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.     

Expression of Ciliary Neurotrophic Factor and the Neurotrophins-Nerve Growth Factor,Brain-Derived Neurotrophic Factor and Neurotrophin 3-in Cultured Rat Hippocampal Astrocytes

Cultured astrocytes are known to possess a range of neurotrophic activities in culture. In order to examine which factors may be responsible for these activities, we have examined the expression of the genes for four known neurotrophic factors – ciliary neurotrophic factor (CNTF), nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF) and neurotrophin 3 (NT3) – in purified astrocyte cultures derived from neonatal rat hippocampus. Hippocampal astrocytes were found to express mRNA for three neurotrophic factors – CNTF, NGF and NT3 – at significantly higher levels than other cultured cell types or cell lines examined. BDNF messenger RNA (mRNA), however, was undetectable in these astrocytes. The levels of CNTF, NGF and NT3 mRNA in astrocytes were largely unaffected by their degree of confluency, while serum removal caused only a transient decrease in mRNA levels, which returned to basal levels within 48 h. Astrocyte-derived CNTF was found to comigrate with recombinant rat CNTF at 23 kD on a Western blot. Immunocytochemical analysis revealed strong CNTF immunoreactivity in the cytoplasm of astrocytes, weak staining in the nucleus, but no CNTF at the cell surface. NGF and NT3 were undetectable immunocytochemically. CNTF-like activity, as assessed by bioassay on ciliary ganglion neurons, was found in the extract of cultured astrocytes but not in conditioned medium, whereas astrocyte-conditioned medium supported survival of dorsal root ganglion neurons but not ciliary or nodose ganglion neurons. This conditioned medium activity was neutralized with antibodies to NGF. Astrocyte extract also supported survival of dorsal root ganglion and nodose ganglion neurons, but these activities were not blocked by anti-NGF. Part, but not all, of the activity in astrocyte extracts which sustained nodose ganglion neurons could be attributed to CNTF.     

Basic Fibroblast Growth Factor in the Adrenal Gland

The importance of trophic agents for the development and maintenance of neurons and their presence in mesenchyme-derived neuronal target organs such as muscle is well exemplified by the protein nerve growth factor (NGF) and its synthesis in target areas of sympathetic and sensory nerves. Stringent conceptualization of target organ-regulated neuronal maintenance would imply that neurons were able to provide trophic support to their presynaptic counterparts. We present data suggesting that basic fibroblast growth factor (bFGF), a mitogen and trophic factor for several neuron populations in vitro, may be such a protein involved in retrograde trophic neuron - neuron interaction. Basic FGF or a closely related protein is present in the adrenal medulla and its sympathetic neuron-like chromaffin cells. A polyclonal antibody specific for bFGF recognizes an 18 kD band in Western blots of bFGF-enriched bovine adrenal medulla extracts and immunostains isolated bovine chromaffin cells. This antibody also blocks the bFGF-like activity present in adrenal medullary extracts and chromaffin granule extracts that both promote in vitro survival of embryonic chick ciliary ganglionic neurons. Furthermore, like bFGF, the soluble proteins of bovine chromaffin granules are mitogenic for cultured bovine aorta endothelial cells. Electrothermal unilateral destruction of the adrenal medulla causes the disappearance of 25% of Nissl-stained neurons in the ipsilateral intermediolateral column (IML) of the spinal cord between levels Th7 and L1, which contains the preganglionic neurons projecting to the adrenal medulla. Substitution of the adrenal medulla by gel foams soaked with bFGF prevents neuron losses in the IML. The effects are specific in that NGF and cytochrome C are ineffective. Our results suggest that bFGF is located in chromaffin cells and maintains target-deprived autonomic spinal cord neurons, thus possibly acting as an interneuronal trophic messenger in vivo.     

Expression and regulation of CNTF receptor-alpha in the in situ and in oculo grafted adult rat adrenal medulla

Cultured and transplanted adrenal medullary cells respond to ciliary neurotrophic factor (CNTF) with neurite formation and improved cell survival although the presence of the CNTF receptor-alpha (CNTFRalpha) has been unclear. This study show that CNTFRalpha mRNA was expressed in the postnatal day 1 as well as in the adult rat adrenal medulla. The highest CNTFRalpha mRNA signal was found in the ganglion cells of the adrenal medulla. After transplantation of adrenal medullary tissue the CNTFRalpha mRNA levels were down-regulated in the chromaffin cells. CNTF treatment of grafts did not normalize the receptor levels, but treatment with nerve growth factor (NGF) did. Thus, we demonstrate that CNTFRalpha mRNA is expressed in adrenal medulla, the levels becomes down-regulated after transplantation, but normalized after treatment with NGF.     

