Translational regulation of somatostatin in cultured sympathetic neurons

Coculture of sympathetic neurons with ganglion nonneuronal cells elevated levels of preprosomatostatin mRNA but did not alter neuronal synthesis, content, or release of somatostatin. Treatment of sympathetic neurons with culture medium conditioned by exposure to ganglion nonneuronal cells similarly elevated preprosomatostatin mRNA. Treatment with conditioned medium elevated somatostatin levels in pure neuronal cultures, but not in neurons cocultured with nonneuronal cells. Conditioned medium also failed to increase peptide levels in neurons cultured on a substratum of killed nonneuronal cells, despite a large increase in preprosomatostatin mRNA. These observations suggest that contact of sympathetic neurons with nonneuronal cell membranes inhibits the increase in peptide synthesis, but not the increase in preprosomatostatin mRNA after treatment with conditioned medium. Thus neuronal interactions with nonneuronal cells regulate somatostatin metabolism at both the mRNA and peptide levels. Regulatory effects on the mRNA and the peptide are separable and do not necessarily occur in parallel, and translational controls may be the rate-limiting factors.     

Conditions increasing the adrenergic properties of dissociated chick superior cervical ganglion neurons grown in long-term culture

Neurons dissociated from the embryonic chick superior cervical ganglion (SCG) were separated from ganglionic nonneuronal cells using a density gradient formed with Percoll. The sympathetic neurons were then grown for 3-4 weeks in serum containing medium on a polyornithine substrate precoated with heart-conditioned medium. Both catecholamine (CA) and acetylcholine (ACh) are synthesized and accumulated by these neurons, but the amount of CA is higher and increases much more over time in culture than the amount of ACh. The cultures become therefore more adrenergic with time. We report here that the adrenergic properties of these cells can be enhanced. A 3-fold increase in CA synthesis, as expressed on a per neuron basis, is obtained by increasing neuron cell density 3- to 4-fold. ACh synthesis, however, is decreased at high neuronal density. Optimal CA production is obtained at densities of 120-150,000 neurons/cm2. This effect is due to direct cell contact since it cannot be transferred to low density cultures by medium conditioned by high density cultures. Nerve growth factor concentrations 5-10-fold higher than the amount necessary for optimal neuronal survival (1 microgram/ml 7S NGF) increases CA production but do not affect ACh synthesis. This effect is highest at low plating densities (20-30,000 neurons/cm2, 10-fold increase) and progressively decreases with increasing neuronal density. No increase is obtained in high density cultures where CA production is maximal. In addition, we made the novel observation that medium conditioned by chick liver cells in culture (LCM) increases CA production approximately 4-fold, whereas it does not increase ACh production by the SCG neurons. Work is in progress to biochemically characterize the active component(s) present in the LCM and to determine whether they favor the survival of a subpopulation of adrenergic neurons possible present in these ganglia. Alternatively, the adrenergic differentiation of neurons initially capable of synthesizing both CA and ACh could be selectively increased by LCM.     

Calcium signals and the in vitro migration of chick ciliary ganglion cells

We have studied calcium signals and their role in the migration of neuronal and nonneuronal cells of embryonic chick ciliary ganglion (CG). In vitro, neurons migrate in association with nonneuronal cells to form cellular aggregates. Changes in the modulus of the velocity of the neuron-nonneuronal cell complex were observed in response to treatments that increased or decreased intracellular calcium concentration. In addition, both cell types generated spontaneous calcium activity that was abolished by removal of extracellular calcium. Calcium signals in neurons could be characterized as either spikes or waves. Neuronal spikes were found to be related to action potential generation whereas neuronal waves were due to voltage-independent calcium influx. Nonneuronal cells generated calcium oscillations that were dependent on calcium release from intracellular stores and on voltage-independent calcium influx. Application of thimerosal, a compound that stimulates calcium mobilization from internal stores, increased: (1) the amplitude of spontaneous nonneuronal oscillations; (2) the area of migrating nonneuronal cells; and (3) the velocity of the neuronal-nonneuronal cell complex. We conclude that CG cell migration is a calcium dependent process and that nonneuronal cell calcium oscillations play a key role in the modulation of velocity.     

