In vivo ANTI-NGF induces sprouting of sensory axons in dorsal roots

Newborn rats were given subcutaneous injections of antibodies to mouse beta -NGF (ANTI-NGF) daily for 1 month. The number of neurons in T4-T6 dorsal root ganglia (DRG) and the numbers of myelinated and unmyelinated axons in the dorsal roots of the same segments were counted in the ANTI-NGF animals and in normal littermates. The ANTI-NGF rats had 38% fewer neurons in thoracic ganglia but 17% more myelinated and 40% more unmyelinated fibers than their untreated littermates. Dorsal root ganglion cells also have a larger average size in the ANTI-NGF animals, which we interpret as a disproportionate loss of small cells. These data are interpreted as showing that some dorsal root ganglion cells, principally small ones, die when endogenous NGF is inactivated, and that the remaining cells emit more processes than normal. Thus, removal of NGF has what appears to be a paradoxical effect, a reduction in dorsal root ganglion cell numbers but an increase in dorsal root axon numbers. The relation of myelin thickness to fiber diameter is also altered, with small fibers being more thinly myelinated in the ANTI-NGF group. Thus, Schwann cell-neuronal interactions are also affected by inactivation of NGF.     

Effects of postnatal anti-NGF on the development of CGRP-IR neurons in the dorsal root ganglion

Experiments were undertaken to examine anatomical correlates of physiological effects of rabbit sera raised against nerve growth factor (anti-NGF) on nociceptive afferents. This antiserum has been shown to deplete the population of A-δ high threshold mechanoreceptors and to reduce neurogenic vasodilatation. Because numerous studies implicate calcitonin gene related peptide (CGRP)- containing sensory neurons in these effects, immunocytochemical and anatomical techniques were used to examine the normal development of CGRP-immunoreactive (-IR) neurons in the dorsal root ganglion (DRG) of rats from 13 days to 19 weeks of age, and to compare this to the development in rats treated neonatally (postnatal days 2-14) with anti-NGF. In controls the rate of increase in the mean diameter of CGRP-IR cells was substantially greater between 13 days and 5 weeks of age than it was between 5 weeks and 19 weeks, in contrast to CGRP-negative neurons whose rate of growth remained relatively constant. Anti-NGF had no significant effect on growth rate, but rats treated with anti-NGF exhibited a reduced proportion of CGRP-IR neurons at 5 weeks. This deficit was reversed by 19 weeks unlike the physiological changes. These results indicate independent regulation of CGRP expression and nociceptor physiology by NGF. J. Comp. Neurol. 392: 489–498, 1998. © 1998 Wiley-Liss, Inc.     

Nitric oxide synthase and growth-associated protein are coexpressed in primary sensory neurons after peripheral injury

A possible role for nitric oxide in growth and regeneration of dorsal root ganglion (DRG) afferents has been explored in lesion experiments by comparing immunocytochemistry for nitric oxide synthase (NOS) with that for the growth-associated phosphoprotein 43 (GAP-43). Sciatic nerve ligature induced a progressive increase in the number of small DRG cell profiles immunopositive for NOS between 2 days and 4 weeks of survival. In the proximal stump of the ligature, NOS-immunopositive fibers began to appear 2 days after injury and their growth cones were especially evident after 7 days. NOS-immunopositive fibers appeared past (i.e., distal to) the ligature at 14 days of survival and extended for at least 6 mm in either direction 4 weeks after the lesion. Dorsal root ligature alone at L4–L5 did not result in expression of NOS in DRG neurons or in the appearence of NOS-immunopositive fibers. In rats with dorsal root ligature and nerve ligature, the results were similar to those with nerve ligature only. DRG cell profiles immunopositive for GAP-43 kept increasing from 2 days to 4 weeks after sciatic nerve ligature and included small neurons initially and large neurons subsequently. Numerous axons became GAP-43 immunopositive on both sides of the ligature from 2 days after injury. In double-labeled material, about 80% of DRG cell profiles immunopositive for NOS were also immunopositive for GAP-43. The two antigens co-occurred in peripheral nerve axons proximal to the ligature starting at about 7 days and distal to it at about 2 weeks after ligature. Thus, in response to nerve lesion, nitric oxide may not only provide an injury signal to the central nervous system but may also contribute to the growth and regeneration of injured axons. J. Comp. Neurol. 404:64–74, 1999. © 1999 Wiley-Liss, Inc.     

