Nerve growth factor: from neurotrophin to neurokine

Nerve growth factor (NGF) is largely known as a target-derived factor responsible for the survival and maintenance of the phenotype of specific subsets of peripheral neurones and basal forebrain cholinergic nuclei during development and maturation. However, NGF also exerts a modulatory role on sensory, nociceptive nerve physiology during adulthood that appears to correlate with hyperalgesic phenomena occurring in tissue inflammation. Other NGF-responsive cells are now recognized as belonging to the haemopoietic-immune system and to populations in the brain involved in neuroendocrine functions. The concentration of NGF is elevated in a number of inflammatory and autoimmune states in conjunction with an increased accumulation of mast cells. Mast cells and NGF appear to be involved in neuroimmune interactions and tissue inflammation, with NGF acting as a general 'alert' molecule capable of recruiting and priming tissue defence processes following insult as well as systemic defensive mechanisms. Moreover, mast cells themselves produce NGF, suggesting that alterations in normal mast cell behaviours can provoke maladaptive neuroimmune tissue responses whose consequences could have profound implications in inflammatory disease states. This review discusses recent discoveries involving novel and diverse biological activities of this fascinating molecule.     

A comprehensive study of the spatiotemporal pattern of beta-amyloid precursor protein mRNA and protein in the rat brain: lack of modulation by exogenously applied nerve growth factor

Nerve growth factor (NGF) is a neurotrophic factor for basal forebrain cholinergic neurons, a population that degenerates and dies in Alzheimer's disease (AD). It has been suggested that NGF be used to treat AD patients. However, in vivo administration of NGF to the developing hamster brain was shown to induce the expression of the beta-amyloid precursor protein (beta APP) gene. The association of alterations in beta APP gene expression with AD-like neuropathological changes and cognitive impairment in animals, and with AD-like neurodegeneration in Down syndrome patients suggests that NGF-mediated increases in beta APP expression could negate or attenuate NGF's neurotrophic activity in AD treatment trials. The present study was undertaken to explore further the influence of NGF on beta APP expression, and to determine which, if any, of the beta APP mRNAs is altered in response to NGF treatment. We first examined the spatiotemporal pattern of beta APP-695 and Kunitz protease inhibitor (KPI)-containing beta APP mRNA expression in the rat brain. Specific oligonucleotide probes were used to show that these mRNAs are present during embryonic development. In addition, we evaluated postnatal expression in nine brain regions and showed that beta APP mRNAs were readily detected in all regions at postnatal day 2. In human brain, the relative levels of beta APP-695 and beta APP-KPI mRNA and their protein are discordant, in that the level of beta APP-695 mRNA is slightly higher than that of beta APP-KPI, but beta APP-KPI protein predominates. In contrast, the several-fold excess of beta APP-695 mRNA relative to beta APP-KPI mRNA in the rat brain was also reflected at the protein level. Surprisingly, administration of exogenous NGF failed to affect rat beta APP mRNA levels either in vitro or during postnatal development in vivo.     

The effects of anti-nerve growth factor monoclonal antibodies on developing basal forebrain neurons are transient and reversible

In order to reassess the role of nerve growth factor (NGF) on rat basal forebrain cholinergic neurons (BFCNs) survival and/or phenotype maturation during the early postnatal life, we immunoneutralized NGF in vivo. Hybridoma cells producing the neutralizing anti-NGF monoclonal antibody alphaD11 were implanted in the lateral ventricle of the rat at different postnatal ages (P2, P8 and P15) and the effects on the number and the soma size of cholinacetyltransferase (ChAT) positive neurons were analysed 1, 2 or 3 weeks after the injection. A marked decrease in the number and in the soma size of BFCNs was observed implanting hybridoma cells at P2 and performing the analysis 1 week later. These effects are reversed 3 weeks after the implant of hybridoma cells at P2. At this time point, the levels of alphaD11 antibodies in the brain parenchyma are still in a vast molar excess over endogenous NGF. No effects on BFCNs were observed implanting alphaD11 cells at P15 while LGN neurons showed marked shrinkage. Our results demonstrate that the reduction in the number of ChAT-positive neurons during the first two postnatal weeks of anti-NGF treatment is not due to cell death. We conclude that NGF is not a survival factor for BFCNs, and that the influence of NGF on BFCNs cell maturation during the first 2 postnatal weeks is transient and reversible. Our results on tyrosine kinase (Trk) coexpression, suggest that NGF may cooperate with other factors in the cholinergic phenotype differentiation and maintenance after the second postnatal week.     

