Differences in Sympathetic Innervation of Mouse DRG Following Proximal or Distal Nerve Lesions

Nerve injury leads to novel sympathetic innervation of the dorsal root ganglion (DRG). We have hypothesized previously that the degenerating nerve increases the sympathetic sprouting in the DRG and pain after chronic sciatic constriction injury (CCI) by virtue of its influence on sensory and sympathetic axons spared by the injury. However, L5 spinal nerve ligation and transection (SNL) results in the complete isolation of the L5 DRG from the degenerating stump, yet sympathetic axons invade the ganglion, and sympathetically dependent pain develops. We investigated the role of Wallerian degeneration in both sympathetic sprouting and neuropathic pain in these two models of painful peripheral neuropathy by comparing responses of normal C57B1/6J and C57B1/Wld^smice in which degeneration is impaired. After CCI, Wld^smice, unlike 6J mice, did not develop thermal or mechanoallodynia or sympathetic innervation of the L5 DRG. After SNL, both strains developed mechanoallodynia and sympathetic sprouts in L5, but only 6J mice developed thermal allodynia. Observation of the origins of the invading sympathetic axons revealed that after CCI, sympathetics innervating blood vessels and dura (probably intact) sprouted into the ganglion, but after SNL sympathetics (probably axotomized) invaded from the injured spinal nerve. Based on these findings, we hypothesize that there are two mechanisms for sympathetic sprouting into DRG, differentially dependent on Wallerian degeneration. Analysis of pain behavior in these animals reveals that (i) mechanoallodynia and sympathetic innervation of the DRG tend to coincide and (ii) thermal allodynia and Wallerian degeneration, but not sympathetic innervation of the DRG tend to coincide.     

Satellite-cell-derived nerve growth factor and neurotrophin-3 are involved in noradrenergic sprouting in the dorsal root ganglia following peripheral nerve injury in the rat

Injury to a peripheral nerve induces in the dorsal root ganglia (DRG) sprouting of sympathetic and peptidergic terminals around large-diameter sensory neurons that project in the damaged nerve. This pathological change may be implicated in the chronic pain syndromes seen in some patients with peripheral nerve injury. The mechanisms underlying the sprouting are not known. Using in situ hybridization and immunohistochemical techniques, we have now found that nerve growth factor (NGF) and neurotrophin-3 (NT3) synthesis is upregulated in satellite cells surrounding neurons in lesioned DRG as early as 48 h after nerve injury. This response lasts for at least 2 months. Quantitative analysis showed that the levels of mRNAs for NT3 and NGF increased in ipsilateral but not contralateral DRG after nerve injury. Noradrenergic sprouting around the axotomized neurons was associated with p75-immunoreactive satellite cells. Further, antibodies specific to NGF or NT3, delivered by an osmotic mini-pump to the DRG via the lesioned L5 spinal nerve, significantly reduced noradrenergic sprouting. These results implicate satellite cell-derived neurotrophins in the induction of sympathetic sprouting following peripheral nerve injury.     

Normal and injury-induced sympathetic innervation of rat dorsal root ganglia increases with age

In rats, partial injury to a peripheral nerve often leads to sympathetically maintained pain (SMP). In humans, this condition is especially apparent in the elderly. Nerve injury also causes perivascular sympathetic axons to sprout into the dorsal root ganglion (DRG), forming a possible anatomical substrate for SMP. Here, we describe the effects of chronic sciatic nerve constriction injury (CCI) in young (3 months) and old (16 months) rats on neuropathic pain behavior and on sympathetic sprouting in DRG. Behavioral tests assessed changes in thermal allodynia and hyperalgesia and in mechanical allodynia. We found that 1) sympathetic innervation of the DRG increased naturally with age, forming pericellular baskets mainly around large DRG neurons, and that sympathetic fibers were often associated with myelinated sensory axons; 2) sympathetic fiber density following CCI was also greater in old than in young rats; and 3) in old rats, thermal allodynia was less pronounced than in young rats, whereas thermal hyperalgesia and mechanical allodynia were more pronounced. These results highlight the possibility that sympathetic sprouting in the DRG is responsible for the sympathetic generation or maintenance of pain, especially in the elderly. J. Comp. Neurol. 394:38–47, 1998. © 1998 Wiley-Liss, Inc.     

