Nerve growth factor and its mode of action

Nerve growth factor increases activity of ornithine decarboxylase in rat brain

Intraventricular administration of nanogram quantities of nerve growth factor to adult rats results in a marked increase in the activity of ornithine decarboxylase (L-ornithine carboxy-lyase, EC 4.1.1.17) in the brain. The increase occurs in all major brain regions and the activity is maximal by 7.5 hr after administration. The enzyme response to nerve growth factor increases in magnitude during maturation; the relative increase in ornithine decarboxylase activity in adult animals is much greater than that in young. Neither insulin nor bovine growth hormone was able to increase ornithine decarboxylase activity to the same extent as did nerve growth factor. When brain was separated into neuronal- and glial-enriched fractions, induction of ornithine decarboxylase was found in both, but a greater increase was observed in the glial fraction.

In vitro responses of sympathetic neurons to nerve growth factor and other macromolecular agents

Cells in the dissociated state from the sympathetic ganglia (SG) of 11-day-old chick embryos, and monolayer cultures of these cells are used to illustrate some of th extrinsic influences that regulate neuronal performance. In culture, the survival of SG neurons can be measured, as an assay for survival-promoting agents. Among the requirements of the SG discussed are: (1) nerve growth factor and other trophic factors that can replace it, (2) serum, and a defined mixture (N1) that can substitute for it, and (3) a minimal presence of non-neuronal cells. Also reviewed are factors that confer neurite-promoting competence on certain culture substrata. Suspensions of SG cells permit analysis of "short-latency" events triggered within minutes of the presentation of nerve growth factors and provide an insight into its possible mode of action. The most striking such event is its control over Na+/K+ pumps, since ionic control is a fundamental feature of living cells and may well mediate their regulation by trophic factors, hormones or mitogens.

Nerve growth factor concentration in human saliva

OBJECTIVE

The aims of this study were to measure the normal concentration of nerve growth factor (NGF) in healthy human saliva and to investigate the effects of age and gender differences on saliva NGF level.

MATERIALS AND METHODS

Resting whole, stimulated parotid, and stimulated submandibular/sublingual saliva were collected from 127 healthy volunteers with ages ranging from 20 to 81 years. The saliva NGF concentration was measured by enzyme immunoassay.

RESULTS AND CONCLUSIONS

The mean concentrations of NGF were 901.4 +/- 75.6 pg ml(-1) in resting whole saliva, 885.9 +/- 79.9 pg ml(-1) in stimulated parotid saliva, and 1066.1 +/- 88.1 pg ml(-1) in stimulated submandibular/sublingual saliva. The stimulated submandibular saliva showed lower NGF concentrations with increasing age (rho = -0.296, P = 0.001). The NGF concentrations of resting whole saliva (P = 0.025) and stimulated parotid saliva (P = 0.005) were significantly higher in women than men. The NGF concentration of stimulated submandibular saliva was significantly higher than stimulated parotid saliva (P = 0.005) and significantly correlated with stimulated parotid saliva NGF level (rho = -0.244, P = 0.008). We found measurable concentrations of NGF in all three sources of saliva; the concentration was affected by the source for the stimulated parotid and submandibular saliva, age for stimulated submandibular saliva, and gender difference for resting whole saliva and stimulated parotid saliva.

Nerve growth factor and Alzheimer's disease

Nerve growth factor (NGF) is a well-characterized protein that exerts pharmacological effects on a group of cholinergic neurons known to atrophy in Alzheimer's disease (AD). Considerable evidence from animal studies suggests that NGF may be useful in reversing, halting, or at least slowing the progression of AD-related cholinergic basal forebrain atrophy, perhaps even attenuating the cognitive deficit associated with the disorder. However, many questions remain concerning the role of NGF in AD. Levels of the low-affinity receptor for NGF appear to be at least stable in AD basal forebrain, and the recent finding of AD-related increases in cortical NGF brings into question whether endogenous NGF levels are related to the observed cholinergic atrophy and whether additional NGF will be useful in treating this disorder. Evidence regarding the localization of NGF within the central nervous system and its presumed role in maintaining basal forebrain cholinergic neurons is summarized, followed by a synopsis of the relevant aspects of AD neuropathology. The available data regarding levels of NGF and its receptor in the AD brain, as well as potential roles for NGF in the pathogenesis and treatment of AD, are also reviewed. NGF and its low affinity receptor are abundantly present within the AD brain, although this does not rule out an NGF-related mechanism in the degeneration of basal forebrain neurons, nor does it eliminate the possibility that exogenous NGF may be successfully used to treat AD. Further studies of the degree and distribution of NGF within the human brain in normal aging and in AD, and of the possible relationship between target NGF levels and the status of basal forebrain neurons in vivo, are necessary before engaging in clinical trials.

Potential- and acetylcholine-activated ionic currents of pheochromocytoma PC12 cells during incubation with nerve growth factor

Pheochromocytoma PC12 cells incubated with and without nerve growth factor were investigated using the patch-clamp technique in the whole-cell recording mode, and the concentration clamp method in the rat. On the fourth day of incubation with nerve growth factor, sodium potential-activated ionic currents appeared in the membranes of the most morphologically differentiated cells. At the same period a three-fold increase of acetylcholine-activated current density, compared with the cells incubated without nerve growth factor, was observed. Thus, the qualitative and quantitative changes in membrane properties can be a result of metabolic reorganization in PC12 cells induced by nerve growth factor and accompanied by morphological differentiation according to neuronal phenotype.