Axonal accumulation of p75NTR and TrkA in the septum following lesion of septo-hippocampal pathways

Septal cholinergic neurones depend on trophic support by nerve growth factor (NGF) which can rescue them from injury-induced degeneration. Since NGF exerts its effects via p75NTR and TrkA receptors coexpressed in vast majority of these neurones and down-regulated without NGF treatment after injury, in this study we aimed to examine how does the lesion to the cholinergic tracts affect distribution of both types of receptor proteins in damaged fibres. Early changes (two and seven days) were examined immunocytochemically within the septum and supracallosal stria after unilateral lesion to the supracallosal area and cingulum transecting some septal cholinergic efferents. We found accumulation of p75NTR and TrkA immunoreactive material (so-called "pile-up") within axonal segments of distended appearance proximal to the transection at two days postlesion and its translocation towards cell bodies seven days postsurgery. We observed p75NTR pile-up to be more intense than TrkA, which may indicate different cellular concentrations of both receptors. Receptor pile-up resembled acetylcholinesterase pile-up reported previously, suggesting a common response mechanism involving axonal transport disturbances.     

Death of developing septal cholinergic neurons following NGF withdrawal in vitro: protection by protein synthesis inhibition

Fetal septal neurons were grown in vitro under glass coverslips. This sandwich culture method significantly increased general neuronal survival, reduced glial proliferation, and permitted the removal of serum from the growth medium after 5 d in vitro. Thereafter, a simple, and completely defined, medium was used, and the effects of NGF, NGF withdrawal, and protein synthesis inhibition were examined on septal cholinergic neurons. NGF added to septal cultures at the time of plating resulted in a threefold increase in the number of cholinergic neurons seen at 14 d in vitro but had no effect on the survival of non-cholinergic cells. Cholinergic neurons identified by staining for AChE, ChAT, and p75NGFR could be maintained in serum-free, NGF-supplemented medium for over 40 d. When NGF was removed and NGF antibodies added to 14-d-old cultures, less than 30% of cholinergic neurons survived a further 4 d, but when NGF was similarly withdrawn from 35-d-old cultures, over 75% of cholinergic neurons survived. Reapplication of NGF after 3 but not after 12 or more hours of NGF withdrawal from 14-d-old cultures prevented the death of most cholinergic neurons. When NGF was withdrawn from 14-d-old cultures in the presence of the protein synthesis inhibitor cycloheximide, over 75% of the cholinergic neurons survived. These findings suggest that septal cholinergic neurons are dependent on NGF for survival only during a critical period of development and that growth factor-regulated developmental cell death may occur in CNS neurons by activation of programmed cell death requiring protein synthesis.     

Role of nerve growth factor in the development of rat sympathetic neurons in vitro. III. Effect on acetylcholine production

The effect of nerve growth factor (NGF) on the development of cholinergic sympathetic neurons was studied in cultures grown either on monolayers of dissociated rat heart cells or in medium conditioned by them. In the presence of rat heart cells the absolute requirement of neurons for exogenous NGF was partially spared. The ability of heart cells to support neuronal survival was due at least in part to production of a diffusable NGF-like substance into the medium. Although some neurons survived on the heart cell monolayer without added NGF, increased levels of exogenous NGF increased neuronal survival until saturation was achieved at 0.5 microgram/ml 7S NGF. The ability of neurons to produce acetylcholine (ACh) from choline was also dependent on the level of exogenous NGF. In mixed neuron-heart cell cultures, NGF increased both ACh and catecholamine (CA) production per neuron to the same extent; saturation occurred at 1 microgram/ml 7S NGF. As cholinergic neurons developed in culture, they became less dependent on NGF for survival and ACh production, but even in older cultures approximately 40% of the neurons died when NGF was withdrawn. Thus, NGF is as necessary for survival, growth, and differentiation of sympathetic neurons when the neurons express cholinergic functions as when the neurons express adrenergic functions (4, 5).     

