Expression of NGF and NGF receptor mRNAs in the developing brain: Evidence for local delivery and action of NGF

Nerve growth factor (NGF) is a well-documented target-derived trophic factor in the peripheral nervous system. Recently, proteins as well as mRNAs for both NGF and its receptor (NGF-R) have been detected in diverse areas in the central nervous system (CNS). Considerable evidence suggests that NGF also functions in the target synthesis/retrograde transport mode in the brain. For example, NGF is synthesized in the target hippocampus, as indicated by the presence of NGF message, and interacts with the receptors on terminals projecting from basal forebrain, where receptor mRNA is detectable. Spatial separation of NGF and receptor gene expression is consistent with the target mechanism of action. To ascertain whether local action may also occur in the CNS, we used sensitive nuclease protection assays to study the relationship of NGF and NGF-R expression in the developing brain. Our results indicate that in some brain areas, such as diencephalon, postnatal hippocampus, and olfactory bulb, NGF message was highly expressed, while receptor mRNA was virtually undetectable, suggesting that these areas serve as target sources of NGF for distant afferent neurons. By contrast, in other brain areas, such as cerebellum, striatum, perinatal olfactory bulb, and prenatal hippocampus, NGF and NGF-R mRNAs were coexpressed and coregulated developmentally. Consequently, local delivery and action of the trophic molecule may occur in these areas during these periods. We tentatively conclude that NGF may act through both distant and local modes in the developing CNS.     

Messenger RNAs for trk and the low-affinity NGF receptor in rat basal forebrain.

Nerve growth factor (NGF) acts by binding to specific sets of neurons. Low-affinity binding (Kd of 10(-9) M) is mediated via a 75 kDa glycoprotein (LNGFR). Recently, a 140 kDa tyrosine protein kinase encoded by the proto-oncogene trk has been found to bind NGF with high affinity (Kd of 10(-11) M) and to evoke neurotrophic responses. In addition, the related trkB protein and the LNGFR have been shown to bind brain-derived neurotrophic factor (BDNF) and neurotrophin-3 (NT-3) with an affinity of Kd 10(-9) M. We demonstrate the distribution of mRNA encoding the neurotrophin-binding proteins in the forebrain of the 21-day-old Sprague-Dawley rat by in-situ hybridization. Expression of trk and LNGFR mRNA showed co-localization and was restricted to the medial septal nucleus and the nucleus of Broca's diagonal band, suggesting a receptor function in these cells for both proteins encoded. In contrast, expression of trkB was widely spread in many areas. Thus trkB protein might serve general functions in the forebrain.     

Colocalization of NGF binding sites, trk mRNA, and low-affinity NGF receptor mRNA in primary sensory neurons: responses to injury and infusion of NGF.

The distributions of mRNAs for the protooncogene trk and the low-affinity NGF receptor (LNGFR) were studied by hybridization with oligonucleotide probes on sections of adult rat primary sensory and sympathetic ganglia. For comparison with high-affinity binding sites, adjacent sections were processed for NGF receptor radioautography. Among neurons in lumbar dorsal root ganglia and trigeminal ganglia, trk mRNA and NGF-binding sites were closely colocalized; this finding together with previous direct evidence in other cell types is taken to indicate that trk protein is an essential component of the high-affinity NGF receptor in adult sensory neurons. In lumbar dorsal root ganglia and trigeminal ganglia, abundant LNGFR mRNA was found in all neurons with strong 125I-NGF labeling and on additional neurons lacking high-affinity NGF-binding sites. The presence of abundant LNGFR in neurons with high-affinity receptors could be the cause and/or consequence of their ability to respond to NGF. Neurons with abundant LNGFR mRNA but few high-affinity NGF-binding sites may have receptors for other members of the neurotrophin family. In nodose ganglia, neurons with high concentrations of LNGFR mRNA greatly outnumbered the small percentage with abundant trk mRNA. Following intrathecal infusion of NGF to otherwise normal dorsal root ganglia, the concentrations of LNGFR mRNA but not those of trk mRNA and NGF-binding sites were increased in NGF-responsive neurons. The usual single normal pattern of frequency histograms of LNGFR labeling indices became bimodal in response to NGF. Concentrations of NGF-binding sites, LNGFR mRNA, and trk mRNA were all decreased by peripheral nerve transection and restored by exogenous NGF, the restoration being complete for LNGFR mRNA and partial for trk mRNA and NGF-binding sites. The data indicate that NGF can regulate both LNGFR and trk mRNAs but do not clarify the possible contribution of the LNGFR protein to high-affinity binding sites.     

