c-JUN-like immunoreactivity in the CNS of the adult rat: basal and transynaptically induced expression of an immediate-early gene

Expression of immediate early gene proteins following axotomy and inhibition of axonal transport in the rat central nervous system

The expression of the immediate early gene-encoded proteins c-Jun, Jun B, Jun D, c-Fos, Fos B and Krox-24 in central neurons following transection of, or inhibition of, axonal transport in their axons was investigated in the rat using immunocytochemistry. Transection of the medial forebrain bundle, which produces an essentially complete axotomy of neurons in the ipsilateral mammillary nucleus, substantia nigra pars compacta, ventral tegmental area and parafascicularis, induced the expression of c-Jun, Jun D and, to a lesser extent, Krox-24, in these nuclei. Microinjection of colchicine into the medial forebrain bundle to chemically inhibit axonal transport similarly induced the expression of these proteins in these areas. The expression of the proteins was first evident 24 h after transection, reached a maximum at 48 h and was still present after 10 days. However, after 30 days the proteins were absent from the substantia nigra, ventral tegmentum and parafascicularis, and were still present only in the mammillary nuclei. The other immediate early genes, Jun B, c-Fos and Fos B, were never expressed above the basal levels seen in untreated rats. Transection of the corpus callosum and the hippocampal commissure, which produces only a partial axotomy of neurons in the cerebral cortex and hippocampus, respectively, did not induce the expression of any of the genes in these neurons. Microinjection of colchicine or vinblastine to produce a localized inhibition of axonal transport in the cerebral cortex, hippocampus, thalamus and cerebellum also induced the expression of c-Jun, Jun D and, again to a lesser extent, Krox-24, in neurons surrounding the injection site. In contrast to this selective expression, administration of the neuronal excitant metrazole induced the expression of all six immediate early gene proteins in central nervous system neurons. These results demonstrate that transection of, or inhibition of, transport in the axons of central neurons induces a particular pattern of expression of transcriptionally operating immediate early genes that may be related to the regenerative competency of the neurons.

The role of excitatory amino acid receptors and intracellular messengers in persistent nociception after tissue injury in rats

Increased pain sensitivity (hyperalgesia) and persistent nociception following peripheral tissue injury depends both on an increase in the sensitivity of primary afferent nociceptors at the site of injury (peripheral sensitization), and on an increase in the excitability of neurons in the central nervous system (central sensitization). We will review evidence that central sensitization, and the persistent nociception it leads to, are dependent on an action of glutamate and aspartate at excitatory amino acid (EAA) receptors. Additional evidence will be presented implicating a role of various intracellular second messengers that are coupled to EAA receptors (nitric oxide, arachidonic acid, and protein kinase C) to central sensitization and persistent nociception following tissue injury. Finally, we will examine the evidence for a contribution of molecular events, including noxious stimulus-induced expression of immediate-early genes such as c-fos to persistent nociception.

JUN, FOS, KROX, and CREB transcription factor proteins in the rat cortex: basal expression and induction by spreading depression and epileptic seizures

