-L, NF-M were downregulated to a lesser extent in diabetic animals compared to control rats. These changes were associated with impaired axonal elongation and caliber growth of regenerating fibers in diabetic rats. We propose that upregulation of tubulin has a negative feedback on NF expression in response to nerve injury, as seen in control rats. The absence of this upregulation in diabetic animals may impair its regulatory effect on NF expression and contribute to perturbed nerve regeneration seen in diabetic nerve.     

Modifications in the cytoskeleton transported by slow component A during axonal regeneration

We studied the modifications occurring in the parent cytoskeleton carried by SCa (the slower of the two slow axonal transport subcomponents) after peripheral nerve crush. The proteins transported in rat sciatic motor axons were radiolabelled by injecting [35S]methionine into the ventral horn of the spinal cord, and the nerve was crushed so as to entrap only the proteins transported by SCa along the parent axon. Two weeks after the crush, the regenerating nerve was removed and the distributions of the polymerized and unpolymerized radiolabelled cytoskeletal proteins were compared with those in normal, non-regenerating nerves. We found that in the parent axons, most of the radioactive neurofilaments were arrested by the crush, but microtubules, soluble tubulin, insoluble and soluble actin were normally transported. Thus, when the resulting cytoskeleton transported by SCa entered the daughter axon, it was enriched in microtubules and actin, and partially depleted of neurofilaments. This cytoskeleton contained larger proportions of soluble tubulin and insoluble actin than the parent cytoskeleton, but retained its coordinated progression and transport velocity, suggesting that after axotomy, the main destiny of the parent cytoskeleton carried by SCa is to become the equivalent cytoskeleton in the daughter axons.