Concentration-dependent regulation of neuronal gene expression by nerve growth factor

NGF is a neurotrophic protein that promotes the survival, growth, and differentiation of developing sympathetic neurons. To directly determine the effects of different concentrations of NGF on neuronal gene expression, we examined mRNAs encoding the p75 low-affinity NGF (LNGF) receptor, T alpha 1 alpha-tubulin (T alpha 1), and tyrosine hydroxylase (TH) in pure cultures of rat sympathetic neurons from postnatal day 1 superior cervical ganglia. Studies of the timecourse of gene expression during 2 wk in culture indicated that a 5-d incubation period would be optimal for the concentration-effect studies. Analysis of RNA isolated from neurons cultured in 2-200 ng/ml 2.5S NGF for 5 d revealed that, as the NGF concentration increased, neurons expressed correspondingly increased levels of all three mRNAs. Both LNGF receptor and TH mRNAs increased seven-fold, and T alpha 1 mRNA increased four-fold in neurons cultured in 200 versus 10 ng/ml NGF. In contrast, T26 alpha-tubulin mRNA, which is constitutively expressed, did not alter as a function of NGF concentration. When neurons were initially cultured in 10 ng/ml NGF for 5 d, and then 200 ng/ml NGF was added, LNGF receptor, T alpha 1, and TH mRNAs all increased within 48 h. The timecourse of induction differed: T alpha 1 mRNA was maximal by 5 h, whereas LNGF receptor and TH mRNAs first began to increase at 12 h after the NGF increase. These experiments show that NGF regulates expression of a subset of mRNAs important to neuronal growth and differentiation over a broad concentration range, suggesting that the effects of NGF may be mediated by more than just a single receptor operating at one fixed affinity. These results also suggest a mechanism for coupling neuronal synthesis of axonal proteins to increases in size of the innervated target territory during growth of the organism.     

Nerve growth factor and neuronal cell death

The regulation of neuronal cell death by the neuronotrophic factor, nerve growth factor (NGF), has been described during neural development and following injury to the nervous system. Also, reduced NGF activity has been reported for the aged NGF-responsive neurons of the sympathetic nervous system and cholinergic regions of the central nervous system (CNS) in aged rodents and man. Although there is some knowledge of the molecular structure of the NGF and its receptor, less is known as to the mechanism of action of NGF. Here, a possible role for NGF in the regulation of oxidant--antioxidant balance is discussed as part of a molecular explanation for the known effects of NGF on neuronal survival during development, after injury, and in the aged CNS.     

Enhanced expression of cellular prion protein gene by insulin or nerve growth factor in immortalized mouse neuronal precursor cell lines

In order to understand the fundamental and putative roles of PrP(c) in the central nervous system, neuronal cell lines were established. Cells were immortalized by recombinant retrovirus vector-mediated transduction of SV40 T-antigen gene. Among these, two cell lines were selected based on their RT-PCR expressions of neuron-specific neurofilament (NF-H, NF-M) and cell morphology. These cell lines showed the properties of neuronal progenitor cells in antigenicity, morphology and responses to differentiating agents. Expression of PrP(c) was detected by immunocytochemical analysis. These cell lines responded to differentiating agents such as dibutyl cyclic AMP (dcAMP) and phorbol 12-myristate 13-acetate (PMA) before developing into neuronal-like cells. Neurite extensions were observed 20 min after incubation with the differentiating agents. Treatment with nerve growth factor (NGF) and insulin induced cell differentiation and enhanced expression of PrP gene (Prnp) mRNA and protein. The latter phenomenon was not inhibited by wortmannin, which is a specific inhibitor of phosphatidylinositol 3-kinase. These results suggest that PrP(c) plays an important role in the differentiation-mediated classic signaling pathway of neuronal cell.     

Pro-domain in precursor nerve growth factor mediates cell death

Nerve growth factor (NGF) is synthesized as a precursor, proNGF that undergoes post-translational processing to generate the biologically active mature NGF. While the neurotrophic function of NGF is well established, the activity of the proNGF precursor is still unclear. In this study, we have cloned the pro-domain of the precursor NGF molecule and have elucidated its function. We have used both mature and the furin resistant pro((R/G))NGF as controls in our experiments. Both pro((R/G))NGF and mature NGF (NGF) exhibited neurotrophic activity on PC12 cells while the pro-domain itself promoted cell death. The pro-domain, has been found to mediate apoptosis possibly by promoting the formation of a signaling complex comprising of endogenous p75(NTR) receptor, Bim/Bcl2 group of proteins and JNK and MEK1/2 signaling pathways.     