Effects of autoimmune NGF deprivation in the adult rabbit and offspring

An experimental autoimmune approach to the production of nerve growth factor deprivation, which we have previously described in the rat and guinea pig, has been applied to the rabbit. This species was chosen for study because of several potential advantages. The rabbit produces large litters and has a relatively short gestation period. More importantly, rabbits generate high titers of antibody against mouse NGF and large amounts of maternal antibody are passively transferred to the developing rabbit fetus compared to most other species, particularly the rat. The sympathetic nervous system of adult rabbit immunized against mouse NGF underwent degeneration with up to an 85% decrease in neuronal numbers in the superior cervical ganglion after 10 months of immunization, thus providing further evidence that NGF is required for the survival of mature sympathetic neurons. Despite the fact that newborn rabbits born to anti-NGF producing mothers had much higher titers of anti-NGF than did rats, the effects on the developing sympathetic and sensory nervous systems were not found to be any greater than in rats. Reductions in norepinephrine levels in the heart and spleen of adult rabbits born to anti-NGF producing mothers were greater than in small intestine. Prenatal exposure to maternal anti-NGF caused reductions (up to 70%) in the number of neurons in the dorsal root ganglia. Substance-P immunoreactivity was reduced in the substantia gelatinosa of the spinal cord of rabbit exposed to maternal anti-NGF. These changes, however, were not greater than seen in the rat. We conclide that although the rabbits offers some advantage in the study of the effects of NGF deprivation in the adult animal, it appears less well suited than the rat or guinea pig to the study of the effects of NGF deprivation on development.     

Constitutive expression of GAP-43 correlates with rapid, but not slow regrowth of injured dorsal root axons in the adult rat

It has been postulated that the neuronal growth-associated protein GAP-43 plays an essential role in axon elongation. Although termination of developmental axon growth is generally accompanied by a decline in expression of GAP-43, a subpopulation of dorsal root ganglion (DRG) neurons retains constitutive expression of GAP-43 throughout adulthood. Peripheral nerve regeneration occurring subsequent to injury of the peripheral axon branches of adult DRG neurons is accompanied by renewed elevation of GAP-43 expression. Lesions of DRG central axon branches in the dorsal roots are also followed by some regenerative growth, but little or no increase in GAP-43 expression above the constitutive level is observed. To determine whether dorsal root axon regeneration occurs only from neurons which constitutively express GAP-43, we have used retrograde fluorescent labeling to identify those DRG neurons which extend axons beyond a crush lesion of the dorsal root. Only GAP-43 immunoreactive neurons supported axon regrowth of 7 mm or greater within the first week. At later times, axon regrowth is seen to occur from neurons both with and without GAP-43 immunoreactivity. We conclude that regeneration of injured axons within the dorsal root is not absolutely dependent on the presence of GAP-43, but that expression of GAP-43 is correlated with a capacity for rapid growth.     