Nerve growth factor-independent development of embryonic mouse sympathetic neurons in dissociated cell culture

Although ganglia from neonatal mouse sympathetic ganglia require nerve growth factor (NGF) for survival in culture, explanted sympathetic ganglia from early embryonic stages do not require added NGF for survival and growth. To determine whether the change in growth factor requirement is due to changes in the neurons themselves, to variations in neuronal populations, or to changes in nonneuronal cells, we examined the response to growth factors by dissociated sympathetic neurons at various stages of development. Results indicate that neurons from the 14-day gestational (E14) superior cervical ganglion (SCG) do not require NGF for initial survival and neurite extension, but do require the conditioned medium neurite extension factor, CMF. By 2 to 3 days thereafter, whether in vivo or in culture, most neurons have developed a requirement for NGF for survival in culture. During the same period, there is a concomitant increase in responsiveness to NGF alone as a trophic agent. Changes in response to NGF are not due to changes in NGF content of ganglia, to interactions in culture with nonneuronal cells, or to age-related differences in NGF requirements for maximum survival. The changes in growth factor requirements may be related to mechanisms regulating specificity of nerve-target connections.     

Neuronal survival activity of s100betabeta is enhanced by calcineurin inhibitors and requires activation of NF-kappaB.

S100betabeta is a calcium binding, neurotrophic protein produced by nonneuronal cells in the nervous system. The pathway by which it enhances neuronal survival is unknown. Here we show that S100betabeta enhances survival of embryonic chick forebrain neurons in a dose-dependent manner. In the presence of suboptimal amounts of S100betabeta, neuronal survival is enhanced by the immunosuppressants FK506 and cyclosporin A at concentrations that inhibit calcineurin, which is present in these cells. Rapamycin, an immunosuppressant that does not inhibit calcineurin, did not enhance cell survival. Cypermethrin, a direct and highly specific calcineurin inhibitor, mimicked the immunophilin ligands in its neurotrophic effect. None of the drugs stimulated neuronal survival in the absence of S100betabeta. In the presence of suboptimal amounts of S100betabeta, FK506, cyclosporin A, and cypermethrin (but not rapamycin) also increased NF-kappaB activity, as measured by immunofluorescence of cells stained with antibody to the active subunit (p65) and by immunoblotting of nuclear extracts. Antioxidant and glucocorticoid inhibitors of NF-kappaB decreased both the amount of active NF-kappaB and the survival of neurons caused by S100betabeta alone or in the presence of augmenting drugs. We conclude that S100betabeta enhances the survival of chick embryo forebrain neurons through the activation of NF-kappaB.     

Survival and maturation of cerebral neurons on poly(l-lysine) surfaces in the absence of serum

Several phenotypic properties of dissociated rat embryo cerebral cells cultivated in the absence of serum on poly(l-lysine) coated surfaces were investigated. A great enrichment of neuronal cells is attained after 3–4 weeks in culture as a result of cessation of nonneuronal cell proliferation. The monolayer pattern of cell-cell reassociation and neuritic sprouting is promoted by poly(l-lysine) and it is independent of serum presence or the existence of a layer of nonneuronal cells. Synaptic profiles and typical regions of neuropil are prominent. The neuronal plasma membrane is often characterized by irregular foldings at points of cell-cell contacts. A few biochemical parameters investigated lend support to the suggestion that the cerebral neurons acquire a certain state of functional maturation. It is proposed that substances secreted by the cells or released as a result of cell death may be conspicuous components for long-term survival of the cerebral neurons.     

The survival of early chick sympathetic neurons in vitro is dependent on a suitable substrate but independent of NGF

