Neuropeptide expression in rat dorsal root ganglion cells and spinal cord after peripheral nerve injury with special reference to galanin

The temporal course of changes in peptide expression in the dorsal root ganglia L4 and L5 and in the dorsal horn of the spinal cord has been studied in rats subjected to a sciatic nerve transection at a mid-thigh level following different survival times. Galanin-, substance P-, vasoactive intestinal polypeptide-, peptide histidine-isoleucine- and calcitonin gene-related peptide-like immunoreactivities have been studied both by immunohistochemistry and radioimmunoassay. Galanin messenger ribonucleic acid has also been studied by in situ hybridization in the dorsal root ganglia of normal and lesioned animals. In addition, a group of animals with a sciatic nerve crush was studied to compare possible differences in peptide expression after both types of lesions. The results show that the transection induces an increase in the number of cell bodies expressing galanin-like immunoreactivity in the ganglia, and that the galanin levels rise about 120-fold after three and 14 days of survival. This increase reflected increased synthesis of the peptide, since there was a rise in the galanin messenger ribonucleic acid already at 24 h post-lesion, which was maintained for at least 60 days. In the spinal cord there was an increase of staining in the midportion of the outer layers of the dorsal horn that corresponded to fibers thought to arise from cells of the dorsal root ganglia affected by the transection. Also a depletion of substance P-like and an increase in vasoactive intestinal polypeptide- and peptide histidine-isoleucine-like immunoreactivities in the dorsal root ganglia were confirmed. These changes were shown to be rapidly detectable and were paralleled by similar changes in the dorsal horn of the spinal cord. For calcitonin gene-related peptide the immunohistochemistry was inconclusive, and the radioimmunoassay showed no detectable changes. After nerve crush a transient increase in the number of galanin immunoreactive neurons was observed, as well as a decrease in the number of neurons showing substance P-like immunoreactivity. These changes were most noticeable between six and 14 days of survival. After this, peptide expression seemed to return slowly to normal, that is by day 45 post-crush only a few cells showed galanin-like, and many sensory neurons expressed substance P-like immunoreactivity. The results demonstrate that when primary sensory neurons are peripherally lesioned they respond in a complex manner, altering their normal production of peptides by increasing or decreasing their synthesis.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differential galanin upregulation in dorsal root ganglia and spinal cord after graded single ligature nerve constriction of the rat sciatic nerve

Single ligature nerve constriction (SLNC) is a newly developed animal model for the study of neuropathic pain. SLNC of the rat sciatic nerve induces pain-related behaviors, as well as changes in the expression of neuropeptide tyrosine and the Y(1) receptor in lumbar dorsal root ganglia (DRGs) and spinal cord. In the present study, we have analyzed the expression of another neuropeptide, galanin, in lumbar DRGs and spinal cord after different degrees of constriction of the rat sciatic nerve. The nerve was ligated and reduced to 10-30, 40-80 or 90% of its original diameter (light, medium or strong SLNCs). At different times after injury (7, 14, 30, 60 days), lumbar 4 and 5 DRGs and the corresponding levels of the spinal cord were dissected out and processed for galanin-immunohistochemistry. In DRGs, SLNC induced a gradual increase in the number of galanin-immunoreactive (IR) neurons, in direct correlation with the degree of constriction. Thus, after light SLNC, a modest upregulation of galanin was observed, mainly in small-sized neurons. However, following medium or strong SLNCs, there was a more drastic increase in the number of galanin-IR neurons, involving also medium and large-sized cells. The highest numbers of galanin-IR neurons were detected 14 days after injury. In the dorsal horn of the spinal cord, medium and strong SLNCs induced a marked ipsilateral increase in galanin-like immunoreactivity in laminae I-II. These results show that galanin expression in DRGs and spinal cord is differentially regulated by different degrees of nerve constriction and further support its modulatory role on neuropathic pain.     