The expression of the nuclear c-JUN, JUN B, JUN D, c-FOS, FOS B, KROX-24, and CREB transcription factors was investigated in the cortex of adult rats by immunocytochemistry. The expression patterns were studied in untreated rats and up to 24 hours following topical application of 1 M KCl to the cortical surface (KCl) or i.v. injection of bicuculline (BIC). Topical KCl induced cortical spreading depression and systemic injection of bicuculline evoked generalized tonic-clonic seizures. In untreated rats, JUN B, c-FOS, and FOS B were expressed in a small number of neurons in the piriform, perirhinal, entorhinal, and insular cortex and in layers II, III, and VI of all neocortical areas. In contrast, c-JUN, JUN D, and KROX-24 were expressed in all cortical layers but with different intensities of immunoreactivity (IR): c-JUN-IR was generally weak and predominantly present in layers II, III, and VI. JUN D-IR was equally strong in all layers. KROX-24 showed a prominent expression in layers II, IV, and VI. The CREB protein exhibited a slight preponderance in layer II and piriform cortex. Following KCl or BIC, a strong induction was seen for c-FOS, JUN B, and KROX-24, whereas c-JUN, JUN D, and FOS B showed only a moderate increase compared to basal levels. Changes of CREB-IR could not be detected. The localization of induced JUN, FOS, and KROX proteins reflected the pattern of labelling in untreated animals but demonstrated a higher intensity of labelling and an increased number of immunoreactive nuclei. The intensity and persistence of IR as well as the number of labelled cells following BIC exceeded those following KCl. Following BIC, increased levels of FOS B and JUN D were still present after 24 hours. Counterstaining with cresyl-violet and GFAP, a marker for astrocytes, revealed that JUN, FOS, and KROX proteins were expressed in neurons but not in glial cell populations. The present data demonstrate that CREB, JUN, FOS, and KROX transcription factors exhibit a layer-specific expression in the cerebral cortex with only slight area-specific differences both in untreated rats and following stimulation with KCl and BIC. The expression of transcription factor proteins indicate complex molecular genetic changes in cortical neurons due to pathophysiological events such as seizure activity and spreading depression.

Expression of JUN, KROX, and CREB transcription factors in goldfish and rat retinal ganglion cells following optic nerve lesion is related to axonal sprouting

Goldfish and rat optic nerves were cut and crushed, respectively, and the expression of the transcription factor proteins c-JUN, JUN B, JUN D, c-FOS, FOS B, KROX-24, and CREB was investigated in retinal ganglion cells (RGCs) by immunocytochemistry. Immunoreactivities (IRs) were followed up to 350 days in the goldfish and up to 22 days in the rat. In RGCs of untreated goldfish and rats, all JUN, FOS, and KROX proteins were absent whereas CREB was constitutively expressed. After optic nerve cut in goldfish, a JUN-like immunoreactivity (JUN-IR) appeared in a small number of RGCs of central retina after 24 h, reached a maximum within 5 days, declined after 30 days, and was on a half-maximal level after 50 days. Between 100 and 200 days, JUN-IR was only visible in a few RGCs and was completely absent after 350 days. Specific antibodies against c-JUN, JUN B, and JUN D gave no distinct immunoreactive signal. Thus, we could not determine which member of the JUN family contributed to the JUN-IR. The expression of CREB declined after 5 days. The number of CREB-labeled RGCs was reduced (not significant) and the intensity of labeling faded out. After 50 days, CREB-IR had returned to basal level. c-FOS, FOS B, and KROX-24 could not be detected in goldfish RGCs following optic nerve cut. After optic nerve crush in the rat, c-JUN, JUN D, and KROX-24 appeared in a substantial number of RGCs after 24 h, had a maximal expression after 5 days, and strongly declined after 8 days. c-JUN and KROX-24 were completely absent after 22 days whereas JUN D was still present in a few rat RGCs. The number of CREB-labeled RGCs decreased after 5 days and had declined by 50% after 22 days. Expression of JUN B, c-FOS, FOS B could not be detected in rat RGCs after optic nerve crush. Our data demonstrate that the decrease of CREB and the increase of JUN and KROX-24 transcription factors precedes and parallels both the alteration of de novo protein synthesis and the axonal sprouting, which are long lasting in goldfish and transient in rat.

Contribution of central neuroplasticity to pathological pain: review of clinical and experimental evidence

Peripheral tissue damage or nerve injury often leads to pathological pain processes, such as spontaneous pain, hyperalgesia and allodynia, that persist for years or decades after all possible tissue healing has occurred. Although peripheral neural mechanisms, such as nociceptor sensitization and neuroma formation, contribute to these pathological pain processes, recent evidence indicates that changes in central neural function may also play a significant role. In this review, we examine the clinical and experimental evidence which points to a contribution of central neural plasticity to the development of pathological pain. We also assess the physiological, biochemical, cellular and molecular mechanisms that underlie plasticity induced in the central nervous system (CNS) in response to noxious peripheral stimulation. Finally, we examine theories which have been proposed to explain how injury or noxious stimulation lead to alterations in CNS function which influence subsequent pain experience.

