Peripheral nerve grafts after cervical spinal cord injury in adult cats

Peripheral nerve grafts (PNG) into the rat spinal cord support axon regeneration after acute or chronic injury, with synaptic reconnection across the lesion site and some level of behavioral recovery. Here, we grafted a peripheral nerve into the injured spinal cord of cats as a preclinical treatment approach to promote regeneration for eventual translational use. Adult female cats received a partial hemisection lesion at the cervical level (C7) and immediate apposition of an autologous tibial nerve segment to the lesion site. Five weeks later, a dorsal quadrant lesion was performed caudally (T1), the lesion site treated with chondroitinase ABC 2 days later to digest growth inhibiting extracellular matrix molecules, and the distal end of the PNG apposed to the injury site. After 4-20 weeks, the grafts survived in 10/12 animals with several thousand myelinated axons present in each graft. The distal end of 9/10 grafts was well apposed to the spinal cord and numerous axons extended beyond the lesion site. Intraspinal stimulation evoked compound action potentials in the graft with an appropriate latency illustrating normal axonal conduction of the regenerated axons. Although stimulation of the PNG failed to elicit responses in the spinal cord distal to the lesion site, the presence of c-Fos immunoreactive neurons close to the distal apposition site indicates that regenerated axons formed functional synapses with host neurons. This study demonstrates the successful application of a nerve grafting approach to promote regeneration after spinal cord injury in a non-rodent, large animal model.     

Neuronal overexpression of tissue-type plasminogen activator does not enhance sensory axon regeneration or locomotor recovery following dorsal hemisection of adult mouse thoracic spinal cord

CNS axons rarely regenerate spontaneously back to original targets following spinal cord injury (SCI). Neuronal expression of the serine protease tissue-type plasminogen activator (tPA) enhances axon growth in vitro and following PNS injury. Here we test the hypothesis that neuronal overexpression of tPA in adult transgenic mice promotes CNS axon regeneration and functional recovery following SCI. Adult wild-type and transgenic mouse spinal cords were subjected to dorsal hemisection at the level of the T10/T11 vertebrae. PCR confirmed incorporation of the transgene. Immunolabeling revealed overexpression of tPA in transgenic mice in neurons, including large-diameter neurons in lumbar dorsal root ganglia that contribute axons to the dorsal columns. Immunolabeling also revealed the presence of tPA protein within axons juxtaposing the injury site in transgenics but not wild types. In situ zymography revealed abundant enzymatic activity of tPA in gray matter of thoracic spinal cords of transgenics but not wild types. Rotorod locomotor testing revealed no differences between groups in locomotor function up to 21 days postinjury. Transganglionic tracer was injected into the crushed right sciatic nerve 28 days postinjury, and mice were killed 3 days later. There was no evidence for regrowth of ascending dorsal column sensory axons through or beyond the injury site. In conclusion, despite neuronal overexpression of tPA in injured neurons of transgenics, neither locomotor recovery nor regeneration of ascending sensory axons was observed following thoracic dorsal hemisection.     

Progressive morphological abnormalities observed in rat spinal motor neurons at extended intervals after axonal regeneration.

It is generally accepted that mammalian spinal motor neurons return to normal after axotomy if their regenerated axons successfully reinnervate appropriate peripheral targets. However, morphological abnormalities, recently observed in spinal motor neurons examined 1 year after nerve crush injury, raise the possibility that delayed perikaryal changes occur after regeneration is complete. In order to distinguish between chronic and progressive alterations in neurons with long-term regenerated axons, rat spinal motor neurons and dorsal root ganglion cells were examined at 5 and 10 months following unilateral sciatic nerve crush. Neurons with regenerated axons were identified by retrograde labelling with horseradish peroxidase. The structural properties of neurons ipsilateral to nerve injury were compared to those of neurons from the spinal cord and dorsal root ganglia on the contralateral side and from age-matched control rats. At 5 months postcrush, the morphology of motor and sensory neurons ipsilateral to injury was comparable to that of control cells. However, several features of the motor neurons with regenerated axons distinguished them from control motor neurons at 10 months postcrush. Mean perikaryal area of ipsilateral spinal motor neurons was larger than the means for control motor neurons (p less than .001). Ipsilateral spinal motor neurons also appeared clustered within the spinal cord and had thicker dendrites. Dorsal root ganglion cells with regenerated axons were slightly larger than control cells at 10 months postcrush but they exhibited no other morphological changes. The present findings indicate that spinal motor neurons are progressively altered after their regenerated axons have reestablished functional synapses with their peripheral targets.     