Blot and culture analysis of neuronotrophic factors in nerve regeneration chamber fluids

The fluid accumulating in silicone nerve regeneration chambers implanted between the cut ends of rat sciatic nerve contains neuronotrophic activities towards embryonic chick ciliary and sympathetic neurons. The blot and culture technique of Carnow et al. was used to determine if part of the neuronotrophic activities is due to ciliary neuronotrophic factor, which supports the survival of both types of neurons in vitro. The technique involves separating the fluid proteins by SDS-polyacrylamide gel electrophoresis, Western transfer, and then culturing of purified neurons on the nitrocellulose blots. After 24 hr surviving neurons are restricted to regions of the blot where neuronotrophic factor is present. Analysis of 1 and 2 day fluids showed that a multitude of factors are present, particularly in the 19-30 kD molecular weight range, with discrete peaks of activity at molecular weights consistent with those reported for ciliary neuronotrophic factor. There were several other peaks of activity present in the fluids in addition to these.

Nerve growth factor modulates tubulin transcript levels in pheochromocytoma PC12 cells

We report that nerve growth factor (NGF) can elevate tubulin transcript levels in cultured rat pheochromocytoma PC12 cells in a manner which correlates with its capacity to enhance neurite formation. The elevation is due, at least in part, to transcript stabilization. We have previously shown that insulin and its homologs can similarly enhance neurite outgrowth and tubulin mRNA levels in human neuroblastoma cells. Insulin by itself can neither induce neurite formation nor increase tubulin transcript levels in PC12 cells. However, both responses are potentiated in cells treated with the combination of insulin and NGF. The results together support the generalization that tubulin transcript levels are specifically elevated whenever neurite elongation is initiated by polypeptide neuritogenic factors.

Pathogenesis of port wine stains. A new hypothesis

Port wine stains have been shown to be lesions formed by the progressive dilatation of vessels within the superficial cutaneous vascular plexus. Previous investigators have been unable to define abnormalities of vessel structure or perivascular stromal tissues. We, however, have demonstrated morphologically that port wine stains are lacking proper innervation, and have shown them to behave differently than normal skin, physiologically. Dermal vessels are under the control of sympathetic nerves which course through the dermis and cause vasoconstriction without a parasympathetic system for counterregulation. We, therefore, propose that continued blood flow in the absence of tonic modulation is the basis for the vascular ectasia that characterizes the port wine stain.

Nerve growth factor (NGF) receptor expression in chicken cranial development

In order to map the expression of receptors for nerve growth factor (NGF) during brain and cranial ganglia development, iodinated NGF (125I beta NGF) was used as a probe in an autoradiographical analysis performed between embryonic day 3 (E3) and posthatching day 3 (P3) of chicken development. Heavy autoradiographic labelling was observed at the classical NGF target sites, the proximal cranial sensory ganglia and the sympathetic superior cervical ganglion, throughout development and after hatching. In contrast, only weak labelling could be detected during a restricted time span in the vestibulocochlear (E4-E8) and the distal cranial sensory ganglia (E4-E10), the neurons of which originate from the otic and epibranchial placodes. Specific 125I beta NGF binding was also observed in various brain regions during early brain development. NGF receptor expression there followed a characteristic pattern. The neuroepithelial layer displayed very low levels of specific 125I beta NGF binding, while strong 125I beta NGF labelling was found in the mantle layer. Brainstem somatomotor nuclei, visceromotor columns, brainstem alar plate, cerebellar anlage, tectum, and basal forebrain (epithalamus, striatum) were found to be transiently labelled by 125I beta NGF in early development (E4-E12). Non-nervous tissues such as parts of the otic vesicle epithelium and skeletal muscle anlagen of the head were also labelled. These results, showing specific binding of 125I beta NGF to cranial cells of different origin (neural tube, neural crest, placode, and possibly mesoderm) strengthen the concept that NGF may have diverse functions in growth and differentiation of various tissues and cell types.

Neuritic growth from a new subline of PC12 pheochromocytoma cells: cyclic AMP mimics the action of nerve growth factor

We have identified a new subline of PC12 pheochromocytoma cells (PC12D cells) in which neurites are extended within 24 hr in response to cAMP-enhancing reagents as well as in response to nerve growth factor (NGF), but not in response to epidermal growth factor or phorbol diester. Anti-NGF antiserum did not affect forskolin (FRK)-induced neuritic recruitment. FRK-induced neurites exhibited growth cones and contained secretion granules and many parallel arrays of microtubules as was the case with NGF-induced neurites. FRK, but not NGF, increased the levels of intracellular cAMP and activated adenylate cyclase in the membrane fraction. Both NGF and FRK enhanced the activities of tyrosine hydroxylase (TH), acetylcholinesterase (AchE), and ornithine decarboxylase (ODC), but not the levels of neuron-specific enolase. Enhanced levels of intracellular cAMP mimicked the effects of NGF on neuritic growth, TH, AchE, and ODC activities in PC12D cells, even though NGF does not act through elevation of levels of cAMP.