Nerve growth factor: structure, function and therapeutic implications for Alzheimer's disease

Over the past decade, neurotrophic factors have generated much excitement for their potential as therapy for neurological disorders. In this regard, nerve growth factor (NGF), the founding member of the neurotrophin family, has generated great interest as a potential target for the treatment of Alzheimer's disease (AD). This interest is based on the observation that cholinergic basal forebrain (CBF) neurons which provide the major source of cholinergic innervation to the cerebral cortex and hippocampus undergo selective and severe degeneration in advanced AD and that these neurons are dependent upon NGF and its receptors for their survival. In fact, NGF transduces its effects by binding two classes of cell surface receptors, TrkA and p75(NTR), both of which are produced by CBF neurons. This review focuses on NGF/receptor binding, signal transduction, regulation of specific cellular endpoints, and the potential use of NGF in AD. Alterations in NGF ligand and receptor expression at different stages of AD are summarized. Recent results suggest that cognitive deficits in early AD and mild cognitive impairment (MCI) are not associated with a cholinergic deficit. Thus, the earliest cognitive deficits in AD may involve brain changes other than simply cholinergic system dysfunction. Recent findings indicate an early defect in NGF receptor expression in CBF neurons; therefore treatments aimed at facilitating NGF actions may prove highly beneficial in counteracting the cholinergic dysfunction found in end-stage AD and attenuating the rate of degeneration of these cholinergic neurons.     

NT-3 has a tropic effect on process outgrowth by postnatal auditory neurones in vitro

CONFOCAL analysis of early postnatal auditory neurones in a bicompartmental culture system was used to test for chemoattractant properties of NGF, BDNF and NT-3 on neuronal process outgrowth. NT-3 exerted a strong tropic effect on neuritic outgrowth from auditory neurones in this system. BDNF and NGF did not have any tropic activity that directed processes outgrowth from auditory neurones. However, BDNF was important for the support of neuronal survival in NGF-treated cultures and for neuritogenesis in NT-3-treated cultures. Since NT-3 has been identified as both a survival factor and a chemotropic agent for auditory neurones, it is likely that this neurotrophin will be a useful therapeutic agent in the treatment of damaged cochleae for the recovery of hearing.     

NGF mRNA is expressed by GABAergic but not cholinergic neurons in rat basal forebrain

Nerve growth factor (NGF) supports the survival and biosynthetic activities of basal forebrain cholinergic neurons and is expressed by neurons within lateral aspects of this system including the horizontal limb of the diagonal bands and magnocellular preoptic areas. In the present study, colormetric and isotopic in situ hybridization techniques were combined to identify the neurotransmitter phenotype of the NGF-producing cells in these two areas. Adult rat forebrain tissue was processed for the colocalization of mRNA for NGF with mRNA for either choline acetyltransferase, a cholinergic cell marker, or glutamic acid decarboxylase, a GABAergic cell marker. In both regions, many neurons were single-labeled for choline acetyltransferase mRNA, but cells containing both choline acetyltransferase and NGF mRNA were not detected. In these fields, virtually all NGF mRNA-positive neurons contained glutamic acid decarboxylase mRNA. The double-labeled cells comprised a subpopulation of GABAergic neurons; numerous cells labeled with glutamic acid decarboxylase cRNA alone were codistributed with the double-labeled neurons. These data demonstrate that in basal forebrain GABAergic neurons are the principal source of locally produced NGF.     

Neurotrophin effects on survival and expression of cholinergic properties in cultured rat septal neurons under normal and stress conditions

These studies tested the hypothesis that survival-promoting effects of neurotrophins on basal forebrain cholinergic neurons are enhanced under stress. Septal neurons from embryonic day 14-15 rats exposed for 10-14 d to neurotrophin [nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3), or neurotrophin-4 (NT-4), each at 100 ng/ml] showed a two- to threefold increase in choline acetyltransferase (ChAT) activity, with little evidence of synergistic interactions. Neurotrophins produced no significant increase in the survival of total or acetylcholinesterase (AChE)-positive neurons at moderate plating density (1200-1600 cells/mm2). However, with very low plating densities (2-28 cells/mm2) BDNF, NT-3, and NT-4 (but not NGF) increased total neuronal survival, and BDNF increased survival of AChE-positive neurons. NGF and BDNF enhanced ChAT activity and survival of cholinergic neurons after a 24 hr hypoglycemic stress, even when added 1 hr after stress onset. All four tested neurotrophins increased total neuronal survival after hypoglycemic stress. These results suggest that neurotrophins are important for preservation of central cholinergic function under stress conditions, with different neurotrophins protecting against different stresses. The stress-associated survival-promoting effects of neurotrophins were not limited to the cholinergic subpopulation.     

