Permanent effects of neonatally administered resiniferatoxin in the rat

We have previously demonstrated that resiniferatoxin functions in adult rats as an ultrapotent analog of capsaicin. In adults, capsaicin excites and then desensitizes a specific population of sensory neurons; when administered to neonates capsaicin causes degeneration of these neurons. We report here that treatment of newborn rats with resiniferatoxin caused a substantial (47%) loss of dorsal root ganglia neurons in adults and an almost complete loss of calcitonin gene related peptide-like immunoreactivity in both dorsal root ganglia and gasserian ganglia. The animals were unresponsive to noxious chemical stimuli and showed marked diminution (88%) of their neurogenic inflammatory response. Resiniferatoxin was at least 2 orders of magnitude more potent than capsaicin for inducing neurodegeneration in the neonates. Specific resiniferatoxin binding, thought to represent capsaicin receptors, decreased 80-90% in membranes from dorsal root ganglia and 50-70% in membranes from gasserian ganglia of adult rats treated neonatally with resiniferatoxin. The affinity for the residual binding decreased. We speculate that subpopulations of sensory neurons differ in susceptibility to neonatal resiniferatoxin treatment. Resiniferatoxin promises to be a useful probe to explore mechanisms of sensorotoxin-induced degeneration for subpopulations of capsaicin-sensitive sensory neurons.     

Galanin-like immunoreactivity in capsaicin sensitive sensory neurons and ganglia

In rats treated with capsaicin (CAP) as neonates, galanin-like (GA) immunoreactivity is markedly decreased in the trigeminal ganglion and the dorsal root ganglia as well as in the superficial layers of the dorsal spinal cord (laminae I and II), the substantia gelatinosa, the nucleus and tractus of the spinal trigeminal nerve and the nucleus commissuralis. Since CAP causes selective degeneration of primary sensory neurons of the C-fiber type and type B-cells of sensory ganglia, it is concluded that GA in CAP-sensitive primary sensory neurons represents a novel peptidergic system possibly involved in the transformation or modulation of peripheral nociceptive impulses. This system differs from the CAP-resistant GA-like neurons in other brain areas.     

Parvalbumin and calbindin D-28 k immunoreactivity in dorsal root ganglia in acquired immunodeficiency syndrome

Various degrees of neuronal degeneration have been found in lumbosacral dorsal root ganglia of patients with acquired immunodeficiency syndrome (AIDS). To characterize the subpopulations of primary sensory neurons affected in AIDS. we immunostained dorsal root ganglion tissues from 11 AIDS patients and six controls using antibodies to the calcium binding proteins, parvalbumin and calbindin D-28 k. In controls, the proportion of neurons containing parvalbumin and calbindin was 18.0% and 22.4%, respectively. The majority of parvalbumin-positive neurons, which are thought to be proprioceptive neurons, were of medium to large size, while calbindin was found in both large- and small-sized neurons. The density of parvalbumin-immunoreactive neurons was reduced by 7.3% in AIDS patients, but the density of calbindin-immunoreactive neurons was preserved. Furthermore, in AIDS cases, the number of parvalbumin-positive neurons was reduced more in dorsal root ganglia in which human immunodeficiency virus (HIV) antigen was detected than in HIV-negative ganglia. These results suggest that specific subpopulations of sensory neurons positive for parvalbumin may be differentially affected over the course of AIDS, and that this could be related to peripheral neuropathy which frequently occurs in the late stages of AIDS.     

Axon and neuron numbers after forelimb amputation in neonatal rats

It seems a paradox that more primary sensory neurons are lost but recovery is better after peripheral nerve injury in neonates as compared to adult mammals. A possible explanation is that surviving neurons sprout in the neonate. To test this, forelimbs in neonatal rats were amputated, which caused the death of many primary sensory neurons. The number of neurons in the dorsal root ganglia, and the number of myelinated and unmyelinated fibers in the dorsal and ventral roots were determined on the amputated and contralateral normal sides. On the amputated side, soma loss in the ganglia was 30%, and the fiber numbers were decreased by 16% in the dorsal root and increased by 20% in the ventral root. These data are compatible with the hypothesis that there is axonal branching or sprouting from surviving sensory neurons. In addition, morphometric analyses showed a changed myelin-axon relationship for central processes of sensory cells whose distal processes have been cut.     

