The transcription factors c-JUN, JUN D and CREB, but not FOS and KROX-24, are differentially regulated in axotomized neurons following transection of rat sciatic nerve.

In adult rats, expression of c-JUN, JUN B, JUN D, c-FOS, FOS B, KROX-24 and CREB proteins was investigated by immunocytochemistry in L4 and L5 dorsal root ganglia and lumbar spinal cord for up to 300 days following transection of the left sciatic nerve. In dorsal root ganglia, expressions of c-JUN and JUN D were increased 10 h and 15 h after sciatic nerve transection, respectively. c-JUN was still at an elevated level after 300 days predominantly in small diameter neurons, whereas JUN D had declined to control levels after 100 days. In contrast to the JUN proteins, expression of CREB showed a delayed onset after 10 days and reached a maximum between 70 and 150 days. In motoneurons, expression of c-JUN and JUN D was increased 15 h and 25 h after sciatic nerve transection, respectively. Expression of c-JUN remained increased after 150 days, whereas JUN D had declined to control levels after 70 days. In contrast, expression of CREB declined within 30 h in axotomized motoneurons and remained on a reduced level for up to 150 days. JUN B, c-FOS, FOS B and KROX-24 were not induced either following axotomy or following a repeated nerve crush. Sciatic nerve transection including the surgical procedure transynaptically provoked a transient expression of all JUN, FOS and KROX-24 proteins in neurons of spinal dorsal horn which disappeared after 5 days except the expression of JUN D which lasted for up to 20 days. In contrast, CREB immunoreactivity was not at all altered in neurons of spinal dorsal horn. In untreated animals, CREB and to a lesser extent JUN D showed an ubiquitous expression in neurons and glia cells of spinal cord, whereas expression of c-JUN and a weak expression of FOS B were restricted to motoneurons. In neurons of the dorsal root ganglia, a basal expression was found for c-JUN, JUN D and CREB and, at a low level, for FOS B and KROX-24. c-JUN and JUN D were colocalized with CREB in many cells such as interneurons, motoneurons, dorsal root ganglion cells and glial cells indicating the possibility for both the control of c-jun and jun D expression by CREB and the competition of JUN and CREB proteins for CRE consensus sequences.     

Ciliary neurotrophic factor stimulates neurite outgrowth from spinal cord neurons

Ciliary neurotrophic factor (CNTF) has been shown to promote the survival of motoneurons, but its effects on axonal outgrowth have not been examined in detail. Since nerve growth factor (NGF) promotes the outgrowth of neurites within the same populations of neurons that depend on NGF for survival, we investigated whether CNTF would stimulate neurite outgrowth from motoneurons in addition to enhancing their survival. We found that CNTF is a powerful promoter of neurite outgrowth from cultured chick embryo ventral spinal cord neurons. An effect of CNTF on neurite outgrowth was detectable within 7 hours, and at a concentration of 10 ng/ml, CNTF enhanced neurite length by about 3- to 4-fold within 48 hours. The neurite growth-promoting effect of CNTF does not appear to be a consequence of its survival-promoting effect. To determine whether the effect of CNTF on spinal cord neurons was specific for motoneurons, we analyzed cell survival and neurite outgrowth for motoneurons labeled with diI, as well as for neurons taken from the dorsal half of the spinal cord, which lacks motoneurons. We found that the effect of CNTF was about the same for motoneurons as it was for neurons from the dorsal spinal cord. The responsiveness of a variety of spinal cord neurons to CNTF may broaden the appeal of CNTF as a candidate for the treatment of spinal cord injury or disease. © 1996 Wiley-Liss, Inc.     

Purification of adult rat sciatic nerve ciliary neuronotrophic factor

The ciliary neuronotrophic factor (CNTF), a protein required for the survival of cultured avian embryonic parasympathetic ciliary ganglionic neurons, was recently purified from extracts of selected chick intraocular tissues. Here we report the purification of a mammalian CNTF activity from extracts of adult rat sciatic nerve using a fractionation procedure similar to that employed for isolating chick eye CNTF. About 2 micrograms of CNTF protein can be obtained from each 1.5 g batch of nerve tissue. Like the chick CNTF, the mammalian factor displays trophic activity for dorsal root and sympathetic as well as ciliary ganglionic neurons. The nerve CNTF activity differs from its chick counterpart in molecular weight and chromatographic behavior on ion-exchange columns. Unlike purified nerve growth factor (NGF), nerve CNTF activity is insensitive to anti-NGF antibodies and is unable to support the survival of 8-day chick embryo dorsal root ganglion neurons.     