Selective induction of c-Jun and NGF in reactive astrocytes after cholinergic degenerations in rat basal forebrain

Cholinergic basal forebrain neurons are the major source of cortical cholinergic innervation. The number of these neurons is regulated by the availability of nerve growth factor (NGF) during development while in adulthood their cholinergic activity is modulated by NGF. In previous studies we have shown that cholinergic immunolesions of basal forebrain neurons increase local immediate early gene expression and NGF synthesis in the regions of degeneration. In this study we identify the cellular source of c-Jun and NGF expression using dual immunolabeling of c-Jun and NGF in combination with neuronal and glial markers. We demonstrate that both c-Jun and NGF are exclusively expressed in reactive astrocytes but not in microglia or in GABAergic basal forebrain neurons. These observations support the hypothesis that reactive astrocytes synthesize neurotrophic substances in vivo in response to neuronal degeneration in the basal forebrain.     

Opioid-mediated responses of dietary protein on reticular motility and plasma insulin

This study explores the effects of infusion of nerve growth factor (NGF) on behavioral outcome and cell death in the septal region using the clinically relevant model of fluid-percussion brain injury in the rat. Animals were subjected to fluid-percussion brain injury and 24 hours later a miniosmotic pump was implanted to infuse NGF (12 animals) or vehicle (12 animals) directly into the region of maximum injury for 2 weeks. Four weeks postinjury the animals were tested for cognitive function using a Morris Water Maze paradigm. Neurological motor function was evaluated over a 4-week postinjury period. The rats receiving NGF infusions had significantly higher memory scores than vehicle-treated animals. Examination of the cholinergic neurons in the medial septal region using choline acetyltransferase immunohistochemistry demonstrated significant cell loss after injury. Infusion of NGF significantly attenuated loss of these cholinergic neurons. A second group of animals was subjected to fluid-percussion brain injury alone (23 rats) or injury followed by NGF infusion (18 rats). These animals were killed between 24 hours and 2 weeks postinjury and the septal region was examined for the presence of apoptotic cells using the terminal deoxynucleotidyl transferase-mediated biotinylated-deoxyuridinetriphosphate nick-end labeling technique. Apoptotic cells were identified as early as 24 hours postinjury; their numbers peaked at 4 and 7 days, and then declined by 14 days. The NGF-treated animals had some apoptotic cells; however, even at 7 days there were significantly fewer of these cells. No significant motor differences were observed between the NGF- and vehicle-treated groups. These data indicate that NGF administration beginning 24 hours after fluid-percussion brain injury has a beneficial effect on cognition and results in sparing of cholinergic septal neurons. These improvements persist after cessation of NGF administration. The beneficial effects of NGF may be related to its ability to attenuate traumatically induced apoptotic cell death.     

Survival and neurite formation of mesencephalic trigeminal neurones of the rat in vitro

In order to study the development and functional properties of single, isolated, rat mesencephalic trigeminal neurones, a cell-culture procedure was developed for these specific primary sensory neurones. Mesencephalic trigeminal neurones were isolated from the brainstem of 16-day-old rat embryos. Various factors thought to promote the survival and growth of these neurones in vitro were examined. Outgrowth and maintenance of mesencephalic trigeminal neurones in vitro appeared to be stimulated by a muscle-derived factor, present in muscle-conditioned medium or in muscle extract. Of the neurotrophic factors examined, brain-derived neurotrophic factor and neurotrophin-3, but not nerve-growth factor, promoted the survival of rat mesencephalic trigeminal neurones. Optimal survival of these neurones was found to occur on a monolayer of astrocytes, an effect mediated through direct cell-to-cell interactions.     

Pattern of dietary intake and consumption of street foods among Nigerian students

We have previously shown that the level of nerve growth factor (NGF) undergoes significant changes in the cerebrospinal fluid of patients with Multiple Sclerosis and in the brain of rats affected by Experimental Allergic Encephalomyelitis (EAE). The functional significance of the endogenous disregulation of NGF is not known, though recent studies seem to suggest that NGF might be associated with the ability of oligodendrocytes (OLs) to produce and/or utilise NGF. The aim of the present study was therefore to investigate whether NGF is involved in the development and differentiation of cells of the subventricular zone (SVz) which arbors undifferentiated cells that can give rise to OLs. The results show that NGF injected into the brain of developing rats and of rats affected by EAE is retrogradely transported from the SVz to the brain parenchyma. These findings suggest that during the early phase of brain development and during EAE, NGF, along with other growth factors, is implicated in growth and/or differentiation of OLs and in protecting neuronal injury. The possible functional role of NGF in these events has been discussed.     