Growth factors effects on the expression of morphological and biochemical properties of avian embryonic sympathetic cells. Emphasis on NGF

Growth factors are known to be important agents in the differentiation and modulation of neuronal phenotypes. We have analyzed the effect of several growth factors on the modulation of morphological and biochemical properties of avian embryonic sympathetic neurons. The growth factors studied include: nerve growth factor (NGF), neurotrophin-3 (NT-3), brain derived neurotrophic factor (BDNF), ciliary neurotrophic factor (CNTF), basic fibroblast growth factor (bFGF) and transforming growth factor beta-1 (TGF-beta1). Morphological properties were analyzed by immunocytochemistry to neurofilament proteins and visualization of fibers after glyoxylic acid-induced fluorescence. Biochemical modulation was determined by radioimmunoanalysis for the peptides enkephalin (ENK), somatostatin (SS) and neuropeptide Y (NPY) and by HPLC-electrochemistry quantification of catecholamines. Similar to previous results using chromaffin cell cultures [R. Ramírez-Ordó?ez, J.E. García-Arrarás, Peptidergic, catecholaminergic and morphological properties of avian chromaffin cells are modulated distinctively by growth factors, Dev. Brain Res., 87 (1995) 160-171], we found a dissociation in the modulation of biochemical and morphological properties, however, the effect of specific factors differed between the chromaffin and sympathetic cultures. We have focused on NGF to analyze its effect on the sympathetic peptide phenotypes and its lack of an effect on the chromaffin cell peptide phenotypes. The results presented here, establish interesting differences between chromaffin cells and sympathetic neurons that are of importance to studies of cell lineage and differentiation.     

Oncostatin M regulates VIP expression in a human neuroblastoma cell line.

Oncostatin-M (OM), a recently described glycoprotein cytokine, is structurally and functionally related to cholinergic differentiation factor/leukemia inhibitory factor (CDF/LIF) and ciliary neurotrophic factor (CNTF). To determine whether OM, like CDF/LIF and CNTF, possesses trophic or differentiative functions for neurons we examined the effects of recombinant human OM on ciliary neuron survival and neurotransmitter expression in sympathetic neurons. Like CDF/LIF, but in contrast to CNTF, OM had no effect on ciliary neuronal survival at any concentration tested. OM produced small but reproducible increases in choline acetyl transferase (ChAT) activity and vasoactive intestinal peptide (VIP) levels in rat sympathetic neuron cultures, but this effect was significantly less than that of CNTF or CDF/LIF. To determine if human OM would elicit a more robust response from human cells, we utilized a human neuroblastoma cell line, NBFL, that responds to CNTF and CDF/LIF by altering vasoactive intestinal peptide (VIP) levels. OM specifically elevated VIP and c-fos mRNA levels in NBFL cells and was as potent as CDF/LIF in this assay. Our data provides evidence that OM acts on neurons and identifies a neural cell line responsive to OM, CNTF, CDF/LIF.     

Survival effect of ciliary neurotrophic factor (CNTF) on chick embryonic motoneurons in culture: comparison with other neurotrophic factors and cytokines

In previous studies, it has been demonstrated that ciliary neurotrophic factor (CNTF) has a potent survival effect on various populations of neurons in culture, in particular, neurons isolated from chick ciliary, dorsal root sensory, and sympathetic ganglia (Barbin et al., 1984). After recent investigations demonstrated that CNTF prevents the degeneration of motoneurons in newborn rats after axonal lesion (Sendtner et al., 1990), the question arose as to whether CNTF also has a survival effect on embryonic chick motoneurons at the developmental stage where physiological cell death occurs. To study this, it was essential to develop an isolation and culture procedure for the survival of chick E6 spinal motoneurons in which non-neuronal cells were eliminated and the motoneurons were highly enriched. In these cultures, virtually all of the initially plated motoneurons survived for at least 3 d in the presence of muscle extract, which was chosen as a positive control. Retrograde labeling of the motoneurons prior to their isolation showed that there is more than an 80% enrichment for motoneurons by the method used. The retrogradely labeled neurons also fulfilled the morphological criteria (diameter of neurons, appearance of processes) to identify motoneurons independent of retrograde labeling. Under these conditions, CNTF at a concentration of 1.5 ng/ml (EC50, 0.023 ng/ml) supported maximally 64% of the initially plated spinal motoneurons after 3 d and 53% after 6 d (the longest time period investigated). Other neurotrophic factors, such as NGF, brain-derived neurotrophic factor (BDNF), and neurotrophin-3, had no survival effect at all, even at concentrations up to 10 micrograms/ml for NGF and BDNF.(ABSTRACT TRUNCATED AT 250 WORDS)     