Vasoactive intestinal polypeptide (VIP) increases in the spinal cord after peripheral axotomy of the sciatic nerve originate from primary afferent neurons

Following sciatic nerve axotomy, vasoactive intestinal polypeptide (VIP) immunoreactivity increases dramatically in the central terminal areas of the nerve whereas other primary afferent neuropeptides are depleted. The contribution of the peripheral nerve to VIP increases in the spinal cord was investigated by performing sciatic nerve section alone, dorsal rhizotomy of the lumbar roots, axotomy and rhizotomy in combination or section of other peripheral nerves terminating in the same segments as the sciatic nerve. VIP, and for comparison, substance P (SP), cholecystokinin (CCK), somatostatin (SOM), were localized in the lumbar spinal cord and corresponding sensory ganglia using unlabeled antibody immunohistochemistry. After sciatic nerve section, SP, CCK and SOM were depleted in the lumbar dorsal horn whereas VIP increased. After rhizotomy alone all neuropeptide staining including VIP was depleted; axotomy followed by rhizotomy prodiced the same result. Axotomy of other peripheral nerves terminating in the lumbar cord increased the area of neuropeptide depletion but correspondingly increased the area of VIP staining. A large proportion of small and medium diameter dorsal root ganglion cells were stained for VIP after nerve section or axotomy but not after rhizotomy alone. A radical change in neuropeptide metabolism of dorsal root ganglion cells occurs after peripheral axotomy, in the form of a maked increase in VIP synthesis. An intact dorsal root is necessary for increases in VIP in the spinal cord indicating the primary afferent origin of the response.     

Changes in the expression of parvalbumin immunoreactivity in the lumbar spinal cord of the rat following neonatal nerve injury

Nerve injury in newborn animals results in the loss of motoneurons and dorsal root ganglion neurons and long-term changes in reflex activation of surviving motoneurons. Parvalbumin has been previously shown to be found in large-diameter primary afferent axons and interneurons in the spinal cord, and was used here to study the changes in parvalbumin-immunoreactive appositions onto identified tibialis anterior/extensor digitorum longus (TA/EDL) motoneurons, during both normal development and following neonatal nerve injury in the rat spinal cord. During normal development, there was a decrease in the number of parvalbumin-immunoreactive appositions onto TA/EDL motoneurons. Thus, at postnatal day 7 (P7), there were 72.8 +/- 17.5 (mean +/- SD) appositions per motoneuron and by P14, it had decreased to 38.8 +/- 13.2 (mean +/- SD; p > 0.05). Following neonatal nerve injury at P2, there were fewer parvalbumin-positive afferent appositions close to the TA/EDL motoneurons than normal, so that at P7, there were 53.5 +/- 17.1 (mean +/- SD), and at P14, it further decreased to 25.8 +/- 8.6 (mean +/- SD; p > 0.05). This injury-induced reduction in the number of parvalbumin-immunoreactive boutons apposing TA/EDL motoneurons may result, at least in part, from the death of dorsal root ganglion cells with the consequent loss of their central projections. The alterations in the number of parvalbumin-positive appositions close to motoneurons observed in this study may contribute to the changes in the pattern of reflex activity observed in the developing spinal cord both during normal development and following neonatal injury.     

大鼠坐骨神经切断后腰脊髓腹角内胶质细胞和神经元的可塑性变化

目的：探讨大鼠单侧坐骨神经切断后腰脊髓腹角胶质细胞和运动神经元的反应及其相互关系。方法：用免疫组织化学技术、HE染色和Tunnel法，观察坐骨神经切断后1，6，12，24h及3，7和14d腰脊髓腹角胶质原纤维酸性蛋白(GFAP)标记的星形胶质细胞、OX-42标记的小胶质细胞及运动神经元的变化。结果：坐骨神经切断侧腰脊髓腹角可见星形胶质细胞和小胶质细胞活化，星形胶质细胞的活化早于小胶质细胞；后期运动神经元发生凋亡，HE染色显示凋亡细胞周围为反应性OX-42阳性小胶质细胞和GFAP阳性星形胶质细胞包绕。结论：研究结果提示，坐骨神经切断后切断侧腰脊髓腹角活化的胶质细胞与凋亡的运动神经元之间关系密切。     

Effects of ciliary neuronotrophic factor on rat spinal cord neurons in vitro: survival and expression of choline acetyltransferase and low-affinity nerve growth factor receptors.