Cell loss in lumbar dorsal root ganglia and transganglionic degeneration after sciatic nerve resection in the rat

The effects of sciatic nerve resection on lumbar dorsal root ganglion cells and their central branches have been studied in the adult rat. A quantitative analysis of the lumbar dorsal root ganglia indicated a 15–30% cell loss on the operated side. Argyrophilia indicating transganglionic degeneration was observed in Fink-Heimer stained sections from the lumbar spinal cord and the brainstem. The areas of degeneration argyrophilia were mainly located in the medial part of the ipsilateral L2–L6 dorsal horn laminae I–IV, the tract of Lissauer, the dorsal funiculus and the gracile nucleus. A few degenerating fibers could also be observed in the ipsilateral dorsal horn laminae V and VI, and in the ipsilateral ventral horn as well as in the contralateral dorsal and the gracile nucleus. The results confirm and extend previous findings at other levels and in other species. This suggests that cell loss and transganglionic degeneration may be general phenomena affecting a substantial proportion of primary sensory neurons following peripheral nerve injury.     

Comparison of reorganization of the somatosensory system in rats that sustained forelimb removal as neonates and as adults

Studies of sensory pathways in several species indicate that the extent and form of reorganization resulting from deafferentation early in life vs. adulthood are not the same. The reasons for such differences are not well understood. To gain further insight into age-dependent mechanisms of reorganization, this study compared the consequences of neonatal vs. adult forelimb amputation in rats at multiple levels of the sensory pathway, including primary somatosensory cortex, brainstem, and dorsal root ganglia. At the cortical level, the average area of the functional forelimb-stump representation from rats amputated as adults was significantly smaller (P < 0.05) than that of neonatally amputated rats (4.3 +/- 1.3 mm(2) vs. 6.6 +/- 1.5 mm(2), respectively). At the brainstem level, neonatally amputated rat cuneate neurons possessed the following responsivities: 20% stump responsive, 40% responsive to both stump and hindlimb, 30% responsive to another body region, and 10% unresponsive. In contrast, cuneate neurons of adult amputated rats were 70% stump responsive, 2% responsive to both stump and hindlimb, and 30% unresponsive. A significantly (P < 0.001) greater percentage of the C(6)-C(8) dorsal root ganglia neurons of adult amputated rats were unresponsive to peripheral stimulation vs. neurons from neonatally amputated rats (48% vs. 16%, respectively). These results indicate that the reorganization that occurs in response to forelimb amputation at birth vs. adulthood is distinctly different at each of these levels of the dorsal column-medial lemniscal pathway. Possible mechanisms to account for these differences are considered.     

Capsaicin-induced neuronal degeneration: silver impregnation of cell bodies, axons, and terminals in the central nervous system of the adult rat

Capsaicin is a neurotoxic substance valued in neurobiological research because of its ability to selectively damage small unmyelinated primary sensory neurons. Previous work has indicated that systemic capsaicin administration causes permanent neuronal degeneration in neonatal rats, but evidence that capsaicin has a similar effect in adults is equivocal and incomplete. Therefore, we used silver impregnation, a method that labels degenerating neurons, to examine the central nervous system of adult rats after systemic capsaicin treatment. Adult rats were injected with a single intraperitoneal dose of capsaicin (50 or 90 mg/kg) or vehicle solution and killed 6, 12, 18, 24, 48, 96, or 240 hours later. Sections of brain and spinal cord were stained with the Carlsen-de Olmos cupric silver method. As reported previously, stained sections revealed degeneration in areas known to be innervated by small-diameter primary sensory fibers: the substantia gelatinosa of the spinal cord dorsal horn and spinal trigeminal nucleus, the solitary nucleus and tract, and the lateral borders of the area postrema. In addition, axon and terminal degeneration was observed in several discrete forebrain and hindbrain areas not previously associated with capsaicin-induced degeneration in either adult or neonatal rats: the inferior olive, the olivary pretectal nucleus, the interpeduncular nucleus, the suprachiasmatic nucleus, and the lateral septum/medial accumbens region. Furthermore, degenerating cell bodies were observed in the intrafascicular nucleus of the ventromedial midbrain tegmentum, in the supramammillary nucleus, and in the posterior hypothalamic area. Unilateral nodose ganglionectomy produced terminal staining on the denervated side very similar to that induced bilaterally by capsaicin. In addition, unilateral nodose ganglionectomy 1 month prior to capsaicin injection greatly attenuated staining in the ipsilateral nucleus of the solitary tract, confirming the hypothesis that capsaicin damages vagal sensory neurons innervating this nucleus. Capsaicin-induced damage in adult rats was long-lasting, since the second of two capsaicin treatments spaced 4.5 months apart produced no additional degeneration.     