Sympathetic Fiber Sprouting in Chronically Compressed Dorsal Root Ganglia Without Peripheral Axotomy

Sympathetic axonal sprouting in axotomized dorsal root ganglia (DRG) has been shown to be a major phenomenon implicated in neuropathic pain. However, it is not known whether sympathetic sprouting can occur in pathologic ganglia without peripheral axotomy. We thus examined presence and density of sympathetic axonal sprouting within DRG of rats subjected to a persistent compressive injury by inserting a stainless steel metal rod into L(4) and L(5) lumbar intervertebral foramen. Sympathetic axons were identified by immunohistochemical staining with anti-tyrosine hydroxylase antibodies. Results indicate that progressive increase in sympathetic axonal sprouting occurred in the bilateral DRGs between postoperative days 2 and 28. The sympathetic fiber density was greater on the lesion side than the contralateral side. In conclusion, chronic compressive injury of the DRG results in sympathetic sprouting in the non-axotomized ganglion and may partially contribute to the development and maintenance of certain pathological pain states.     

Sympathetic nerves in adult rats regenerate normally and restore pilomotor function during an anti-NGF treatment that prevents their collateral sprouting.

We have used anti-nerve growth factor (anti-NGF) [corrected] administration to study the NGF dependency of the reinnervation of denervated skin by sympathetic nerves in the adult rat. Sympathetic pilomotor fields were revealed by electrical stimulation of selected dorsal cutaneous nerves; the affected skin rapidly assumed a "gooseflesh" appearance, sharply demarcated from surrounding unstimulated skin. Examined 2-5 days after section of neighboring nerves, the "isolated" pilomotor field of the spared nerve was found to be coextensive with an area of amine-fluorescent fibers that were associated with pilomotor muscles and blood vessels. After its isolation, a pilomotor field begins to expand into the surrounding deprived territory, reaching a maximum size at approximately 40 days. Fluorescence studies confirmed that new sympathetic fiber growth had occurred into the expanded regions of such fields. Daily injections of polyclonal anti-NGF serum completely prevented these pilomotor field expansions. Following termination of the anti-NGF treatment, expansion proceeded normally. Finally, if the onset of anti-NGF treatment was delayed until pilomotor field expansion had already commenced, further expansion was halted. Regeneration of sympathetic fibers was evoked by crushing a selected nerve. Recovery of pilomotor function in the totally denervated skin was first detected at about 20 days postcrush, and the field progressively enlarged over the next 40 days. Although the imposed NGF deprivation is known to cause a demonstrable shrinkage, and presumably atrophy, of sympathetic ganglia, the anti-NGF treatment appeared to impair neither the restoration of a pilomotor field after nerve crush, nor its continued expansion into skin regions well beyond that originally supplied by the nerve, i.e., into territory whose invasion by collateral sprouts would have been totally prevented by the treatment. During such NGF deprivation, fluorescent regenerating fibers were visualized in the nerve trunk. We conclude that even though the regenerating and collaterally sprouting sympathetic fibers probably utilise the same degenerating dermal pathways to reach and functionally reinnervate the same denervated targets, only the collateral sprouting of the uninjured axons is dependent upon endogenous NGF. These findings extend the results described earlier for nociceptive fibers, and suggest that the contrasting dependencies upon growth factors of sprouting and regeneration might apply throughout the adult nervous system.     