We have studied the effects of ciliary neuronotrophic factor (CNTF) and nerve growth factor (NGF) on cultures of E14 rat spinal cord cells maintained for 7 days. The trophic factors were supplied at the day of seeding and every other day thereafter. Treatments with CNTF (human recombinant or purified from rat sciatic nerve, 100 TU/ml) resulted after 7 days in an increase, relative to control cultures, of: (i) the total number of neurons (identified by neurofilament protein and neuron-specific enolase immunostaining) that were not stained with choline, acetyltransferase (ChAT) and low affinity nerve growth factor receptor (LNGFR) antibodies; (ii) the number of motoneurons (0.5% of the neuronal population) as identified by size (greater than 25 microns), morphology and immunostaining for ChAT and LNGFR; and (iii) a population of small- to medium-sized (less than 25 microns), ChAT- and LNGFR-positive neurons, representing 5-10% of the total neuronal population. NGF treatments (mouse submaxillary beta NGF; 10-3000 TU/ml) were without effect on all 3 neuronal populations. Experiments in which CNTF administration was delayed revealed that the population of ChAT- and LNGFR-negative neurons and the population of motoneurons, were both dependent on CNTF for their survival. The third population, small ChAT and LNGFR-positive neurons, was not dependent on CNTF for survival but was induced by CNTF to express its two markers. These observations indicate that CNTF is a neuronotrophic factor for motoneurons, but that the effect of CNTF is not restricted to that cell population. In addition to its survival promoting effect, CNTF has also a regulatory role on the expression of ChAT and LNGFR for some spinal cord neurons.     

Upregulation of brain-derived neurotrophic factor in the sensory pathway by selective motor nerve injury in adult rats

Selective motor nerve injury by lumbar 5 ventral root transection (L5 VRT) induces neuropathic pain, but the underlying mechanisms remain unknown. Previously, increased expression and secretion of brain-derived neurotrophic factor (BDNF) had been implicated in injury-induced neuropathic pain in the sensory system. In this study, as a step to examine potential roles of BDNF in L5 VRT-induced neuropathic pain, we investigated BDNF gene and protein expression in adult rats with L5 VRT. L5 VRT induced a dramatic upregulation of BDNF mRNA in intact sensory neurons in the ipsilateral L5 dorsal root ganglia (DRG), in non-neuronal cells in the ipsilateral sciatic nerve, and in motoneurons in the ipsilateral spinal cord. L5 VRT also induced de novo synthesis of BDNF mRNA in spinal dorsal horn neurons and in glial cells in the white matter of the ipsilateral spinal cord. Consistent with the mRNA expression pattern, BDNF protein was also mainly upregulated in all populations of sensory neurons in the ipsilateral L5 DRG and in spinal neurons and glia. Quantitative analysis by ELISA showed that the BDNF content in the DRG and sciatic nerve peaked on day 1 and remained elevated 14 days after L5 VRT. These results suggest that increased BDNF expression in intact primary sensory neurons and spinal cord may be an important factor in the induction of neuropathic pain without axotomy of sensory neurons.     

Nerve growth factor counteracts the neurophysiological and neurochemical effects of chronic sciatic nerve section

The sciatic nerve was sectioned unilaterally in rats and nerve growth factor (NGF) applied locally to the nerve stump for the following 10-14 days using an indwelling osmotic pump. The aim of the experiment was to test whether NGF had any effect on the previously reported neurophysiological and neurochemical events that occur central to a peripheral nerve lesion. The method of application allowed the sciatic nerve on the other side to be used as a control. Primary afferent depolarization fell, as expected, to 13% of its control value after chronic nerve section but if NGF was administered it fell to only 43.5% of control. Chronic nerve section is also known to result in expansion of the receptive fields of deafferented dorsal horn cells. NGF treatment reduced the number of such large receptive fields by 50%. The normal depletion of fluoride resistant acid phosphatase from the cut nerve terminals in the dorsal horn did not occur following NGF treatment. Radioimmunoassay of substance P revealed that the 30% reduction in dorsal horn levels that follows chronic sciatic nerve section did not occur when NGF was applied and that the accompanying 60% decrease in dorsal root ganglion levels was changed to a 64% increase by NGF. The results show that chronic NGF treatment of a cut sciatic nerve does partially reverse the central changes that normally follow deafferentation.     