Expression of NGF receptor and NGF receptor mRNA in the developing and adult rat retina

Nerve growth factor (NGF) has been recently found to rescue axotomized retinal ganglion cells (RGCs) of the adult rat from degeneration. Because the trophic effect of NGF involves a receptor-coupling event, the characterization and cellular localization of the NGF receptor (NGFR) in the retina are essential to understanding the possible specific action of NGF in this district of the central nervous system. We report here that the NGFR mRNA is expressed in fetal, neonatal, and adult rat retina. Using monoclonal antibody 192-IgG to immunoprecipitate and immunohistochemically identify NGFR, we also found that the NGFR from the retina has a molecular weight identical to that of the NGFR from PC12 cells. The NGFR is localized on RGCs and Müller cells. Finally, following ligation of the optic nerve, NGFR-immunopositive material was found to accumulate both distal and proximal to the site of ligation, suggesting that RGC axons anterogradely and retrogradely transport the NGFR. These data raise the possibility that NGF may play a specific role in rat RGCs.     

IL-2 deficiency results in altered septal and hippocampal cytoarchitecture: relation to development and neurotrophins

We have found previously that brain IL-2 receptors are enriched in the hippocampal formation, and that loss of this cytokine results in cytoarchitectural alterations in the hippocampus and septum and related behavioral changes in IL-2 knockout (IL-2 KO) mice. These alterations included decreased cholinergic somata in the medial septum/vertical limb of the diagonal band of Broca (MS/vDB) and decreased distance across the infrapyramidal (IP) granule cell layer (GCL) of the dentate gyrus (DG). To extend our previous findings, several experiments were conducted comparing IL-2 KO mice and wild-type littermates to determine (1) whether the GABAergic projection neurons of IL-2 KO mice in this region were also affected; (2) if the reduction in septal cholinergic projection neurons found in adult IL-2 KO mice is present at weaning (and prior to the development of peripheral autoimmune disease); and (3) if loss of IL-2 may result in changes in the neurotrophins, brain-derived neurotrophic factor (BDNF) and nerve growth factor (NGF), involved in maintenance of hippocampal neurons. No differences in GABAergic neurons in the MS/vDB were found in adult mice, and the reduction in cholinergic neurons seen in adult IL-2 KO mice was not found in animals at postnatal day 21. The number of neurons in the IP-GCL was also significantly reduced. Compared to wild-type mice, IL-2 KO mice had significantly reduced concentration of BDNF protein and increased concentrations of NGF. These data suggest that the septohippocampal neuronal loss in IL-2 KO mice is selective for the cholinergic neurons and appears to be due to a failure in neuronal maintenance/survival that may be, in part, associated with changes in neurotrophins.     

Purification of embryonic rat motoneurons by panning on a monoclonal antibody to the low-affinity NGF receptor.

Available methods for purifying motoneurons to homogeneity from rodent spinal cord involve retrograde labelling and fluorescence-activated cell sorting, making them costly and time consuming. Motoneurons are the only neurons within the 15-day embryonic rat spinal cord to express the p75 low-affinity NGF receptor and we show that monoclonal antibody 192-IgG, which binds to the extracellular domain of p75, selectively labels a sub-population of large multipolar ventral spinal cord neurons in vitro. We have developed a bench-top panning method for purifying these motoneurons using antibody 192-IgG. Approximately 10(5) cells/spinal cord are obtained in 2 h by this method; 95% of them express p75 in culture. They rapidly put out neurites on laminin substrata, and their survival is enhanced by extracts of skeletal muscle. Using the panning method in conjunction with centrifugation on a 6.8% metrizamide cushion, separate populations of large and small motoneurons were obtained, each containing more than 90% neurons staining with antibody 192. The large motoneurons had choline acetyltransferase activities/cell approximately 4-fold greater than those of dissociated total spinal cells and 7-fold higher than those of the small motoneurons. These methods should be of considerable use for studies on factors affecting motoneuron survival and development and for transplantation of highly purified neuronal populations.     

Comparison between the behavioural effects of septal and hippocampal lesions: A review

The literature on the behavioural effects of septal and hippocampal lesions is classified according to behavioural paradigm. The effects of the two kinds of lesion are summarized and compared to each other. A ‘septo-hippocampal syndrome,’ consisting of the effects common to both lesions, is delineated, and divergences between the effects of the two lesions are noted.     

Medial septal cell interactions in relation to hippocampal field activity and the effects of atropine.