The dorsal root ganglion in Friedreich’s ataxia

Atrophy of dorsal root ganglia (DRG) and thinning of dorsal roots (DR) are hallmarks of Friedreich’s ataxia (FRDA). Many previous authors also emphasized the selective vulnerability of larger neurons in DRG and thicker myelinated DR axons. This report is based on a systematic reexamination of DRG, DR and ventral roots (VR) in 19 genetically confirmed cases of FRDA by immunocytochemistry and single- and double-label immunofluorescence with antibodies to specific proteins of myelin, neurons and axons; S-100α as a marker of satellite and Schwann cells; laminin; and the iron-responsive proteins ferritin, mitochondrial ferritin, and ferroportin. Confocal images of axons and myelin allowed the quantitative analysis of fiber density and size, and the extent of DR and VR myelination. A novel technology, high-definition X-ray fluorescence (HDXRF) of polyethylene glycol-embedded fixed tissue, was used to “map” iron in DRG. Unfixed frozen tissue of DRG in three cases was available for the chemical assay of total iron. Proliferation of S-100α-positive satellite cells accompanied neuronal destruction in DRG of all FRDA cases. Double-label visualization of peripheral nerve myelin protein 22 and phosphorylated neurofilament protein confirmed the known loss of large myelinated DR fibers, but quantitative fiber counts per unit area did not change. The ratio of myelinated to neurofilament-positive fibers in DR rose significantly from 0.55 to 0.66. In VR of FRDA patients, fiber counts and degree of myelination did not differ from normal. Pooled histograms of axonal perimeters disclosed a shift to thinner fibers in DR, but also a modest excess of smaller axons in VR. Schwann cell cytoplasm in DR of FRDA was depleted while laminin reaction product remained prominent. Numerous small axons clustered around fewer Schwann cells. Ferritin in normal DRG localized to satellite cells, and proliferation of these cells in FRDA caused wide rims of reaction product about degenerating nerve cells. Mitochondrial ferritin was not detectable. Ferroportin was present in the cytoplasm of normal satellite cells and neurons, and in large axons of DR and VR. In FRDA, some DRG neurons lost their cytoplasmic ferroportin immunoreactivity, whereas the cytoplasm of satellite cells remained ferroportin positive. Ferroportin in DR axons disappeared in parallel with atrophy of large fibers. HDXRF of DRG detected regional and diffuse increases in iron fluorescence that matched ferritin expression in satellite cells. The observations support the conclusions that satellite cells and DRG neurons are affected by iron dysmetabolism; and that regeneration and inappropriate myelination of small axons in DR are characteristic of the disease.     

Preconditioning selective ventral root injury promotes plasticity of ascending sensory neurons in the injured spinal cord of adult rats – possible roles of brain-derived neurotrophic factor, TrkB and p75 neurotrophin receptor

Preconditioning sciatic nerve injury enhances axonal regeneration of ascending sensory neurons after spinal cord injury. A key question is whether direct injury of sensory nerves is necessary for the enhanced regeneration. The lumbar 5 ventral root transection (L5 VRT) model, a model of selective motor nerve injury, provides a useful tool to address this question. Here we examined the effects of a preconditioning L5 VRT on the regeneration after a subsequent dorsal column transection (DCT) in adult Sprague–Dawley rats. We found that L5 VRT 1 week before DCT increased the number of Fast Blue (FB)-labeled neurons in the L5 dorsal root ganglia (DRG) and promoted sprouting/regenerating axons to grow into the glial scar. L5 VRT also induced a dramatic upregulation of expression of brain-derived neurotrophic factor (BDNF) in the preconditioned DRG and in the injured spinal cord. Moreover, almost all of the FB-labeled sprouting/regenerating neurons expressed BDNF, and approximately 55% of these neurons were surrounded by p75 neurotrophin receptor-positive glial cells. This combined injury led to an increase in the number of BDNF- and TrkB-immunoreactive nerve fibers in the dorsal column caudal to the lesion site. Taken together, these findings demonstrate that L5 VRT promotes sprouting/regeneration of ascending sensory neurons, indicating that sensory axotomy may not be essential for the plasticity of injured dorsal column axons. Thus, the sensory neurons could be preprimed in the regenerative milieu of Wallerian degeneration and neuroinflammation, which might alter the expression of neurotrophic factors and their receptors, facilitating sprouting/regeneration of ascending sensory neurons.     

Dynamic changes in glypican-1 expression in dorsal root ganglion neurons after peripheral and central axonal injury