Cellular mechanism of action of resiniferatoxin: a potent sensory neuron excitotoxin

The mechanism of activation of sensory neurons by the potent irritant resiniferatoxin (RTX) was compared with that of the pungent compound, capsaicin. RTX and capsaicin evoked an inward, depolarising current associated with an increase in membrane conductance in a subpopulation of dissociated cultured neurons from rat dorsal root ganglia. RTX also evoked an uptake of⁴⁵Ca into and an efflux of [¹⁴C]guanidinium and of⁸⁶Rb from these cells but was at least 100-fold potent than capsaicin. The levels of cGMP, but not cAMP were elevated by RTX. Prolonged exposure to RTX damaged DRG neurons by a predominantly osmotic process. RTX-sensitive cells were identified by a cobalt-staining method; neurofilament-containing DRG neurons were RTX-insensitive as were all sympathetic neurons and non-neuronal cells. Cultured DRG neurons from chick embryos were also unaffected by RTX. In a neonatal rat spinal cord-tail preparation in vitro, RTX activated capsaicin-sensitive peripheral noiciceptive fibres and caused a subsequent spinal cord depolarization measured in the ventral spinal roots. Neither prolonged exposure to a phorbol ester, to desensitize/down-regulate protein kinase C, nor inhibition of protein kinase C by staurosporine affected responses produced by RTX or capsaicin. The effects of capsaicin were abolished when preparations were exposed to desensitizing concentrations of RTX. RTX therefore acts as a highly potent capsaicin analogue to activate a subpopulation of rat sensory neurons.     

Neurophysiological effects of capsaicin

Data obtained from neonatally treated rats are fairly consistent. However, there is disagreement as to whether mechanical and thermal nociceptive thresholds are elevated or unchanged in this group. There are at least two major areas of disagreement in adult animal capsaicin research. Behavioral data are extremely variable. The thermal nociceptive threshold after systemic capsaicin has been reported to be both raised and lowered. After intrathecal capsaicin injection, the thermal nociceptive threshold was reported raised, but onset and duration of responses varied and some animals exhibited no changes. Capsaicin application to peripheral nerve, however, drastically increased thermal threshold. Mechanical pain threshold has been reported both increased and unchanged after systemic capsaicin treatment and unchanged after intrathecal injection. Obviously, capsaicin's effects upon pain perception are not fully understood. Although lower on the phylogenetic scale than many mammals, rodents exhibit complex individualistic behavior. Lower vertebrates may eventually provide more simple behavioral models for pain tolerance.Investigators also disagree as to whether C fibres can conduct action potentials after local capsaicin application. C fibre conduction was reported unaffected by capsaicin in an acute preparation and for 13–21 days after treatment. On the other hand, C fibre compound action potentials have been reported diminished for up to 2 h after capsaicin application. Additional conduction impairment studies will be useful in comparing peripheral and intrathecal capsaicin application.There is general agreement that, allowing for variation in dosages and route of administration, capsaicin causes central and peripheral C fibre damage, though never as extensive in adults as in neonates. Neonatal capsaicin treatment (always s.c.) results in destruction of C and some Aδ fibres and their central terminals. Capsaicin causes degeneration of C terminals in the adult CNS only when applied centrally.In both neonates and adults, s.c. capsaicin depletes the putative ‘pain’ peptide neurotransmitter, SP, from peripheral and sensory neurons and the tissues they innervate but not from the gut. Capsaicin-induced SP depletion in neonates is permanent. Systemic administration to adult depleted SP from much the same areas as observed in neonates, but all areas but the medulla exhibited a slow, regional recovery.Intraventricular injection of capsaicin depleted SP in the adult medulla only, while other SP-containing areas affected by systemic injection remained intact. Intranigral capsaicin injection had no effect on SP content but depleted 5-HT and its metabolite, 5-HIAA, and dopamine metabolites. Direct application of capsaicin to the sciatic nerve may block axonal peptide transport in sensory C fibres but not in motor fibres.In neonates, capsaicin depleted peptide markers of primary afferents, i.e., SRIF, VIP, CCK, FRAP, GABA and opiate receptors from the spinal cord and/or DRG. Systemic administration to adults depleted SRIF and FRAP in the dorsal spinal cord but not opiate receptors or glutamic acid decarboxylase (GAD) activity. Probably because of capsaicin-induced structural and biochemical alterations, spinal, medullary, and peripheral neurons become at least temporarily less responsive, although not uniformly so.Neonatal capsaicin treatment abolished the C fibre mediated neurogenic oedema response to injury or irritation. Subcutaneous administration or direct (but not intrathecal) application of capsaicin to peripheral nerve temporarily blocked neurogenic oedema in adults. On a gross scale, pharmacological tests employing capsaicin are aimed at identifying the receptors it affects to explain complex visceral reflex mechanisms. Neurophysiological tests are more specific because so far, capsaicin has been found to affect only nociceptive primary afferents. At the cellular level, capsaicin depolarizes sensory terminals and exerts a Ca²⁺ dependent SP release in the spinal cord. Capsaicin prolongs sensory neuron action potentials, whereas opiates and opioid peptides shorten AP duration and inhibit SP release from spinal sensory terminals. Capsaicin's hyperpolarization of DRG neurons provides an interesting contrast that indicates differences in its effects on ganglionic, axonal, terminal and receptor sites. Also due to its specific action, capsaicin has been used to indicate presynaptic opiate receptors on SP-releasing spinal nociceptive terminals.     