Effects of endogenous neurotrophins on sympathetic sprouting in the dorsal root ganglia and allodynia following spinal nerve injury

Peripheral nerve injury is often complicated by a chronic pain syndrome that is difficult to treat. In animal models of peripheral nerve injury, sympathetic nerve terminals in the dorsal root ganglia (DRG) sprout to form baskets around large diameter neurons, an anatomical change that has been implicated in the induction of neuropathic pain. In the present study, we have investigated whether neurotrophins derived from peripheral sources play any roles in sympathetic sprouting and neuropathic pain in a rat model of peripheral nerve injury. After transection of the left lumbar (L) 5 spinal nerve, antisera specific to neurotrophins were injected intraperitoneally twice a week for 2 weeks. The foot withdrawal response to von Frey hairs was examined on days 1, 3, 7, 10, and 14 postlesion. After completion of behavioral tests, sympathetic sprouting in DRG was examined by tyrosine hydroxylase (TH) immunohistochemistry. The number of TH-immunoreactive (ir) fibers and baskets around large neurons within the lesioned DRG was dramatically increased in the rats treated with control normal sheep serum. Antisera specific to nerve growth factor (NGF), neurotrophin-3 (NT3), and brain-derived neurotrophic factor (BDNF) significantly reduced the sympathetic sprouting and the formation of baskets. L5 spinal nerve lesion induced a significant increase in foot withdrawal responses to von Frey hair stimuli, which was attenuated by treatment of antisera to neurotrophins with a different time sequential. The effect of BDNF antiserum occurred earlier and lasted longer than those of NGF and NT3 antisera. These results implicate that peripherally derived neurotrophins are involved in the induction of sympathetic sprouting and neuropathic pain following peripheral nerve injury.     

Sprouting sympathetic fibers form synaptic varicosities in the dorsal root ganglion of the rat with neuropathic injury

Peripheral nerve injury in a rat model (spinal nerve ligation) of neuropathic pain triggers sprouting of sympathetic fibers in the dorsal root ganglion (DRG). This sympathetic sprouting has been suggested as an important underlying mechanism for pain behaviors. To investigate the possibility of functional interaction between sprouted sympathetic fibers and sensory neurons, the present study examined the fine morphology and structural relationship between sympathetic fibers and the DRG neurons by electron microscopy. Sympathetic postganglionic fibers, as identified by electron microscopic immunostaining for tyrosine hydroxylase (TH), were all unmyelinated fibers and some of them ended as growth cones. In addition, many vesicle-containing axonal enlargements (we will refer these as synaptic varicosities) were found in the interstitial space around DRG neurons, and some were enclosed within the satellite cell capsule which surrounded the DRG soma. The presence of sympathetic synaptic varicosities near or in apposition with either the DRG somata or their processes provides a structural basis for possible interactions between sensory neurons and sympathetic fibers in the DRG of neuropathic rats. © 1997 Elsevier Science B.V. All rights reserved.     

Sympathetic sprouting in the dorsal root ganglion after spinal nerve ligation: evidence of regenerative collateral sprouting

It is well documented that there is an increase in the number of sympathetic fibers within the dorsal root ganglion (DRG) after a peripheral nerve injury. The present study examined the numbers and distribution of sympathetic fibers in the DRG and their sprouting routes by utilizing various surgical manipulations and retrograde tracing and immunohistochemical staining methods in spinal nerve-ligated neuropathic rats. The appearance of many double immunostained fibers with antibodies to tyrosine hydroxylase (TH) and growth associated protein-43 (GAP-43) in the L5 DRG 1 week after L5 spinal nerve ligation, indicated sprouting of sympathetic fibers. The confined location of early sprouting sympathetic fibers in the distal half of the L5 DRG confirmed that sprouting fibers come primarily from the injured spinal nerve. A second cut proximal to the previously ligated L5 spinal nerve -- a process which would transect the regenerating sympathetic fibers extending from the injury site -- did not change the density of sympathetic fibers in the L5 DRG. When retrograde tracers (fast blue and diamidino yellow) were injected into the L5 spinal nerve and DRG, respectively, the number of double-labeled sympathetic postganglionic neurons was greatly increased after spinal nerve ligation, suggesting the increased number of sympathetic neurons projecting to both the spinal nerve and DRG. All these results indicate that many sympathetic fibers in the DRG are regenerating branches that are sprouting from the proximal part of the injured spinal nerve (regenerative collateral sprouting).     