Intracerebroventricular infusion of nerve growth factor in three patients with Alzheimer's disease

Nerve growth factor (NGF) is important for the survival and maintenance of central cholinergic neurons, a signalling system impaired in Alzheimer's disease. We have treated 3 patients with Alzheimer's disease with a total of 6.6 mg NGF administered continuously into the lateral cerebral ventricle for 3 months in the first 2 patients and a total of 0.55 mg for 3 shorter periods in the third patient. The patients were extensively evaluated with clinical, neuropsychological, neurophysiological and neuroradiological techniques. Three months after the NGF treatment ended, a significant increase in nicotine binding was found in several brain areas in the first 2 patients and in the hippocampus in the third patient as studied by positron emission tomography. A clear cognitive amelioration could not be demonstrated, although a few neuropsychology tests showed slight improvements. The amount of slow-wave cortical activity as studied by electroencephalography was reduced in the first 2 patients. Two negative side effects occurred with NGF treatment: first, a dull, constant back pain was observed in all 3 patients, which in 1 patient was aggravated by axial loading resulting in sharp, shooting pain of short duration. When stopping the NGF infusion, the pain disappeared within a couple of days. Reducing the dose of NGF lessened the pain. Secondly, a marked weight reduction during the infusion with a clear weight gain after ending the infusion was seen in the first 2 patients. We conclude from this limited trial that, while long-term intracerebroventricular NGF administration may cause certain potentially beneficial effects, the intraventricular route of administration is also associated with negative side effects that appear to outweigh the positive effects of the present protocol. Alternative routes of administration, and/or lower doses of NGF, perhaps combined with low doses of other neurotrophic factors, may shift this balance in favor of positive effects.     

Are there cholinergic and non-cholinergic paradoxical sleep-on neurones in the pons?

Using microiontophoresis on unanesthetized head-restrained cats, we have found two distinct groups of neurones exhibiting tonic discharge specific to paradoxical sleep (PS) (PS-on neurones) in the mesopontine tegmentum, which contains both cholinergic and non-cholinergic neurones. One group is characterized by a broad action potential, slow conduction velocity and an inhibitory response to a potent cholinergic agonist, carbachol, applied iontophoretically during PS. The other is characterized by a short action potential, fast conduction velocity and an excitatory response to applied carbachol. All PS-on neurones were excited by glutamate. The present findings demonstrate the existence of two types of PS-on neurones and suggest their cholinergic and noncholinergic neurochemical properties.     

Role of Leukotriene-degrading enzymes in pulmonary response to antigen infusion in sensitized guinea pigs in vivo

Although the expression of nerve growth factor (NGF) in the rat striatum is the highest at 2 postnatal weeks (P2w), the action of NGF at that age has not been studied in detail. We examined the effects of several neurotrophic factors, including NGF, on striatal cholinergic neurons cultured from P2w rats. We also examined the effects of a cyclic AMP (cAMP) analog and high K(+)-evoked depolarization. NGF specifically promoted the survival of choline acetyltransferase (ChAT)-positive neurons, and consequently increased the ChAT activity per well, whereas it did not induce the ChAT activity per cholinergic neuron. NGF-responsiveness was the highest in striatal cultures from P2w rats, but it was almost lost in cultures from P4w rats. Brain-derived neurotrophic factor (BDNF), neurotrophin-4/5 (NT-4/5), and a cAMP analog had survival-promoting effects on striatal total neurons including cholinergic neurons. On the other hand, high K+ hardly promoted the survival of striatal cholinergic neurons in cultures from P2w rats, although it increased the viable number of total striatal neurons. High K+ did not increase the ChAT activity in any tested cultures from postnatal 3- to 28-day-old rats. These results demonstrated that NGF prevented the death of striatal cholinergic neurons in cultures from P2w rats, but not from P4w rats, and that high K+ could not rescue these deaths. We propose that cholinergic neurons in the striatum are programmed to die at P2w, and that this programmed cell death can be restored by neurotrophins, but not by depolarization.     

