Transganglionic regulation of the primary sensory neuron

Central terminals of the primary sensory neurons depend on the integrity of the retrograde transport mechanism within the peripheral axon. Whenever retrograde transport is impaired (either by injury or by blockade induced by perineural application of microtubule inhibitors) central terminals undergo transganglionic degenerative atrophy (TDA), characterized by depletion of substance P, somatostatin, FRAP (fluoride resistant acid phosphatase), TMPase (thiamine monophosphatase) and lectin-binding fucose-terminated glyco-conjugates. The TDA is essentially a failure of the central terminals to bind the above genuine marker substances. TDA-inflicted central terminals undergo a slowly proceeding ultrastructural deterioration, accompanied by derangement of the dorsal root potential, reflecting decreased functional activity of synaptic transmission between first and second-order cells. One of the important trophic substances carried by retrograde axoplasmic transport to dorsal root ganglion cells is nerve growth factor (NGF); blockade of NGF transport results in TDA; conversely, locally applied NGF delays or prevents TDA.     

Depletion of substance P and somatostatin in the upper dorsal horn after blockade of axoplasmic transport

Summary In the upper dorsal horn of the rat lumbosacral spinal cord, substance P and somatostatin are present in two distinct and different populations of primary central afferent terminals. Substance-P-positive terminals are mainly concentrated in lamina I, while somatostatin-positive terminals are confined to lamina II. Although these two populations of primary afferent terminals differ at light- and electron-microscopic level, they are equally affected by transganglionic degenerative atrophy (TDA) which is induced by the blockade of axoplasmic transport in the segmentally related, ipsilateral sensory nerve by the local application of Vinblastin, a microtubule inhibitor. In consequence, substance P and somatostatin are depleted in the medial and intermediate portions of the upper dorsal horn, while the lateralmost area, which represents the postaxial portion of the dermatome, remains virtually intact. Substance P and somatostatin in propriospinal elements and the axonal meshwork within the dorsolateral funicle are not affected by TDA. Neurotensine, a propriospinal neuropeptide, does not show any alterations in the affected spinal segments.This work was supported by research grant no. 06/4-01/449 from the Hungarian Ministry of Health and no. 375/82/3.2 from the Hungarian Academy of Sciences     

Presynaptic facilitatory action of locus coeruleus stimulation upon hindlimb sensory impulse transmission in decerebrate cats

This study sought to delineate the presynaptic role of the locus coeruleus (LC) on hindlimb primary afferent terminals. Changes in presynaptic function in response to LC stimulation were assessed by measuring the dorsal root potential (DRP), interaction of LC- and peripherally-evoked DRPs, and intraspinal afferent terminal excitability. LC stimulation in unanesthetized, decerebrate cats produced a sequence of early and late positive DRPs succeeded by a small-sized negative DRP. Conditioning the negative DRPs elicited from individual hindlimb nerve branches with LC stimuli led to a decrease in test DRPs. Similarly, there was a predominant decrease in excitability in both large muscle and cutaneous afferent terminals. These data suggest a presynaptic role of the LC in augmenting afferent impulse transmission, presumably through inhibition of tonically active interneurons having axoaxonic contacts on primary afferents; functionally, presynaptic facilitation.     

Transganglionic degenerative atrophy in the substantia gelatinosa of the spinal cord after peripheral nerve transection in rhesus monkeys

Summary The effect of sciatic nerve transection on its centrally located terminals in the spinal cord was analyzed by electron microscopy in adult rhesus monkeys one and three months following lesion. Although the peripheral and intermediate portions of the dorsal roots, where the axons are enveloped by Schwann cells were normal, their central portion and their terminals in the substantia gelatinosa were remarkably altered. Transganglionic degenerative atrophy (TDA) is characterized by three distinct types of electronmicroscopic alterations. The first type exhibits a conspicuous electron density of the terminal and pre-terminal axoplasm. Importantly, shrinkage replaces fragmentation and glial engulfement of the terminal seen in the course of Wallerian degeneration. The second type is characterized by the disappearance of synaptic vesicles from the terminals. The third type of TDA consists of intricate labyrinthine structures, composed of flattened profiles of axonal, dendritic and glial elements. The complex and diverse cellular changes that occur in the upper dorsal horn following peripheral nerve injury may provide the structural basis of plasticity of the primary nociceptive system.     