Construction of pathways to promote axon growth within the adult central nervous system

Inducing significant axon growth or regeneration after spinal cord injury has been difficult, primarily due to the poor growth supportive environment and low intrinsic growth ability of neurons within the CNS. Neurotrophins alone have been shown to readily induce regeneration of sensory axons after dorsal root lesions, however if neurotrophin gradients are expressed within the spinal cord these axons fail to terminate within appropriate target regions. Under such conditions, addition of a “stop” signal reduces growth into deeper dorsal laminae to support more specific targeting. Such neurotrophin gradients alone lose their effectiveness when lesions are within the spinal cord, requiring a combined treatment regime. Construction of pathways using combined treatments support good regeneration when they increase the intrinsic growth properties of neurons, provide a bridge across the lesion site, and supply a growth supportive substrate to induce axon growth out of the bridge and back into the host. Neurotrophin gradients distal to the bridge greatly enhance axon outgrowth. In disorders where neuronal circuits are lost, construction of preformed growth supportive pathways sustain long distance axon growth from a neuronal transplant to distal target locations.     

Role of the peripheral benzodiazepine receptor in sensory neuron regeneration

Peripheral benzodiazepine receptor (PBR) expression increases in small dorsal root ganglion (DRG) sensory neurons after peripheral nerve injury. To determine the functional significance of this induction, we evaluated the effects of PBR ligands on rodent sensory axon outgrowth. In vitro, Ro5-4864, a PBR agonist, enhanced outgrowth only of small peripherin-positive DRG neurons. When DRG cells were preconditioned into an active growth state by a prior peripheral nerve injury Ro5-4864 augmented and PK 11195, a PBR antagonist, blocked the injury-induced increased outgrowth. In vivo, Ro5-4864 increased the initiation of regeneration after a sciatic nerve crush injury and the number of GAP-43-positive axons in the distal nerve while PK 11195 inhibited the enhanced growth produced by a preconditioning lesion. These results show that PBR has a role in the early regenerative response of small caliber sensory axons, the preconditioning effect, and that PBR agonists enhance sensory axon regeneration.     

Transplantation of olfactory ensheathing cells or Schwann cells restores rapid and secure conduction across the transected spinal cord

Olfactory ensheathing cells (OECs) or Schwann cells were transplanted into the transected dorsal columns of the rat spinal cord to induce axonal regeneration. Electrophysiological recordings were obtained in an isolated spinal cord preparation. Without transplantation of cells, no impulse conduction was observed across the transection site; but following cell transplantation, impulse conduction was observed for over a centimeter beyond the lesion. Cell labelling indicated that the regenerated axons were derived from the appropriate neuronal source, and that donor cells migrated into the denervated host tract. As reported in previous studies, the number of regenerated axons was limited. Conduction velocity measurements and morphology indicated that the regenerated axons were myelinated, but conducted faster and had larger axon areas than normal axons. These results indicate that the regenerated spinal cord axons induced by cell transplantation provide a quantitatively limited but rapidly conducting new pathway across the transection site.     

Peripheral nerve injury fails to induce growth of lesioned ascending dorsal column axons into spinal cord scar tissue expressing the axon repellent Semaphorin3A

We have investigated the hypothesis that the chemorepellent Semaphorin3A may be involved in the failure of axonal regeneration after injury to the ascending dorsal columns of adult rats. Following transection of the thoracic dorsal columns, fibroblasts in the dorsolateral parts of the lesion site showed robust expression of Semaphorin3A mRNA. In addition, dorsal root ganglion (DRG) neurons with projections through the dorsal columns to the injury site persistently expressed both Semaphorin3A receptor components, neuropilin-1 and plexin-A1. These ascending DRG collaterals failed to invade scar regions occupied by Semaphorin3A-positive fibroblasts, even in animals which had received conditioning lesions of the sciatic nerve to enhance regeneration. Other axon populations in the dorsal spinal cord were similarly unable to penetrate Semaphorin3A-positive scar tissue. These data suggest that Semaphorin3A may create an exclusion zone for regenerating dorsal column fibres and that enhancing the intrinsic regenerative response of DRG neurons has only limited effects on axonal regrowth. Tenascin-C and chondroitin sulphate proteoglycans were also detected at the injury site, which was largely devoid of central nervous system (CNS) myelin, showing that several classes of inhibitory factors, including semaphorins, with only partially overlapping spatial and temporal patterns of expression are in a position to participate in preventing regenerative axonal growth in the injured dorsal columns. Interestingly, conditioning nerve injuries enabled numerous ascending DRG axons to regrow across areas of strong tenascin-C and chondroitin sulphate proteoglycan expression, while areas containing Semaphorin3A and CNS myelin were selectively avoided by (pre)primed axonal sprouts.     