Increase of preprotachykinin mRNA and substance P immunoreactivity in spared dorsal root ganglion neurons following partial sciatic nerve injury

Complete sciatic nerve injury reduces substance P (SP) expression in primary sensory neurons of the L4 and L5 dorsal root ganglia (DRG), due to loss of target-derived nerve growth factor (NGF). Partial nerve injury spares a proportion of DRG neurons, whose axons lie in the partially degenerating nerve, and are exposed to elevated NGF levels from Schwann and other endoneurial cells involved in Wallerian degeneration. To test the hypothesis that SP is elevated in spared DRG neurons following partial nerve injury, we compared the effects of complete sciatic nerve transection (CSNT) with those of two types of partial injury, partial sciatic nerve transection (PSNT) and chronic constriction injury (CCI). As expected, a CSNT profoundly decreased SP expression at 4 and 14 days postinjury, but after PSNT and CCI the levels of preprotachykinin (PPT) mRNA, assessed by in situ hybridization, and the SP immunoreactivity (SP-IR) of the L4 and L5 DRGs did not decrease, nor did dorsal horn SP-IR decrease. Using retrograde labelling with fluorogold to identify spared DRG neurons, we found that the proportion of these neurons expressing SP-IR 14 days after injury was much higher than in neurons of normal DRGs. Further, the highest levels of SP-IR in individual neurons were detected in ipsilateral L4 and L5 DRG neurons after PSNT and CCI. We conclude that partial sciatic nerve injury elevates SP levels in spared DRG neurons. This phenomenon might be involved in the development of neuropathic pain, which commonly follows partial nerve injury.     

Sensory nerves in adult rats regenerate and restore sensory function to the skin independently of endogenous NGF.

We have investigated the possible roles of NGF, and of impulse activity, in the regeneration of sensory nerves. Unexpectedly, the ability of crushed axons to regrow and to restore functional recovery of three sensory modalities in adult rat skin (A alpha-mediated touch, A delta-mediated mechanonociception, and C-fiber-mediated heat nociception) was totally unaffected by anti-NGF treatment. This finding applied even when the anti-NGF dosage was almost eight times that which entirely blocked collateral sprouting of the undamaged axons of both classes of nociceptive nerves (the A alpha-axons do not sprout in adult animals). In the same anti-NGF-treated animal, regeneration would proceed normally on the one side, while collateral sprouting was prevented on the other. Light microscopic and EM examination revealed that in the denervated skin the regenerating axons utilized the same dermal perineurial pathways followed by collaterally sprouting axons. Regeneration within these antibody-accessible pathways progressed normally during anti-NGF treatment, extending 1-2 cm beyond the former field borders, that is, into territory whose invasion by collaterally sprouting axons was totally blocked. The blood-nerve barrier is absent within the degenerating peripheral nerve trunk, a putative NGF source for regenerating fibers but not for sprouting ones. The NGF-independent regeneration was also found to be unaffected when putative spinal cord sources of NGF were eliminated by dorsal root excision. Anti-NGF treatment also failed to block regeneration across 4 mm excision gaps in the nerve trunk. The daily anti-NGF regime continued to be effective for at least 8 weeks, at which time newly evoked collateral sprouting could still be blocked. Exogenous NGF, in doses that evoke collateral sprouting de novo in normal skin, failed to influence regeneration. Finally, an electrical stimulus regime, which markedly reduces the latency of collateral sprouting, failed to affect the time to arrival of regenerating axons at the skin, or the rate of their arborization in it. We conclude that, in striking contrast to their collateral sprouting, the regeneration of nociceptive axons occurs independently of endogenous NGF and is unaffected by impulse activity. These findings further support the proposal that these two growth behaviors have basically different biological functions in the organism.     