Simultaneously recorded pairs (from a single electrode) of cells in the medial septum (MS) vertical limb of the diagonal band of Broca (vDBB) were studied during the simultaneous occurrence of field activity in the hippocampal formation of urethane-anesthetized rats and following the systemic administration of atropine sulphate (ATSO4). The 2 types of field activities recorded were cholinergically mediated type 2 theta (theta) and large-amplitude irregular activity (LIA). The study had 3 objectives: (1) to determine if cells in close proximity in the MS/vDBB had a high probability of having similar discharge properties; (2) to determine the possible functional relationships occurring between pairs of MS/vDBB cells using standard cross correlational analyses; and (3) to determine the effects of ATSO4 on both the discharge properties of MS/vDBB cells and the interactions between these cells. Of the 143 cells recorded, 133 (93%) were theta-related and classified as theta-on or theta-off cells. theta-on cells had a significant increase in mean discharge rate during theta compared to their mean discharge rate during LIA and/or had a linear increase in discharge rate in relation to increases in theta frequency. theta-off cells had a significant increase in mean discharge rate during LIA compared to their mean discharge rate during theta and/or had a linear decrease in discharge rate in relation to increases in theta frequency. The remaining 10 (7%) cells were classified as nonrelated to theta. A probability analysis carried out on each of the separate criteria for classification revealed that several of these could predict whether or not cells were in close proximity of one another. Cells occurred in close proximity according to whether they had higher discharge rates during theta or LIA and according to whether or not they varied their discharge rates as theta frequency varied (linear-nonlinear). Cell discharge patterns of rhythmicity (phasic), or nonrhythmicity (tonic) on the other hand, were not good predictors of whether cells were in close proximity since there was an equal probability of a phasic cell being paired with either a phasic or a tonic cell. The presence of a phasic discharge pattern was, however, the main determinant of whether a correlation occurred between cell pairs. Cross correlations of the cell pair spike trains revealed that 50% of the 36 phasic-phasic cell pairs were correlated during both theta and LIA field activities. The characteristics of the cross correlation functions of these cell pairs (strong symmetrical correlations with sharp primary peaks or troughs occurring around the origin) suggested that they received shared excitatory and inhibitory inputs. The remaining 50% of the phasic-phasic pairs were cross correlated during theta only.(ABSTRACT TRUNCATED AT 400 WORDS)     

Expression of NGF receptor in the developing and adult primate central nervous system

Monoclonal antibodies against human NGF receptor have been used for immunocytochemical localization of NGF receptors in the CNS of macaques and baboons at various stages of development. In the adult, neurons in most brain regions are devoid of detectable NGF receptors. However, abundant NGF receptor immunoreactivity is present on a population of neurons in basal forebrain, which, on the basis of appearance and pattern of distribution, probably correspond, at least in part, to magnocellular cholinergic neurons of this region. NGF receptors were also associated with the vasculature in most brain regions. NGF receptor immunoreactivity is present on Mueller glia of neural retina. In macaque fetuses, approximately 1 month prenatally, retinal Mueller glia possess lower levels of receptor, while higher levels of receptor are present in the retinal nerve fiber layer. In fetal cerebellum, abundant receptor immunoreactivity is present on Purkinje cells, granule cells of the premigratory zone of the external granule layer, and neurons of the deep nuclei. Immunoreactivity decreases with subsequent development and is absent in the adult. In cerebellum, levels of NGF receptor assayed by affinity crosslinking to radioiodinated NGF, and levels of NGF receptor mRNA assayed by Northern blot analysis decrease dramatically during the last month of fetal life.     

Electrophysiological studies of the septal nuclei: I. The lateral septal region

Electrophysiological studies of the lateral septal region were performed on acutely prepared cats. The data indicate that the lateral septal region consists of two functionally distinct zones: a dorsal zone (i.e., dorsal septal nucleus) and a ventral zone (i.e., lateral septal nucleus). The dorsal septal nucleus receives a heavy ipsilateral fimbria projection, but receives no projection via the ventral septal afferent system. There is no return projection through the fimbria. Test responses recorded from the dorsal septal nucleus show prolonged periods of suppression. The lateral septal nucleus receives a lesser share of the ipsilateral fimbria input, but does receive input via the ventral septal afferent system. Convergence upon single cells between ipsilateral fimbria and ventral septal afferent input was an outstanding feature of lateral septal nucleus organization. Cells in the lateral septal nucleus project out of the lateral septal region in both dorsal and ventral directions.     

NGF and anti-NGF: evidence against effects on fiber growth in locus coeruleus from cultures of perinatal CNS tissues.