The neuronal cell population of lumbosacral sympathetic ganglia from 7-day-old chick embryos is characterized by a high proportion of cells with the ability to proliferate in culture (Rohrer and Thoenen, 1987). It is now demonstrated that neither proliferation nor survival of these neurons depend on the presence of nerve growth factor (NGF). However, neuronal survival did depend on the culture substrate used: on laminin, E7 neurons survived and their number increased due to proliferation, whereas on fibronectin (FN) or a substrate of molecules from heart cell-conditioned medium (HCM) a significant number of the cells died during early culture periods. Less than 70 and 50% of the number of neurons surviving on a laminin substrate were found on FN and HCM, respectively, after 3 days in culture. Although NGF did not affect neuronal survival, a small increase in neurite extension on these substrates was observed in the presence of NGF. Furthermore, although NGF did not prevent neuronal death after extended culture periods, this could be prevented by elevated extracellular potassium concentrations. Sympathetic neurons of E8 chick embryos however showed a strikingly different response to NGF compared with those of E7: whereas neuronal survival on laminin was not influenced by NGF, a significant effect of NGF on survival and on neurite extension was observed for E8 neurons on a HCM substrate. In contrast to cells from E7 and E8 embryos, the majority of neurons from E11 chick embryos required NGF for survival even on a laminin substrate as described previously (D. Edgar, R. Timpl, and H. Thoenen, 1984, EMBO J. 3, 1463-1468). These results demonstrate that while sympathetic neurons from E7 chick embryos do not depend on the soluble neurotrophic factor NGF for survival in vitro, they are dependent on molecules of the extracellular matrix. With increasing age, the survival requirements demonstrated in vitro change toward the classical pattern of NGF dependency. Low amounts of laminin-like immunoreactivity were shown to be present in sympathetic ganglia of E7 chick embryos which were then shown to increase as development proceeded. These data indicate that laminin may play a role in the survival and development of chick sympathetic neurons not only in vitro, but also in vivo.     

Neuronal survival in intact ciliary ganglia in vivo and in vitro: Ciliary neuronotrophic factor as a target surrogate

Ciliary neuronotrophic factor (CNTF) requirements for neuronal survival in the intact ciliary ganglion (CG) have been investigated in organ culture. Exogenous CNTF was not essential for neuronal survival until embryonic Day 8. Three-day cultures from 5-day ganglia were similar with or without CNTF, showing numerous neurons and extensive neuritic development. In 3-day cultures from 8-day-old ganglia, however, no neurons survived without CNTF, and the ganglia contained only nonneuronal cells and cell debris. Similar ganglia cultured with CNTF contained many neurons, surrounded by nonneuronal cells, and abundant neuritic processes. Morphologic maturation of the neurons was less advanced in CNTF-supported ganglia than in their in vivo counterparts.     

The culture of chick embryo dorsal root ganglionic cells on polylysine-coated plastic

Polylysine-coated culture surfaces are strongly adhesive for neural cells, restrict locomotion on nonneuronal elements, but do not inhibit neurite elongation. In the present study, culture dishes were pre-treated with poly-d-lysine (PDL) at various concentrations, seeded with dissociates from 8-day chick embryo dorsal root ganglia, and incubated under conditions that normally support both neuronal survival and nonneuronal proliferation. Pretreatment with low (0.1 mg/ml) PDL concentrations had no effect on neuronal survival and neuritic growth, but entirely prevented an increase in ganglionic nonneurons, yielding a numerically stable culture greatly enriched in neurons. Higher PDL concentrations caused increasing losses in both cell classes. The 50% levels of cell loss were achieved at about the same PDL dose, but earlier for neurons than nonneurons and still with no impairment of neuritic growth from the surviving neurons. A procedure was developed to compare acid-soluble and acid-precipitable accumulation of radioactivity under 1-hr pulses of [³H]uridine, which was applicable even to poorly attached cells. The cytotoxic effects of higher PDL pretreatments was revealed as early as 6 hr after seeding by 2- to 4-fold lower radioaccumulation. The data are discussed in terms of possible regulations of cell permeability and metabolism by adhesive interactions between cells and their substratum, or other cells.     