Expression of neuropeptides and neuropeptide mRNAs in spinal cord after axotomy in the rat,with special reference to motoneurons and galanin

The extent to which the plasticity in peptide expression observed in developing spinal motoneurons occurs following proximal peripheral axotomy in the adult rat was examined using in situ hybridization and immunohistochemical techniques to visualize the changes. Transient upregulation of galanin, vasoactive intestinal polypeptide (VIP) and substance P messenger ribonucleic acids (mRNAs) was observed within subpopulations of motoneurons ipsilateral to lesion for periods lasting 2–3 weeks after injury. In contrast, the axotomy-induced heterogenous increases in somatostatin and neuropeptide tyrosine mRNA expression in ipsilateral motoneurons remained elevated, or, in the case of somatostatin, continued to increase for the time period studied (1 month). Immunohistochemical analysis agreed with the in situ hybridization results, showing some motoneurons within the injured ventral horn to contain galanin-, VIP-or somatostatin-like immunoreactivity. In some instances, galanin-immunoreactive motoneurons colocalized with calcitonin gene-related peptide immunoreactivity. Most of the neurons expressing the injury-induced peptides appeared large, presumably alpha-motoneurons, but there were also many small neurons expressing galanin in the ventral horn ipsilateral to lesion. This may represent evidence for peptide synthesis in gamma-motoneurons. The only peptide mRNA studied to be downregulated in response to axotomy was enkephalin. The results show that peptide expression in injured motoneurons is dramatically altered, the significance of which remains to be determined.     

Effect of peripheral nerve section and nerve crush on spinal cord neuropeptides in the rat; increased VIP and PHI in the dorsal horn

An increase in vasoactive intestinal polypeptide (VIP) immunoreactivity in the dorsal lumbar hemisegment L4 of the spinal cord was observed by both radioimmunoassay and immunocytochemistry following sciatic nerve section or crush. Compared to the contralateral control hemisegment there was 125% and 35% more VIP immunoreactivity in the L4 hemisegment ipsilateral to the lesion 14 days following nerve section and crush respectively. The contralateral control hemisegment contained levels similar to L4 hemisegments from unoperated control rats. This increase appeared by immunocytochemistry to be confined to the substantia gelatinosa, in the region of termination of the majority of unmyelinated sciatic nerve afferents. Similar increases to VIP were observed for the peptide PHI, which is closely related to VIP. However, spinal cord substance P and somatostatin immunoreactivities were reduced following nerve section and unchanged following nerve crush whilst neurotensin and bombesin immunoreactivities were not affected following either lesion.Previous studies have shown that peripheral nerve injury produces a number of electrophysiological and biochemical changes in the dorsal horn of the spinal cord, including depletion of substance P in primary afferent neurones.The location of the cell bodies of fibres showing increased immunoreactivity remains to be established. Further studies are required to elucidate how these peptide changes are related to the adaptive processes which occur centrally following peripheral nerve injury.     

Long-term changes in the distribution of galanin in dorsal root ganglia after sciatic or spinal nerve transection in rats

The neuropeptide galanin is upregulated in primary afferent and sympathetic neurones and might be involved in the development of sympathetic perineuronal baskets ("rings") following nerve injury. Galanin, calcitonin gene-related peptide and tyrosine hydroxylase have been examined immunohistochemically in dorsal root ganglia and associated roots at times up to one year after transection of either sciatic or L5 spinal nerves in adult rats. Small diameter somata containing calcitonin gene-related peptide (with or without galanin) were reduced in number, whereas galanin (and, at later times, calcitonin gene-related peptide) appeared in medium to large diameter cells after both types of lesion. Galanin also appeared in axons in grey rami and somata in lumbar paravertebral ganglia. Within dorsal root ganglia, galanin-positive axons formed perineuronal rings of two types: (i) smooth coiled axons surrounded small (< 30 microm diameter) somata from which they probably arose; these were rare after 12 weeks, particularly after a spinal nerve lesion; and (ii) varicose terminals encircled medium to large galanin-positive somata; some arose from brightly immunofluorescent somata nearby and took nearly a year to disappear. About 30% of varicose galanin-positive rings had associated calcitonin gene-related peptide-positive terminals (partly colocalized) whereas nearly 45% had associated tyrosine hydroxylase-positive terminals (partly colocalized). Synaptophysin was present in swollen axons and in some varicosities of all types.We conclude that, after peripheral nerve lesions, varicose perineuronal rings around large diameter dorsal root ganglion cells may be formed by axotomized primary afferent neurones (some containing calcitonin gene-related peptide) and sympathetic neurones, both of which contain upregulated galanin. Exocytosis from the varicosities may modify the excitability of mechanosensitive somata. Small galanin-positive somata disappear over several months after both lesions as calcitonin gene-related peptide reappears in medium to large neurones.     