Intrinsic versus extrinsic factors in determining the regeneration of the central processes of rat dorsal root ganglion neurons: The influence of a peripheral nerve graft

The relative contribution of intrinsic growth capacity versus extrinsic growth-promoting factors in determining the capacity of transected dorsal root axons to regenerate long distances was studied. L4 dorsal root axons regenerating into 4-cm peripheral nerve grafts on transected dorsal roots were counted. Few dorsal root myelinated axons regenerated to the distal end of the grafts by 10 weeks unless the sciatic nerve was also crushed. Regeneration of unmyelinated axons was also increased by peripheral lesions. Crush or transection of the dorsal roots without grafting did not alter GAP-43 mRNA expression in L4 dorsal root ganglion (DRG) cells. Grafting a peripheral nerve onto the cut end of an L4 dorsal root doubled the number of DRG cells expressing high levels of GAP-43 mRNA after a delay of several weeks. Peripheral nerve crush at the time of nerve grafting resulted in a very rapid rise in GAP-43 mRNA expression, which then declined to a steady level, twice that of controls, by 7 weeks. Thus, the rapid increase in the number of DRG neurons expressing high levels of GAP-43 mRNA after peripheral but not central axotomy correlates with the regeneration of central axons through nerve grafts. Because GAP-43 mRNA is slowly upregulated in a subpopulation of sensory neurons in response to exposure of their central axons to a peripheral nerve environment, environments favourable for axonal growth may act by increasing the intrinsic growth response of neurons. Lack of intrinsic growth capacity may contribute to the failure of dorsal root axons to regenerate into the spinal cord. © 1996 Wiley-Liss, Inc.     

Light and electron microscopic localization of B-50 (GAP43) in the rat spinal cord during transganglionic degenerative atrophy and regeneration.

Crush or transection of a peripheral nerve is known to induce transganglionic degenerative atrophy (TDA) in the segmentally related, ipsilateral Rolando substance of the spinal cord. When the lost peripheral connectivity is reestablished, the consecutive regenerative synaptoneogenesis results in restoration of the circuitry in the formerly deteriorated upper dorsal horn. Enhanced expression of the growth-associated protein (GAP43) B-50 occurs during neuronal differentiation, axon outgrowth, and peripheral nerve regeneration. This study documents changes in immunocytochemical distribution of B-50 in the regions of the lumbar spinal cord which are segmentally related to the axotomized sciatic nerve. At the light microscopic level, a weak B-50 immunoreactivity (BIR) is present in the neuropil of the upper dorsal horn of control animals. After unilateral transection and ligation of the sciatic nerve, BIR increased in the ipsilateral upper dorsal horn at 17 days postinjury, but decreased again after 24 days with respect to the contralateral side. Differences between effects of crush and transection were prominent in combined crush-cut experiments as well (i.e., after unilateral crush and contralateral transection and ligation of the sciatic nerve). Electron microscopic studies show that in the uninjured and injured spinal cord, BIR is detected in axons and axon terminals, but not all are stained. After transection of the sciatic nerve, BIR is found in afflicted primary sensory axon terminals, including those contacting substantia gelatinosa neurons and in axon terminals undergoing glial phagocytosis. The localization of BIR seen after crushing the sciatic nerve is similar. However, at 24 days after crush, BIR is detected also in axonal growth cones. In the ventral horn of control animals, synaptic boutons impinging upon motor neurons exhibited weak BIR. At 17 days after unilateral transection of the sciatic nerve, the pericellular BIR surrounding motor neurons is decreased at the ipsilateral with respect to the contralateral side, whereas 24 days after crush injury it increased considerably. Our results show that peripheral nerve injury inducing TDA also affects BIR distribution in the spinal gray matter. Successful regeneration of the peripheral nerve after crush lesion is associated with enhanced expression of B-50 in growth cones of sprouting central axons. The neuroplastic response of B-50 is in line with a function of B-50 in axonal sprouting and reactive synaptogenesis.     