Neuronal differentiation from postmitotic precursors in the ciliary ganglion

In the chick ciliary ganglion, neuronal number is kept constant between St. 29 and St. 34 (E6-E8) despite a large amount of cell death. Here, we characterize the source of neurogenic cells in the ganglion as undifferentiated neural crest-derived cells. At St. 29, neurons and nonneuronal cells in the ciliary ganglion expressed the neural crest markers HNK-1 and p75(NTR). Over 50% of the cells were neurons at St. 29; of the nonneuronal cells, a small population expressed glial markers, whereas the majority was undifferentiated. When placed in culture, nonneuronal cells acquired immunoreactivity for HuD, suggesting that they had commenced neuronal differentiation. The newly differentiated neurons arose from precursors that did not incorporate bromodeoxyuridine. To test whether these precursors could undergo neural differentiation in vivo, purified nonneuronal cells from St. 29 quail ganglia were transplanted into chick embryos at St. 9-14. Subsequently, quail cells expressing neuronal markers were found in the chick ciliary ganglion. The existence of this precursor pool was transient because nonneuronal cells isolated from St. 38 ganglia failed to form neurons. Since all ciliary ganglion neurons are born prior to St. 29, these results demonstrate that there are postmitotic neural crest-derived precursors in the developing ciliary ganglion that can differentiate into neurons in the appropriate environment.     

Identification of early neurogenic cells in the neural crest lineage.

Pluripotent neural crest cells are restricted progressively during development. The sequence of restrictions and the time(s) in early development at which such restrictions are imposed on crest-derived cells are largely unknown. We have used a human autoantibody (Anti-Hu) to characterize neurogenic populations of avian neural crest-derived cells. Anti-Hu binds specifically to neurons and neuroendocrine cells in older (greater than E4) quail embryos. Early in development, Anti-Hu also binds a subpopulation of neural crest-derived cells that lack neuronal morphology and do not express other neuronal traits. These cells may represent a putative neurogenic precursor subpopulation within the early crest cell lineage. To test this hypothesis, we have characterized Anti-Hu immunoreactivity within crest-derived populations known to have, or to lack, the ability to give rise to new neurons. We report that the presence of Anti-Hu+ nonneuronal cells is correlated with the neurogenic ability of a given cell population. Moreover, Anti-Hu+ nonneuronal cells are transient and appear to be replaced by Anti-Hu+ neuronal cells. We conclude that Anti-Hu is a very early indicator of neurogenesis among crest-derived cells and that Anti-Hu+ nonneuronal cells are either neurogenic precursors or immature neurons.     

Effects of neurotransmitters and peptides on phospholipid hydrolysis in sympathetic and sensory neurons

The effects of neurotransmitters and peptides on phosphoinositide hydrolysis were studied by measuring [3H]inositol monophosphate ([3H]IP) and protein kinase C (PKC) activity in the sympathetic and sensory neuronal cultures of the chick embryo. [3H]IP was increased in sympathetic neurons by acetylcholine (ACh), muscarine, serotonin (5-HT), and vasoactive intestinal polypeptide. ACh, muscarine, 5-HT, and bradykinin increased [3H]IP in sensory neuronal cultures. Dopamine, norepinephrine, histamine, and nerve growth factor did not stimulate [3H]IP formation in both cultures. ACh and phorbol 12,13-dibutyrate (PDB) increased the PKC activity by two- to sevenfold in the particulate fraction of both cultures. In sympathetic neurons, PKC activity was increased in the particulate fraction; activity in the cytosolic fraction was not affected. There was a 50% decline in the protein kinase C activity of the cytosolic fraction after PDB and ACh treatment of sensory cultures. The decline in PKC activity in the cytosolic fraction was attributed to the presence of nonneuronal cells in sensory cultures. To confirm this, the enzyme activity was determined in tissues that contain a heterogeneous population of cells. PDB activated PKC in the adrenal medulla and the brain of the rat. In both tissues there was a 65% decline in the PKC activity of the cytosolic fraction and about a 75% increase in the particulate fraction. We conclude that the mechanism of activation of protein kinase C in pure cultures of sympathetic neurons is different than in tissues containing a mixed population of neurons and nonneuronal cells.     