Continuous infusion of nerve growth factor prevents basal forebrain neuronal death after fimbria fornix transection

Neurons in the rat medial septum (MS) and vertical limb of the diagonal band of Broca (VDB) undergo a rapid and severe cell death after transection of their dorsal projection to the hippocampus by aspiration of the ipsilateral fimbria fornix and supracallosal striae. By 2 weeks posttransection, the extent of neuronal loss was 50% of the total neurons and 70% of the cholinergic neurons in the MS and 30% of the total neurons and 40% of the cholinergic neurons in the VDB. We hypothesized that (i) the death was due to the loss of a hippocampus-derived neuronotrophic factor, and (ii) exogenous nerve growth factor (NGF) might provide trophic support to the MS/VDB cholinergic neurons, in light of recent reports that the septal diagonal band cholinergic neurons are responsive to NGF and that NGF is present and produced in the hippocampus. In the present study, we attempted to prevent the transection-induced neuronal death by continuous infusion of exogenous 7S NGF (1 microgram/wk) through an intraventricular cannula device. We report here that NGF treatment significantly reduces both the total neuronal and cholinergic neuronal death found 2 weeks after fimbria fornix transection; there was a sparing of 50% of the neurons in the MS and essentially 100% of those in the VDB that otherwise would have died. We conclude that NGF also has a protective effect on noncholinergic neurons since calculations indicate that 80% of the NGF-affected neurons are noncholinergic.

Control of Na+, K+-pump activity in dorsal root ganglionic neurons by different neuronotrophic agents

Na+, K+-pump activity is indispensable for neuronal survival in vitro and a specific role in its regulation has been demonstrated for the NGF action on its target neurons. We have extended these earlier studies to include two other neuronotrophic agents: the chick eye-derived ciliary neuronotrophic factor (CNTF); and 12-O-tetradecanoyl-phorbol-13-acetate (TPA). CNTF and TPA individually supported the survival of an identical (and maximal) number of embryonic day 10 (E10) dorsal root ganglion (DRG) neurons as did NGF. E10 DRG neurons, seeded as monolayer cultures with 86Rb+ (as K+ tracer) but no trophic supplement in their medium, received NGF, CNTF, TPA, or no agent at 2, 4 or 6 h after seeding. The cultures were analyzed at 6 and 24 h for Na+, K+-pump performance and at 24 h for neuronal survival. Neurons receiving no agent lost their pump activity over the first 6 h and died over the 10-24 h incubation period. Both pump performance and survival were fully supported by any one of the 3 agents when provided at seeding time. Delayed presentation of NGF also led to full restoration of pump activity and survival support, as expected. In contrast, CNTF and TPA failed to correct the increasing pump deficits incurred with increasing times of trophic deprivation, and neuronal survival was proportionally reduced. Delayed addition of CNTF and TPA did, however, prevent further losses of both pump and viability. Close similarities were observed between pump failure and cell losses, demonstrating a linear correlation between pump performance and neuronal survival.(ABSTRACT TRUNCATED AT 250 WORDS)

The role of cAMP in nerve growth factor-promoted neurite outgrowth in PC12 cells

Nerve growth factor (NGF)-mediated neurite outgrowth in rat pheochromocytoma PC12 cells has been described to be synergistically potentiated by the simultaneous addition of dibutyryl cAMP. To elucidate further the role of cAMP in NGF-induced neurite outgrowth we have used the adenylate cyclase activator forskolin, cAMP, and a set of chemically modified cAMP analogues, including the adenosine cyclic 3',5'-phosphorothioates (cAMPS) (Rp)-cAMPS and (Sp)-cAMPS. These diastereomers have differential effects on the activation of cAMP-dependent protein kinases, i.e., (Sp)-cAMPS behaves as a cAMP agonist and (Rp)-cAMPS behaves as a cAMP antagonist. Our data show that the establishment of a neuritic network, as observed from PC12 cells treated with NGF alone, could not be induced by either forskolin, cAMP, or cAMP analogues alone. The presence of NGF in combination with forskolin or cAMP or its agonistic analogues potentiated the initiation of neurite outgrowth from PC12 cells. The (Sp)-cAMPS-induced stimulation of NGF-mediated process formation was successfully blocked by the (Rp)-cAMPS diastereomer. On the other hand, NGF-stimulated neurite outgrowth was not inhibited by the presence of the cAMP antagonist (Rp)-cAMPS. We conclude that the morphological differentiation of PC12 cells stimulated by NGF does not require cAMP as a second messenger. The constant increase of intracellular cAMP, caused by either forskolin or cAMP and the analogues, in combination with NGF, not only rapidly stimulated early neurite outgrowth but also exerted a maintaining effect on the neuronal network established by NGF.

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.

Nerve growth factor promotes cholinergic development in brain striatal cultures

We have examined the effect of the trophic protein, nerve growth factor (NGF), on organotypic cultures of fetal rat striatum. Treatment of cultures with NGF for 10-11 days resulted in a 5- to 12-fold increase in the specific activity of the cholinergic enzyme choline acetyltransferase (CAT; EC 2.3.1.6). in a dose-dependent fashion. This effect was not elicited by insulin, ferritin, or cytochrome c, proteins similar in structure or physicochemical properties to NGF. The effect of NGF on CAT activity was specifically blocked by anti-NGF antiserum, whereas treatment with the antiserum alone did not have a significant effect on the enzyme. Immunocytochemical studies of the treated cultures, using a monoclonal antibody directed against CAT, revealed positively stained neurons exhibiting dendritic and axonal processes. NGF did not have an effect on total protein content of the striatal cultures, suggesting a highly specific effect. Moreover, levels of substance P, a peptide localized to other, noncholinergic neurons, were not altered by NGF. Substance P remained unchanged after treatment with NGF for 12 days, whereas CAT activity increased 12-fold in sister cultures. Although the mechanisms of action of NGF on striatal cholinergic interneurons remain to be determined, the marked, specific response of CAT suggests that this well-defined trophic protein may play a critical role in normal brain development.