Sympathetic sprouting in the dorsal root ganglia of the injured peripheral nerve in a rat neuropathic pain model

The extent of the sprouting of sympathetic postganglionic fibers in the dorsal root ganglion (DRG) and the peripheral nerves was examined in neuropathic rats at different postoperative times. After the L5 and L6 spinal nerves were ligated on one side, three different pain behavior tests (representing mechanical allodynia, cold allodynia, ongoing pain exacerbated by cold stress) were performed at various time intervals. The sympathetic postganglionic fibers were visualized by immunostaining with antibodies to tyrosine hydroxylase (TH). In the neuropathic rats, all three pain behaviors were fully developed within 3 days after the surgery, maintained up to 2 weeks, and then started to decline gradually afterward. At 20 weeks after neuropathic surgery, pain behaviors were reduced significantly compared to the peak response, but were still higher than the presurgery levels. Sympathectomy, performed 4 days after neuropathic surgery, almost completely abolished the signs of mechanical allodynia and ongoing pain behaviors, and it reduced the behaviors of cold allodynia to approximately half. The numerical density of sympathetic fibers in the DRG of an injured segment was significantly higher at 1, 4, and 20 weeks after neuropathic surgery as compared to the normal, suggesting that there is sprouting of sympathetic fibers in the DRG after peripheral nerve injury. Sprouting of sympathetic fibers in the DRG was extensive as early as 2 days after the spinal nerve ligation, and the sprouted fibers were almost completely eliminated after sympathectomy. The data suggest that sympathetic innervation of the DRG may play an important role in the development and maintenance of sympathetically maintained neuropathic pain. © 1996 Wiley-Liss, Inc.     

Persistence of anti-NGF induced dorsal root axons: possible penetration into the mammalian spinal cord

Neonatal rats were given daily injections of antisera to nerve growth factor protein (anti-NGF) for a period of 1 month and then allowed to survive 17 more months. The number of neurons in dorsal root ganglia (DRG) and axons in the dorsal root (DR) were determined in the anti-NGF rats and compared to similar numbers from untreated littermates. We found a 32% decrease in DRG neuron number and 32 and 34% increases in myelinated and unmyelinated DR fibers, respectively, in the anti-NGF rats. The sensory cell bodies in the anti-NGF rats were on the average 23% larger than in the normal rats. We conclude that in an NGF deprived environment a population of DRG neurons dies, principally the small neurons, and in response the surviving neurons emit extra processes which persist for most of the life of the rat. This suggests that the anti-NGF induced axons enter the spinal cord and synapse.     

Cyclooxygenase inhibition in nerve-injury- and TNF-induced hyperalgesia in the rat

After nerve injury, cyclooxygenase-2 (COX-2) is upregulated in spinal cord and peripheral nerve, the latter being dependent on tumor necrosis factor-alpha (TNF). Here we asked whether COX inhibitors attenuate pain behavior induced by chronic constrictive sciatic nerve injury (CCI) or intraneural injection of TNF (2.5 pg/ml). Rats received either 0.9% saline, the nonselective COX inhibitor ibuprofen (40 mg/kg) or the selective COX-2 inhibitor celecoxib (10 or 30 mg/kg) twice daily by gavage started 2 days before, 12 h or 7 days after surgery. Mechanical allodynia and thermal hyperalgesia induced by CCI was moderately, but consistently attenuated by early (day -2 or 12 h after CCI), but not late (7 days after CCI) ibuprofen and celecoxib treatment. Mechanical allodynia, but not thermal hyperalgesia induced by intraneural TNF, was reduced by ibuprofen, but not by celecoxib treatment 5 and 7 days after injection. Sciatic nerves, lumbar dorsal root ganglia (DRG) and spinal cords from rats with treatment started 12 h after surgery were analyzed for prostaglandin E2 (PGE2) levels 10 days after CCI. In injured nerves and ipsilateral DRG, PGE2 levels were increased. Ibuprofen treatment reversed PGE2 levels in injured nerves and DRG, whereas celecoxib blocked increased PGE2 levels only in nerves. In spinal cord, no change in PGE2 levels was observed. In contrast to the marked inhibition of nerve-injury-induced upregulation of PGE2 by COX inhibitors, the effect on pain behavior was modest. Nerve-injury- and TNF-induced pain-related behavior seem to be only partly dependent on peripheral prostaglandins.     