Hemorrhages of dorsal root ganglia and spinal cord in congenitally hydrocephalic HTX rat

The effects on the brain caused by hydrocephalus have been examined in detail. However, only little attention has been paid to the possibility that hydrocephalus may affect the spinal cord and the spinal ganglia via the spinal canal. Therefore, the present study focused on the pathological changes seen in the spinal cord and the dorsal root ganglia. A total of 651 congenitally hydrocephalic HTX rats were used in this study. The age ranged from postnatal day 0 to postnatal day 520. All of the HTX rats were from littermates raised in our laboratory. Macroscopic and microscopic investigations demonstrated hemorrhages of the dorsal root ganglia in 134 rats among the 235 affected HTX rats. The hemorrhages of the dorsal root ganglia were observed most frequently in the lumbar ganglia and, less frequently, in the cervical ganglia. Of the 134 rats with hemorrhages in the dorsal root ganglia, 34 rats had hemorrhages both in the spinal cord and in the dorsal root ganglia. The spinal cord hemorrhages were distributed mainly around the central canal and in the ventral parts of the posterior funiculus at the lower thoracic and upper lumbar cords. These hemorrhages were seen only in those rats having progressive hydrocephalus. These findings suggest that increased cerebrospinal fluid pressure can cause congestion of the radicular veins, leading to hemorrhages of the spinal cord and the dorsal root ganglia.     

Responses of macrophages in rat dorsal root ganglia following peripheral nerve injury

Summary Immunohistochemical studies with monoclonal antibodies to macrophage antigens were performed on sections of rat lumbar dorsal root ganglia. In confirmation of previous observations, cells with macrophage antigenicity were detected in normal ganglia. Many of these presumptive macrophages were perineuronal in contact with the neuron/satellite cell complex, a few were perivascular, and others were in interstitial position not in apparent contact with either blood vessels or neurons. The number of macrophages in lumbar dorsal root ganglia started to increase 2–4 days after sciatic nerve transection and remained elevated for four weeks. Perineuronal macrophages resembled satellite glial cells in light microscope appearance but were distinguished from glial cells by their lack of S-100 immunoreactivity. Following this sciatic nerve injury, macrophage counts were modestly increased in contralateral lumbar dorsal root ganglia but not in cervical dorsal root ganglia. Thus peripheral nerve injury induces a recruitment and/or proliferation of macrophages in the corresponding dorsal root ganglion. Although the functions of these macrophages are unclear, those in perineuronal position could contribute to the survival or regeneration of axotomized neurons.     

Binding patterns of lectins with GalNAc specificity in the mouse dorsal root ganglia and spinal cord