PC12 neurite regeneration and long-term maintenance in the absence of exogenous nerve growth factor in response to contact with Schwann cells

We have investigated mouse and rat ganglionic Schwann cells as possible sources of neurite outgrowth-promoting factors by co-culturing Schwann cells with nerve growth factor (NGF)-responsive PC12 pheochromocytoma cells primed by pretreatment with NGF. NGF-primed PC12 cells are capable of neurite regeneration when provided with an appropriate neurite promoting factor such as NGF. When primed PC12 cells were co-cultured with Schwann cells in the absence of exogenous NGF, PC12 cells that directly contacted Schwann cells became enlarged and flattened, attaining a neuron-like morphology within one day. When contact with Schwann cells was established, PC12 cells regenerated neurites by the first day of co-culture and these were maintained throughout the experiments (7 weeks). Most PC12 cells cultured in the same collagen-coated dishes with Schwann cells, but not directly in contact with them, failed to regenerate neurites. Instead, they began to proliferate, forming cell clusters. Neurite regeneration by PC12 cells in contact with Schwann cells was not blocked by antibody to NGF. These results demonstrate the presence of a neurite-promoting activity localized to the vicinity of the Schwann cell surface which is capable of eliciting regeneration and long-term maintenance of PC12 neurites in the absence of exogenous NGF. This activity does not appear to be due to NGF.

Neuronotrophic and neurite-promoting factors: effects on early postnatal chromaffin cells from rat adrenal medulla

Adrenal chromaffin cells from early postnatal rats maintained in culture have previously been shown to grow neuritic processes and survive better in the presence of nerve growth factor (NGF). In the present study we have quantitated the effects on chromaffin cell (postnatal day (D) 8) survival and neurite outgrowth of: NGF, ciliary neuronotrophic factor (CNTF), activities contained in various types of conditioned media (CM), and various substrata (laminin, fibronectin and polyornithine-binding neurite-promoting factor from RN 22 Schwannoma cells - PNPF). At saturating concentrations CNTF (50 ng/ml) and C6 glioma cell CM, (50-fold concentrated) supported survival over the 4-day culture period of all the chromaffin cells present in culture 2 h after seeding. NGF (50 ng/ml) and the non-concentrated CMs from primary Schwann cell and astrocytes as well as Schwannoma and C6 glioma cell cultures, achieved the maintenance of only about half the number of cells above the baseline survival as compared to CNTF and the concentrated C6-CM. These results are compatible with two subsets of D8 chromaffin cells, one only supported by CNTF and the concentrated CM and the other supported by either NGF or CNTF. Either NGF or CNTF elicited neurite outgrowth from 15-20% of the surviving cells. Combination of maximal doses of NGF and CNTF caused a small increase in neurite recruitment beyond that elicited by either factor alone. Low doses of CNTF added to the effect of NGF, shifting the NGF titration curve by about 4-fold. Neurite outgrowth was also induced by the concentrated, but not the unconcentrated C6-CM. Laminin, fibronectin and PNPF did not affect the fibronectin and PNPF did not affect the recruitment of neurites as compared to a polyornithine substratum unless the cultures were supplemented with a neuronotrophic factor and carried for 7 days. However, even before showing effects on neurite recruitment these substrata affected various neuritic performances, such as length, neurite numbers and endings per cell.

Nerve growth factor induces neural differentiation in undifferentiated cell of early chick embryos

Nerve growth factor (NGF) induced differentiation in postnodal pieces (PNPs) of stage 4 chick embryos. This induction was highly selective for neural tissue; no other structures developed in the NGF-treated PNPs. Furthermore, the number of PNPs showing neural differentiation was dependent on the concentration of NGF, but there was no correlation between the concentration of NGF (5-100 ng/ml) and extent of neuralization. The neural inducing capacity of NGF could be abolished by anti-NGF antibody. NGF-induced neural differentiation was accompanied by elevated intracellular levels of cyclic AMP. Exogenous cyclic AMP (175 micrograms/ml) was able to stimulate neural differentiation but, unlike NGF, induced other structures (e.g., notochord and pulsatile tissue). Overall results suggest that cells from chick embryos at developmental stages much earlier than previously thought are responsive to NGF and NGF or a a closely related substance may serve as a neural inducer in the chick embryo.

Regulation of growth cone morphology by nerve growth factor: a comparative study by scanning electron microscopy

The object of this study was to document and analyze local regulation by nerve growth factor (NGF) of neuronal growth cone properties and to explore the possible diversity of this effect in various NGF-responsive preparations. In particular, scanning electron microscopy was used to characterize the morphology of neuronal growth cones in cultures of dissociated chick embryo dorsal root ganglia (DRG) under conditions of continuous NGF exposure, withdrawal of NGF for 5-6 hr, and restoration of NGF for various times. Comparison was made with similarly manipulated cultures of dissociated newborn rat sympathetic ganglia and neurite-bearing PC12 pheochromocytoma cells. The growth cones of most of the continuously NGF-treated DRG neurons (cultured on poly-L-lysine or collagen-coated glass coverslips) had relatively compact central flattened areas and numerous prominent filopodia. Withdrawal of NGF resulted in a marked spreading of the central growth cone area so that the average maximum width of this structure increased by about threefold as compared to nondeprived cultures. The mean number and lengths of filopodia were unaffected. Restoration of NGF brought about, over a time course of tens of minutes, a return of the original type of growth cone morphology. Rather different responses were observed for the sympathetic neuron and PC12 cultures. Here, surface ruffles, only rarely seen in the chick cultures, were a major feature of the growth cones, whereas filopodia, though present, were less prominent. Removal of NGF led to loss of ruffles and to rounding up of the growth cones; NGF readdition elicited a rapid (less than 30 sec) reinitiation of ruffling and a more gradual (over tens of minutes) respreading of growth cones. These findings illustrate not only that NGF can regulate growth cone properties, but also that there is a diversity as to how this is manifested. Possible mechanisms and biological roles for this regulation are discussed.