Age-dependent control of dorsal root ganglion neuron survival by macromolecular and low-molecular-weight trophic agents and substratum-bound laminins

Chick embryo dorsal root ganglion (DRG) neurons can be supported in vitro by nerve growth factor (NGF) and ciliary neuronotrophic factor (CNTF). Pyruvate is also required for survival of neurons from embryonic day 8 (E8) chick ciliary ganglia and from several chick and rat embryonic central nervous system sources. Here we have examined the survival requirements of chick DRG neurons between E6.5 and E15. These DRG neurons, initially dependent only on NGF, become dependent also on CNTF and later on increasingly independent from both factors. Pyruvate nearly doubles neuronal survival at all ages under all conditions. The pyruvate concentration permitting this additional survival was reduced two-fold with serine present. In the presence of polyornithine-bound laminins, nearly all seeded neurons were rescued by pyruvate plus NGF (E8 on), or pyruvate plus CNTF (E10 on), or pyruvate without trophic factors (E15). The same maximal survival was achieved without pyruvate by supplying E10 or older neurons with both NGF and CNTF. Unmodified polyornithine substrata yielded about one-half this number of surviving neurons.     

Environmental influences in the development of neural crest derivatives: glucocorticoids, growth factors, and chromaffin cell plasticity

The neural crest gives rise to three major adrenergic cell types: sympathetic principal neurons, adrenal chromaffin cells, and small intensely fluorescent (SIF) cells. All of these derivatives synthesize and store catecholamines, but they differ in numerous other characteristics. SIF cells appear intermediate in phenotype between the other two. We have examined the role of several environmental factors in the differentiation of sympathetic principal neurons and adrenal chromaffin cells. In previous studies of young rat adrenal chromaffin cells in dissociated cell culture, differentiated characteristics such as the presence of the enzyme phenylethanolamine N-methyltransferase (PNMT), epinephrine (E) synthesis, and large catecholamine storage vesicles were not well maintained. Here we describe long-term culture of chromaffin cells which, in the presence of micromolar glucocorticoid, maintained all of these characteristics. In addition, chromaffin cells of a variety of ages were found to be dependent on glucocorticoid for long-term survival in culture. In the absence of glucocorticoid, many adrenal chromaffin cells from neonatal rats could be rescued by nerve growth factor (NGF) administration. They extended neurites, as previously described by Unsicker and colleagues (Unsicker, K., B. Krisch, U. Otten, and H. Thoenen (1978) Proc. Natl. Acad. Sci. U.S.A. 75: 3498-3502). In contrast to previous studies, however, with long-term exposure to NGF these cells became indistinguishable from mature sympathetic neurons, as judged by the following morphological and biochemical criteria: increased cell size and loss of intense CA fluorescence in their cell bodies; acquisition of characteristic neuronal ultrastructure, including morphologically specialized synapses; loss of chromaffin granules, PNMT, and E synthesis; and acquisition of neuron markers, including tetanus toxin labeling and immunoreactivity to neurofilament protein. This conversion to neurons was markedly enhanced by addition of a non-neuronal cell conditioned medium (CM) containing a neurite-promoting factor, which acted by increasing the NGF responsiveness of the chromaffin cells. Even chromaffin cells from adult rats, which are known to grow few processes in response to NGF alone, became neuronal in the presence of this CM plus NGF. While converting to neurons, adrenal chromaffin cells transiently assumed an intermediate phenotype resembling type I SIF cells, which suggests particular developmental relationships between the different cell types of the sympathoadrenal lineage.(ABSTRACT TRUNCATED AT 400 WORDS)     