Blockade of retrograde axoplasmic transport induces transganglionic degenerative atrophy of central terminals of primary nociceptive neurons

If applied locally around a peripheral sensory nerve, Formyl-Leurosin, a semi-synthetic diindol alkaloid of Vinca rosea--that, just like other mitotic spindle inhibitors, induces blockade of axoplasmic transport via inhibiting microtubular function--causes transganglionic degenerative atrophy of central terminals of primary nociceptive neurons in the substantia gelatinosa Rolandi of the spinal cord. In contrast, if applied to dorsal roots, Formyl-Leurosin fails to induce such alterations. Based upon these observations it is postulated that blockade of retrograde axoplasmic transport, rather than that of the orthograde one, is the decisive factor in the pathomechanism of transganglionic degenerative atrophy.     

Neurochemical and ionic mechanisms of dorsal root potentials in the spinal cord of immature rats

Dorsal root potentials (DRPs) were recorded by a sucrose gap method in experiments on parasagittal slices of the isolated rat spinal cord. In most cases the DRP consisted of fast and slow waves. The fast wave of DRP was inhibited by the GABA antagonist picrotoxin and the blocker of GABA-activated chloride channels, furosemide, but it was potentiated by pentobarbital sodium. The slow wave of DRP disappeared if the extracellular K⁺ concentration was raised to 10 mM and it was depressed by tetraethylammonium and 4-aminopyridine, blockers of electrically excitable potassium channels. It is concluded that the fast wave of DRP and the initial components of the slow wave of DRP are GABA-ergic in origin; the slow wave of DRP, however, is linked with an increase in extracellular K⁺ concentration near the primary afferent terminals. The possible mechanisms of the increase in extracellular K⁺ concentration during dorsal root stimulation are discussed.A. M. Gor'kii Donetsk Medical Institute. Translated from Neirofiziologiya, Vol. 16, No. 6, pp. 796–800, November–December, 1984.     

Presynaptic mechanisms of changes in segmental responses accompanying the formation of a spinal locomotor generator in the cat

Using unanesthetized and decorticated (or decerebrated at level A 13) cats, it was found that spinalization leads to depolarization of the central terminals of primary afferents and an increase in the N₁ component of dorsal surface potential and dorsal root potential (DRP) produced by stimulating the low-threshold cutaneous and muscle afferents. Other effects include an increase in early polysynaptic responses and DRP produced by stimulation of high-threshold muscle afferents, a reduction in the intensity of interneuron activation in the nucleus interpositus mono- and polysynaptically connected with primary afferents, and a rise in the activity of n. interpositus interneurons di- and oligo-synaptically connected with afferent terminals. Changes in the opposite direction were produced by injecting DOPA into spinal animals. The connection between changes in the state of the segmental neuronal apparatus of the lumbosacral spinal cord and the level of spinal locomotor generator activity is discussed in the light of the findings obtained.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 18, No. 5, pp. 669–678, September–October, 1986.     

Axotomy-induced ornithine decarboxylase activity in the mouse dorsal root ganglion is inhibited by the vinca alkaloids

Vinca alkaloids were used to study the role of retrograde axon transport (RT) in activating neuron perikaryal repair response to nerve transection. Mouse lumbar dorsal root ganglia (DRG) (L₄-L₆) were excised 48 hours after unilateral transection of the sciatic nerve and ornithine decarboxylase (ODC) activity determined. ODC activity in DRG ipsilateral to nerve transection was increased 10–20 fold over contralateral values. Typical ODC activities in ipsilateral and contralateral DRG samples were 6.18±1.4 and 0.31±0.09 pmol¹⁴CO₂ released/h/3DRG, respectively. Systemic administration of single doses of either vincristine (1 mg/kg) or vinblastine (5 mg/kg) immediately prior to axotomy attenuated ODC induction in ipsilateral DRG by 39% and 47%, respectively. A direct inhibition of ODC activity in the DRG appears unlikely since only high concentrations of vinblastine (0.5–1.0 mM) were able to inhibit ODC activity in vitro. We suggest vinca alkaloids inhibit ODC induction as a consequence of distupting retrograde axonal transport. Interruption of this intracellular communication mechanism may be etiologically linked to the distal axon degeneration which follows repetitive exposure to vinca alkaloids and other agents that induce toxic axonal neuropathy.     