C3 exoenzyme lacks effects on peripheral axon regeneration in vivo

Peripheral nerve injury triggers the activation of the small GTPase RhoA in spinal motor and peripheral sensory neurons. C3 transferase, an exoenzyme produced by Clostridium botulinum that inactivates RhoA by ADP‐ribosylation, has been successfully applied in central nervous system (CNS) lesion models to facilitate regeneration functionally and morphologically. Until now it has not been demonstrated if C3_bot exerts positive effects on peripheral axon regeneration as well. In organotypic spinal cord preparations, C3_bot reduced axonal growth of motoneurons, while no effect on sensory axon outgrowth from dorsal root ganglia (DRG) explants was observed. Enzymatically inactive C3_E174Q was ineffective in both culture models. Spinal cord slices exhibited a significant increase in microglia/macrophages after treatment with C3_bot suggesting an inflammatory component in the inhibition of axon growth. C3_bot or C3_E174Q were then applied into conduits implanted after transection of the sciatic nerve in rats. Functional evaluation by electrophysiology, nociception, and walking track tests did not show any significant difference between groups with active or mutant C3_E174Q. Transmission electron microscopy of the regenerated nerves revealed no significant differences in the number of myelinated and unmyelinated axons 6 weeks after surgery. Compared to the CNS, the functional significance of RhoA may be limited during nerve regeneration in a growth‐promoting environment.     

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.     

Cyclic AMP elevates tubulin expression without increasing intrinsic axon growth capacity

Exposing rat dorsal root ganglion (DRG) neurons to dibutyryl cAMP (db-cAMP) enables central branches to regenerate in the spinal cord by nullifying the ability of CNS myelin to inhibit elongation. A conditioning lesion (CL) promotes similar regeneration of central branches in the spinal cord by increasing neuronal cAMP levels. It is a matter of speculation whether any of the other effects of a CL are triggered by elevated cAMP. We found that like a CL, intraganglionic injection of db-cAMP increases the expression of growth-associated tubulin isotypes. However, unlike a CL, db-cAMP does not increase the velocity at which tubulin is delivered to the tips of growing axons by slow component b (SCb). db-cAMP also fails to increase intrinsic axon growth capacity enough to raise the rate of regeneration of peripheral branches in the sciatic nerve or enable central branches to elongate long distances in an environment free of all CNS inhibitors of elongation (i.e., a peripheral nerve graft transplanted into the spinal cord at the site of dorsal column transection). Thus, the increase in cAMP induced by a CL induces some, but not all, of the changes that may be necessary to increase intrinsic axon growth capacity.     

Expression of c-Jun as a Response to Dorsal Root and Peripheral Nerve Section in Damaged and Adjacent Intact Primary Sensory Neurons in the Rat

It was previously shown that the immediate early gene, c-jun , was highly expressed over long periods, in both peripheral sensory and motor neurons following axon damage or block of axoplasmic transport. Here we have examined the question of whether the expression of c-Jun protein is related to axon injury per se or to the process of axon growth. We have examined dorsal root ganglion (DRG) cells subjected to different manipulations which are associated with varying degrees of regrowth, as follows: (i) after peripheral nerve section, where it appears that all damaged neurons make some regenerative effort. 1 – 24 days after sciatic nerve section and ligation most cells in L4/L5 DRG were c-Jun-positive; (ii) after section of the central processes of the DRG cells, which then showed a slow and limited regrowth of their axons towards, but not into, the spinal cord. This resulted in a variable, but significant, expression of c-Jun in a small number of DRG cells; (iii) in intact sensory neurons that were offered the opportunity to sprout into adjacent denervated peripheral tissue. The sciatic nerve was ligated and the response of cells in the L3 ganglia (many of which project to the saphenous nerve) was measured. A small but significant number of cells were c-Jun-positive; (iv) in intact sensory neurons that were offered the opportunity to sprout centrally into partialy denervated neuropil of the spinal cord. We examined neurons in the L3 DRG after rhizotomy of the adjacent L4/L5 dorsal roots. Previous work suggests that sensory neurons show at best a very limited growth under these conditions. No significant increase was seen in c-Jun expression in these cases. These results suggest that c-Jun expression is closely correlated with growth and regeneration, and not simply a consequence of neuronal injury.     