Trophic protection of motor neurons: clinical potential in motor neuron diseases

Recent advances in understanding the physiologic role of nerve growth factor (NGF), obtained both from tissue culture and efficacy studies in animals, have suggested that neurotrophic factors may have clinical potential in the treatment of neurodegenerative diseases or nerve trauma [12, 21]. First characterized as a target-derived survival factor for developing sympathetic and sensory neurons, it is now clear that NGF plays an important role in the maintenance and regeneration of mature peripheral neurons. Prompted by in vitro findings, it was established in the mid-1980's that intracerebroventricular infusions of NGF are capable of rescuing basal forebrain cholineric neurons from axotomy-induced cell death produced by fimbria-fornix lesion. Given that degeneration of cholinergic neurons is a major contributing factor in the loss of cognitive function in Alzheimer's disease, there has been a great deal of interest in exploring the therapeutic potential of NGF in this disease [16]. The highly restricted specificity of NGF for sympathetic neurons, sub-populations of neural crest-derived sensory neurons and striatal and basal forebrain cholinergic neurons has for almost two decades spurred the search for other neurotrophic factors with specificities directed to the many classes of neurons which do not respond to NGF. The biology of the recently discovered NGF-related family of neurotrophic factors, the neurotrophins and ciliary neurotrophic factor (CNTF), and their receptors, offers new prospects for the therapeutic potential of neurotrophic factors in the motor neuron diseases.     

Glial cell line-derived neurotrophic factor stimulates fiber formation and survival in cultured neurons from peripheral autonomic ganglia

Human recombinant glial cell line-derived neurotrophic factor (GDNF) was tested for its ability to stimulate fiber formation and neuron survival in primary cultures of peripheral ganglia dissected from the chicken embryo. GDNF, first characterized by its actions on central nervous system (CNS) neurons, had a marked stimulatory effect on fiber outgrowth in sympathetic and ciliary ganglia. Weaker responses were evoked in sensory spinal and nodose ganglia and in the ganglion of Remak. In addition, survival of neurons from the sympathetic and ciliary ganglia was stimulated by GDNF at 50 ng/ml. The effects were not mimicked by the distant but related protein transforming growth factor beta 1 (TGFβ1). The profile of neurons stimulated by GDNF is also distinct from the patterns of stimulation shown by nerve growth factor (NGF), stimulation strongly sympathetic but not ciliary ganglia, and ciliary neurotrophic factor (CNTF), stimulating mainly the ciliary ganglion. Moreover, using in situ hybridization histochemistry, GDNF was demonstrated to be present in the pineal gland in the new born rat, a target organ for sympathetic innervation. The present results suggest that GDNF is likely to act upon receptors present in several autonomic and sensory neuronal populations. GDNF may serve to support fiber outgrowth and cell survival in peripheral ganglia, adding yet one more trophic factor to the list of specific proteins controlling development and maintenance of the peripheral nervous system. © 1995 Wiley-Liss, Inc.     

Developmental time course of the effect of nerve growth factor on the parasympathetic ciliary ganglion

Neurite outgrowth in the presence and absence of nerve growth factor (NGF) was compared in neuronal cultures from the parasympathetic ciliary ganglion and from a traditional target of NGF, the sensory dorsal root ganglion. Both ciliary and dorsal root ganglion cultures exhibited a developmental time window during which the effect of NGF on neurite length was maximal. Although neuronal cultures from embryonic day 4 and 5 ganglia exhibited considerable neurite outgrowth in the absence of NGF, there was no significant increase in neurite outgrowth in the presence of NGF. After embryonic day 6, there was a steady increase in the effect of NGF in both types of ganglia. With ciliary ganglia, the effect of NGF increased until day 8, plateaued, then fell off significantly after day 11. With dorsal root ganglia, the effect of NGF continued to increase until day 12, plateaued, then fell off significantly after day 17. Thus, the period of maximal responsiveness of chick ciliary ganglia to NGF occurs earlier in development than for dorsal root ganglia. At the ages when the effect of NGF was maximal, approximately 20% of ciliary ganglion neurons exhibited substantial increases in neurite length compared to approximately 40% of dorsal root ganglion neurons. The effect of NGF was maximal at or below 1 ng/ml (4 X 10(-11) M) for both types of ganglia. These results support previous evidence that NGF does not simply boost ciliary ganglionic neurite growth non-specifically: the effect of NGF is already maximal at low, physiological concentrations and it appears at a specific time in development.     