Neurotoxin induced nerve cell degeneration: Possible involvement of calcium

Neurotoxin induced nerve cell degeneration has been studied in sensory ganglia of newborn and in the area postrema of adult rats following the administration of the selective sensory neurotoxin, capsaicin and the amino acid excitotoxin, glutamic acid, respectively. Light microscopic histochemical, autoradiographic, electroncytochemical and X-ray microanalytical studies revealed that degeneration of certain small-sized, type B primary sensory neurons, induced by capsaicin, was associated with a marked accumulation of calcium predominantly in mitochondria of the damaged ganglion cells. Similarly, monosodium glutamate treatment resulted in the appearance of calcium-containing electron-dense granules in mitochondria of degenerating area postrema neurons. In addition, after a combined administration of⁴⁵Ca²⁺ and capsaicin or monosodium glutamate, significantly higher levels of radioactivity have been detected by liquid scintillation spectroscopy in the Gasserian ganglia and the area postrema, respectively. It is concluded that an enhancement in intracellular calcium level may be intimately involved in the process of neuronal cell death and may represent a common basic mechanism responsible for the development of cellular events leading ultimately to the degeneration of nerve cells.     

Reciprocal actions of interleukin-6 and brain-derived neurotrophic factor on rat and mouse primary sensory neurons

In low-density, serum-free cultures of neurons from embryonic rat dorsal root ganglia, interleukin-6 supports the survival of less than one third of the neurons yet virtually all of them bear interleukin-6 alpha-receptors. A finding that might explain this selectivity is that interleukin-6 acts on sensory neurons in culture through a mechanism requiring endogenous brain-derived neurotrophic factor. Antibodies or a trkB fusion protein that block the biological activity of brain-derived neurotrophic factor synthesized by dorsal root ganglion neurons also block the survival-promoting actions of interleukin-6 on these neurons. Two results indicate that interleukin-6 influences synthesis of brain-derived neurotrophic factor in adult dorsal root ganglion neurons. Intrathecal infusion of interleukin-6 in rats increases the concentration of brain-derived neurotrophic factor mRNA in rat lumbar dorsal root ganglia. The induction of brain-derived neurotrophic factor in dorsal root ganglion neurons that is seen after nerve injury in rats or wild-type mice is severely attenuated in mice with null mutation of the interleukin-6 gene. In brief, the ability of interleukin-6 to support the survival of embryonic sensory neurons in vitro depends upon the presence of endogenous brain-derived neurotrophic factor and the induction of brain-derived neurotrophic factor in injured adult sensory neurons depends upon the presence of endogenous interleukin-6.     