Nonneuronal cells mediate neurotrophic action of vasoactive intestinal peptide

The developmental regulation of neuronal survival by vasoactive intestinal peptide (VIP) was investigated in dissociated spinal cord-dorsal root ganglion (SC-DRG) cultures. Previous studies demonstrated that VIP increased neuronal survival in SC-DRG cultures when synaptic transmission was blocked with tetrodotoxin (TTX). This effect was further investigated to determine if VIP acted directly on neurons or via nonneuronal cells. For these studies, SC-DRG cells were cultured under conditions designed to provide preparations enriched for a particular cell type: astrocyte-enriched background cell (BG) cultures, meningeal fibroblast cultures, standard mixed neuron-nonneuron (STD) cultures, and neuron-enriched (N) cultures. Addition of 0.1 nM VIP to TTX-treated STD cultures for 5 d prevented the TTX-mediated death and the death that occurred naturally during development in culture, whereas the same treatment on N cultures did not prevent neuronal cell death. Conditioned medium from VIP-stimulated BG cultures prevented neuronal cell death when added to the medium (10% of total volume) of N cultures treated with TTX. The same amount of conditioned medium from BG cultures that were not treated with VIP had no protective action on N cultures. Conditioned medium from N or meningeal fibroblast cultures, either with or without VIP treatment, did not prevent TTX-mediated cell death in N test cultures. These data indicate that VIP increases the availability of neurotrophic survival-promoting substances derived from nonneuronal cultures, the most likely source being astroglial cells. This study suggests that VIP has a role in mediating a neuron-glia-neuron interaction that influences the trophic regulation of neuronal survival.     

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).     

Transforming growth factor beta has neurotrophic actions on sensory neurons in vitro and is synergistic with nerve growth factor.

Transforming growth factor beta (TGF beta) influences the growth and differentiation of a wide variety of nonneuronal cells (nnc) during embryogenesis and in response to wounding. In the present study TGF beta 1 and TGF beta 2 were examined for their neurotrophic actions on neonatal rat dorsal root ganglion (DRG) neurons with ganglionic nnc in dissociated cultures. TGF beta 1 and TGF beta 2 each increased both neuronal survival and levels of the peptide neurotransmitter substance P (SP) expressed per neuron as well as per culture. TGF beta 1 was maximally effective at a concentration of 40 pM, whereas TGF beta 2 was about 10-fold less potent. Survival effects promoted by simultaneous treatment with both factors were not additive. TGF beta 1 also changed the morphology and distribution of DRG nnc which resulted in clustering of DRG neurons on top of the nnc. Cotreatment of the cultures with two different anti-nerve growth factor (NGF) antibodies eliminated the neurotrophic effects of TGF beta 1. However, treatment with TGF beta 1 did not alter NGF mRNA expression in the cultures nor did it change the amount of NGF in the medium. Further, TGF beta 1 greatly enhanced survival effects and SP stimulation promoted by exogenous NGF at concentrations up to 100 ng/ml. The neurotrophic effects of TGF beta 1 were significantly attenuated by decreasing the proportion of the ganglionic nnc, suggesting a role for these cells in mediating TGF beta 1 action on the neurons. It is hypothesized that the neurotrophic activity of TGF beta depended upon the presence of molecules immunologically related to NGF and that the effects of TGF beta were synergistic with NGF. These observations suggest that TGF beta may play a role in the differentiation and regeneration of DRG neurons in vivo.     

Cholinergic neuronotrophic factors: VI. Age-dependent requirements by chick embryo ciliary ganglionic neurons

During development, ciliary ganglionic neurons become postmitotic and extend neurites in apparent independence of the presence of their future intraocular innervation targets. After reaching their peripheral innervation territory, however, these neurons become target dependent and about half of them die. We have previously reported that chick embryo intraocular target tissues contain a ciliary neuronotrophic factor (CNTF), which can be extracted and partially purified in a soluble form and which ensures near-total survival of 8-day chick embryo ciliary ganglionic neurons in monolayer cultures. In this study we have dissociated and cultured ciliary ganglia from embryonic Day (ED) 5 through 14, and examined dependence and responsiveness of their neurons to exogenously added CNTF. Two cell classes (dark and bright) could be distinguished by phase microscopy and differentially counted in cell dissociates from ED7–14, but not in ED5–6 ones. Dark cell number per ganglion increased from 6000 to 78,000 over this developmental time period. In contrast, bright cells (putative neurons) declined from a maximum of about 10,000 to 6000, suggesting a correlation with the expected neuronal cell death in vivo. Dissociated cells from ED5–14 ganglia were seeded on a polyornithine substratum coated with neurite promoting factor, cultured for 24 hr with or without added CNTF, and numerically examined for survival and neuritic development. Cultures from ED7–14 ganglia showed two cell categories: (i) flat nonneuronal elements dramatically increased in number with ganglionic age (thereby correlating with the increasing number of dark cells in the dissociates) and (ii) large, bright cells (often displaying neurite outgrowth) decreased in number in parallel with bright cell number in the dissociate. The survival of these neuronal elements was strictly dependent on exogenously added CNTF between ED7 and 10, but became progressively independent with older ages. ED14 neurons (fully capable of surviving for 24 hr without added CNTF) continued to require CNTF for neurite extension, thus displaying retained sensitivity to this factor. Although the ED5–6 cultures contained well-recognizable flat cells, the dominant category comprised cells with variable morphology, practically all of which exhibited neurite-like processes. Both the survival and neurite extension of these cells, which we tentatively interpret as immature neurons were independent of the presence of added CNTF.     