Inhibitors of protein synthesis and RNA synthesis prevent neuronal death caused by nerve growth factor deprivation

We have developed an experimental paradigm to study the mechanism by which nerve growth factor (NGF) allows the survival of sympathetic neurons. Dissociated sympathetic neurons from embryonic day-21 rats were grown in vitro for 7 d in the presence of NGF. Neurons were then deprived of trophic support by adding anti-NGF antiserum, causing them to die between 24 and 48 h later. Ultrastructural changes included disruption of neurites, followed by cell body changes characterized by an accumulation of lipid droplets, changes in the nuclear membrane, and dilation of the rough endoplasmic reticulum. No primary alterations of mitochondria or lysosomes were observed. The death of NGF-deprived neurons was characterized biochemically by assessing [35S]methionine incorporation into TCA precipitable protein and by measuring the release of the cytosolic enzyme adenylate kinase into the culture medium. Methionine incorporation began to decrease approximately 18 h post-deprivation and was maximally depressed by 36 h. Adenylate kinase began to appear in the culture medium approximately 30 h after deprivation, reaching a maximum by 54 h. The death of NGF-deprived neurons was entirely prevented by inhibiting protein or RNA synthesis. Cycloheximide, puromycin, anisomycin, actinomycin-D, and dichlorobenzimidazole riboside all prevented neuronal death subsequent to NGF deprivation as assessed by the above morphologic and biochemical criteria. The fact that sympathetic neurons must synthesize protein and RNA to die when deprived of NGF indicates that NGF, and presumably other neurotrophic factors, maintains neuronal survival by suppressing an endogenous, active death program.     

Identification of a novel kinase-like gene induced during neuronal cell death.

When deprived of neurotrophic factors, neuronal cells undergo a form of programmed cell death that involves a cascade of gene expression. To better understand this cascade, we screened the genes induced during programmed cell death evoked in neuronal PC6-3 cells by NGF-depletion and discovered a novel gene, NIPK (Neuronal cell death Inducible Putative Kinase), that contains a kinase-like domain. Expression of NIPK was also induced in cultured sympathetic neurons by NGF deprivation and in cortical neurons exposed to the Ca2+ ionophore, A23187. In contrast, NIPK was not induced during non-neuronal cell death evoked by serum or growth factor deprivation, or by treatment with methyl methanesulfonate, an agent that causes cell death by damaging DNA. Taken together, these findings suggest that NIPK is involved in programmed cell death via a pathway that is present in neurons but is absent in non-neurons.     

Protein tyrosine nitration is triggered by nerve growth factor during neuronal differentiation of PC12 cells

Nitric oxide (NO) is a signaling molecule implicated in a spectrum of cellular processes including neuronal differentiation. The signaling pathway triggered by NO in physiological processes involves the activation of soluble guanylate cyclase and S-nitrosylation of proteins, and, as recently proposed, nitration of tyrosine residues in proteins. However, little is known about the mechanisms involved and the target proteins for endogenous NO during the progression of neuronal differentiation. To address this question, we investigated the presence, localization, and subcellular distribution of nitrated proteins during neurotrophin-induced differentiation of PC12 cells. We find that some proteins show basal levels of tyrosine nitration in PC12 cells grown in the absence of nerve growth factor (NGF) and that nitration levels increase significantly after 2 days of incubation with this neurotrophin. Nitrated proteins accumulate over a period of several days in the presence of NGF. We demonstrate that this nitration is coupled to activation of nitric oxide synthase. The subcellular distribution of nitrated proteins changes during PC12 cell differentiation, displaying a shift from the cytosolic to the cytoskeletal fraction and we identified alpha-tubulin as the major target of nitration in PC12 cells by N-terminal sequence and MALDI-TOF analyses. We conclude that tyrosine nitration of proteins could be a novel molecular mechanism involved in the signaling pathway by which NO modulates NGF-induced differentiation in PC12 cells.     

Activation of polyubiquitin gene expression during developmentally programmed cell death

Ubiquitin, a highly conserved 76 amino acid protein, plays a role in targeting intracellular proteins for degradation. Ubiquitin expression was examined during the developmentally programmed atrophy and degeneration of the intersegmental muscles (ISMs) in the hawk-moth, Manduca sexta. A clone containing nine repeats of the ubiquitin coding sequence was isolated from an ISM cDNA library and was used as a probe to examine polyubiquitin expression during development. When the ISMs became committed to degenerate, polyubiquitin gene expression increased dramatically. Injection of 20-hydroxyecdysone, which delays degeneration in this system, prevented the increase in polyubiquitin mRNA. The expression of polyubiquitin occurred without apparent activation of the cell's heat shock response. These data suggest that ubiquitin plays a role in programmed cell death.     

Rapid regulation of neuronal growth cone shape and surface morphology by nerve growth factor