Expression of receptors for glial cell line-derived neurotrophic factor family ligands in sacral spinal cord reveals separate targets of pelvic afferent fibers

Nerve growth factor has been proposed to mediate many structural and chemical changes in bladder sensory neurons after injury or inflammation. We have examined the expression of receptors for the glial cell line-derived neurotrophic factor (GDNF) family within sensory terminals located in the sacral spinal cord and in bladder-projecting sacral dorsal root ganglion neurons of adult female Sprague-Dawley rats. Nerve fibers immunolabelled for GFRalpha1 (GDNF receptor), GFRalpha2 (neurturin receptor), or GFRalpha3 (artemin receptor) showed distinct distribution patterns in the spinal cord, suggesting separate populations of sensory fibers with different functions: GFRalpha1-labeled fibers were in outer lamina II and the lateral-collateral pathway and associated with autonomic interneurons and preganglionic neurons; GFRalpha2-labeled fibers were only in inner lamina II; GFRalpha3-labeled fibers were in lamina I, the lateral-collateral pathway, and areas surrounding dorsal groups of preganglionic neurons and associated interneurons. Immunofluorescence studies of retrogradely labelled bladder-projecting neurons in sacral dorsal root ganglia showed that approximately 25% expressed GFRalpha1 or GFRalpha3 immunoreactivity, the preferred receptors for GDNF and artemin, respectively. After cyclophosphamide-induced bladder inflammation, fluorescence intensity of GFRalpha1-positive fibers increased within the dorsal horn, but there was no change in the GFRalpha2- or GFRalpha3-positive fibers. These studies have shown that GDNF and artemin may target bladder sensory neurons and potentially mediate plasticity of sacral visceral afferent neurons following inflammation. Our results have also revealed three distinct subpopulations of sensory fibers within the sacral spinal cord, which have not been identified previously using other markers.     

Regulation of substance P by nerve growth factor: disruption by capsaicin

Capsaicin depleted substance P from guinea pig dorsal root ganglia and inhibited the retrograde axoplasmic transport of nerve growth factor (NGF). Doses of capsaicin which depleted substance P also inhibited the retrograde axoplasmic transport of NGF. Inhibition of the retrograde transport of NGF by capsaicin preceded substance P depletion. Supplementation of guinea pigs with mouse NGF completely prevented capsaicin-induced substance P depletion. It is concluded that capsaicin depletes substance P from primary afferent neurons of the adult guinea pig by altering the availability of NGF. The data support a role for NGF in the normal maintenance of neuropeptide levels in some sensory neurons in the adult animal.     

Co-localization of endomorphin-2 and substance P in primary afferent nociceptors and effects of injury: a light and electron microscopic study in the rat

Endomorphin-2 (EM2) is a tetrapeptide with remarkable affinity and selectivity for the mu-opioid receptor. In the present study, we used double-fluorescence and electron microscopic immunocytochemistry to identify subsets of EM2-expressing neurons in dorsal root ganglia and spinal cord dorsal horn of adult rats. Within the lumbar dorsal root ganglia, we found EM2 immunoreactivity mainly in small-to-medium size neurons, most of which co-expressed the neuropeptide substance P (SP). In adult rat L4 dorsal root ganglia, 23.9% of neuronal profiles contained EM2 immunoreactivity and ranged in size from 15 to 36 microM in diameter (mean 24.3 +/- 4.3 microM). Double-labelling experiments with cytochemical markers of dorsal root ganglia neurons showed that approximately 95% of EM2-immunoreactive cell bodies also label with SP antisera, 83% co-express vanilloid receptor subtype 1/capsaicin receptor, and 17% label with isolectin B4, a marker of non-peptide nociceptors. Importantly, EM2 immunostaining persisted in mice with a deletion of the preprotachykinin-A gene that encodes SP. In the lumbar spinal cord dorsal horn, EM2 expression was concentrated in presumptive primary afferent terminals in laminae I and outer II. At the ultrastructural level, electron microscopic double-labelling showed co-localization of EM2 and SP in dense core vesicles of lumbar superficial dorsal horn synaptic terminals. Finally, 2 weeks after sciatic nerve axotomy we observed a greater than 50% reduction in EM2 immunoreactivity in the superficial dorsal horn. We suggest that the very strong anatomical relationship between primary afferent nociceptors that express SP and EM2 underlies an EM2 regulation of SP release via mu-opioid autoreceptors.     

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.     

