Expression of NGF receptor in the rat forebrain detected with in situ hybridization and immunohistochemistry

The expression of nerve growth factor (NGF) receptor mRNA and NGF receptor protein was examined in the adult rat basal forebrain using in situ hybridization and immunohistochemical techniques. NGF receptor mRNA and protein were detected within cells in the medial septum, diagonal band of Broca, and nucleus basalis of Meynert. Controls showed that the hybridization signal was not due to nonspecific binding of the probe to heterologous RNAs or other molecules. As expected, the distribution of NGF receptor mRNA-containing cells correlated nicely with the distribution of NGF receptor immunoreactive cells in each of these areas. These data extend previous work which suggests that neurons in these areas express the NGF receptor mRNA and manufacture functional NGF receptors. NGF receptor immunoreactivity was also detected in the arcuate nucleus of the hypothalamus, in the leptomeninges at the base of the brain and overlying the tectum, and within ependymal regions along the lateral walls of the cerebral ventricles. A few weakly stained neurons in the lateral hypothalamus and ventrolateral striatum were also consistently observed. In contrast, NGF receptor mRNA was not detected within any meningial, ependymal, or hypothalamic tissues using in situ hybridization. A cross-linking/immunoprecipitation assay demonstrated normal, membrane-bound NGF receptors within extracts of dorsal superior colliculus, ventromedial hypothalamic, and overlying meningial tissues, proving that the staining observed in these areas was not a non-specific artifact associated with the immunohistochemistry. The lack of hybridization in these areas may reflect levels of NGF receptor mRNA which are too low to be detected by the in situ hybridization methods being used. Alternatively, the staining may represent innervation of these areas by afferents whose cell bodies are located elsewhere, and whose terminals contain the NGF receptor protein.     

Investigation of cortical reorganization in area 17 and nine extrastriate visual areas through the detection of changes in immediate early gene expression as induced by retinal lesions

The effect of binocular central retinal lesions on the expression of the immediate early genes c-fos and zif268 in the dorsal lateral geniculate nucleus (dLGN) and the visual cortex of adult cats was investigated by in situ hybridization and immunocytochemistry. In the deafferented region of the dLGN, the c-fos mRNA level was decreased within 3 days. The dimensions of the geniculate region showing decreased amounts of c-fos mRNA matched the predictions based on the lesion size and the retinotopic maps of Sanderson ([1971] J. Comp. Neurol. 143:101-118). We did not detect zif268 mRNA in the dLGN. At the cortical level, both c-fos and zif268 mRNA expression decreased in the sensory-deprived region of area 17. In addition, the portions of areas 18, 19, 21a, 21b, and 7, as well as the posterior medial lateral suprasylvian area, the posterior lateral lateral suprasylvian area, the ventral lateral suprasylvian area, and the dorsal lateral suprasylvian area corresponding to the retinal lesions also displayed decreased c-fos and zif268 mRNA levels. Immunocytochemistry revealed similar changes for Zif268 and Fos protein. Three days post lesion, the dimensions of the lesion-affected cortical loci exceeded the predictions in relation to the size of the retinal lesions and the available retinotopic maps. Longer postlesion survival times clearly resulted in a time-dependent restoration of immediate early gene expression from the border to the center of the lesion-affected cortical portions. Our findings represent a new approach for investigating the capacity of adult sensory systems to undergo plastic changes following sensory deprivation and for defining the topographic nature of sensory subcortical and cortical structures.     