To localize membrane glycoconjugates in neurons of the mouse spinal cord and dorsal root ganglia (DRG), cryostat sections of newborn (P0), 7 day-old (P7), P14, P21 and P31 animals were stained with ten FITC-conjugated plant lectins, the majority of them recognizing N-acetyl-D-galactosamine (GalNAc) terminal sugar residues. In the dorsal root ganglia of P0 animals, the different lectins showed distinct patterns of labeling in either cells of the nervous system, including neurons, or other structures such as nerves or blood vessels. Moreover, some of these lectins showed important changes in their pattern of labeling during postnatal development. This was especially relevant for lectins that label a subpopulation of small-sized cells that have been previously identified as the nociceptive cells of the DRG. Enzymatic digestion of sections with neuraminidase removes sialic acid from the carbohydrate chains of glycoconjugates thus exposing novel sugar residues. When this treatment was applied to DRG sections from postnatal animals the pattern of lectin staining was either changed or eliminated and heterogeneous subsets of glycoconjugates normally masked by this sugar were exposed. In the spinal cord of PO animals, none of the lectins labeled cells in the central gray matter. However, after the enzymatic digestion of sections with neuraminidase, spinal cord motoneurons and some other cells were labeled by two of the lectins suggesting that GalNAc residues present in these cells are normally masked by terminal sialic acid. Altogether, these results show important changes in the temporal and spatial expression of glycoconjugates that may be relevant for the postnatal development of the CNS and PNS of mice.     

加巴喷丁对脊神经结扎大鼠背根神经节交感神经芽生的影响

目的:观察加巴喷丁干预后疼痛大鼠痛阈变化及背根神经节(DRGs)中交感神经芽生的改变。方法:将SD雄性大鼠随机分为正常对照组、模型组和加巴喷丁组,于术前及术后5 d每天检测大鼠痛阈变化;术后5 d取各组大鼠手术侧腰5和腰4及对侧腰5 DRG,观察DRGs中交感纤维数量及篮状结构的变化。结果:加巴喷丁可以显著抑制脊神经结扎引起的痛觉过敏;模型组(手术侧腰5及腰4)表现为交感神经节后纤维的异常增生,加巴喷丁干预后,手术侧腰5和腰4 DRGs TH-IR纤维及篮状结构的数量明显低于模型组。结论:加巴喷丁能提高疼痛大鼠痛阈,其机制可能是通过降低脊髓DRG中交感神经的芽生而产生镇痛作用。     

神经营养因子-3对大鼠脊髓半横断后背根神经节c-Jun表达的影响

目的：研究神经营养因子-3(NT-3)对脊髓半横断后背根神经节c-Jun表达的影响,探索NT-3促进脊髓修复的作用机制。方法：将实验动物分为：对照组,损伤组和NT-3注射组,应用荧光免疫组化法结合激光扫描共聚焦显微镜,观察各组背根神经节c-Jun的表达,并计数细胞核完整的神经元数目。结果：脊髓损伤后,背根神经节的细胞内c-Jun的表达上调;NT-3注射组脊髓损伤侧背根神经节神经元的c-Jun表达明显上调,背根神经节内细胞核呈完整状态的神经元数量明显增多。结论：(1)c-Jun在轴突损伤后表达上调。(2)NT-3对轴突损伤后的神经元有保护作用。(3)NT-3可能通过使c-Jun表达上调而发挥其促神经再生作用。     

Macrophage and lymphocyte invasion of dorsal root ganglia after peripheral nerve lesions in the rat

The distribution of major histocompatibility complex class II (MHC II)-positive non-neuronal cells and T-lymphocytes was examined immunohistochemically in dorsal root ganglia (DRGs) up to 12 weeks following transection of one sciatic or lumbar spinal nerve in adult rats. Unlike within the brain, MHC II immunopositive (+) and T-cells are normally present within DRGs. After nerve transection, MHC II+ cell density increased (by about four times after each lesion) in DRGs projecting into lesioned nerves. Subsequently the number declined after sciatic but not spinal nerve transection. MHC II+ cells did not contain glial markers, even when these were up-regulated after the lesions. Initially, MHC II+ cells lay outside the satellite glia but, by 11 weeks, they had moved through them to lie against the somata. T-cells invaded the lesioned DRGs earlier than the MHC II+ cells. They achieved greater numbers after spinal (30 x control) than after sciatic (12 x control) nerve transection. They also increased in undamaged ganglia adjacent to the spinal nerve injury. T-cell density progressively declined after spinal but not sciatic nerve transection. Both cell types appeared to invade the DRGs initially through blood vessels and the meninges, particularly near the subarachnoid angle. At later stages, occasional neurones had dense aggregations of T-cell receptor+ and MHC II+ cells associated with them.We conclude that the magnitude and time course of changes in MHC II expression and T-cell numbers in lesioned DRGs differ from the responses within motor nuclei after axotomy. The influx of inflammatory cells may contribute to neurone survival in the short term. Their long-term presence has implications for patients. These cells have the potential to release excitatory cytokines that may generate ectopic impulse activity in sensory neurones after nerve injury and so may play a role in the generation of chronic neuropathic pain.     