Glypican-1, a glycosyl phosphatidyl inositol (GPI)-anchored heparan sulphate proteoglycan expressed in the developing and mature cells of the central nervous system, acts as a coreceptor for diverse ligands, including slit axonal guidance proteins, fibroblast growth factors and laminin. We have examined its expression in primary sensory dorsal root ganglion (DRG) neurons and spinal cord after axonal injury. In noninjured rats, glypican-1 mRNA and protein are constitutively expressed at low levels in lumbar DRGs. Sciatic nerve transection results in a two-fold increase in mRNA and protein expression. High glypican-1 expression persists until the injured axons reinnervate their peripheral targets, as in the case of a crushed nerve. Injury to the central axons of DRG neurons by either a dorsal column injury or a dorsal root transection also up-regulates glypican-1, a feature that differs from most DRG axonal injury-induced genes, whose regulation changes only after peripheral and not central axonal injury. After axonal injury, the cellular localization of glypican-1 changes from a nuclear pattern restricted to neurons in noninjured DRGs, to the cytoplasm and membrane of injured neurons, as well as neighbouring non-neuronal cells. Sciatic nerve transection also leads to an accumulation of glypican-1 in the proximal nerve segment of injured axons. Glypican-1 is coexpressed with robo 2 and its up-regulation after axonal injury may contribute to an altered sensitivity to axonal growth or guidance cues.     

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.     

Adrenergic innervation of rat sensory ganglia following proximal or distal painful sciatic neuropathy: distinct mechanisms revealed by anti-NGF treatment

Sympathetic axons invade dorsal root ganglia (DRG) following nerve injury, and activity in the resulting pericellular axonal 'baskets' may underlie painful sympathetic-sensory coupling. Sympathetic sprouting into the DRG may be stimulated by nerve growth factor (NGF). To test this hypothesis, we investigated the effect of daily anti-NGF administration on pain and on sprouting in the DRG induced by chronic sciatic constriction injury (CCI) or L5 spinal nerve ligation (SNL). These models have been shown to differ subtly in the onset of pain behaviours and adrenergic sprouting, and we now demonstrate a fundamental difference in the way sympathetic axons invade the DRG: after CCI, perivascular noradrenergic collaterals sprouted into the DRG in a manner dependent upon peripherally derived NGF. In contrast, after SNL, regenerating sympathetic axons were diverted towards the DRG from the spinal nerve by the obstructing ligature, and this effect was only moderately impeded by anti-NGF. The differential dependence on anti-NGF suggests that adrenergic innervation of the DRG after SNL and CCI may reflect regenerative and collateral sprouting, respectively. Pain behaviour was similarly affected: anti-NGF completely prevented CCI-induced thermal hyperalgesia and mechanoallodynia, but the same treatment only partly relieved these symptoms following SNL. These differences emphasize that although CCI and SNL may result in similar behavioural abnormalities, the underlying mechanisms may be governed by distinct processes, differentially dependent on peripheral NGF. These mechanistic differences will have to be considered in the development of appropriate treatment strategies for neuropathic pain produced by different types of pathology.     

Flunarizine enhances survival and regeneration of sensory and motor neurons after peripheral nerve injury

The diphenylpiperazine, flunarizine, partially prevents apoptosis after trophic factor deprivation in neural crest-derived neurons. Flunarizine protects dorsal root ganglion neurons (DRG) after nerve growth factor (NGF) withdrawal in vitro and after peripheral nerve injury in newborn rats in vivo. We have further studied the mechanisms of neuronal protection by flunarizine. Oligosomal DNA fragmentation, a hallmark of apoptosis, was significantly decreased by treatment of DRG neurons with flunarizine after NGF deprivation. We examined the effect on survival of the timing of administration of flunarizine to DRG neurons both in vitro and in vivo. Flunarizine effectively rescued dissociated DRG neurons if administered up to six hours after NGF withdrawal. In vivo, flunarizine prevented DRG neuronal death after sciatic axotomy in newborn rats if given soon after injury. Long-term experiments were done to test the ability of flunarizine to protect neurons and enhance regeneration after sciatic nerve injury. Newborn rats were subjected to peripheral nerve injury and administered flunarizine for four weeks; no further treatment was given for an additional 12 weeks. The group treated with flunarizine demonstrated a significantly increased number of DRG and spinal motor neurons that had regenerated axons into the distal sciatic nerve as determined by retrograde labeling with HRR Myelinated axons in the sural nerve in the group treated with flunarizine increased by nearly two-fold compared to control animals. Thus, flunarizine was able to enhance survival and promote long-term regeneration of sensory and motor spinal neurons after peripheral nerve injury.     