Carboxypeptidase E (enkephalin convertase): mRNA distribution in rat brain by in situ hybridization

Carboxypeptidase E (CPE), also referred to as enkephalin convertase or carboxypeptidase H (EC 3.4.17.10), is present in neurotransmitter secretory granules and can remove C-terminal basic residues following endopeptidase cleavage during peptide processing. Using in situ hybridization with 35S-labeled oligonucleotide probes, we have mapped the localization of CPE mRNA in the rat brain. Specificity for CPE was confirmed by control experiments, which included production of identical patterns hybridization with 3 different antisense oligonucleotide probes, loss of label with RNase pretreatment of sections or co-incubation with excess unlabeled probe, and lack of labeling with sense orientation probes. In addition, the regional distribution of CPE mRNA by Northern blot analysis corresponded with distribution of labeling by in situ hybridization. The highest levels of CPE mRNA were found to be present in the pyramidal cells of the hippocampus, the pituitary anterior and intermediate lobes, the ependymal cells of the lateral ventricle, the endopiriform nucleus, the basolateral amygdala, the supraoptic nucleus, and the paraventricular nucleus. Intermediate levels were present in the thalamus, medial geniculate nucleus, lateral septal nucleus, piriform and entorhinal cortex, nucleus of the tractus solitarius, cerebellar cortex, pontine nuclei, and inferior olive. The lowest levels were found in the hippocampal granule cell layer, lateral hypothalamus, globus pallidus, and brain stem reticular formation. Ibotenic acid lesions of the hippocampus eliminated the majority of the label, which had been present over pyramidal cells, though labeling was increased over areas of reactive gliosis, suggesting that activated astrocytes can also synthesize CPE mRNA. In general, the localization of CPE mRNA in the rat brain corresponded to the distribution of enkephalin and other peptide neurotransmitter-synthesizing neurons, though CPE mRNA was also present in neurons that do not secrete known peptides and in reactive glia. The widespread yet specific localization of CPE mRNA in the rat brain suggests it may be an excellent marker for peptide synthesizing cells in the CNS.     

Restricted expression of protocadherin 2A in the developing mouse brain

Protocadherins are cell-cell adhesion molecules that are thought to be involved in neural development. Here, we report the expression pattern of protocadherin 2A (Pc2A) in the developing mouse brain as determined by the in situ hybridization technique. In the postnatal day 2 brain, various regions expressed Pc2A including the cerebellar cortex, ventral posterior thalamic nucleus, dorsal lateral geniculate nucleus, hippocampus and cerebellum (Purkinje cells). In particular, some ependymal cells that form the lining of the lateral ventricle and the third ventricle and floor plate cells lining the fourth ventricle showed prominent expression. In the adult brain, strong expression was restricted to the Purkinje cells. Expression in other areas of the adult brain was down-regulated to a faint level, and only a weak signal was detected in regions such as the retina, olfactory bulb, dentate gyrus of the hippocampus, and in some parts of the medial eminence. These observations suggest that Pc2A is expressed in various regions of the brain in a developmentally regulated manner.     

Differential distribution of the glutamate transporters GLT-1 and GLAST in tanycytes of the third ventricle

The ventral one-third of the ventricular lining in the hypothalamus is formed by specialized ependymal cells called the tanycytes. These cells may serve a neuroendocrine transport function because of their structural specializations, which include apical microvili on the ventricular surface and long basal processes that terminate on blood vessels or on the glia limitans. Here, we describe the expression of mRNA and protein for the glutamate transporters GLT-1 and GLAST in unique tanycyte populations of the third ventricle in rat brain. Using nonisotopic in situ hybridization, we demonstrate GLAST mRNA labeling in tanycytes of the ventral floor and lateral walls in the tuberal and mammillary recess portions of the third ventricle. This GLAST mRNA labeling had a higher intensity than the labeling intensity observed in regular ependymal cells throughout the ventricular system. Furthermore, we have identified strong GLT-1 mRNA labeling in a population of tanycytes situated in the dorsolateral walls of caudal tuberal and mammillary recess portions. Immunocytochemical staining indicates that both GLT-1 and GLAST protein are expressed in the tanycyte populations as well. These data corroborate previous findings that third ventricle tanycytes are functionally heterogeneous. Furthermore, the GLT-1-expressing tanycytes represent a population of tanycytes that, to date, has not been recognized as functionally distinct. The strong GLAST expression by the ventral tanycytes in the hypophysiotropic area suggests a role of tanycyte-mediated glutamate transport in neuroendocrine activity. The functional role of GLT-1 in dorsal wall tanycytes remains to be explored.     