Uptake of Vinca Alkaloids into Mammalian Nerve and its Subcellular Components

Three Vinca alkaloids, vinblastine (VLB), vincristine (VCR), and vindesine (VDS), were recently found to affect axoplasmic transport to different degrees, with VCR the most potent. The uptake of these three species by desheathed cat sciatic nerves in vitro was determined by using tritium-labeled derivatives. In a sucrose medium, the uptake of VCR was found to be three to four times greater than that of VLB and VDS, which is in accord with the neurotoxicity of VCR. Uptake of VCR was dependent on Ca2+ concentration in the medium. Removal of Ca2+ from the incubation medium reduced the uptake of VCR, without having much effect on VLB or VDS uptake. The uptake of all three Vinca agents into nerve in a saline medium was about 50% of that in a sucrose medium, and elimination of Ca2+ from the saline incubation medium did not result in any significant change in uptake. High Ca2+ concentrations (100 mM) in the incubation medium, which cause a block of axoplasmic transport, did not change the total uptake of the Vinca alkaloids to any significant degree. The amount of labeled alkaloid found in the soluble fraction was, however, decreased by 50%. There was an increase in the amount present in the particulate fraction, caused, most likely, by an aggregation of vinca-binding components. The amount of VCR associated with tubulin-containing components isolated by gel filtration of the soluble fraction increased twofold when the nerves were exposed to a high-Ca2+ medium, as might be expected of a microtubule disassembly. Exposure of the nerve to low temperatures (0 degrees-4 degrees C) for 90 min did not show any effect on the total uptake of Vinca alkaloids.     

Measuring Spinal Presynaptic Inhibition in Mice By Dorsal Root Potential Recording In Vivo

Presynaptic inhibition is one of the most powerful inhibitory mechanisms in the spinal cord. The underlying physiological mechanism is a depolarization of primary afferent fibers mediated by GABAergic axo-axonal synapses (primary afferent depolarization). The strength of primary afferent depolarization can be measured by recording of volume-conducted potentials at the dorsal root (dorsal root potentials, DRP). Pathological changes of presynaptic inhibition are crucial in the abnormal central processing of certain pain conditions and in some disorders of motor hyperexcitability. Here, we describe a method of recording DRP in vivo in mice. The preparation of spinal cord dorsal roots in the anesthetized animal and the recording procedure using suction electrodes are explained. This method allows measuring GABAergic DRP and thereby estimating spinal presynaptic inhibition in the living mouse. In combination with transgenic mouse models, DRP recording may serve as a powerful tool to investigate disease-associated spinal pathophysiology. In vivo recording has several advantages compared to ex vivo isolated spinal cord preparations, e.g. the possibility of simultaneous recording or manipulation of supraspinal networks and induction of DRP by stimulation of peripheral nerves.     

Endogenous Interleukin-1β in Neuropathic Rats Enhances Glutamate Release from the Primary Afferents in the Spinal Dorsal Horn through Coupling with Presynaptic N-Methyl-d-aspartic Acid Receptors

Excessive activation of glutamate receptors and overproduction of proinflammatory cytokines, including interleukin-1β (IL-1β) in the spinal dorsal horn, are key mechanisms underlying the development and maintenance of neuropathic pain. In this study, we investigated the mechanisms by which endogenous IL-1β alters glutamatergic synaptic transmission in the spinal dorsal horn in rats with neuropathic pain induced by ligation of the L5 spinal nerve. We demonstrated that endogenous IL-1β in neuropathic rats enhances glutamate release from the primary afferent terminals and non-NMDA glutamate receptor activities in postsynaptic neurons in the spinal dorsal horn. Myeloid differentiation primary response protein 88 (MyD88) is a mediator used by IL-1β to enhance non-NMDA glutamate receptor activities in postsynaptic neurons in the spinal dorsal horn. Presynaptic NMDA receptors are effector receptors used by the endogenous IL-1β to enhance glutamate release from the primary afferents in neuropathic rats. This is further supported by the fact that NMDA currents recorded from small neurons in the dorsal root ganglion of normal rats are potentiated by exogenous IL-1β. Furthermore, we provided evidence that functional coupling between IL-1β receptors and presynaptic NMDA receptors at the primary afferent terminals is mediated by the neutral sphingomyelinase/ceramide signaling pathway. Hence, functional coupling between IL-1β receptors and presynaptic NMDA receptors at the primary afferent terminals is a crucial mechanism leading to enhanced glutamate release and activation of non-NMDA receptors in the spinal dorsal horn neurons in neuropathic pain conditions. Interruption of such functional coupling could be an effective approach for the treatment of neuropathic pain.     