Delayed loss of small dorsal root ganglion cells after transection of the rat sciatic nerve

The present study deals with changes in numbers and sizes of primary afferent neurons (dorsal root ganglion [DRG] cells) after sciatic nerve transection. We find that this lesion in adult rats leads to death of some DRG cells by 8 weeks and 37% by 32 weeks after the lesion. The loss of cells appears earlier in and is more severe in B-cells (small, dark cells with unmyelinated axons) than A-cells (large, light cells with myelinated axons). With regard to mean cell volumes, there is a tendency for both categories of DRG cells to be smaller, but except for isolated time points, these differences are not statistically significant. These findings differ from most earlier reports in that the cell loss takes place later than usually reported, that the loss is more severe for B-cells, and that neither A- or B-cells change size significantly. Accordingly, we conclude that sciatic nerve transection in adult rats leads to a slowly developing but relatively profound loss of primary afferent neurons that is more severe for B-cells. These results can serve as a basis for studies to determine the effectiveness of trophic or survival factors in avoiding axotomy induced cell death.     

Nerve growth factors (NGF, BDNF) enhance axonal regeneration but are not required for survival of adult sensory neurons

Largely on the basis of studies with nerve growth factor (NGF), it is now widely accepted that development of the peripheral nervous system of vertebrates is dependent in part on the interaction of immature sensory and autonomic neurons with specific survival factors that are derived from peripheral target fields. I have found, in marked contrast to an absolute requirement for NGF during development, that adult rat dorsal root ganglion sensory neurons are not dependent on NGF or other survival factors for long-term (3-4 weeks) maintenance in vitro. When dissociated and enriched, at least 70-80% of adult DRG neurons survived and extended long processes either in the absence of exogenously added NGF or upon the removal of any possible source of endogenous NGF or other neurotrophic activity (i.e., nonneuronal cells, in chemically defined culture medium, in the presence of an excess of anti-NGF antibodies, or when cultured as single neurons in microwells). Although not required for survival or expression of a range of complex morphologies, both NGF and brain-derived neurotrophic factor (BDNF) were found to stimulate the regeneration of axons from adult DRG neurons.     

3,3′-Iminodipropionitrile induces neurofilament accumulations in the perikarya of rat vestibular ganglion neurons

Exposure of rats to 3,3′-iminodipropionitrile (IDPN) results in neurofilament (NF)-filled swellings in the proximal axons of a number of large neurons, including sensory neurons in the dorsal root ganglia (DRG) and motor neurons in the spinal cord. The present report describes the effects of acute and chronic IDPN exposure on the vestibular ganglion (VG) neurons as compared to those on the DRG neurons. In the VG, IDPN induced intra-perikaryal accumulation of morphologically and immunocytochemically identified NFs. In the DRG of the same treated animals, IDPN induced proximal axonal swelling but no perikaryal NF accumulations. We concluded that the VG neurons preferentially express the IDPN-induced NF pathology in their myelinated cell bodies. It is hypothesized that the NF pathology occurring after IDPN is preferentially expressed in myelinated structures.     

Thermosensitivity of large primary sensory neurons

Spontaneous activity originating in the injured nerve or the dorsal root ganglion (DRG) has been implicated in the development and maintenance of neuropathic pain. The inherent characteristics of spontaneous activity and the causal factors that modulate its firing pattern and frequency are not fully understood. We attempted to assess the thermosensitivity of spontaneous activity in dorsal root ganglion (DRG) neurons in normal rats and in rats with chronic compression of the DRG (CCD) in an in vitro nerve-DRG preparation. Extracellular, dorsal root recording from 66 spontaneously active CCD Abeta fibers indicate that: (1) decreasing bath temperature from 37 to 36-26 degrees C significantly decreased the firing rate (FR) in 85% (56/66) of fibers tested, of which 19 fibers (34%) responded to temperature change at physiological range (36-37 degrees C), whereas the remaining fibers responded at lower temperature levels (26-36 degrees C); (2) cooling of the DRG increased the FR in 12% (8/66) of fibers tested; (3) similarly, the firing rate of 21/26 spontaneously active Abeta fibers from normal rats was decreased following temperature decrease; (4) intracellular recordings from 38 normal neurons revealed that cooling the DRG significantly increased the action potential (AP) threshold, AP duration, AP amplitude and afterhyperpolarization (AHP) duration, but decreased AHP amplitude, maximal depolarizing and repolarizing rates. There was no significant change in the rheobase currents or the resting membrane potential. The present study indicates that large sensory neurons with myelinated axons are temperature dependent. It also suggests that maintenance of a stable temperature is critical for reliable characterization of spontaneous activity of sensory neurons.     