Kainate-induced changes in opioid peptide genes and AP-1 protein expression in the rat hippocampus

In the rat hippocampus, jun, c-fos, and fos-related antigen immunoreactivity, AP-1 DNA binding, and opioid peptide gene expression were examined after kainate treatment to determine whether the induction and DNA binding of AP-1 transcription factors are correlated with the expression of the opioid peptide genes. One and one-half hours after kainate administration, fos-related antigen and jun immunoreactivity and AP-1 DNA binding were induced; maximal elevation was observed after 4.5 h. Transcription factor expression and DNA binding increased in a dose-dependent manner. Preprodynorphin and preproenkephalin mRNA induction was also dose dependent. The anticonvulsants, pentobarbital and diazepam, effectively blocked electroencephalographic seizure activity caused by kainate treatment, whereas valproic acid was approximately 50% effective. Opioid peptide gene expression, fos-related antigen and jun immunoreactivity, and AP-1 DNA binding all reflected similar reductions after anticonvulsant treatment. Therefore, expression and DNA binding activity of the AP-1 transcription factors are correlated with opioid peptide gene expression in the rat hippocampus.

Colocalisation and covariation of c-JUN transcription factor with galanin in primary afferent neurons and with CGRP in spinal motoneurons following transection of rat sciatic nerve

The expression of galanin (GAL) in L5 dorsal root ganglia (DRG) and calcitonin gene-related peptide (CGRP) in motoneurons (MN) of lumbar spinal cord and their colocalisation with the nuclear c-JUN protein was investigated by immunocytochemistry following transection of rat sciatic nerve. Expression of c-JUN in L5 DRG neurons increased 10 h following transection. Between 24 h and 10 days 64%-72% of all neurons were labelled. After 50 and 150 days, the end of the observation period, 62% and 27%, respectively, of neurons were labelled by c-JUN. Expression of GAL started after 24 h, reached a maximum between 2 and 10 days in 40-50% of all neurons and persisted in 37% up to 50 days. After 150 days, GAL-IR had returned to basal levels. Between 24 h and 150 days, 75%-86% of all GAL positive neurons showed a nuclear c-JUN immunoreactivity, the maximal number was visible between 2 and 10 days. After 30 days, small diameter neurons showed a slightly increased colocalisation of GAL and c-JUN compared to large diameter neurons. In motoneurons (MN) of lumbar spinal cord of untreated rats, c-JUN was predominantly visible in small diameter MN. The number of c-JUN labelled MN raised 15 h following sciatic nerve transection in both small and large diameter MN. It reached its maximum after 2 days and declined after 40 days. CGRP showed basal expression exclusively in large MN. Its expression raised after 20 h, showed a maximum after 48 h and returned to control levels after 20 days.(ABSTRACT TRUNCATED AT 250 WORDS)

Differential regulation of alpha-calcitonin gene-related peptide and preprocholecystokinin messenger RNA expression in alpha-motoneurons: effects of testosterone and inactivity induced factors