Neurocalcin-like immunoreactivity in the rat esophageal nervous system

Neurocalcin is a newly identified neuronal calcium-binding protein. We tried here to investigate the immunohistochemical distribution of neurocalcin in the rat esophagus. Nerve cell bodies having neurocalcin immunoreactivity were found throughout the myenteric plexus. In the myenteric ganglia, two types of nerve terminals showed neurocalcin immunoreactivity. One was varicose terminals containing numerous small clear vesicles and forming a synapse with nerve cells. The other terminals were characterized by laminar or pleomorphic structure and many mitochondria. These laminar terminals were supposed to be sensory receptors of the esophageal wall. In the motor endplates of the striated muscles, nerve terminals containing many small clear vesicles and mitochondria also had neurocalcin immunoreactivity. After left vagus nerve cutting under the nodose ganglia, the number of immunopositive thick nerve fibers, laminar endings and nerve terminals on the striated muscles decreased markedly. Retrograde tracing experiments using Fast Blue showed extrinsic innervation of esophagus from ambiguus nucleus, dorsal motor nucleus of vagus, superior cervical ganglia, celiac ganglia, nodose ganglia and dorsal root ganglia. In the celiac ganglia, nodose ganglia and dorsal root ganglia, retrogradely labeled nerve cells were neurocalcin-immunoreactive. Neurons in the celiac ganglia may project varicose terminals, while nodose and dorsal root neurons project laminar terminals. Although cell bodies of motoneurons in the ambiguus nucleus lacked neurocalcin immunoreactivity, these neurons may contain neurocalcin only in the nerve terminals in the motor endplates. Neurocalcin immunoreactivity is distributed in many extrinsic and intrinsic neurons in the esophagus and this protein may play important roles in regulating calcium signaling in the neurons.     

Vinflunine, a novel microtubule inhibitor, suppresses calmodulin interaction with the microtubule-associated protein STOP

Vinca alkaloids vinblastine and vincristine and some of their derivatives such as vinorelbine are widely used in therapy of leukemia and several solid tumors. Their action is associated with alterations of the mitotic spindle functions that prevent the cell cycle progression and lead to mitotic block. A number of studies show that some Vinca alkaloids inhibit CaM-target interaction. The newest microtubule inhibitor, vinflunine (Javlor), currently in clinical trials, is remarkably more active than vinblastine against a number of tumors. Moreover, vinflunine is significantly less toxic than other Vinca alkaloids. The high antitumor activity of this molecule is not well understood since it binds to tubulin with an overall affinity several-fold lower than that of vinblastine or vincristine. In this study, we examined the interaction of Ca2+-CaM with vinflunine, vinblastine, and stable tubule only polypeptide (STOP) by using a combination of thermodynamic and mass spectrometric approaches. We characterized the influence of Vinca alkaloids on Ca2+-CaM-STOP complex formation. Our results revealed different binding modes to Ca2+-CaM for vinflunine and vinblastine, highlighting that adding fluorine atoms on the cleavamine moiety of the Vinca alkaloid molecule is critical for the localization of the drug on calmodulin. We demonstrate that vinflunine is a better inhibitor for STOP binding to calmodulin than vinblastine. We suggest that vinflunine action on calmodulin can have an effect on microtubule dynamics. These data may contribute to a better understanding of the superior antitumor efficiency and lower toxicity of vinflunine.     

Nerve growth factor regulates central terminals of primary sensory neurons

Transection of peripheral sensory axons results in transganglionic degenerative atrophy of central terminals of the affected primary sensory neurons. Nerve growth factor applied at the central stump of the transected nerve prevents or delays transganglionic degenerative atrophy. It is concluded that, under normal conditions, nerve growth factor taken up by receptors at peripheral sensory nerve endings and transported retrogradely to perikarya in dorsal root ganglia, regulates synthesis of neuroproteins destined for maintenance of central terminals of these neurons. Accordingly, transganglionic degenerative atrophy is the consequence of failure of nerve growth factor to reach perikarya of primary sensory neurons.     