IL-6 promotes regeneration and functional recovery after cortical spinal tract injury by reactivating intrinsic growth program of neurons and enhancing synapse formation

Most neurons in adult mammalian central nervous system (CNS) fail to regenerate their axons after injury. Peripherally conditioned primary sensory neurons have an increased capacity to regenerate their central processes. Recent studies demonstrate that a conditioning lesion increased intrinsic growth capability is associated with the up-regulation of a group of growth-associated genes, one of the most established is interleukin-6 (IL-6). However, the cellular and molecular mechanisms by which IL-6 exerts its beneficial effect on axonal regeneration and functional recovery remain to be elucidated. The purpose of this study is to further investigate the molecular mechanisms of IL-6 in promoting regeneration and functional recovery after spinal cord injury (SCI). Here, we demonstrate that in vitro administration of IL-6 enhances neurite outgrowth of neurons on an inhibitory substrate myelin proteins, accompanied by increased expression of growth-associated genes GAP-43, SPRR1A and Arginase I. In vivo, intrathecal delivery of IL-6 for 7 days after cortical spinal tract injury induces synaptic rearrangements of sprouting axons and increases the expression of mTOR in neurons surrounding the lesion site, accompanied by improved functional recovery. In conclusion, our results show that IL-6 increases the expression of growth-associated genes and induces the expression of mTOR in lesion adjacent neurons, resulting in reactivating the intrinsic growth program of neurons to promote axonal regrowth and functional recovery after SCI.     

Axonal regeneration from injured dorsal roots into the spinal cord of adult rats.

Injury to the central processes of primary sensory neurons produces less profound changes in the expression of growth-related molecules and less vigorous axonal regeneration than does injury to their peripheral processes. The left L4, L5, and L6 dorsal roots of deeply anaesthetized adult Sprague-Dawley rats were severed and reanastomosed, and in some animals, the ipsilateral sciatic nerve was crushed to increase the expression of growth-related molecules. After between 28 days and three months, the sciatic nerve of most animals was injected with transganglionic tracers and the animals were killed 2-3 days later. Other animals were perfused for electron microscopy. Very few regenerating axons entered the spinal cord of the rats without sciatic nerve injuries. Labelled axons, however, were always found in the spinal cord of rats with sciatic nerve injuries. They often entered the cord around blood vessels, ran rostrally within the superficial dorsal horn, and avoided the degenerating white matter. The animals with a conditioning sciatic nerve crush had many more myelinated axons around the dorsal root entry zone (DREZ) and on the surface of the cord. Thus, a conditioning lesion of their peripheral processes increased the ability of the central processes of myelinated A fibres to regenerate, including to sites (such as lamina II) they do not normally occupy. Astrocytes, oligodendrocytes, and meningeal fibroblasts in and around the DREZ may have inhibited regeneration in that region, but growth of the axons into the deep grey matter and degenerated dorsal column was also blocked.     

Brain-derived neurotrophic factor applied to the motor cortex promotes sprouting of corticospinal fibers but not regeneration into a peripheral nerve transplant

Previous experiments from our laboratory have shown that application of brain-derived neurotrophic factor (BDNF) to the red nucleus or the motor cortex stimulates an increase in the expression of regeneration-associated genes in rubrospinal and corticospinal neurons. Furthermore, we have previously shown that BDNF application stimulates regeneration of rubrospinal axons into a peripheral graft after a thoracic injury. The current study investigates whether application of BDNF to the motor cortex will facilitate regeneration of corticospinal neurons into a peripheral nerve graft placed into the thoracic spinal cord. In adult Sprague Dawley rats, the dorsal columns and the corticospinal tract between T9 and T10 were ablated by suction, and a 5-mm-long segment of predegenerated tibial nerve was autograft implanted into the lesion. With an osmotic pump, BDNF was infused directly into the parenchyma of the motor cortex for 14 days. Growth of the corticospinal tract into the nerve graft was then evaluated by transport of an anterograde tracer. Anterogradely labeled corticospinal fibers were not observed in the peripheral nerve graft in animals treated with saline or BDNF. Serotinergic and noradrenergic fibers, as well as peripheral sensory afferents, were observed to penetrate the graft, indicating the viability of the peripheral nerve graft as a permissive growth substrate for these specific fiber types. Although treatment of the corticospinal fibers with BDNF failed to produce regeneration into the graft, there was a distinct increase in the number of axonal sprouts rostral to the injury site. This indicates that treatment of corticospinal neurons with neurotrophins, e.g., BDNF, can be used to enhance sprouting of corticospinal axons within the spinal cord. Whether such sprouting leads to functional recovery after spinal cord injury is currently under investigation.     