alpha-Calcitonin gene-related peptide expression in alpha-motoneurons is regulated by spinal cord transection, axotomy and testosterone, but to date there are no studies which examine the regulation of cholecystokinin expression in motoneurons. In the present study, we compared the regulation of preprocholecystokinin and alpha-calcitonin gene-related peptide messenger RNA levels in motoneurons of the spinal nucleus of the bulbocavernosus. Previously, we demonstrated that manipulations which decrease activity in target muscles of the spinal nucleus of the bulbocavernosus motoneurons increase alpha-calcitonin gene-related peptide message and peptide levels in spinal nucleus of the bulbocavernosus motoneurons. This muscle-nerve interaction is mediated by a soluble factor which is increased by castration. We now report that decreasing plasma testosterone levels decreased preprocholecystokinin messenger RNA levels. Testosterone replacement at the time of castration restored preprocholecystokinin messenger RNA levels to intact values. Injections of crude extracts prepared from denervated bulbocavernosus/levator ani into the homologous muscles of gonadally intact rats increased the levels of alpha-calcitonin gene-related peptide messenger RNA in spinal nucleus of the bulbocavernosus motoneurons. The levels of preprocholecystokinin messenger RNA did not differ in rats injected with denervated bulbocavernosus/levator ani extract or buffer, both of which were significantly higher than in intact, untreated rats. The results of the present experiments imply that levels of preprocholecystokinin and alpha-calcitonin gene-related peptide messenger ribonucleic acid are differentially regulated in spinal nucleus of the bulbocavernosus motoneurons.

In situ DNA-protein binding: a novel method for detecting DNA-binding activity of transcription factor in brain

A novel method, in situ DNA-protein binding (in situ DPB), was developed to detect the distribution and DNA-binding activity of AP-1 and Sp1 binding proteins in situ. The regional distribution of AP-1 binding protein in mouse brain was different from that of Sp1. Antibody against the DNA-binding domain of Jun protein markedly reduced the AP-1 but not the Sp1 binding activity. The binding activity of AP-1 probe increased markedly in the brain after administration of methamphetamine. These results suggest that the in situ DPB is convenient and sensitive for detecting the distribution and the DNA-binding activity of transcription factors in situ.

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.

Potentiated expression of FOS protein in the rat spinal cord following bilateral noxious cutaneous stimulation

A noxious mechanical or chemical stimulus to the ventral skin of one hindpaw induced the expression of FOS proteins ipsilaterally in the spinal dorsal horn neurons in the rat. The number of FOS-labelled cells reached a maximum at 2-3 h, and decayed to basal levels within 6 h after the stimulus. When a first noxious stimulus was applied to the contralateral hindpaw 1-1.5 h prior to this stimulus, the number of FOS-labelled cells increased, over all laminae, to 153% (mechanical) and 164% (chemical) compared to the number produced by a single stimulus. This effect of a prior stimulus in increasing the number of FOS-labelled cells produced by a contralateral stimulus persisted for several hours after the first stimulus. The results are interpreted as a sensitization of dorsal horn neurons induced by peripheral noxious stimuli, which is manifest at the molecular biological level.

Induction of immediate early gene encoded proteins in the rat hippocampus after bicuculline-induced seizures: differential expression of KROX-24, FOS and JUN proteins

Immunocytochemistry with specific antisera was used to assess regional levels of six immediate early gene encoded proteins (KROX-24, c-FOS, FOS B, c-JUN, JUN B and JUN D) in the rat hippocampus after 15 min of bicuculline-induced seizures. Serial sections of the dorsal hippocampus were examined at various postictal recovery periods up to 24 h. The results demonstrate a complex temporal and spatial pattern of immediate early gene synthesis and accumulation. Three major categories of immediate early gene products could best be distinguished in the dentate gyrus: KROX-24 and c-FOS showed a concurrent rapid rise with peak levels at 2 h and a return to baseline levels within 8 h after seizure termination. FOS B, c-JUN and JUN B levels increased more gradually with peak intensities in the dentate gyrus reached at 4 h. These immediate early gene products showed above normal levels in various hippocampal subpopulations up to 24 h. JUN D exhibited the most delayed onset combined with a prolonged increase of seizure-induced immunoreactivity. Irrespective of this differential temporal expression profile of individual transcription factors, the sequence of induction in the hippocampal subpopulations was identical for all immediate early gene-encoded proteins examined: first in the dentate gyrus granule cells followed by CA1 and CA3 neurons, respectively. Our data indicate an asynchronous synthesis of several immediate early gene-encoded proteins in the brain after status epilepticus. FOS and JUN proteins act via homo- or heterodimer complexes at the AP-1 and other DNA binding sites. The different time-courses for individual immediate early gene products strongly suggest, that at different time-points after status epilepticus, different AP-1 complexes are effective. In vitro studies have shown that different AP-1 complexes possess different DNA binding affinities as well as different transcriptional regulatory effects. Our results suggest that these molecular mechanisms are also effective in vivo.