Scanning electron microscopy was used to study regulation of growth cone shape and surface morphology by nerve growth factor (NGF). The growth cones of cultured rat sympathetic neurons and neuronally-differentiated PC12 cells were observed under conditions of continuous NGF exposure, NGF withdrawal, and NGF readdition. Growth cones of cells cultured in the continuous presence of NGF were mostly spread in shape and about 60% possessed surface ruffles. Ruffles appeared to be largely restricted to growth cones in that few were observed on cell bodies and neurites. Withdrawal of NGF for 4–5 hr caused most of the growth cones to take on a non-spread or contracted appearance and to lose their ruffles. Readdition of NGF promoted rapid changes in growth cone properties. Within 30 sec, ruffling was again evident on the growth cones and remained prominent there throughout the course of treatment (up to 5 hr). This was in contrast to cell bodies on which, as previously reported, ruffling also occurred following NGF readdition, but only transiently (for less than 15 min). Respreading of growth cones also occurred under these conditions. This was evident within 1 min of NGF readdition and reached the levels observed in continuously-treated cultures within 1–2 hr. Neurites were also examined. Ruffles were only rarely present in the continuous presence of NGF and were absent after NGF withdrawal. NGF readdition elicited ruffling along neurites within 30 sec; the prevalence of such ruffles diminished to that seen in continuously-treated cultures within about an hour. As evidence of the specificity of these NGF effects, epidermal growth factor and dibutyryl cAMP, agents that elicit responses in PC12 cells, but do not promote their neuronal differentiation, had no observable effect on NGF-deprived growth cones. These findings demonstrate that NGF exerts very rapid effects on growth cone shape and surface morphology. Such actions may play roles in regulation of growth cone movement and guidance by NGF.Special Issue dedicated to Dr. E. M. Shooter and Dr. S. Varon.     

Changes in gene expression during programmed cell death in tomato cell suspensions

To identify genes involved in plant programmed cell death (PCD), changes in gene expression during PCD in a model system of suspension-cultured tomato cells were studied. In this system, cell death is triggered by treatment with camptothecin, an inhibitor of topoisomerase I. Cell death was accompanied by internucleosomal DNA degradation, indicating that the cell death process shares similarities with apoptosis in animals. Tomato homologues of DAD1 and HSR203, two genes that have been implicated in PCD, were isolated. During camptothecin-induced PCD tomato DAD1 mRNA levels roughly halve, while tomato HSR203 mRNA levels increase 5-fold. A differential display approach was used to identify novel genes that show changes in expression levels during camptothecin-induced PCD. This resulted in isolation of two up-regulated (CTU1 and CTU2) and four down-regulated (CTD1, CTD2, CTD4, and CTD5) cDNA clones. CTU1 shows high homology to various gluthatione S-transferases, whereas CTU2 is as yet unidentified. CTD1 is highly similar to Aux/IAA early-auxin-responsive genes. CTD2 corresponds to the tomato RSI-1 gene, CTD4 is an unknown clone, and CTD5 shows limited homology with a proline-rich protein from maize. Addition of the calcium channel blocker lanthanum chloride prevented camptothecin-induced cell death. The effect of lanthanum chloride on camptothecin-induced gene expression was studied to discriminate between putative cell death genes and general stress genes. The possible role of the various predicted gene products in plant PCD is discussed.     

Prolyl hydroxylase inhibitors delay neuronal cell death caused by trophic factor deprivation

Nerve growth factor (NGF) serves a critical survival-promoting function for developing sympathetic neurons. Following removal of NGF, sympathetic neurons undergo apoptosis characterized by the activation of c-Jun N-terminal kinases (JNKs), up-regulation of BH3-only proteins including BcL-2-interacting mediator of cell death (BIM)_EL, release of cytochrome c from mitochondria, and activation of caspases. Here we show that two small-molecule prolyl hydroxylase inhibitors frequently used to activate hypoxia-inducible factor (HIF) – ethyl 3,4-dihydroxybenzoic acid (DHB) and dimethyloxalylglycine (DMOG) – can inhibit apoptosis caused by trophic factor deprivation. Both DHB and DMOG blocked the release of cytochrome c from mitochondria after NGF withdrawal, whereas only DHB blocked c-Jun up-regulation and phosphorylation. DHB, but not DMOG, also attenuated the induction of BIM_EL in NGF-deprived neurons, suggesting a possible mechanism whereby DHB could inhibit cytochrome c release. DMOG, on the other hand, was substantially more effective at stabilizing HIF-2α and inducing expression of the HIF target gene hexokinase 2 than was DHB. Thus, while HIF prolyl hydroxylase inhibitors can delay cell death in NGF-deprived neurons, they do so through distinct mechanisms that, at least in the case of DHB, are partly independent of HIF stabilization.     

Structure and expression of the chicken beta nerve growth factor gene.

The 3' exon of the chicken beta nerve growth factor (NGF) gene was isolated by the use of a murine cDNA probe. DNA sequence analysis of the clone suggests a mature chicken NGF protein of 118 amino acids, showing approximately 85% homology to mouse and human NGF. In addition to this conservation of the mature NGF, parts of the propeptide and the untranslated 3' end of the NGF gene are also highly homologous in chicken, human and mouse. Therefore, these sequences probably subserve important functions. Expression of NGF mRNA in various chicken tissues was examined by RNA blot analysis with a chicken NGF probe. A single mRNA of 1.3 kb was detected at high levels in heart and brain of 10-week-old roosters, and, at lower levels in spleen, liver and skeletal muscle. These data suggest a correlation between NGF expression and the density of sympathetic innervation in peripheral organs, in analogy with findings for mammalian tissues. In the adult avian brain, NGF mRNA is found at higher concentration in the optic tectum and cerebellum than in the cortex and hippocampus. This pattern of NGF expression differs from that previously described for the rat brain. During late stages of development (day 18), NGF mRNA was expressed both in heart and brain of embryos but at lower levels than in the adult.