Effects of long-term nerve growth factor deprivation on the nervous system of the adult rat: An experimental autoimmune approach

Adult rats immunized with 2.5S mouse nerve growth factor (NGF) produced antibodies which cross-reacted with rat NGF. By the criterion of ammonium sulfate precipitation followed by Sephadex G-200 chromatography, all serum anti-NGF activity was retained in the IgG fraction. Animals which developed and maintained chronic (5–6 months) serum titers of anti-NGF demonstrated a pronounced biochemical and morphological atrophy of the superior cervical ganglion which was accompanied by a 35–40% reduction in neuronal number. Norepinephrine was reduced by approximately 90% in heart and brown fat. The extent of biochemical atrophy correlated well with serum titers of anti-NGF. No effects were observed on the short adrenergic neurons of the vas deferens, adrenal medullary chromaffin cells, central adrenergic neurons, or peripheral sensory neurons. These results strongly suggest that mature peripheral sympathetic neurons remain dependent on NGF for survival as well as for maintenance.     

Effect of injury on nerve growth factor uptake by sensory ganglia

The level of the nerve growth factor protein, NGF, in vivo has a profound influence on axonal sprouting by sensory neurons of vertebrate dorsal root ganglia. There is evidence also that NGF may play similar roles in cholinergic central structures in brain. In both instances, retrograde transport of NGF has been demonstrated. Here we examined uptake of NGF by DRG neurons in response to contusion injury of the spinal cord. Under these conditions there was uptake and transport of NGF into large DRG neurons via central processes but no uptake by non-DRG central neurons. Thus, any effects of NGF on spinal neurons or their processes would be secondary to the direct effects of NGF on DRG neurons.     

GADD45A protects against cell death in dorsal root ganglion neurons following peripheral nerve injury

A significant loss of neurons in the dorsal root ganglia (DRG) has been reported in animal models of peripheral nerve injury. Neonatal sensory neurons are more susceptible than adult neurons to axotomy- or nerve growth factor (NGF) withdrawal-induced cell death. To develop therapies for preventing irreversible sensory cell loss, it is essential to understand the molecular mechanisms responsible for DRG cell death and survival. Here we describe how the expression of the growth arrest- and DNA damage-inducible gene 45α (GADD45A) is correlated with neuronal survival after axotomy in vivo and after NGF withdrawal in vitro. GADD45A expression is low at birth and does not change significantly after spinal nerve ligation (SNL). In contrast, GADD45A is robustly up-regulated in the adult rat DRG 24 hr after SNL, and this up-regulation persists as long as the injured fibers are prevented from regenerating. In vitro delivery of GADD45A protects neonatal rat DRG neurons from NGF withdrawal-induced cytochrome c release and cell death. In addition, in vivo knockdown of GADD45A expression in adult injured DRG by small hairpin RNA increased cell death. Our results indicate that GADD45A protects neuronal cells from SNL-induced cell death.     

Nerve growth factor alleviates a painful peripheral neuropathy in rats

Nerve growth factor (NGF) reverses some effects of axotomy and prevents toxic neuropathy in adult rodents. We tested the effect of NGF on behavioral hyperalgesia resulting from a chronic constriction injury (CCI) of the sciatic nerve in the rat [5]. CCI rats exhibit thermal hyperalgesia as demonstrated by a reduction of paw withdrawal latency to a noxious thermal stimulus applied to the paw on the side of injury. The mechanical sensitivity of the ipsilateral hindpaw, assessed with von Frey filaments, was also significantly increased. There were no significant changes in nociceptive thresholds on the contralateral side. When NGF was infused directly on the ligated nerve via an osmotic pump (0.5 μg/μl/h for 7 days) immediately after the ligation, thermal hyperalgesia was abolished from postoperative days 5 up to at least two weeks. The CCI-induced decrease in mechanical threshold was also abolished by NGF. However, NGF had only a minor effect on the abnormally long response duration, a second measure of mechanical sensitivity, to the mechanical stimulus. Delayed infusion of NGF four days after the ligation failed to block hyperalgesia. Infusion of NGF on the sciatic nerve of rats that had no CCI had no significant effect on paw withdrawal latency. Infusion of anti-NGF antiserum did not enhance hyperalgesia in CCI rats. These results suggest that alterations in neurotrophic factor(s) contribute to the development of behavioral hyperalgesia in an animal model of neuropathy and that NGF may have therapeutic value in the treatment of neuropathic pain in humans.     