Identification of a neuronal laminin receptor: an Mr 200K/120K integrin heterodimer that binds laminin in a divalent cation-dependent manner

Neuronal interactions with extracellular matrix (ECM) components are crucial for axon growth and guidance during development and nerve regeneration. Laminin (LN), a prominent ECM glycoprotein, promotes neuronal survival and axon growth. To identify neuronal receptors for LN, we looked for cell surface proteins on the neuronal cell line B50 that bind LN. An integrin alpha/beta 1 dimeric receptor was identified and purified using lectin and LN affinity chromatography. The purified integrin contains two subunits with Mrs of 200 K and 120 K that bind LN specifically in the presence, but not the absence, of divalent cations (Ca2+/Mg2+ or Ca2+/Mn2+). The Mr 120 K protein was identified as the rat integrin beta 1 subunit using two beta 1 subunit-specific antibodies, and was shown to form a noncovalent complex with the Mr 200K putative alpha subunit. Since neurons and neuronal cell lines express similar integrin beta 1-class heterodimers that mediate attachment and process outgrowth on LN, the Mr 200K/120K complex identified here is likely to be an important laminin receptor used by neurons. This integrin may also mediate binding to LN by many nonneuronal cell types.     

Stimulation of Cyclic GMP Production via a Nitrosyl Factor in Sensory Neuronal Cultures by Algesic or Inflammatory Agents

Abstract: Capsaicin stimulates cyclic GMP production via nitric oxide (NO) (or another nitrosyl factor) in dorsal root ganglion (DRG) neurons maintained in culture. The purpose of the present study was to characterize further capsaicin stimulation of cyclic GMP production in DRG cells maintained in culture, investigate other algesic and/or inflammatory agents for effects on cyclic GMP production, and examine cells responsible for NO production and cyclic GMP production. Capsaicin stimulation of cyclic GMP production in DRG cells was dose dependent, receptor mediated, and attenuated by hemoglobin. Prostaglandin E₂, substance P, and calcitonin gene-related peptide did not affect basal, capsaicin-stimulated, or bradykinin-stimulated cyclic GMP production. Other inflammatory or algesic agents, including serotonin, histamine, ATP, glutamate, aspartate, and NMDA, did not affect cyclic GMP production. Pretreatment of DRG cells with lipopolysaccharide increased basal cyclic GMP production in neuronal but not in nonneuronal cultures and facilitated stimulation of cyclic GMP production by l -arginine. Capsaicin pretreatment of neuronal DRG cultures, which destroys capsaicin-sensitive (small diameter) afferent neurons, attenuated capsaicin- and bradykinin-stimulated cyclic GMP production but did not affect basal or sodium nitroprusside-stimulated cyclic GMP production. These results indicate that capsaicin elicits production of a nitrosyl factor via capsaicin-sensitive (small diameter) neurons. Capsaicin evoked cyclic GMP production in nonneuronal DRG cultures in the presence but not in the absence of apposed neuronal DRG cultures. Overall, these findings suggest that specific exogenous (or endogenous) substances may stimulate production of a nitrosyl factor(s) by a subset of DRG neurons, and nitrosyl factors produced by these neurons may affect cyclic GMP production in neighboring neuronal or non-neuronal cells.