Differential ontogenetic patterns of levocabastine-sensitive neurotensin NT2 receptors and of NT1 receptors in the rat brain revealed by in situ hybridization

The postnatal ontogeny of the levocabastine-sensitive neurotensin receptor (NT2) mRNA was studied by in situ hybridization in the rat brain and compared with the distribution of the levocabastine-insensitive NT1 receptor. NT2 receptor mRNA was absent at birth from all brain structures except the ependymal cell layer lining the ventricles. The development of NT2 receptor mRNA followed three ontogenetic patterns. The first pattern, involving the majority of the cerebral gray matter, was characterized by a continuous increase from postnatal day 5 (P5) to P30. The second one, involving regions rich in myelinated fibers such as the corpus callosum and lacunosum moleculare layer of the hippocampus, exhibited a pronounced increase between P5 and P10, peaked at P15 and was followed by a plateau or a slight decrease. The third pattern was observed in the ependymal cell layer lining the olfactory and lateral ventricles, where the high labeling already present at birth continued to increase during development. These different developmental patterns could reflect the variety of cells expressing NT2 receptor mRNA, including neurons, protoplasmic astrocytes in gray matter, fibrous astrocytes present in myelinated fibers tracts, and ependymal cells. In contrast, NT1 receptor mRNA, which seems to be associated only with neurons, was highly and transiently expressed during the perinatal period in the cerebral cortex, hippocampus and striatal neuroepithelium. Other regions, notably the ventral tegmental area and substantia nigra compacta, exhibited a gradual increase in NT1 receptor signal, reaching adult levels by P21. Both the differential localization and ontogenetic profiles of NT1 and NT2 receptor mRNAs suggest different involvement of these two receptors in brain functions and development.     

GABA(B2) receptor subunit mRNA decreases in the thalamus of monoarthritic animals

Many studies have implicated GABA(B) receptors in pain transmission mechanisms, especially in the spinal cord. In the thalamus, mRNA expression of the GABA(B(1b)) isoform was shown to be regulated in relay nuclei in response to chronic noxious input arising from experimental monoarthritis. GABA(B(1a)) and GABA(B2) mRNA expression was here determined by in situ hybridisation in the brain of control, 2, 4, 7 and 14 days monoarthritic rats, to evaluate whether this expression was regulated by chronic noxious input in thalamic nuclei. mRNA labelling was analysed quantitatively in the ventrobasal complex, posterior, central medial/central lateral and reticular thalamic nuclei; the thalamic visual relay and dentate gyrus were examined for control. No mRNA expression was detected for GABA(B(1a)) in control and monoarthritic animals. Similarly, GABA(B2) mRNA was not found in the reticular nucleus. However, GABA(B2) mRNA expression was observed in the ventrobasal complex, posterior and central medial/central lateral nuclei of control animals. A significant decrease of 42% at 2 days and 27% at 4 days of monoarthritis was observed in the ventrobasal complex contralaterally, when compared with controls, returning to basal levels at 7 days of monoarthritis. In the ipsilateral posterior nucleus, there was a significant decrease of 38% at 2 days of monoarthritis. No significant changes were observed in central medial/central lateral nuclei. The data suggest that GABA(B2) mRNA expression in the ventrobasal complex and posterior nucleus is regulated by noxious input and that GABA(B) receptors might play a role in the plasticity of these relay nuclei during chronic inflammatory pain.     