Experimental sensory ganglionectomy by way of suicide axoplasmic transport

In attempts to destroy selectively the sensory ganglion cells via retrograde axoplasmic transport, either one or the other of the Ricinus communis agglutinins (RCA 60 and RCA 120), highly toxic lectins from castor beans, was topically applied to the proximal stump of the rat trigeminal branches (the mental and supraorbital nerves) or to the sciatic nerve. Within several days, the sensory ganglion cells associated with the nerve to which RCA was applied developed diffuse chromatolysis and subsequent dissolution of neuronal cell bodies. The resultant Wallerian degeneration of their primary afferent fibers could be traced within the brain stem and, in cases with RCA application to the sciatic nerve, within the spinal cord. This observation implies that the central counterpart of the peripheral nerve may be effectively destroyed by way of retrograde axoplasmic transport without direct attack on the target structure, and thus this method may be utilized in the future as a means for controlling various pain problems.

Nerve growth factor stimulates phospholipid methylation in target ganglionic neurons independently of the cyclic AMP and sodium pump responses

Suspensions of neurons prepared from embryonic day 12 (E12) chick sympathetic ganglia were incubated with [methyl-3H]methionine in the absence of nerve growth factor (NGF). Presentation of the factor for different periods of time resulted in an approximate three-fold stimulation of radioactivity incorporated into total phospholipid, followed by a rapid decline thereafter. Both the magnitude and the time of the response were dependent on the NGF concentration used. Also examined were possible relationships of phospholipid methylation to two other short-latency responses to NGF, i.e., control of the Na+,K+-pump and elevation of cyclic AMP content. Incubation of E12 sympathetic neurons with known transmethylase inhibitors (shown to be active in the present system) failed to prevent reactivation of the Na+,K+-pump in response to NGF administration. E16 sympathetic neurons and E15 sensory neurons, which do not depend on exogenous NGF for control of their Na+,K+-pump, still show a stimulation of phospholipid methylation when challenged with the factor. Blockage of the pump with ouabain also fails to prevent a methylation response. Thus, the pump and methylation responses to NGF occur independently of each other. Intact E8 chick dorsal root ganglia, but not E12 sympathetic ganglia, display a rapid and transient rise in their cyclic AMP content when presented with NGF. At a concentration of 10 biological units/ml, NGF elicits a peak of phospholipid methylation at 4 min, and a peak of cyclic AMP at 10 min. Methylation inhibitors prevent the methylation response, but not that of cyclic AMP.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of nerve growth factor and antibodies to nerve growth factor on ethylnitrosourea-induced neoplastic proliferation in rat trigeminal nerves

Sprague-Dawley (CD) rats were injected intravenously with ethylnitrosourea at a dose of 20 mg/kg on day 20 of gestation. This exposure resulted in early neoplastic proliferation or development of a neurinoma of the trigeminal nerve in 58% of the offspring at 90 days of age. Implantation of osmotic microinfusion pumps containing 2.5S nerve growth factor prior to ethylnitrosourea administration significantly reduced the incidence of early neoplastic proliferation. Postnatal implantation of microinfusion pumps containing 2.5S nerve growth factor also resulted in a significant but less pronounced reduction of early neoplastic proliferation. Immunoglobulin G directed against nerve growth factor (anti-nerve growth factor) did not influence the incidence of early neoplastic proliferation when administered via microinfusion pumps implanted on day 15 postnatally. These findings suggest that nerve growth factor has a protective effect on the developing nervous system against ethylnitrosourea-induced carcinogenesis.

Interaction of GM1 ganglioside with PC12 pheochromocytoma cells: serum- and NGF-dependent effects on neuritic growth (and proliferation)

The effects of ganglioside GM1 on proliferation and neuritic growth of PC12 pheochromocytoma cells were studied in the presence and absence of nerve growth factor (NGF). In the absence of NGF, but not in its presence, a decrease in the total number of PC12 cells was first observed after 4-6 days of culture with 10(-6) M GM1 in 0.1% fetal calf serum, and with 10(-3) M GM1 on 10% serum. NGF, with or without GM1, limits cell growth to the first 4-6 days. GM1 enhanced neuritic recruitment with serum concentrations of 0.3% or more. Optimal neurite response varied from 10(-6) M GM1 with 0.3% serum to 10(-4) M GM1 with 10% serum. The influence of GM1 on neurites became more pronounced with increasing serum concentrations, becoming maximal with 1% or greater serum. Serum exhibited a concentration-dependent inhibitory influence (lag) on NGF-induced neuritic recruitment, which was abolished by GM1. Rates of neuritic recruitment following the lag were unaffected by GM1, while showing an inverse correlation with serum concentrations of 0.1-0.5%. Serum may delay the NGF-induced neuritic recruitment of PC12 cells by two independent mechanisms. These results suggest that GM1, in some manner, prevents the serum-induced delay in the onset of neuritic recruitment, rather than stimulating the rate at which it precedes.