Expression patterns of erythropoietin and its receptor in the developing spinal cord and dorsal root ganglia

Recombinant human erythropoietin (EPO) is neuroprotective in animal models of adult spinal cord injury, and reduces apoptosis in adult dorsal root ganglia after spinal nerve crush. The present work demonstrates that spinal cord and dorsal root ganglia share dynamic expression patterns of EPO and its receptor (EPOR) during development. C57Bl mice from embryonic days (E) 8 (E8) to E19 were studied. In spinal cord and dorsal root ganglia, EPOR expression in all precursor cells preceded the expression of EPO in subsets of neurons. On E11, EPO-immunoreactive spinal motoneurons and ganglionic sensory neurons resided adjacent to EPOR-expressing radial glial cells and satellite cells, respectively. From E12 onwards, EPOR-immunoreactivity decreased in radial glial cells and, transiently, in satellite cells. Simultaneously, large-scale apoptosis of motoneurons and sensory neurons started, and subsets of neurons were labelled by antibodies against EPOR. Viable neurons expressed EPO and EPOR. Up to E12.5, apoptotic cells were EPOR-immunopositive, but variably EPO-immunonegative or EPO-immunopositive. Thereafter, EPO-immunonegative and EPOR-immunopositive apoptotic cells predominated. Our findings suggest that EPO-mediated neuron-glial and, later, neuron–neuronal interactions promote the differentiation and/or the survival of subsets of neurons and glial cells in central as well as in peripheral parts of the embryonic nervous system. Correspondingly, expression of phospho-Akt-1/protein-kinase B extensively overlapped expression sites of EPO and EPOR, but was absent from apoptotic cells. Identified other sites of EPO and/or EPOR expression include radial glial cells that transform to astrocytes, cells of the floor plate and notochord as well as neural crest-derived boundary cap cells at motor exit points and cells of the primary sympathetic chain.     

Expression of peripherin in solid transplants of foetal spinal cord and dorsal root ganglia grafted to the injured cervical spinal cord of adult rats

The expression of the neuronal type III intermediate filament protein peripherin was studied in E14 spinal cord fragments and E15 dorsal root ganglia 1–30 weeks after their transplantation to the injured cervical spinal cord of the adult rat. In the dorsal root ganglion transplants, the surviving neurons generally appeared as a rather healthy looking population of small strongly immunoreactive cells which are very similar to the small dorsal root ganglion neurons of adult control rats. In the spinal cord transplants, there were only a few peripherin-immunoreactive neurons, morphologically close to the motoneurons or to the preganglionic sympathetic neurons of adult rats. In both types of transplants, peripherin expression of the immunoreactive neurons was apparently correlated with the previously established ability of these transplanted neurons for extensive axonal growth into a co-grafted peripheral nerve.     