Effects of unilateral cochlea ablation on the distribution of calretinin mRNA and immunoreactivity in the guinea pig ventral cochlear nucleus

The predominantly neuronal, calcium-binding protein calretinin is highly expressed in the guinea pig auditory system. Within the ventral cochlear nucleus (VCN), calretinin-positive auditory nerve fibers terminate on many calretinin-containing bushy, octopus, and multipolar cells. The abundance of calretinin in the cochlear nucleus provides an ideal system for examining the effects of altered neuronal input on the expression of this calcium-binding protein. The present experiments examined the effects of unilateral cochlea ablation on calretinin immunoreactivity and mRNA levels in the VCN. Calretinin mRNA was labeled by in situ hybridization histochemistry using a radioactive oligonucleotide probe and was quantified by optical density measures on autoradiograms. Survival times of 1, 7, and 56 days postlesion were examined. The results revealed a consistent increase in calretinin mRNA in the rostral portion of the ipsilateral anterior VCN 1 day postlesion but no effect on calretinin mRNA in this region at 7 and 56 days postlesion. The intensity of immunohistochemical label was also increased at 1 and 7 days after surgery. In contrast, calretinin mRNA was not affected 1 day postlesion in the ipsilateral posterior VCN but was decreased at both 7 and 56 days postlesion. The decrease in calretinin mRNA in the posterior VCN at longer survival times was accompanied by decreased immunolabeling of fibers projecting from VCN cells to the superior olivary complex. These results suggest that calretinin gene expression is regulated in part by auditory nerve activity in some cochlear neurons but that additional factors related to the unique cellular milieu also control calretinin expression. © 1995 Wiley-Liss, Inc.     

Differential expression of vomeromodulin and odorant-binding protein,putative pheromone and odorant transporters,in the developing rat nasal chemosensory mucosae

Expression of the putative pheromone and odorant transporter, vomeromodulin, was characterized in developing rat nasal mucosae using in situ hybridization and immunocytochemistry. Initial expression of vomeromodulin mRNA and protein was detected at embryonic day (E)16 in the maxillary sinus component of the lateral nasal glands. The abundance of mRNA and protein in the lateral nasal glands increased with age and reached a peak at postnatal day (P)27. Also at P27, vomeromodulin mRNA and protein expression was initiated in vomeronasal glands and posterior glands of the nasal septum. Comparison of the developmental expression of odorant-binding protein, another carrier protein synthesized in the lateral nasal glands, with that of vomeromodulin demonstrated major differences. In contrast to vomeromodulin, odorant-binding protein was not detected until postnatal day 2 in the ventral component of the lateral nasal glands and anterior glands of the nasal septum. These results suggest that the expression of vomeromodulin and odorant-binding protein is developmentally and differentially regulated and confirms the suggestion that vomeromodulin may function in olfactory and vomeronasal perireceptor processes as a transporter for pheromones and odorants. In addition, the embryonic expression of vomeromodulin suggests its involvement in olfactory perireceptor processes in utero. © 1995 Wiley-Liss, Inc.     

Involvement of the Bed Nucleus of the Stria Terminalis in Tonic Regulation of Paraventricular Hypothalamic CRH and AVP mRNA Expression

The bed nucleus of the stria terminalis (BNST) occupies a central position in pathways regulating hypothalamo-pituitary-adrenocortical (HPA) stress regulation. The potential role of the BNST in tonic neural control of HPA function was assessed by examining effects of selective BNST lesions on expression of ACTH secretagogues in HPA-integrative neurons of the medial parvocellular paraventricular nucleus. Anterior BNST lesions (ABN) involved major portions of the anteromedial, anterolateral, ventromedial, ventrolateral, dorsolateral and juxtacapsular subnuclei. These lesions resulted in significant (30%) decreases in corticotropin-releasing hormone (CRH) mRNA expression across the rostrocaudal extent of the medial parvocellular PVN, with no accompanying changes in basal arginine vasopressin (AVP) mRNA levels. Posterior BNST (PBN) lesions involved large but subtotal damage to the posterior intermediate, posterior medial, posterior lateral and preoptic subnuclei; these lesions resulted in small but significant changes in CRH mRNA and slight increases in number of AVP mRNA-producing parvocellular neurons. PBN effects on CRH mRNA expression were most pronounced at the caudal extent of the medial parvocellular zone, suggesting a topographic input from the posterior BNST to the PVN that is only partially compromised by PBN lesions. Analysis of individual cases revealed a correlation between damage of the anterolateral BNST and decreased CRH mRNA levels, and damage of the posterior intermediate and/or posterior medial BNST and increased CRH mRNA levels. The results suggest differential BNST input into HPA regulation, perhaps reflecting the diversity of limbic input into the BNST region.     