Ionic behaviors and nerve growth factor dependence in developing chick ganglia. II. Studies with neurons of dorsal root ganglia

Using intact dorsal root ganglia (DRG) from embryonic (E) chick and measuring 22Na+ accumulation, the authors have recently shown that (i) ionic control by the ganglia has a complete requirement for exogenous NGF between E6 and E10, and (ii) control of ion pump mechanisms independent of exogenous NGF is progressively acquired by these ganglia from E10 to E16. Similar experiments have now been carried out using enriched suspensions of ganglionic neurons to test whether the acquisition of endogenous control by older ganglia was (1) due to the close association between neurons and nonneurons, and (2) correlated with a decreasing need by these neurons for exogenous NGF for survival in culture. In this enriched neuronal population, Na+ accumulation in the absence of NGF increases from E7 to E10, paralleling the increase in Na+ accessible space under ouabain, but then decreases conspicuously between E10 and E16, despite little change in the ouabain-sensitive Na+ space. NGF prevents Na+ accumulation during the early period, and becomes increasingly irrelevant for this behavior in later (after E10) development. K+ movements (traced with 86Rb+) behaved similarly. Active K+ influx (Na+, K+-pump mediated) also increases severalfold between E7 and E10. This K+ influx is sensitive to NGF at E7 and E10 but not at E14, paralleling the observed Na+ and K+ behaviors. These data suggest that the control of Na+, K+-pump performances acquired by these neurons between E10 and E16 represents the development of a neuronal self-sufficiency. This increase in ionic control is not due to an increase in pump molecules or pumping efficiency. No increases in the binding of [3H]ouabain or active K+ influx occur between E10 and E16, when ionic control is developing. The ionic dependence on NGF by the DRG neurons changes with their developmental age along the same temporal pattern displayed by their survival response to NGF in culture.

Ionic responses and growth stimulation induced by nerve growth factor and epidermal growth factor in rat pheochromocytoma (PC12) cells

Rat pheochromocytoma cells (clone PC12) respond to nerve growth factor (NGF) by the acquirement of a phenotype resembling neuronal cells. In an earlier study we showed that NGF causes an increase in Na+,K+ pump activity, as monitored by ouabain-sensitive Rb+ influx. Here we show that addition of epidermal growth factor (EGF) to PC12 cells resulted in a stimulation of Na+,K+ pump activity as well. The increase of Na+,K+ pump activity by NGF or EGF was due to increased Na+ influx. This increased Na+ influx was sensitive to amiloride, an inhibitor of Na+,H+ exchange. Furthermore, no changes in membrane potential were observed upon addition of NGF or EGF. Amiloride-sensitive Na+,H+ exchange in PC12 cells was demonstrated by H+ efflux measurements and the effects of weak acids on Na+ influx. These observations suggest that both NGF and EGF activate an amiloride-sensitive, electroneutral Na+,H+ exchange mechanism in PC12 cells. These findings were surprising in view of the opposite ultimate biological effects of NGF and EGF, e.g., growth arrest vs. growth stimulation. However, within 24 h after addition, NGF was found to stimulate growth of PC12 cells, comparable to EGF. In the presence of amiloride, this stimulated growth by NGF and EGF was abolished. In contrast, amiloride did not affect NGF-induced neurite outgrowth of PC12 cells. From these observations it is concluded that in PC12 cells: (a) NGF has an initial growth stimulating effect; (b) neurite outgrowth is independent of increased amiloride-sensitive Na+ influx; and (c) growth stimulation by NGF and EGF is associated with increased amiloride-sensitive Na+ influx.

Nerve regeneration across an extended gap: a neurobiological view of nerve repair and the possible involvement of neuronotrophic factors

We have compared the anatomic and functional regeneration of a transected sciatic nerve following regrowth from its proximal stump through either preformed empty mesothelial chambers or autologous nerve grafts bridging a 10 mm gap. Within the mesothelial chambers an organized multifascicular nerve trunk forms between the proximal and distal stumps. After 3 months, distal segment cross sections from the mesothelial chamber and nerve graft groups did not differ with respect to axonal density or distribution of axonal diameters. Mean conduction velocities across the gaps were also similar, although the nerve graft group had a wider distribution of velocities. Little or no regeneration was evident when the gap between the nerve stumps was left empty. These results suggest that if the regrowing proximal stump is in an appropriate environment, it can form a well organized and oriented nerve trunk. In the mesothelial chambers, the regenerating nerve is surrounded by a loose cellular stroma and a small amount of interstitial fluid, which was found to contain trophic activity for cultured rodent sensory neurons. Such factors may also support nerve regeneration in vivo.

Regulation of Na+,K+ pump activity by nerve growth factor in chick embryo dorsal root ganglion cells

Nerve growth factor (NGF) is required for the growth and development of sensory and sympathetic neurons. Incubation of chick dorsal root ganglionic cells without NGF resulted in a decrease of active (Na+,K+-pump-mediated) K+ influx over a period of several hours. Addition of NGF to NGF-deprived cells caused 1) a return of the active K+ influx to the values occurring in cells continuously exposed to NGF, preceded by 2) a very rapid, but transient overstimulation of the Na+,K+-pump-mediated K+ influx. Restoration of normal Na+,K+-pump activity occurred at NGF concentrations of 1 biological unit/ml or greater, whereas the NGF concentration in the 1-100 biological unit/ml range affected the rapidity with which the pump restoration took place. The transient pump behavior was only observed in NGF-deprived cells and could not be elicited in NGF-supported steady-state cells or in cells having already received delayed NGF once. This transient Na+,K+-pump behavior was exclusively displayed in conjunction with a high intracellular Na+ concentration. Decreasing the external Na+ concentration below 70 mM reduced the hyperstimulation response to NGF, until at 10 mM Na+ the delayed presentation of NGF caused no overshoot at all. The effect of NGF on the Na+,K+-pump was specific for the NGF molecule and could not be mimicked by other proteins.