Expression of c-fos and NGFI-A messenger RNA in the medulla oblongata of the anaesthetized rat following stimulation of vagal and cardiovascular afferents

Messenger RNA encoding the immediate early genes (IEGs) c-fos and NGFI-A was localized by in situ hybridization of specific 35S-labelled oligonucleotides to detect activated neurones in the medulla oblongata following unilateral electrical stimulation of the vagus (nX) and aortic depressor nerve (ADN), and following mechanical stimulation of the left carotid sinus (CS). In electrically stimulated rats, c-fos and NGFI-A mRNA was strongly expressed in the nucleus tractus solitarius (NTS) (predominantly ipsilaterally), area postrema (AP) and in a dorsal subregion of the paratrigeminal nucleus (PTN). Lower levels of c-fos and NGFI-A mRNA were seen in the ipsilateral NTS and PTN following mechanical stimulation of the left CS. In general these data correlate with the topography of innervation by the different nerve afferents, although the expression in the PTN (and in some cases the AP) would not be predicted on the basis of neuronal innervation patterns reported for the rat. Expression of these IEGs also occurred in the rostral and caudal ventrolateral medulla and inferior olive of both stimulated and sham-operated rats; presumably due to effects of the anaesthesia and surgical procedures. In conclusion the localization of the expression of c-fos and NGFI-A mRNAs represents a useful neuroanatomical technique for detecting the cell bodies of neurones that are activated by cardiovascular nerve afferents and should allow the further characterization of the neurochemical identity of these neurones.

Selective expression of Jun proteins following axotomy and axonal transport block in peripheral nerves in the rat: evidence for a role in the regeneration process

Expression of the protein products of the immediate-early genes (IEGs), members of the fos, jun and krox families (Jun, Fos, and Krox, resp.) was investigated in the spinal cord and sensory ganglia (DRG) of normal rats; and following transection of, block of axonal transport in, or electrical stimulation of their peripheral axons. The nuclei of many moto- and DRG neurons showed a faint basal immunoreactivity (IR) for Jun proteins, but not for Fos or Krox proteins. There was a strong and selective induction of Jun-IR in moto- and DRG neurons after peripheral nerve transection or crush, or colchicine- or vinblastine-induced block of axonal transport. The Jun-IR induced by nerve transection disappeared after nerve regeneration. In contrast, Jun, Fos and Krox proteins were all induced transynaptically in spinal dorsal horn neurons following electrical stimulation of the C-fibers in the afferent nerves. Thus in differentiated neurons in vivo these IEG proteins can be expressed either independently or concomitantly depending on the type of stimulus.

Specific temporal and spatial distribution of JUN, FOS, and KROX-24 proteins in spinal neurons following noxious transsynaptic stimulation