Anterograde TNFα Transport From Rat Dorsal Root Ganglion To Spinal Cord And Injured Sciatic Nerve

Spontaneous activity originating in the injured nerve or the dorsal root ganglion (DRG) has been implicated in the development and maintenance of neuropathic pain. The inherent characteristics of spontaneous activity and the causal factors that modulate its firing pattern and frequency are not fully understood. We attempted to assess the thermosensitivity of spontaneous activity in dorsal root ganglion (DRG) neurons in normal rats and in rat, with cl-ironic compression of the DRG (CCD) in an in vitro nerve-DRG preparation. Extracellular, dorsal root recording from 66 spontaneously active CCD Abeta fibers indicate that: (1) decreasing bath temperature from 37 to 36-26 °C significantly decreased the firing rate (FR) in 85% (56/66) of fibers tested, of which 19 fibers (34%) responded to temperature change at physiological range (36-37 °C), whereas the remaining fibers responded at lower temperature levels (26-36 °C); (2) cooling of the DRG increased the FR in 12% (8/66) of fibers tested; (3) similarly, the firing rate of 21/26 spontaneously active Abeta fibers from normal rats was decreased following temperature decrease; (4) intracellular recordings from 38 normal neurons revealed that cooling the DRG significantly increased the action potential (AP) threshold, A-P duration, AP amplitude and afterhyperpolarization (AHP) duration, but decreased AHP amplitude, maximal depolarizing and repolarizing rates. There was no significant change in the rheobase currents or the resting membrane potential. The present study indicates that large sensory neurons with myelinated axons are temperature dependent. It also suggests that maintenance of a stable temperature is critical for reliable characterization of spontaneous activity of sensory neurons.     

Regeneration of primary sensory axons into the adult rat spinal cord via a peripheral nerve graft bridging the lumbar dorsal roots to the dorsal column

This study investigated the feasibility of using a peripheral nerve autograft (NAG) to promote and guide regeneration of sensory axons from the caudal lumbar dorsal roots to the rostral dorsal column following a lower thoracic cordotomy in adult rats. After a left hemicordotomy at the T13 vertebra level and ipsilateral L3 and L4 rhizotomies, a peripheral NAG (peroneal nerve) was connected to the distal roots stumps, then implanted into the left dorsal column 10 mm rostral to hemicordotomy site (n = 12). After surgery, all animals of the experimental group experienced complete anesthesia in their left hindlimb. Three months later, a slight response to nociceptive stimulation reappeared in L3 and/or L4 dermatomes in 6 of the 12 experimental animals. None of these animals exhibited self-mutilation. Nine months after surgery, we performed retrograde tracing studies by injecting horseradish peroxidase (HRP) into the left dorsal column 30 mm rostral to the NAG implantation site. In eight animals, we found HRP-stained neurons in the left L3 and/or L4 dorsal root ganglia (DRG). The mean number of HRP-stained neurons per DRG was 71 +/- 92 (range 2-259). In control groups, no HRP-stained neurons were found in L3 or L4 DRG. Histological analysis of the NAG showed evidence of axonal regeneration in all 8 animals with positive retrograde labeling of DRG neurons. However, we did not find a statistical correlation between the number of HRP-stained neurons and the degree of sensory recovery. This study demonstrates that an NAG joining dorsal roots to the dorsal column, thus shunting the original CNS-PNS junction, can support regeneration of central axons from DRG primary sensory neurons into the dorsal column over distances of at least 30 mm despite the inhibitory influence of the CNS white matter.