Effect of nerve growth factor on regeneration of goldfish optic axons

Axonal outgrowth following a crush of the goldfish optic nerve was enhanced if nerve growth factor (NGF) was administered by intraocular injection or by local application to the lesion site. Various forms of NGF (beta, 2.5S and 7S) were effective, producing a 20-40% decrease in the time required for recovery of the startle reaction to a bright light. A corresponding increase in axonal outgrowth was revealed by histological examination of the optic nerves. The effect produced by a single intraocular injection given at the time of the lesion was not further increased by subsequent injections. Up to 14 days after the lesion, the size of the retinal ganglion cell bodies and the incidence of nucleoli detectable by light microscopy were not affected by the NGF treatment.

Ionic behaviors and nerve growth factor dependence in developing embryonic chick ganglia. I. Studies with intact dorsal root ganglia

We have recently shown that intact and dissociated 8-day embryonic (E8) chick dorsal root ganglia (DRG) lose the ability to regulate their intracellular Na+, K+ levels when deprived of nerve growth factor (NGF) for 6 h; recovery occurs within minutes of NGF presentation. These ganglionic neurons are believed to depend on NGF for survival and neurite production over a defined period of embryonic life--between about E6 and E15 in the chick. Using intact DRG from E6-E16 chick embryos we determined developmental changes in: (i) 22Na+ accumulation in the presence and absence of NGF, or in the presence of ouabain; and (ii) intra- and extracellular fluid spaces. Sodium accumulation, in the presence of NGF, increases from E6 to E10. It parallels the total fluid space under ouabain but then decreases conspicuously between E10 and E16, despite little change in the latter. NGF thus prevents Na+ accumulation during the early period, and becomes increasingly irrelevant for this behavior in later (after E10) development. These data are interpreted as indicating that: (i) NGF is required for ionic control by DRG neurons up to E10; and (ii) indigenous behaviors for the control of ion pump mechanism(s) are progressively acquired by these cells from E10 to E16, in parallel with the decreasing ionic relevance of NGF. These findings are consistent with the view that the ionic responses to NGF correlate closely with the survival and neurite-promoting effects of this factor.

Spinal cord neuronotrophic factors (SCNTFs): I. Bioassay of schwannoma and other conditioned media

We present a procedure for the dissociation and growth in serum-free defined culture medium of 4-day chick embryo lumbar spinal cord (LC4) neurons. LC4 neurons will not survive for even 24 h without the addition of trophic supplements (putative spinal cord neuronotrophic factors, SCNTFs). Serum-free medium conditioned over chick embryo heart and skeletal muscle, mouse Schwann and rat RN22 Schwannoma cell cultures were found to contain SCNTF activity which could be quantitated using a convenient neuronal survival bioassay. RN22 conditioned medium also contains polyornithine-binding neurite promoting factors (PNPFs) which can be physically separated from SCNTF. When SCNTF and PNPF were presented to LC4 neurons individually or in combination (i) SCNTF, but not PNPF, supported neuronal survival whereas (ii) PNPF, but not SCNTF, induced neurite production. When LC4 neurons were grown in SCNTF alone, nearly all of them exhibited a flattened, circular, 'fried-egg' morphology. The subsequent addition of PNPF caused these cells to extend long neurites with characteristic terminal growth-cone-like structures.

Serum-free culture of chicken embryonic sensory ganglia in a balanced salt solution with nerve growth factor for periods up to two weeks

Culture of embryonic chicken dorsal root ganglia for periods exceeding a week generally require serum supplementation and a trophic factor such as nerve growth factor. In this communication we describe the culture of chicken E-9 dorsal root ganglia for periods up to 2 weeks in a system that is composed only of a simple basic salts solution and 10 ng/ml (3.8 X 10(-10)M) beta nerve growth factor. Commercially available tissue culture dishes are used which have a hydrophilic, gas-diffusable membrane on the bottom to which the ganglia directly attach, eliminating the need for added substratum. Sparse fiber outgrowth appears after 24 hours and growth of the fibers continues for 120 hours of incubation. At this time, the fibers are extremely dense and reach approximately 3.5-4.0 diameters from the body of the ganglion. Continued survival of these fibers appears to depend on the concentration of nonneuronal cells present in the dish. No fiber outgrowth occurs at any time in the absence of beta nerve growth factor. The simplicity and purity of this culture system makes it an attractive tool in the study of primary cell-cell interactions, the production of trophic factors by nonneuronal cells, and biochemical and physiological analyses of growing neurons.

Nerve growth factor effects and receptors in cultured human neuroblastoma cell lines

We studied the effects of nerve growth factor (NGF) to determine whether neuroblastoma (NB) cells share the pattern of altered response to growth regulatory factors shown by various malignant transformed cells. NGF induces neurite outgrowth, arrests growth, and enhances survival in normal neurons and in the rat pheochromocytoma, a tumor cell closely related to NB. With respect to neurite outgrowth, lines SK-N-SH, SH-SY5Y, LA-N-5, and CHP-126 were sensitive, IMR-32 was resistant, and SH-EP1, SK-N-MC, MC-IXC, CHP-100, and CHP-134 were unresponsive. Conditioned media from unresponsive cells did not inhibit response in sensitive cells. Unexpectedly, NGF neither reduced the growth rate nor enhanced survival in any NB cell line. Conditioned medium from all NB cell lines enhanced 125I-NGF binding in embryonic sensory cells. Regulation of growth rate and neurite outgrowth, then, are separable. A fundamental defect in NB may be the acquisition of a capacity for growth and survival independent of NGF. 125I-NGF was bound to both Fast and Slow receptors in MC-IXC cells, but only to Slow receptors in NGF-responsive SH-SY5Y and LA-N-5 cells, showing Fast receptors are not required for neurite outgrowth. Independence from NGF-regulated growth and survival is unexplainable by an absence of NGF receptors.