Immunohistochemical demonstration of the calcium channel alpha2 subunit in the chicken dorsal root ganglion and spinal cord: a special reference to colocalization with calbindin-D28k in dorsal root ganglion neurons

We used immunohistochemical methods to examine the distribution of the calcium channel alpha2 (CCalpha2) subunit in the chicken spinal cord and dorsal root ganglion (DRG) neurons and determine its relationship with calbindin-D28k (CB) in the DRG neurons. In the spinal cord, CCalpha2 subunit was detected in nerve terminals, which were observed as dot-like structures, and in laminae I, II, III and Lissauer's tract in the dorsal horn. In the DRG neurons, approximately 65% of the total neurons were CCalpha2 subunit positive, and most (86%) of these neurons were small to medium sized, suggesting that the CCalpha2 subunit and/or a complex of the CCalpha2 and delta subunits is possibly localized in a number of nociceptive neurons. A majority (77%) of the positive neurons showed CB immunoreactivity and most (88%) of these neurons were small to medium sized. This may indicate a close correlation between the CCalpha2 subunit and CB in the nociceptive neurons. Thus, it is postulated that the mode of nociceptive transmission may involve a cellular Ca(2+)-regulating system that consists of both Ca(2+) entry via calcium channels with the alpha2delta subunit and intracellular Ca(2+)-binding activity of CB in the nociceptive neurons of the DRG.     

Release of sensory neuropeptides in the spinal cord: studies with calcitonin gene-related peptide and galanin

In anaesthetized cats, antibody microprobes were used to investigate the release of immunoreactive calcitonin gene-related peptide and galanin in the lower lumbar spinal cord. In the absence of applied stimulation, a basal release of both peptides was detected at the level of the substantia gelatinosa. This release of calcitonin gene-related peptide was not altered by innocuous thermal cutaneous stimulation nor by electrical stimulation of low-threshold myelinated primary afferent fibres, but was increased by noxious thermal or noxious mechanical cutaneous stimuli and by electrical stimulation of unmyelinated primary afferents. A simultaneous release of both calcitonin gene-related peptide and substance P was detected in the substantia gelatinosa region by the use of pairs of microprobes. In contrast, none of the peripheral stimulation procedures increased intraspinal galanin release. The results suggest that the spinal transmission of nociceptive information may involve the simultaneous release and action of several neuropeptides within the superficial layers of the dorsal horn.     

大鼠坐骨神经受压和解压后背根节和脊髓内神经元nNOS表达的变化

目的 :观察坐骨神经受压及解压后大鼠腰段背根节和脊髓内神经元型一氧化氮合酶 (nNOS)表达的变化 ,借以探讨外周神经源性痛的发病和影响机制。方法 :大鼠随机分为压迫组、解压组和对照组 ,采用聚乙烯管压迫坐骨神经的动物模型 ,用免疫细胞化学方法并结合计算机图像分析进行研究。结果 :与对照组比较 ,压迫组和解压组腰4～ 6背根节中nNOS的表达显著增加 ,相应节段脊髓背角的表达则明显降低 ;解压组与压迫组比较 ,背根节中nNOS的表达明显减少 ,而脊髓背角的已经下调的nNOS表达则回升 ,但仍然低于对照组水平。结论 :NO可能与神经源性痛时在中枢和外周的痛觉敏感性形成和神经系统长时程改变有关。     

The growth-associated protein GAP-43 appears in dorsal root ganglion cells and in the dorsal horn of the rat spinal cord following peripheral nerve injury