The expression of CNTF message and immunoreactivity in the central and peripheral nervous system of the rat.

We have examined the temporal and spatial expression of ciliary neurotrophic factor (CNTF) and its messenger RNA (mRNA) by immunocytochemistry and Northern blot analysis. Specific CNTF-like (CNTF-IR) immunoreactivity and CNTF message were detected primarily in sciatic nerve, spinal cord, and optic nerve sections in the adult rat. In the sciatic nerve immunostaining was localized primarily to the Schwann cell cytoplasm. Schwann cells in the dorsal root ganglion and in the spinal motor roots were immunoreactive for CNTF but no CNTF immunoreactivity was detected in Schwann cells associated with unmyelinated sympathetic fibers in the superior cervical ganglion. CNTF-IR was first detected in sciatic nerve sections on postnatal day 8 and increased in intensity until reaching adult levels by postnatal day 21. In the adult rat, optic nerve staining was confined to astrocyte-like cells and their projections, and this pattern of immunoreactivity was first apparent at postnatal day 8. Double labelling experiments suggest that a GFAP-positive cell in the optic nerve synthesizes CNTF. In the spinal cord, CNTF-IR was seen only in white matter non-neuronal cells at all ages studied. Branched oligodendrocyte-like cells appeared stained and the staining was first apparent at postnatal day 8. The data, therefore, suggest that myelinating Schwann cells produce CNTF and demonstrate the presence of CNTF and its messenger RNA at the appropriate time period in tissues previously defined as having biological responses to CNTF.     

Plasticity in the nucleus gracilis of the rat

The nucleus gracilis of the rat contains a somatotopic map of the hindquarter similar to that in other mammals. Acute deafferentation of this dorsal column nucleus (DCN) either by dorsal root transection (roots L4, 5, and 6), by transection of the spinal cord at L3, or by peripheral nerve transection (the sciatic and saphenous nerves) creates as expected a clearly demarcated region in which cells have no receptive fields (RFs). Plasticity in the nucleus gracilis after four types of chronic deafferentiation was investigated: Experiment 1—15 to 20 days after transection of L4, 5, and 6 dorsal roots, cells in the acutely unresponsive region were found to be excited from nearby intact afferent fibers. This expansion of the effective input of intact afferent fibers is known to occur in the spinal cord. Experiment 2—Chronic transection of the sciatic and saphenous nerves was not followed by expansion of the intact input although this does occur in the spinal cord. Experiment 3—Neonatal treatment with capsaicin which destroys unmyelinated afferent fibers produced adult animals with somatotopically organized nucleus gracilis but with cells which exhibited very large RFs. This enlargement is also known to occur in the spinal cord. Experiment 4—Local application of capsaicin to a sciatic nerve of an adult enlarged the RFs of spinal cord cells after some days but had no effect on the functional organization of nucleus gracilis. Expansion of the RF of nucleus gracilis cells was, therefore, seen after dorsal root transection and after neonatal application of capsaicin but not after peripheral nerve transection or application of capsaicin to the adult single nerve. All four maneuvers produced RF expansion in the spinal cord. We conclude that the DCN has a more limited ability to respond to deafferentation than the spinal cord, and suggested that the former lacks a mechanism of connectivity control. The results are consistent with the hypothesis that primary afferent C fibers which innervate the spinal cord but not the DCN, play a role in the formation and stability of RFs formed by A fibers in adult animals.     

Peripheral nerve insult induces NMDA receptor‐mediated, delayed degeneration in spinal neurons

Injury of a peripheral nerve gives rise to adaptive functional and structural alterations in spinal neurons. We report that the rearrangement of the spinal circuitry in response to sciatic nerve transection in adult rats involves a delayed mode of degeneration of lumbar spinal cord neurons. Nuclear fragmentation was detected by the TUNEL technique 7 days after sciatic neurectomy but not after 3 or 14 days. Dying cells were preferentially located in the ipsilateral superficial dorsal horn and expressed the neuronal cytoskeletal marker SMI-31. Degeneration was prevented by continous systemic treatment with the NMDA receptor-antagonist MK-801. These data are supportive that apoptosis is induced in spinal neurons in a transsynaptic manner by an early signal from injured afferent fibres via activation of spinal NMDA receptors.     

