Mutually independent cyclic AMP and sodium responses to nerve growth factor in embryonic chick dorsal root ganglia

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.

The effects of nerve growth factor and dibutyryl cyclic AMP on cytoskeletal densities in cultured sensory ganglia

The effects of nerve growth factor (NGF) and dibutyryl cyclic AMP (DBC) on the density of cytoskeletal structures in cultured dorsal root ganglia were examined using morphometric techniques. After 24 hr in culture, NGF-treated neurites were longer than either DBC-treated or control neurites. At 48 hr, neurites produced in response to NGF and DBC were of equivalent length, while controls were considerably shorter. Comparison of electron micrographs of neuritic profiles revealed some differences of area and cytoskeletal density between treatment groups. Morphometric analysis was used to determine these differences under several growth conditions, at various rates of elongation and at different neurite lengths. As shown by analysis of variance, both NGF-treated and control neurites tapered in diameter at 48 hr in vitro, while DBC-induced neurites increased in area. An increase in cytoskeletal density for all treatment groups indicated that density was not always correlated with changes in area. An increased density of microtubules as compared to neurofilaments was seen at 24 hr, with equal densities of both cytoskeletal elements present after 48 hr in vitro. Comparisons between individual groups of data indicated that NGF-treated neurites relied primarily on microtubular density at 24 hr in vitro, when NGF induced longer, faster growing neurites. At 48 hr, there was an increase in neurofilaments proximal to the explant in the presence of DBC, implying that DBC may cause increased synthesis and/or transport of these structures. A comparison of microtubule to neurofilament ratios indicated that at 24 hr, there was always a greater density of microtubules. However, after 48 hr, neurofilament density increased such that there were equivalent densities of both cytoskeletal elements, possibly due to the overall increase in length observed in each treatment group. These data imply that 1) neurites with different rates of elongation may exhibit differences in cytoskeletal density; 2) neurites of equivalent lengths may be of differing stabilities; 3) NGF and DBC produce neurites with different cytoskeletal densities, implying divergent mechanisms of neurite induction; 4) the presence or absence of NGF may be partially responsible for variations in cytoskeletal densities observed between peripheral and central processes of DRG during development.

Differential regulation of calcitonin gene-related peptide and substance P in cultured neonatal rat vagal sensory neurons

Nodose (inferior vagal sensory) ganglia were removed from neonatal rats, enzymatically dispersed using neutral protease, and maintained on previously dispersed rat atriacytes. After 7-10 days in culture, calcitonin gene-related peptide (CGRP) was present in 1-3 times the molar amount of substance P (SP). The content of SP was doubled by the addition of nerve growth factor (NGF) whereas CGRP was significantly less increased by 50% or less. The addition of forskolin increased SP and CGRP levels in cultures with or without NGF by 60-80 percent. Phorbol ester (PMA) did not alter SP content but significantly raised CGRP content by 40% in NGF supplemented cultures (P less than 0.001). Corticosterone, 0.01-0.1 microM, reduced SP content by 30% independently of NGF but had no effect on CGRP. These studies demonstrate that SP in vagal sensory neurons is more sensitive than CGRP to the effects of NGF or corticosterone. Both peptides are up-regulated by presumed increases in intracellular cyclic AMP, while CGRP (or CGRP neurons) may be independently regulated by protein kinase C.

Nerve growth factor increases the cyclic GMP level and activates the cyclic GMP phosphodiesterase in PC12 cells

Nerve growth factor (NGF) rapidly increases the cyclic GMP (cGMP) level about 2-3-fold and enhances the cGMP phosphodiesterase (PDE) activity about 2-fold in rat pheochromocytoma PC12 cells. No changes in the level of cyclic AMP (cAMP) and in the activity of cAMP PDE were found. GTP and a nonhydrolysable analog of GTP, GMP-PCP, at 100 microM, were able to mimic the effect of NGF on the cGMP PDE activity. These results suggest that the cGMP system may be one of the second messengers of NGF action in PC12 cells.

Dissociation of the stellate morphology from intracellular cyclic AMP levels in cultured rat brain astroglial cells: effects of ganglioside GM1 and lysophosphatidylserine

Secondary microcultures of newborn rat cerebrum astroglial (AG) cells, maintained in a serum-free, chemically defined medium, were treated with various agents known to elevate intracellular cyclic AMP (cAMP) levels. Earlier studies had shown these drugs to induce a process-bearing (stellate) morphology in the AG cells, a response that was antagonized by the presence of gangliosides. One millimolar dibutyryl cyclic AMP (dBcAMP), 10 microM forskolin, 12 nM cholera toxin, and 30 microM isoproterenol all raised intracellular cAMP levels, from basal values of 3 pmol/10(6) cells to 30-30,000 pmol/10(6) cells, depending on the agent tested. dBcAMP caused the greatest elevation, and forskolin the least. The timing and/or the level of the AMP response did not precisely correlate with those of the stellation response. Values of ED50 with the four agents, as determined for the cAMP response, were always higher than stellation ED50 values in all treatments, and ED50 did not correlate with the maximal levels of cyclic AMP induced by the four agents. The capacity of ganglioside GM1 to block the stellation response to the four agents was not accompanied by a similar capacity to block the cAMP responses. Lysophosphatidylserine (lysoPS) had the capacity to induce AG cell stellation as well, without altering the basal level of cAMP. Both lysoPS and gangliosides, therefore, may act directly on the cellular machinery underlying the stellation response without involving changes in intracellular AMP.

Regulation of nerve growth factor action on Nsp100 phosphorylation in PC12h cells by calcium

Previous work from these laboratories has shown that in PC12 cells the phosphorylation of a specific soluble protein is decreased by treatment with nerve growth factor. This protein, designated Nsp100, and its kinase have been separated and partially purified from PC12 cells. The present studies have been designed to investigate the role of calcium in this action of nerve growth factor. It is shown here, using PC12h cells, that A23187, a calcium ionophore, and high levels of K+, a depolarizing stimulus, also decrease phosphorylation of Nsp100. Furthermore, the actions of nerve growth factor as well as those of A23187 and high levels of K+ are prevented by treatment of the cells with the calcium chelator EGTA. It is also shown that agents that raise levels of cyclic AMP in the cells, specifically dibutyryl cyclic AMP and cholera toxin, also decrease phosphorylation of Nsp100 but, in addition, increase phosphorylation of tyrosine hydroxylase. The action of these latter agents on Nsp100 is blocked by EGTA, but their action on tyrosine hydroxylase is not, indicating that even agents such as cholera toxin act on Nsp100 through a Ca2+-dependent mechanism.

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.

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)

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.

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.