Localization of mRNAs for phospholipase D (PLD) type 1 and 2 in the brain of developing and mature rat

Phospholipase D (PLD) is known as one of the key enzymes in the lipid metabolism which produces several second messengers. We demonstrated the localization of the gene expression for PLD1 and PLD2 using in situ hybridization histochemistry in the brain of developing and mature rats. Whereas PLD1 mRNA expression was detected mainly in presumptive oligodendrocytes, PLD2 mRNA expression was detected mainly in presumptive astrocytes. In addition, the gene expression for PLDs were expressed in neuroepithelial cells of the ventricular/ependymal zones and the gene for PLD2 was expressed transiently in early postnatal gray matters, presumptive neurons.     

Cellular variations in estrogen receptor mRNA translation in the developing brain: evidence from combined [125I]estrogen autoradiography and non-isotopic in situ hybridization histochemistry.

The spatial distribution of cells in the adult rodent forebrain which express estrogen receptor mRNA, as shown by in situ hybridization histochemistry with isotopically-labeled probes, has been reported to overlap with regions that are known targets of estrogen and which bind estrogen. The extent to which detection of estrogen receptor mRNA within developing forebrain neurons of the postnatal day 10-12 female rat is accompanied by translation into estrogen binding sites was investigated by combining [125I]estrogen autoradiography with non-isotopic (digoxigenin) in situ hybridization, using a 48-base oligodeoxyribonucleotide probe encoding a sequence of the estrogen-binding domain of rat uterine estrogen receptor cDNA. Estrogen receptor mRNA and estrogen binding sites appeared to be restricted to neurons. No mRNA or binding was seen in ependymal cells. Cells expressing estrogen receptor mRNA were widely distributed in the developing rat forebrain and were found in brain regions generally corresponding to those previously shown in the adult, with the addition of some regions not previously described, such as the medial habenula and dorsal endopiriform nucleus. Although there was widespread overlapping of estrogen receptor mRNA expression with known estrogen binding sites, there were regional and cellular variations in the extent of receptor mRNA translation. This pattern was true for developing forebrain regions previously defined as estrogen receptor-containing (hypothalamus, preoptic area, medial and lateral septum, vertical and horizontal nuclei of the diagonal band, cerebral cortex, hippocampus and amygdala) as well as for regions heretofore not considered estrogen targets (the thalamus, dorsal endopiriform nucleus, claustrum, ventral pallidum/substantia innominata and the basal nucleus of Meynert) or characterized as estrogen-responsive in the adult without previously documented estrogen binding [caudate-putamen (striatum)]. While estrogen binding and receptor mRNA expression always co-localized, neurons expressing estrogen receptor mRNA did not always exhibit ligand binding and there was no clear-cut relationship between the intensity of the hybridization signal and estrogen binding. Little, however, is known about translational control of estrogen receptor expression in the brain. Localization of estrogen binding sites to regions not generally considered targets of estrogen would appear to reflect the greater sensitivity of the iodinated ligand than the tritiated estrogens more commonly used for autoradiography. Non-isotopic in situ hybridization histochemistry combined with [125I]estrogen autoradiography represents a very powerful tool with which to study regulation of estrogen receptor gene expression at the single cell level with an exceptional degree of cellular and anatomical resolution.(ABSTRACT TRUNCATED AT 400 WORDS)     

Stimulated serotonin release from hyperinnervated terminals subsequent to neonatal dopamine depletion regulates striatal tachykinin, but not enkephalin gene expression