NGF-dependent and NGF-independent recovery of sympathetic function after chemical sympathectomy with 6-hydroxydopamine

To help clarify the distinction between the nerve growth factor (NGF)-dependent collateral sprouting of sympathetic nerves and their NGF-independent regeneration after crush, we used 6-hydoxydopamine (OHDA) to destroy the sympathetic terminals in adult rats; this leaves the axons damage-free. Would recovery occur by regeneration and/or collateral sprouting? A single 6-OHDA injection abolished the sympathetic pilomotor field revealed by electrical stimulation of a cutaneous nerve. Recovery began within 2 days, and by 20 days the field was reestablished. If the field was “isolated” by adjacent denervations at the time of 6-OHDA treatment, the recovering pilomotor field expanded extensively into the surrounding territory. In the presence of anti-NGF, however, the pilomotor field expansion ceased at about 60% of its former size; if anti-NGF treatment was discontinued, expansion recommenced and extended into the surrounding skin. We suggest that the latter, NGF-dependent, growth phase corresponds to collateral sprouting, and the initial NGF-independent one to regeneration. After simple nerve crush, however, such regeneration can triple the normal sympathetic field size. This difference between crush- and 6-OHDA-induced regeneration might relate to the “cell body reaction” (CBR); the CBR is reduced with increasing distance of the lesion and is undetectable after a 6-OHDA lesion. Since the CBR and the vigor of regeneration are both increased by repeated axonal injury, we tested the effects of multiple 6-OHDA treatments; this significantly increased the initial NGF-independent expansion. We hyprthesize that regeneration is regulated largely by mechanisms associated with the CBR, and that neurotrophin-dependent collateral sprouting occurs independently of these. © 1995 Wiley-Liss, Inc.     

Differential activation of MAPK in injured and uninjured DRG neurons following chronic constriction injury of the sciatic nerve in rats

To investigate the intracellular signal transduction pathways involved in the pathophysiological mechanisms of neuropathic pain after partial nerve injury, we examined the activation of extracellular signal-regulated protein kinase (ERK) and p38 mitogen-activated protein kinase (MAPK) in the dorsal root ganglion (DRG) in the chronic constriction injury (CCI) model. The CCI induced an increase in the phosphorylation of ERK in predominantly injured medium-sized and large-sized DRG neurons and in satellite glial cells. Treatment with the MAPK kinase 1/2 inhibitor, U0126, suppressed CCI-induced mechanical allodynia and partially reversed the increase in neuropeptide Y (NPY) expression in damaged DRG neurons. In contrast, the CCI induced the activation of p38, mainly in uninjured small-to-medium-diameter DRG neurons and in satellite glial cells. The p38 inhibitor, SB203580, reversed the CCI-induced heat hyperalgesia and also the increase in brain-derived neurotrophic factor (BDNF) expression in intact DRG neurons. On the other hand, the nerve growth factor (NGF)-induced increase in BDNF expression in small-to-medium-diameter neurons was reversed by SB203580, whereas the anti-NGF-induced increase in NPY in medium-sized and large-sized neurons was partially blocked by U0126. Taken together, our results demonstrate that the activation of ERK and p38 and also the changes in NPY and BDNF expression may occur in different populations of DRG neurons after CCI, partially through alterations in the target-derived NGF. These changes in injured and intact primary afferents are likely to have a substantial role in pathological states, and MAPK pathways in nociceptors may be potential targets for the development of novel analgesics.