Origin of sympathetic and sensory innervation of the elbow joint in the rat: A retrograde axonal tracing study with wheat germ agglutinin conjugated horseradish peroxidase

After injection of wheat germ agglutinin conjugated horseradish peroxidase (WGA-HRP) into the elbow joint of adult rats, labeled neurons were found in the stellate and the T2-T4 ganglia of the ipsilateral sympathetic trunk, and also in dorsal root ganglia at the C4–T4 levels. Most labeled sympathetic cells, 90% or more, were located in the stellate ganglion. The sensory innervation to the joint originated mainly from the dorsal root ganglia at the levels of C7–T1.     

Specific binding of resiniferatoxin, an ultrapotent capsaicin analog, by dorsal root ganglion membranes

We have previously demonstrated that resiniferatoxin (RTX), an unusual phorbol-related diterpene, induces similar responses in rodents to those induced by capsaicin, the pungent constituent of hot peppers (the genus Capsicum). Strikingly, RTX was 3-4 orders of magnitude more potent than was capsaicin. We report here specific binding of [3H]RTX to particulate preparations from dorsal root ganglia (DRG), a target tissue of both RTX and capsaicin action. The Kd was 0.27 nM for DRG from the rat; the Bmax was 160 fmol/mg. The respective values for pig DRG were 2.2 nM and 730 fmol/mg. Typical phorbol esters did not inhibit [3H]RTX binding. Capsaicin inhibited binding with 10(4)-fold lower affinity than RTX, consistent with the relative in vivo potencies. The specific [3H]RTX binding appears to represent the postulated capsaicin receptor.     

Preferential Growth of Neonatal Rat Dorsal Root Ganglion Cells on Homotypic Peripheral Nerve Substrates In Vitro

Developing sensory neurons interact with molecular signals in the local environment to generate stereotypic nerve pathways. Regenerating neurons seem to lose the ability to reinnervate their original sites in the targets, resulting in abnormal sensory input and consequent clinical pathophysiology. The specificity of reinnervation of peripheral targets by regenerating axons is thus crucial for normal recovery of function. In this study, we have examined evidence for selectivity of interactions between primary afferent neurons from identified levels of the spinal cord and different peripheral nerve environments by culturing these neurons on sections of nerves to muscle and viscera. We have compared the growth of a population of sensory afferents normally innervating somatic targets (dorsal root ganglion cells from L4 and L5) with populations containing many afferents innervating visceral targets (L6 and S1 dorsal root ganglia and nodose ganglion). These neurons, from newly born rats, were cultured on unfixed cryostat sections of normal and prelesioned gastrocnemius nerve, pelvic spinal nerve and vagus nerve from adult rats. Normal muscle nerve was seen to support the regeneration of a significantly greater proportion of somatic neurons, with longer neurites, than the visceral nerves. Similarly, much higher proportions of the‘visceral’population of afferent neurons were seen to extend neurites on the normal visceral nerve substrates, with longer neurites, than on the muscle nerve substrate. The selectivity displayed by the sensory neurons for their normal nerve substrates was abolished when they were cultured on prelesioned nerve substrates subjected to Wallerian degeneration, which was apparent from the equivalent and increased proportions of growing neurons having comparable neurite lengths, on all the nerve substrates. We conclude that sensory neurons recognize and respond to substrate-specific and substrate-bound molecules present in normal adult peripheral nerves, and that these differences are lost in prelesioned nerves following Wallerian degeneration.     

Specific binding of resiniferatoxin, an ultrapotent capsaicin analog, by dorsal root anglion membranes

We have previously demonstrated that resiniferatoxin (RTX), an unusual phorbol-related diterpene, induces similar responses in rodents to those induced by capsaicin, the pungent constituent of hot peppers (the genus Capsicum). Strikingly, RTX was 3–4 orders of magnitude more potent than was capsaicin. We report here specific binding of [³H]RTX to particulate preparations from dorsal root ganglia (DRG), a target tissue of both RTX and capsaicin action. The K_d was 0.27 nM for DRG from the rat; the B_max was 160 fmol/mg. The respective values for pig DRG were 2.2 nM and 730 fmol/mg. Typical phorbol esters did not inhibit [³H]RTX binding. Capsaicin inhibited binding with 10⁴-fold lower affinity than RTX, consistent with the relative in vivo potencies. The specific [³H]RTX binding appears to represent the postulated capsaicin receptor.