Instability of pleomorphic tubulin paracrystals artificially induced by Vinca alkaloids in tissue-cultured cells

The processes of tubulin paracrystal induction in Chinese hamster ovary cells treated with a Vinca alkaloid, ie, vinblastine or vincristine, and treated simultaneously with one of the Vinca alkaloids and colcemid or colchicine were followed by four different microscopic techniques, in particular by tubulin-immunofluorescence. Vinca alkaloid alone, in lower concentrations, induced basically tactoid or needle-shaped (N-shaped) paracrystals. However, the formation of crystalloid was greatly enhanced by increasing the concentration of Vinca alkaloid. Square or barrel-shaped (S-shaped) and hexagonal paracrystals were also commonly induced by simultaneous treatment with a Vinca alkaloid and colcemid or colchicine. Large rectangular paracrystals often displayed fibrillar or lamellar fine structures which ran perpendicular to the long axis but tended to cleave into fragments by spontaneous splitting. Electron micrographs revealed the fine structure of crystalloids to be aggregates of numerous filaments. The growth of paracrystals, particularly N-shaped crystals, was markedly inhibited when cells were exposed to drug(s) at a low temperature (4 degrees C). We confirmed that both N- and S-shaped paracrystals dissociated rapidly after the culture medium was replaced with fresh, drug-free medium. Glutaraldehyde-fixed paracrystals treated with RNase solution were stained with acridine orange, showing a weak orange color. Possible factors involved in the assembly and disassembly of tubulin paracrystals are discussed.     

The glutamatergic nature of TRPV1-expressing neurons in the spinal dorsal horn

The transient receptor potential vanilloid receptor 1 (TRPV1) is expressed on primary afferent terminals and spinal dorsal horn neurons. However, the neurochemical phenotypes and functions of TRPV1-expressing post-synaptic neurons in the spinal cord are not clear. In this study, we tested the hypothesis that TRPV1-expressing dorsal horn neurons are glutamatergic. Immunocytochemical labeling revealed that TRPV1 and vesicular glutamate transporter-2 were colocalized in dorsal horn neurons and their terminals in the rat spinal cord. Resiniferatoxin (RTX) treatment or dorsal rhizotomy ablated TRPV1-expressing primary afferents but did not affect TRPV1- and vesicular glutamate transporter-2-expressing dorsal horn neurons. Capsaicin significantly increased the frequency of glutamatergic spontaneous excitatory post-synaptic currents and miniature excitatory post-synaptic currents in almost all the lamina II neurons tested in control rats. In RTX-treated or dorsal rhizotomized rats, capsaicin still increased the frequency of spontaneous excitatory post-synaptic currents and miniature excitatory post-synaptic currents in the majority of neurons examined, and this effect was abolished by a TRPV1 blocker or by non-NMDA receptor antagonist. In RTX-treated or in dorsal rhizotomized rats, capsaicin also produced an inward current in a subpopulation of lamina II neurons. However, capsaicin had no effect on GABAergic and glycinergic spontaneous inhibitory post-synaptic currents of lamina II neurons in RTX-treated or dorsal rhizotomized rats. Collectively, our study provides new histological and functional evidence that TRPV1-expressing dorsal horn neurons in the spinal cord are glutamatergic and that they mediate excitatory synaptic transmission. This finding is important to our understanding of the circuitry and phenotypes of intrinsic dorsal horn neurons in the spinal cord.     

Vinca alkaloids inhibit conversion of arachidonic acid to thromboxane by human platelet microsomes: comparison with other microtubule-active drugs

The Vinca alkaloid vinblastine causes dose-dependent inhibition of malondialdehyde formation and aggregation in activated human platelets as a result of inhibition of arachidonic acid metabolism via the thromboxane pathway (Brammer, J.P., Kerecsen, L. and Maguire, M.H. (1982) Eur. J. Pharmacol. 81, 577). The nature of the inhibition by vinblastine has been investigated with human platelet microsomes, measuring conversion of arachidonic acid to malondialdehyde and thromboxane B2 via spectrophotometric assay and RIA, respectively, determining arachidonate oxygenation by monitoring oxygen consumption, and identifying metabolites formed from [1-14C]arachidonic acid. Vinblastine was compared with other Vinca alkaloids and with structurally unrelated microtubule-active drugs. Vinca alkaloids were unique in causing dose-dependent inhibition of both malondialdehyde and thromboxane B2. Order of potency was vinblastine = vincristine = vindesine greater than leurosine greater than vinepidine. Inhibition of malondialdehyde and thromboxane B2 by 50 microM vinblastine was at least 60%. Microsomal cyclooxygenase was not inhibited by 200 microM vinblastine. Inhibition by vinblastine of [1-14C]arachidonic acid conversion to thromboxane B2 was associated with a 4-fold increase in prostaglandin E2 formation. Thromboxane B2, but not malondialdehyde, formation was inhibited by colchicine less than nocodazole much less than vinblastine. Results indicate that microsomal thromboxane synthetase is inhibited by Vinca alkaloids and other tubulin-binding drugs, and suggest that the action of vinblastine in inhibiting thromboxane synthesis, aggregation and release in intact platelets is not dependent upon its antimicrotubular actions.     