Choline acetyltransferase and acetylcholinesterase in canine spinal ganglia: increase of choline acetyltransferase activity following sciatic nerve lesion

Activities of choline acetyltransferase (ChAT) and acetylcholinesterase (AChE) were measured in the dorsal spinal ganglia, the dorsal spinal root and the spinal cord of the normal adult dogs and following one side transection of the sciatic nerve in the intervals 5, 10, 15 and 21 days respectively. In the spinal ganglia of normal dogs very low ChAT activity was found; it was three orders lower than AChE activity. Within 5-10 days after the nerve section ChAT activity increased almost five times in the spinal ganglia while AChE activity remained without any changes. The elevation of ChAT activity correlated with that in the dorsal roots at 15th day and in the dorsal spinal cord at 21st day after the nerve section. Histochemical "direct-colouring" thiocholine method showed AChE-positive cells were distributed mainly in the peripheral area of the spinal ganglia. The spinal ganglion cells ranged from intensely AChE-positive to AChE-negative without correlation between cell size and AChE activity. The ChAT activity changes were evaluated in correlation to the cholinergic function in the spinal ganglion neurons.     

Cholecystokinin in Mammalian Primary Sensory Neurons and Spinal Cord: In Situ Hybridization Studies in Rat and Monkey

The peptide cholecystokinin (CCK) has been suggested to be involved in nociception, but its exact localization at the level of the spinal cord and in spinal ganglia has been a controversial issue. Therefore the distribution of messenger RNA (mRNA) for CCK was studied by in situ hybridization using oligonucleotide probes on sections of adult rat lumbar dorsal root ganglia following unilateral section of the sciatic nerve and on sections of untreated monkey trigeminal ganglia, spinal cord and spinal ganglia from all levels. For comparison, calcitonin gene-related peptide (CGRP) mRNA was also studied in the monkey tissue using the same techniques. Peripheral sectioning of the sciatic nerve in the rat resulted in the appearance of detectable CCK mRNA in up to 30% of remaining ipsilateral L4 and L5 dorsal root ganglion neurons 3 weeks after surgery, with a distinct but more limited appearance also in the contralateral ganglia. No cells, or only single cells, could be seen in normal control rat ganglia. In contrast, in the normal monkey, ∼20% of dorsal root ganglion neurons, regardless of spinal level, and 10% of trigeminal ganglia neurons expressed mRNA for CCK. CGRP mRNA was expressed at detectable levels in ∼80% of these monkey dorsal root ganglion neurons. In the monkey spinal cord, CCK mRNA was detected in the dorsal horn and in motoneurons, whereas CGRP mRNA was only seen in motoneurons. The present results suggest that CCK peptides can be involved in sensory processing in the dorsal horn of the spinal cord in normal monkeys and in rats after peripheral nerve injury, adding one more possible excitatory peptide to the group of mediators in the dorsal horn.     

坐骨神经非冻结性冷损伤后背根神经节细胞的凋亡

目的观察大鼠坐骨神经在非冻结性低温作用后,腰段脊髓L4-L6背根神经节(dorsal root ganglion,DRG)凋亡神经元的数量以及形态学改变,探讨周围神经非冻结性冷损伤致DRG神经元凋亡的情况。方法雄性Wistar大鼠33只,随机分为1周组、2周组、3周组,每组11只。每只大鼠取任意一侧坐骨神经为实验侧,给予冷损伤(4℃,2h),对照侧坐骨神经同样方法暴露,不给予低温处理。根据坐骨神经和DRG的病理变化,分别取两侧的L4、L5、L6背根神经节于低温结束后1周、2周、3周采用流式细胞仪(Annexin/PI法)和Tunel法对DRG神经元凋亡进行定量和定性检测。结果流式细胞仪(Annexin/PI法)定量测定结果显示,实验侧凋亡率明显高于对照侧。Tunel法检测发现受冷侧的DRG出现典型的Tunel染色阳性的早期凋亡细胞,半定量测定显示实验侧DRG神经元凋亡率明显高于对照侧。两种方法均显示受冷后1周开始凋亡细胞增多,2周时到达高峰,3周时略下降。结论非冻结性低温可以造成坐骨神经对应的L4、L5、L6DRG神经元出现凋亡,凋亡的高峰出现在冷损伤后2周,以早期凋亡为主。凋亡可能是坐骨神经冷损伤的机制之一。     