The present study examines whether the developing noradrenergic neurons of locus coeruleus depend on endogenous nerve growth factor (NGF) for nerve fiber production and if exogenous NGF stimulates fiber growth in this nucleus, using a collagen gel tissue culture technique. Lucus coeruleus from perinatal rat brain was used in three culture experiments: (1) lucus coeruleus, parietal cerebral cortex, and the superior cervical ganglion, prepared from newborn rats and cultured in different sectors of the same dishes; (2) locus coeruleus and parietal cerebral cortex from 17-day-old rat fetuses cultured in the same manner, and (3) locus coeruleus from 17-day-old rat fetuses co-cultured with spinal, sympathetic and ciliary ganglia from 8-day chick embryos. Experiments 1 and 2 were run with and without addition of NGF and anti-NGF, experiment 3 with and without anti-NGF. Total fiber production in all cultured tissues was evaluated daily by dark field and phase contrast microscopy during 4 days. Adrenergic nerve fiber production was then studied in the same locus coeruleus and superior cervical ganglia from the rats by Falck-Hillarp fluorescence histochemistry. Locus coeruleus and cortex cerebri from fetal rats produced dense fiber halos in culture. Locus coeruleus from newborn rats produced considerably less fibers, newborn cortex only few fibers. Superior cervical ganglia from the same newborn animals produced no or almost no fibers. Addition of NGF was not able to stimulate fiber growth in locus coeruleus nor in cortex cerebri as observed both in the living cultures and by fluorescence microscopy. Likewise, addition of anti-NGF did not affect fiber production in the CNS areas. The negative results with NGF on newborn locus coeruleus and cortex cerebri were in sharp contrast to the strong, highly significant fiber growth response demonstrated by the superior cervical ganglion from the same animals cultured in the same dishes. The third experiment tested whether locus coeruleus in tissue culture contained or produced nerve growth factor or any one of the three chick embryo ganglia. No response whatsoever in these three ganglia was observed. It is concluded that the developing locus coeruleus area does not contain or produce NGF, does not depend on NGF for fiber production, and is not stimulated by exogenous NGF.     

Quantitative effects produced by modifications of neuronal activity on the size of GABAA receptor clusters in hippocampal slice cultures

The number and strength of GABAergic synapses needs to be precisely adjusted for adequate control of excitatory activity. We investigated to what extent the size of GABA(A) receptor clusters at inhibitory synapses is under the regulation of neuronal activity. Slices from P7 rat hippocampus were cultured for 13 days in the presence of bicuculline or 4-aminopyridine (4-AP) to increase neuronal activity, or DNQX to decrease activity. The changes provoked by these treatments on clusters immunoreactive for the alpha1 and alpha2 subunits of the GABA(A) receptor or gephyrin were quantitatively evaluated. While an increase in activity augmented the density of these clusters, a decrease in activity provoked, in contrast, a decrease in their density. An inverse regulation was observed for the size of individual clusters. Bicuculline and 4-AP decreased whilst DNQX increased the mean size of the clusters. When the pharmacological treatments were applied for 2 days instead of 2 weeks, no effects on the size of the clusters were observed. The variations in the mean size of individual clusters were mainly due to changes in the number of small clusters. Finally, a regulation of the size of GABA(A) receptor clusters occurred during development in vivo, with a decrease of the mean size of the clusters between P7 and P21. This physiological change was also the result of an increase in the number of small clusters. These results indicate that neuronal activity regulates the mean size of GABA(A) receptor- and gephyrin-immunoreactive clusters by modifying specifically the number of synapses with small clusters of receptors.     

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.     

Expression of neurotrophins and Trk receptors in the avian retina

Using the RNase protection assay, we have found that nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF), and neurotrophin-3 (NT-3) are expressed in the avian retina during development. The expression peaks around embryonic days 12–15, with decreasing levels at later stages of development. Abundant levels of NGF and BDNF but low levels of NT-3 mRNA were found in the adult retina. We also found that light/darkness regulated the levels of NGF and BDNF mRNAs but not the levels of NT-3 mRNA in the 5-day-old chicken retina. It was demonstrated that NGF and BDNF mRNA levels were up-regulated by light exposure. The cellular localization of mRNA expression for the neurotrophins and neurotrophin receptors TrkA, TrkB, and TrkC in the retina was studied using in situ hybridization. The patterns of NGF and trkA mRNA expression were very similar and were localized to the external part of the inner nuclear layer on the border with the outer plexiform layer and corresponded to the localization of horizontal cells. NT-3 labeling was also found over the external part of the inner nuclear layer, whereas trkC mRNA was found over all layers in the retina. BDNF labeling was found over all layers in the retina, whereas TrkB labeling was intense over cells in the ganglion cell layer, which is in agreement with the response of ganglion cells to BDNF stimulation. Functional neurotrophin receptors were suggested by the response of retinal explants to neurotrophin stimulation. These data indicate that the neurotrophins play local roles in the retina that involve interactions between specific neuronal populations, which were identified by the localization of the Trk receptor expression. The data also suggest that NGF and BDNF expression is regulated by normal neuron usage in the retina. © 1996 Wiley-Liss, Inc.