Developmental growth and degeneration of pulpal axons in feline primary incisors

The life history of pulpal axons in primary mandibular incisors was examined by light and electron microscopy in 56 kittens aged from 25 days postconception to 120 days after birth. Cells resembling Schwann cells preceded the first arrival of pulpal axons, 1 week postnatally. myelination was initiated during the second week. Two months after birth the incisors were fully grown and each pulp contained about 100 axons. Between 10 and 20% of these were myelinated and ranged in size from 1 to 5 micrometer. The relation between number of myelin lamellae and axon size appeared nonlinear and differed markedly from that in similarly sized inferior alveolar nerve axons. During the third month many unmyelinated axons showed signs of degeneration. With progress of root resorption an increasing proportion of both unmyelinated and myelinated axons degenerated. In highly resorbed incisors necrotic Schwann cells were associated with degenerating axons and there was a generalized pulpal tissue reaction. In some teeth with advanced root resorption pulpal axons were lacking. A progressive derangement of all pulpal tissue elements continued until shedding during the second half of the fourth month. In incisor nerve branches below the incisor teeth axon degeneration was very limited.

Glial-released proteins: II. Two-dimensional electrophoretic identification of proteins regulated by hydrocortisone

The proteins released into the culture medium (CM) by confluent C6 glioma cell monolayers were analyzed by two-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis (2-D SDS-PAGE). These cells synthesize and release a complex set of proteins which can be resolved on the basis of molecular charge and size. Over 400 spots on fluorograms corresponding to radio-labeled glial-released protein (GRP) were detected and classified according to their positions in 2-D gels. The marked species charge heterogeneity of the 2-D pattern was used as a criterion to assign the majority of GRP components to "series'. Series are composed of families of related proteins or glycoproteins distributed in a line of evenly spaced members in the isoelectric focusing dimension. Long-term exposure of monolayers to 2 microM hydrocortisone influenced the accumulation in the culture medium of half of the classified GRP species. Five classes of GRP were identified based on their steroid-responsiveness as seen in the deviation of GRP radiolabel ratios from control and hormone-treated culture CM. Hormonal response, verified by reverse-label experiments, showed a number of GRP in CM are either consistently increased 1- to 7- fold (Classes I and II) or decreased 1- to 3-fold (Classes IV and V). The remaining GRP (Class III) included those proteins which were found to be uninfluenced or to change in a week or inconsistent manner. Some GRP series were coordinately induced while other series gave graded responses. These results represent the first high-resolution classification of GRP by physical and biological properties.

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.

Trophic activities for dorsal root and sympathetic ganglionic neurons in media conditioned by Schwann and other peripheral cells

We describe here the use of 3 established nerve growth factor (NGF) targets (cultured neurons from dissociated chick embryo sympathetic ganglia, and chick embryo or neonatal mouse dorsal root ganglia) to investigate neuronotrophic activities in conditioned media (CMs) from: (i) chick embryo heart; (ii) purified mouse Schwann cells; and (iii) clonal rat Schwannoma RN22 cells. In chick sympathetic and mouse dorsal root ganglionic cultures, all 3 CMs supported survival of the same number of neurons as did mouse submaxillary NGF, and in most cases no increased survival resulted from concurrent administration of NGF and any one CM. NGF and CM activities were quantitated in each of the responsive cell systems. No differences were seen when either test population was used for the same agent, or when different CMs were examined on the same test cells. The CM activity, unlike that of NGF, was not blocked by even excess amounts of antiserum against mouse submaxillary NGF. The neuronotrophic activity of CMs appears to reside with macromolecular constituents. None of the CMs displayed trophic activity on chick embryo dorsal root ganglionic neurons. However, at least one of them (RN22 medium) had drastic effects on these ganglionic cells even in the presence of NGF, leaving open the possibility of a 'toxic' factor overriding putative trophic agents.

Glial-released proteins in clonal cultures and their modulation by hydrocortisone

Rat glial C6 cells release into the culture medium a reproducible spectrum of soluble proteins of 12 major peaks over a broad molecular weight range as determined by fractionation on SDS-gel electrophoresis. Exposing C6 monolayers to hydrocortisone (HC) results in a selective alteration in the pattern of glial-released protein (GRP). The selective HC-induced increase or decrease in GRP peaks is specific to HC in that 17 beta-estradiol, dibutyryl cyclic AMP, isoproterenol and melatonin exert either no detectable or a qualitatively different influence on the GRP pattern. The HC influence is dose dependent over a physiological range of concentrations from 10(-9) to 10(-6) M. Differences in culture age and in subclones of C6 can influence both the normal and the HC-induced pattern of GRP. The origin of th GRP is unknown, but pattern reproducibility, viability tests, surface labeling studies and metabolic labeling studies of soluble and particulate compartment proteins and glycoproteins support the position that cell lysis is not an important source of GRP. More importantly, these studies indicate that GRP and HC-induced changes in GRP pattern are physiologically significant aspects of glial cell behavior.