Apoptosis of spinal interneurons induced by sciatic nerve axotomy in the neonatal rat is counteracted by nerve growth factor and ciliary neurotrophic factor

We have previously shown that not only motoneurons and dorsal root ganglion cells but also small neurons, presumably interneurons in the spinal cord, may undergo apoptotic cell death as a result of neonatal peripheral nerve transection in the rat. With the aid of electron microscopy, we have here demonstrated that apoptosis in the spinal cord is confined to neurons and does not involve glial cells at the survival time studied (24 hours). To define the relative importance of the loss of a potential target (motoneuron) and a potential afferent input (dorsal root ganglion cell) for the induction of apoptosis in interneurons in this situation, we have compared the distributions and time courses for TUNEL labeling, which detects apoptotic cell nuclei, in the L5 segment of the spinal cord and the L5 dorsal root ganglion after sciatic nerve transection in the neonatal (P2) rat. In additional experiments, we studied the effects on TUNEL labeling of interneurons after treatment of the cut sciatic nerve with either ciliary neurotrophic factor (CNTF) to rescue motoneurons or nerve growth factor (NGF) to rescue dorsal root ganglion cells. The time courses of the TUNEL labeling in motoneurons and interneurons induced by the lesion show great similarities (peak at 8-48 hours postoperatively), whereas the labeling in dorsal root ganglion cells occurs later (24-72 hours). Both CNTF and NGF decrease the number of TUNEL-labeled interneurons, but there is a regional difference, in that CNTF preferentially saves interneurons in deep dorsal and ventral parts of the spinal cord, whereas the rescuing effects of NGF are seen mainly in the superficial dorsal horn. The results are interpreted as signs of a trophic dependence on both the target and the afferent input for the survival of interneurons neonatally.     

Activation of p44 and p42 MAP Kinases is not Essential for the Survival of Rat Sympathetic Neurons

We have examined whether activation of MAP kinases [or extracellular signal-regulated kinases (ERKs)] is required for the survival of rat sympathetic neurons by comparing the actions of three survival factors whose survival-promoting actions can be blocked by neutralizing Fab fragments to p21 ras (Nobes and Tolkovsky, 1995, Eur. J. Neurosci. , 7, 344–350), nerve growth factor (NGF), the cytokines ciliary neurotrophic factor (CNTF) and leukaemia inhibitory factor (LIF), and the cyclic AMP analogue 4-(8-chlorophenylthio)cAMP (CPTcAMP). NGF-induced survival was accompanied by an intense (15- to 30-fold) and steady (>24 h) activation of p44 and p42 ERKs which waned rapidly ( t _1/2∼30 min) upon NGF withdrawal. However, concentrations of NGF that induced a weak (4- to 5-fold) stimulation of the ERKs were not sufficient to maintain long-term survival. Moreover, prolonged and intense stimulation of the ERKs by NGF for up to 15.5 h was unable to confer long-term survival, since withdrawal of NGF after this time resulted in neuronal death that was kinetically indistinguishable from the death of neurons that had not been exposed to NGF. By contrast, CNTF and LIF continued to support survival for up to 3 days after eliciting only transient (<30 min and 1 h respectively) activation of p44 and p42 ERKs, while CPTcAMP induced survival for several days without any measurable activation of the ERKs. Taken together, these data suggest that ERK activation perse is neither necessary nor sufficient for survival and that alternative pathways exist for effecting long-term survival of rat sympathetic neurons.     

Cooperation between HGF and CNTF in promoting the survival and growth of sensory and parasympathetic neurons

Previous studies have shown that hepatocyte growth factor (HGF) enhances the survival and growth of neurons that depend on NGF for survival. To determine if HGF cooperates with other neurotrophic factors in the developing peripheral nervous system, we studied the effect of HGF on parasympathetic ciliary ganglion neurons and proprioceptive trigeminal mesencephalic nucleus (TMN) neurons, both of which survive with CNTF. HGF did not promote the survival of these neurons on its own but did enhance the number that survived with CNTF and increased the length and branching of their neurite arbors. HGF did not, however, enhance the survival and growth of TMN neurons incubated with BDNF, which promoted their survival as effectively as CNTF. These results show that HGF cooperates with CNTF in promoting the survival and growth of parasympathetic and proprioceptive neurons and that within the same neurons, the effects of HGF on survival and growth are selectively dependent on which other signaling pathways are concurrently activated.     