Transganglionic regulation of central terminals of dorsal root ganglion cells by nerve growth factor (NGF)

Blockade of axonal transport or transection of the rat sciatic nerve results in transganglionic degenerative atrophy (TDA) of nerve terminals containing fluoride-resistant acid phosphatase (FRAP) in the Rolando substance of the spinal cord. Application of vinblastine (9 micrograms) in a cuff around the sciatic nerve of adult rats blocked the retrograde transport of [125I]NGF in sensory fibers; this amount of vinblastine is identical to the threshold amount that induces TDA. Conversely, application of NGF to the proximal stump of the transected sciatic nerve prevented or delayed the occurrence of TDA as reflected by the maintenance of FRAP in the upper dorsal horn, that otherwise would inevitably disappear following the peripheral nerve lesion. These results suggest that endogenous NGF transported retrogradely in peripheral sensory fibers of the adult rat under normal conditions may be responsible for the regulation of the structural and functional integrity of the central terminals of these FRAP-containing primary sensory neurons and that TDA may be the consequence of the failure of NGF to reach the perikarya of these neurons.     

Neurofilament phosphorylation in neuronal perikarya following axotomy: a study of rat spinal cord with ventral and dorsal root transection

Rat spinal cord was stained by indirect immunofluorescence with 11 neurofilament monoclonal antibodies that recognize phosphorylated epitopes. All monoclonals were axon-specific in this location. The large motoneurons containing bundles of neurofilaments did not stain and the pattern remained unchanged after transection of the sciatic nerve in the thigh. With nine monoclonals, stained motoneurons were observed in the ventral horns 3 days, 5 days, 1 week, and 2 weeks after transection of the ventral roots close to the spinal cord. The abnormal motoneurons were typically scattered among normal (i.e., nonstained) cells. Even in animals showing the most severe reaction, the whole motoneuron population at the site of rhizotomy was not affected, stained and nonstained perikarya often coexisting side by side. Stained motoneurons were no longer observed 3 weeks after ventral root transection. Changes in neuronal immunoreactivity were also observed after dorsal root transection. However, a different population was affected, i.e., middle-sized neurons in dorsal horns and at the base of ventral horns. With two monoclonals (A9 and D21), cell bodies remained negative following all operations. It is concluded that axotomy in proximity of the cell body may induce certain neurofilament phosphorylation events in motor neuron perikarya, whereas other phosphorylation events remain confined to the axons under these experimental conditions. The absence of changes after transection of the sciatic nerve in the thigh suggests that neurofilament phosphorylation is a reaction to cell injury rather than a cellular event related to nerve regeneration.     

Inhibition of sensory neuron apoptosis and prevention of loss by NT-3 administration following axotomy

Following permanent transection of their peripheral axons, a proportion of adult rat dorsal root ganglion neurons undergo programmed cell death (apoptosis) over a period of months. The underlying causes of this neuron loss are unclear, but may involve the interruption of the supply of target-derived neurotrophic factors, the replacement of which could prevent this loss from occurring. To investigate whether the administration of neurotrophic factors can prevent the dorsal root ganglion neuron death in adults, a 1 mg/ml solution of ciliary neurotrophic factor or of NT-3 was applied via a silicon reservoir to the proximal stump after unilateral sciatic transection at mid-thigh level. The incidence of apoptotic neurons and neuronal loss in the L4 and L5 ganglia ipsilateral to sciatic nerve transection when compared with the contralateral ganglia was then measured 1 month later. This was assessed by examining serial sections of ganglia for neurons undergoing apoptosis and expressing the total counted as a percentage of the total number of neurons estimated using a stereological neuron counting technique. Our results show that NT-3 administration significantly reduced the incidence of apoptotic neurons and prevented neuron loss, while CNTF had no effect on either parameter.