Functional connections are established in the deafferented rat spinal cord by peripherally transplanted human embryonic sensory neurons

Functionally useful repair of the mature spinal cord following injury requires axon growth and the re-establishment of specific synaptic connections. We have shown previously that axons from peripherally grafted human embryonic dorsal root ganglion cells grow for long distances in adult host rat dorsal roots, traverse the interface between the peripheral and central nervous system, and enter the spinal cord to arborize in the dorsal horn. Here we show that these transplants mediate synaptic activity in the host spinal cord. Dorsal root ganglia from human embryonic donors were transplanted in place of native adult rat ganglia. Two to three months after transplantation the recipient rats were examined anatomically and physiologically. Human fibres labelled with a human-specific axon marker were distributed in superficial as well as deep laminae of the recipient rat spinal cord. About 36% of the grafted neurons were double labelled following injections of the fluorescent tracers MiniRuby into the sciatic and Fluoro-Gold into the lower lumbar spinal cord, indicating that some of the grafted neurons had grown processes into the spinal cord as well as towards the denervated peripheral targets. Electrophysiological recordings demonstrated that the transplanted human dorsal roots conducted impulses that evoked postsynaptic activity in dorsal horn neurons and polysynaptic reflexes in ipsilateral ventral roots. The time course of the synaptic activation indicated that the human fibres were non-myelinated or thinly myelinated. Our findings show that growing human sensory nerve fibres which enter the adult deafferentated rat spinal cord become anatomically and physiologically integrated into functional spinal circuits.     

Fate of GAP-43 in ascending spinal axons of DRG neurons after peripheral nerve injury: delayed accumulation and correlation with regenerative potential.

Proteins characteristic of growing axons often fail to be induced or transported along axons that have been interrupted far from their cell bodies in the adult mammalian CNS. Here, we inquire whether long axons in the mammalian CNS can support efficient axonal transport and deposition of one such protein, GAP-43, when the protein is induced in neuron cell bodies. We have used immunocytochemistry to follow the fate of GAP-43 in dorsal column axons ascending the rat spinal cord from dorsal column axons ascending the rat spinal cord from dorsal root ganglion (DRG) neurons, after synthesis of the protein is induced in these cells by peripheral nerve injury. Sciatic nerve lesions do lead to an accumulation of GAP-43 in dorsal column axons derived from the lumbar DRG. However, in distal segments of these CNS axons, accumulation of GAP-43 is apparent only after a delay of 1-2 weeks, in contrast to its rapid accumulation in axon segments within the PNS environment, suggesting that deposition and stabilization of GAP-43 can be limited by local, posttranslational regulation. GAP-43 immunoreactivity subsides to control levels within 8 weeks after crush lesions that permit peripheral axon regeneration, but remains robust 8 weeks after resection lesions that prevent peripheral regeneration. Accumulation of GAP-43 in cervical dorsal column axons after peripheral nerve injury is closely correlated with the ability of these axons to respond to local cues capable of eliciting axon growth (Richardson and Verge, 1986).     

Guiding adult Mammalian sensory axons during regeneration

Misdirection of axons after nerve injury impairs successful regeneration of adult neurons. Investigations of axon guidance in development have provided an understanding of pathfinding, but their relevance to regenerating adult axons is unclear. We investigated adult mammalian axon guidance during regeneration after peripheral nerve injury and focused on the effects of the prototypic guidance molecule nerve growth factor (NGF). Adult rat sensory neurons from dorsal root ganglia that expressed the NGF receptor tropomyosin-related kinase A (trkA) were presented with a point source of NGF in vitro. Naive trkA neurons had no net turning response to NGF, but if they had been preconditioned by a peripheral nerve transection in vivo before culturing, their growth cones were attracted toward the NGF gradient. A laminin substrate was required for this behavior and an anti-trkA antibody interrupted turning. These data demonstrate that injured adult mammalian axons can be guided as they regenerate. Moreover, despite the downregulation of trkA mRNA and protein levels within the dorsal root ganglion after injury, sensory neurons retain and increase trkA protein at the injury site where the regenerating axons are found. This may enhance the axonal response to NGF and allow guidance along an NGF gradient created in vivo in the distal nerve stump.