We present the first comparative investigation of the basal and transsynaptically induced expression of c-JUN, JUN B, JUN D, c-FOS, FOS B, and KROX-24 proteins in the spinal cord, using immunocytochemistry with specific antibodies. We demonstrate that electrical stimulation of the sciatic nerve at A delta/C-fiber (not A alpha/beta-fiber) intensity strongly induces the expression of these immediate-early gene-encoded proteins. Basal immunoreactivity was found for c-JUN in motoneurons, for JUN D in almost every cell of the gray matter, and for KROX-24 in the superficial dorsal horn. One hour after electrical stimulation of the sciatic nerve at A delta/C-fiber intensity, expression of all proteins except JUN D reached its maximum. Initially immunoreactivity was restricted to the ipsilateral dorsal horn, but after 4 hours appeared contralaterally. Expression of JUN D was increased only after 4 hours. Within the dorsal horn, the expression of c-JUN, JUN B, FOS B, and KROX-24 was mainly restricted to the superficial layers. Immunoreactivity decreased to basal levels between 8 and 16 hours. c-FOS and JUN D were expressed in both the superficial and deep dorsal horn; in the latter, c-FOS and JUN D persisted longer. Induced JUN D was present the longest and was still visible after 32 hours. In motoneurons of the ipsilateral ventral horn, c-JUN, JUN D, and c-FOS appeared after 8 hours. Surgical exposure of the sciatic nerve evoked a strikingly prolonged expression of all proteins compared to that following electrical stimulation of the sciatic nerve. Our results demonstrate that stimulation of nociceptive A delta- and C-fibers induces early and late expression of proteins encoded by immediate-early genes with a specific temporal and spatial distribution of the expression of each protein. Furthermore, the extent of protein expression reflects the intensity of noxious stimulation.

Sequential expression of JUN B, JUN D and FOS B proteins in rat spinal neurons: cascade of transcriptional operations during nociception

Expression of the immediate-early gene encoded proteins JUN B, JUN D and FOS B was investigated by immunocytochemistry in rat L5 spinal cord up to 24 h following stimulation of hind limb somatosensory nociceptors by noxious heat or injection of formalin. In both experimental protocols, JUN B, which did not show basal expression, reached maximum expression after 2 h and thereafter slowly decreased. In contrast, the expression of JUN D, which was present before stimulation in many spinal neurons, was increased after 4 h, reached its maximum after 8 h and thereafter remained elevated. FOS B which was absent under basal conditions reached its maximum between 4 h and 8 h and thereafter declined but was still present after 24 h. All immunoreactivities were restricted to the ipsilateral dorsal horn except JUN D which was also induced in the contralateral side after 8 h. The results are discussed in respect to their meaning for transcriptional operations of JUN and FOS proteins.

Expression of c-JUN, JUN B and JUN D proteins in rat nervous system following transection of vagus nerve and cervical sympathetic trunk

Expression of c-JUN, JUN B and JUN D proteins was investigated in axotomized neurons following transection of the vagus nerve and the cervical sympathetic trunk in the rat. Vagotomy induced the expression of c-JUN and JUN D in the nodose ganglion, dorsal motor nucleus of the vagus nerve and nucleus ambiguus, whereas JUN B was not expressed in these areas, c-JUN and JUN D appeared after 10 h in the nodose ganglion and after 24 h in the dorsal motor nucleus of the vagus nerve with a maximum of immunoreactivity after 48 h. The c-JUN protein remained expressed at an increased level up to 100 days, whereas the immunoreactivity of JUN D declined after five days. Crush of the vagus nerve initially evoked an intense expression of c-JUN and JUN D, but in the course of regeneration the expression of c-JUN and JUN D had returned to more basal levels after 100 days. Similar to vagotomy, application of colchicine and vinblastine on to the intact vagus nerve induced expression of c-JUN and JUN D. On the other hand, application of lidocaine prior to vagotomy did not prevent the expression of these proteins. Transection of the cervical sympathetic trunk induced expression of c-JUN and JUN D, but not of JUN B, in the preganglionic sympathetic neurons of thoracic spinal cord. In these neurons, expression of c-JUN was still enhanced after 60 days whereas JUN D had returned to basal level. One hour after vagotomy, c-JUN and JUN B were transynaptically expressed in the area of central termination of sensory vagal neurons and declined within 10 h to basal levels. JUN D showed a late onset of expression, it appeared after 5 h and persisted for 60 days in this area. We postulate that the expression of c-JUN and JUN D in axotomized neurons is induced by deprivation of a target-derived suppressor.