Modeling the developmental neurotoxicity of chlorpyrifos in vitro: macromolecule synthesis in PC12 cells

Exposure to apparently subtoxic doses of chlorpyrifos during late stages of brain development affects cell acquisition through a mixture of cholinergic and noncholinergic mechanisms. In the current study, we modeled these effects in vitro using rat pheochromocytoma (PC12), a cell line that, upon nerve-growth factor (NGF)-induced differentiation, develops the appearance and function of cholinergic target neurons, including the expression of cholinergic receptors. In the undifferentiated state (no NGF), chlorpyrifos evoked an immediate (1 h), robust, concentration-dependent inhibition of DNA synthesis as evaluated by [3H]thymidine incorporation, with a threshold of 0.5-1.5 microg/ml. Continuous exposure for up to 24 h maintained the same degree of inhibition. The effects were selective for DNA synthesis, as much smaller inhibitions were found for synthesis of RNA or protein. In contrast, direct cholinergic stimulation of the cells by 100 microM nicotine had much smaller effects on DNA synthesis. Moreover, the effects of chlorpyrifos on DNA synthesis could not be blocked by nicotinic or muscarinic antagonists, confirming that the effects were not mediated primarily through cholinergic hyperstimulation consequent to cholinesterase inhibition or to direct receptor-mediated effects. When PC12 cells underwent NGF-induced differentiation, the rate of cell replication fell dramatically and neurite extension was evident both from morphological examination and from biochemical markers (increased protein:DNA ratio). After introduction of NGF, chlorpyrifos maintained its ability to inhibit DNA synthesis acutely. However, the ability to inhibit RNA and protein synthesis initially intensified and then disappeared, indicating a shift in macromolecular targets as differentiation proceeded. We also tested the effects of long-term exposure to chlorpyrifos during the process of NGF-induced differentiation. Continuous chlorpyrifos exposure resulted in severe reductions in macromolecule synthesis and a deficit in the total number of cells, effects similar to those seen with chlorpyrifos treatment in vivo. At the highest concentrations, neurite extension was also inhibited. Our results suggest that chlorpyrifos can interact directly with developing neural cells to inhibit replication and neuritic outgrowth.     

Effects of nerve growth factor on glutathione peroxidase and catalase in PC12 cells

Nerve growth factor (NGF) is a member of the neurotrophin family and is required for the survival and maintenance of peripheral sympathetic and sensory ganglia. In the CNS, NGF regulates cholinergic expression by basal forebrain cholinergic neurons. NGF also stimulates cellular resistance to oxidative stress in the PC12 cell line and protects PC12 cells from the toxic effects of reactive oxygen species. The hypothesis that NGF protection involves changes in antioxidant enzyme expression was tested by measuring its effects on catalase and glutathione peroxidase (GSH Px) mRNA expression in PC12 cells. NGF increased catalase and GSH Px mRNA levels in PC12 cells in a time- and dose-dependent manner. There was also a corresponding increase in the enzyme activities of catalase and GSH Px. Thus, NGF can provide cytoprotection to PC12 cells by inducing the free radical scavenging enzymes catalase and GSH Px.     

Fc gamma RIIIB gene duplication: evidence for presence and expression of three distinct Fc gamma RIIIB genes in NA(1+,2+)SH(+) individuals

To investigate when the neurotrophic cytokines ciliary neurotrophic factor (CNTF), leukaemia inhibitory factor (LIF), oncostatin-M (OSM), interleukin-6 (IL-6) and cardiotrophin-1 (CT-1) act on developing sensory neurones and whether they co-operate with neurotrophins in regulating neuronal survival, we studied the in vitro trophic effects of these factors on two well-characterized populations of cranial sensory neurones at closely staged intervals throughout embryonic development. The cutaneous sensory neurones of the trigeminal ganglion, which show an early, transient survival response to BDNF and NT3 before becoming NGF-dependent, were supported by CNTF, LIF, OSM and CT-1 during the late fetal period, several days after the neurones become NGF-dependent. At this stage of development, these cytokines promoted the survival of a subset of NGF-responsive neurones. The enteroceptive neurones of the nodose ganglion, which retain dependence on BDNF throughout fetal development, were supported throughout their development by CNTF, LIF, OSM and CT-1, and displayed an additional survival response to IL-6 in the late fetal period. These findings indicate that populations of sensory neurones display different developmental patterns of cytokine responsiveness and show that embryonic trigeminal neurones pass through several phases of differing neurotrophic factor survival requirements.