When adult dorsal root ganglion cells are dissociated and maintained in vitro, both the small dark and the large light neurons show increases in the growth-associated protein GAP-43, a membrane phosphoprotein associated with neuronal development and plasticity. Immunoreactivity for GAP-43 appears in the cytoplasm of the cell bodies as early as 3.5 h post axotomy and is present in neurites and growth cones as soon as they develop. At early stages of culture (4 h to eight days) satellite/Schwann cells are also immunoreactive for GAP-43. Neurons in isolated whole dorsal root ganglion maintained in vitro become GAP-43-immunoreactive between 2 and 3 h after axotomy. It takes three days however, after cutting or crushing the sciatic nerve in adult rats in vivo, for GAP-43 immunoreactivity to appear in the axotomized dorsal root ganglion cells. GAP-43 immunoreactivity can be detected in the central terminals of primary afferent neurons in the superficial laminae of the dorsal horn of the lumbar enlargement four days after sciatic cut or crush. The intensity of the GAP-43 staining reaches a peak at 21 days and becomes undetectable nine weeks following crush injury and 36 weeks following sciatic nerve cut. The pattern of GAP-43 staining is identical to the distribution of sciatic small-calibre afferent terminals. Little or no staining is present in the deep dorsal horn, but GAP-43 does appear in the ipsilateral gracile nucleus 22 days after sciatic injury. In investigating the mechanism of GAP-43 regulation, blockade of axon transport in the sciatic nerve with vinblastine (10(-5) M-10(-4) M) or capsaicin (1.5%) was found to produce a pattern of GAP-43 immunoreactivity in the dorsal horn identical to that found with crush, while electrical stimulation of the sciatic nerve had no effect. Axotomy of primary sensory neurons or the interruption of axon transport in the periphery therefore acts to trigger GAP-43 production in the cell body. The GAP-43 is transported to both the peripheral and the central terminals of the afferents. In the CNS the elevated GAP-43 levels may contribute to an inappropriate synaptic reorganization of afferent terminals that could play a role in the sensory disorders that follow nerve injury.     

p75 and TrkA neurotrophin receptors in human skin after spinal cord and peripheral nerve injury,with special reference to sensory corpuscles

Human skin, including nerves and sensory corpuscles, displays immunoreactivity (IR) for low- (p75) and high-affinity (TrkA-like) receptors for nerve growth factor (NGF), the best characterized member of the family of neurotrophins. This study was designed to analyze the changes induced by spinal cord and peripheral nerve injuries in the expression of neurotrophin receptors in digital skin, with special reference to nerves and sensory corpuscles. Skin biopsy samples were obtained from 1) the hand and toes of normal subjects, 2) below the level of the lesion of patients with spinal cord injury affecting dorsal and lateral funiculi, 3) the cutaneous territory of entrapped peripheral nerves (median and ulnar nerves), and 4) the cutaneous territory of sectioned and grafted nerves (median nerve). The pieces were formalin-fixed and paraffin-embedded, cut in serial sections, and processed for immunohistochemistry using antibodies against human p75 and TrkA proteins. The percentage of sensory corpuscles displaying IR for p75 and TrkA-like, as well as the intensity of IR developed within them, was assessed using quantitative image analysis. Spinal cord severance causes a decrease in p75 IR in Meissner and Pacinian corpuscles, whereas TrkA-like IR did not vary. In other nonnervous tissues (i.e., epidermis, sweat glands), both p75 and TrkA-like IR was diminished or even absent. Similar but more severe changes were encountered in the skin from the territory of entrapped nerves. Finally, in subjects with sectioned-grafted nerves, p75 IR was found close to controls in nerves, reduced in Meissner corpuscles, and absent in the inner core of the Pacinian ones; TrkA-like IR was in the perineurium, a small percentage of Meissner corpuscles (about 7%), and the outer core and capsule of the Pacinan corpuscles. In the nonnervous tissues, p75 IR was practically absent, whereas TrkA-like IR did not change. No changes in the expression of neurotrophin receptors were observed in Merkel cells of the different groups. Present results show the following: 1) expression of nerve p75 IR in human cutaneous sensory corpuscles is sensitive to central deafferentation, to blockade or difficulty in axonal transport, and to disruption of axonalcontinuity independently of possible restoration of axonal integrity due to grafts; 2) expression of TrkA-like IR in nerves and sensory corpuscles is sensitive only to nerve transection; 3) the corpuscular Schwann-related cells are the only cells involved in the above modifications, the perineurial cells remaining unchanged; 4) the expression of p75 and TrkA-like IR by Merkel cells is independent of normal innervation; 5) an adequate innervation of the skin seems to be necessary for the expression of p75 but not TrkA-like in nonneuronal cells, especially in the epidermis. A role for NGF in the maintenance of epidermis integrity is discussed. Anat. Rec. 251:371–383, 1998. © 1998 Wiley-Liss, Inc.