Dopamine (DA) depletion in neonatal rodents results in depressed tachykinin and elevated enkephalin gene expression in the adult striatum (STR). Concurrently, serotonin (5-HT) fibers sprout to hyperinnervate the DA-depleted anterior striatum (A-STR). The present study was designed to determine if increased 5-HT release from sprouted terminals influences dysregulated preprotachykinin (PPT) and preproenkephalin (PPE) mRNA expression in the DA-depleted STR. Three-day-old Sprague-Dawley rat pups received bilateral intracerebroventricular injections of vehicle or the DA neurotoxin 6-hydroxydopamine (6-OHDA, 100 microg). Two months later, rats received a single intraperitoneal injection of vehicle or the acute 5-HT releasing agent p-chloroamphetamine (PCA; 10 mg/kg). Rats were killed 4 h later and striata processed for monoamine content by HPLC-ED and mRNA expression by in situ hybridization within specific subregions of the A-STR and posterior striatum (P-STR). 6-OHDA treatment severely (>98%) reduced striatal DA levels, while 5-HT content in the A-STR was significantly elevated (doubled), indicative of 5-HT hyperinnervation. Following 6-OHDA, PPT mRNA levels were depressed 60-66% across three subregions of the A-STR and 52-59% across two subregions of the P-STR, while PPE mRNA expression was elevated in both the A-STR (50-62%) and P-STR (55-82%). PCA normalized PPT mRNA levels in all regions of the DA-depleted A-STR and P-STR, yet did not alter PPE levels in either dorsal central or medial regions from 6-OHDA alone, but reduced PPE to control levels in the dorsal lateral A-STR. These data indicate that increased 5-HT neurotransmission, following neonatal 6-OHDA treatment, primarily influences PPT-containing neurons of the direct striatal output pathway.     

Localization of calcitonin receptor mRNA in the mouse brain: coexistence with serotonin transporter mRNA

To elucidate the sites of and mechanisms of analgesic effect of centrally injected calcitonin, we examined expression of calcitonin receptor mRNA in the mouse brain by in situ hybridization techniques. Calcitonin receptor mRNA was expressed in various brain regions, including the preoptic area, dorsomedial hypothalamic nucleus, lateral hypothalamic area, periaqueductal gray, dorsal raphe nucleus, locus coeruleus, lateral parabrachial nucleus, gigantocellular reticular nucleus alpha part, lateral paragigantocellular nucleus, raphe magnus nucleus and solitary tract nucleus, which are known to play important roles in pain modulation. In addition, a double in situ hybridization technique demonstrated the intense expression of calcitonin receptor mRNA on serotonergic neurons in some raphe nuclei and the lateral paragigantocellular nucleus, suggesting the involvement of central serotonergic pathways in analgesic effect of calcitonin.     

Localization of basic fibroblast growth factor and its mRNA after CNS injury

Basic fibroblast growth factor (FGF) mRNA is increased 4 h after cortical brain injury. In situ hybridization reveals that the increased mRNA persists for at least 2 weeks and that, in areas adjacent and ipsilateral to the lesion, the expression of basic FGF mRNA is also modified. As an example, at three days distal from the lesion, mRNA can be detected in ependymal cells of the lateral ventricle and in selected cells of the hippocampus and cortex. Endothelial cells also synthesize basic FGF mRNA. The increase in basic FGF mRNA is paralleled by similar changes in the localization of the basic FGF protein. Both the intensity and number of cells which stain for basic FGF are increased when they are compared to staining in either the contralateral side or to comparable areas of unlesioned brains. The pattern of mRNA expression is similar from 4 hours to 14 days. Early in the response (4 h to 3 days) on the border of the lesion, the presence of basic FGF is most obvious within the MAC-1-immunopositive population (macrophages and/or microglia). From 7 days to 2 weeks, there has been extensive hypertrophy of the reactive astrocytes which stain intensely for anti-basic FGF(1-24). We conclude that there is increased basic FGF as a function of injury to the CNS. In view of the observation that it is an early and persistent response, the possibility that it plays multiple functions in the regenerative capacity of the CNS is discussed.