电刺激大鼠腓肠神经引起Aδ、 C类传入神经纤维的背根反射

在距脊髓约 15mm处切断大鼠L5背根 ,将中枢端分成 4～ 5条细束 ,电刺激腓肠神经在背根细束上记录背根反射 (dorsalrootreflex ,DRR)。共记录到DRR 5 1例 ,根据引起DRR所兴奋的腓肠神经纤维类别和DRR在背根逆向传出的纤维类别将DRR分为 5类 :Aαβ Aαβ·DRR、Aβδ Aδ·DRR、Aβδ C·DRR、Aαβδδ C·DRR和C C·DRR。结果证明 ,电刺激外周神经激活各类纤维不但能引起A类 (包括Aδ)纤维的DRR ,而且也能引起C类纤维的DRR。记录的Aδ·DRR和C·DRR为细纤维传入终末产生突触前抑制提供了客观指标 ,为DRR逆向传出冲动到达外周组织 ,释放神经肽类递质 ,调节外周效应器的功能提供了证据     

The actions of serotonin on frog primary afferent terminals and cell bodies

The actions of serotonin (5-HT) were studied in the isolated frog spinal cord and dorsal root ganglion preparations. In the spinal cord, 5-HT increased the spontaneous activity recorded from dorsal roots, facilitated evoked spinal reflexes and produced fast and slow primary afferent depolarization (PAD). A direct action of 5-HT on primary afferent terminals is likely since 5-HT induced PAD remained in the presence of 1 microM tetrodotoxin and 2 mM Mn2+. The direct action of 5-HT on primary afferent terminals was blocked by methysergide and attenuated by concentrations of Mn2+ in excess of that required to block transmitter release. Cell bodies of the dorsal root ganglion were also depolarized by 5-HT. A slow hyperpolarization occasionally followed the initial depolarization. The depolarizing action of 5-HT in the dorsal root ganglion was also attenuated by treatment with Mn2+. It is concluded that 5-HT acts directly on frog primary afferents and that this influence may involve a calcium sensitive process. The dorsal root ganglion response to 5-HT appears to be a suitable model of the afferent terminal response.     

Depletion of vesicular zinc in dorsal horn of spinal cord causes increased neuropathic pain in mice

Zinc enriched (ZEN) neurons and terminals are abundant in the rodent spinal cord. Zinc ions have been suggested to modulate the excitability of primary afferent fibers believed to be important in nociceptive transmission. To test the hypothesis that vesicular zinc concentration is related to neuropathic pain we applied Chung’s rodent pain model on BALB/c mice, and traced zinc transporter 3 (ZnT3) proteins and zinc ions with immunohistochemistry and autometallography (AMG), respectively. Under anesthesia the left fifth lumbar spinal nerve was ligated in male mice in order to produced neuropathic pain. The animals were then sacrificed 5 days later. The ZnT3 immunoreactivity was found to have decreased significantly in dorsal horn of fourth, fifth, and sixth lumbar segments. In parallel with the depressed ZnT3 immunoreactivity the amount of vesicular zinc decreased perceptibly in superficial gray matters of especially layer I-IV of the same segments. The transection-induced reduction of vesicular zinc in ZEN terminals of the dorsal horn was synchronic to reduced pain threshold, as measured by von Frey method. In a separate study, we observed intensive zinc selenite precipitation in somata of the smaller spinal ganglion cell, but 5 days after spinal nerve transection zinc precipitation was also found in the lager ganglion cells. The present results indicate that zinc may be involved in pain mechanism in the spinal ganglion level. These results support the hypothesis that vesicular zinc might have a modulatory role for neuropathic pain. Thus, increased pain sensitivity might be related to reduce vesicular zinc level in the dorsal spinal gray matter.