Polyornithine-attached neurite-promoting factors (PNPFs). Culture sources and responsive neurons

We have recently reported the existence within chick embryo heart cell conditioned medium (HCM) of two distinct and independently assayable factors. One agent, ciliary neuronotrophic factor (CNTF), supports the in vitro survival of 8-day chick embryo ciliary ganglionic (CG) neurons. The other factor, polyornithine-attachable neurite promoting factor (PNPF) is required for extensive neuritic growth from these same CNTF-supported CG neurons.In the present study we have examined the occurrence of PNPF activity within nearly 100 different conditioned media using our previously described chick CG bioassay system. From this screening we conclude that: (1) PNPF production is a rather widespread property of cultured neural as well as non-neural cells; and (2) the chick bioassay is sensitive to PNPF activity from all the species examined, including mouse, rat, human and chick cells.We next examined the effects of 3 representative PNPF-containing conditioned media (from chick heart, mouse Schwann and rat Schwannoma) on neurite production from 3 other peripheral ganglionic neuronal cultures (8-day chick dorsal root, 11-day chick sympathetic, and neonatal mouse dorsal root ganglia) as well as 4 central neuronal cultures (8-day chick embryo telencephalon, optic lobe and spinal cord and neonatal mouse cerebellum). The results of these studies indicate: (1) that the peripheral neurons exhibit a dramatic increase in neurite production in response to PNPF which can be easily recognized both qualitatively and quantitatively; whereas (2) the CNS neurons showed essentially no PNPF-induced increase in neurite production. The sole exception to the latter was the appearance within the chick spinal cord cultures of a neuronal population which extended very long neurites in response to PNPF.     

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.     

Lumbar dorsal root ganglia of the cat: a quantitative study of peptide immunoreactivity and cell size

The purpose of the present study was to quantify the extent to which several peptides and serotonin coexist with substance P or somatostatin in selected lumbar dorsal root ganglia of the cat. The technique for the simultaneous visualization of two antigens by immunofluorescence was used to investigate the coexistence of neuropeptides in the lumbar dorsal root ganglia of colchicine-treated cats. Perikarya immunoreactive for calcitonin gene-related peptide, galanin, leu-enkephalin, somatostatin, and substance P were visualized in both the lumbar 5 and 6 dorsal root ganglia. In contrast, no immunoreactivity was observed for adipokinetic hormone, bombesin, dynorphin A, met-enkephalin, oxytocin, tyrosine hydroxylase, thyrotropin-releasing hormone, vasopressin, vasoactive intestinal peptide, or serotonin in either ganglion examined. Substance P coexisted with calcitonin-gene-related peptide, somatostatin, and leu-enkephalin. Somatostatin was colocalized with calcitonin gene-related peptide, leu-enkephalin, and substance P but coexisted with galanin minimally. The cell area of immunoreactive perikarya was also examined. Data concerning the cross-sectional area of immunoreactive cells indicated that somatostatin-immunoreactive perikarya were generally the largest population observed (up to approximately 6,000 microns2). Somatostatin and calcitonin gene-related peptide, as well as substance P and calcitonin gene-related peptide, coexisted in populations of cell bodies that had a smaller size (less than 2,000 microns2). These results suggest that certain peptides which coexist in the dorsal root ganglia may provide histochemical markers for functional groups of primary afferent neurons.     

Receptor-mediated regulation of neuropeptide gene expression in astrocytes

One of the functions of glial receptors is to regulate synthesis and release of a variety of neuropeptides and growth factor peptides, which in turn act on neurons or other glia. Because of the potential importance of these interactions in injured brain, we have examined the role of two different receptors in the regulation of astrocyte neuropeptide synthesis. Stimulation of β-adrenergic receptors on type 1 astrocytes resulted in increased mRNA and protein for the proenkephalin (PE) and somatostatin genes. This receptor also increased expression of nerve growth factor (NGF) and brain-derived neurotrophic factor (BDNF). The potential role of opiate receptors was examined in several ways. Treatment of newborn rats for 7 days with the opiate antagonist naltrex-one, prior to preparation of astrocytes, had no effect on PE mRNA or met-enkephalin content but resulted in a significant increase in NGF content. However, treatment of astrocytes in culture with met-enkephalin, morphine, or naltrexone had no effect on any of these parameters. No opiate binding could be detected, using either etorphine or bremazocine, to membranes of astrocytes prepared from cortex, cerebellum, striatum, or hippocampus of 1-day, 7-day, or 14-day postnatal rats. Thus we conclude that type 1 astrocytes do not express opiate receptors and that the in vivo effects of naltrexone are mediated indirectly via some other cell type/receptor. © 1994 Wiley-Liss, Inc.