The role of extracellular signals in the differentiation of cholinergic neurons from the CNS and PNS in culture

Rat skeletal muscle cells release in culture a macromolecule which stimulates by 25-100 fold the development of choline acetyltransferase (CAT) in cultures of new-born rat sympathetic neurons. This "cholinergic factor" impaired the development of three norepinephrine synthesizing enzymes and of acetylcholinesterase (AChE) in these cultures. The 16S form of AChE failed to develop in cultures grown with the factor, but amounted to 30-40% in 3-week old cultures grown in its absence. Using the development of CAT activity in sympathetic neuron cultures as an assay, the cholinergic factor has been partially purified in 6 steps, and its hydrodynamic parameters determined. The effects of this factor on sympathetic neurotransmitter choice were qualitatively reproduced by 1-10 mM Na butyrate. The cholinergic factor increased CAT activity and decreased AChE in neuron cultures from new-born rat nodose ganglia. The factor also stimulated CAT activity in rat embryo (E14) spinal cord cultures, but stimulated the development of AChE in these cultures.     

Regulation of enzymes responsible for neurotransmitter synthesis and degradation in cultured rat sympathetic neurons. II. Regulation of 16 S acetylcholinesterase by conditioned medium

The molecular forms of acetylcholinesterase (AcChE) have been studied in primary cultures of newborn rat sympathetic neurons grown either in the absence (CM^? cultures) or in the presence (CM⁺ cultures) of muscle conditioned medium. The cultures were treated with a mitotic poison to eliminate non-neuronal cells. CAT activity increased with time in culture 4- to 20-fold faster in CM⁺ than in CM^? cultures. In agreement with previous experiments (J. P. Swerts, A. Le Van Thaï, A. Vigny, and M. J. Weber, 1983, Develop. Biol.100, 1–11), AcChE activity developed at a 3-fold lower rate in CM⁺ than in CM^? cultures. This deficit in AcChE activity in CM⁺ cultures resulted from a deficit in the number of enzyme molecules immunoprecipitable with an antiserum raised against rat brain AcChE. In both types of cultures, AcChE forms were separated by sucrose gradient sedimentation into three main peaks corresponding to the 16 S and 10 S forms and a mixture of the 6.5 and 4 S forms. In 3-day-old CM⁺ and CM^? cultures, the 16 S form represented 2% of the total activity. After 12–26 days, the percentage of 16 S form raised to 15–30% in CM^? cultures, but remained lower than 5% in CM⁺ cultures. This difference was also observed when AcChE molecular forms were analyzed in the presence of protease inhibitors. A similar result was obtained by comparing cultures grown with and without a macromolecular factor partially purified from conditioned medium. These results suggest that an inverse relationship exists between the presence of 16 S AcChE and the presence of cholinergic synapses in these cultures.     

Regulation of enzymes responsible for neurotransmitter synthesis and degradation in cultured rat sympathetic neurons. I. Effects of muscle-conditioned medium

The enzymatic machinery for neurotransmitter synthesis and breakdown have been compared in sister cultures of newborn rat sympathetic neurons grown for 12-28 days either in the presence (CM+ cultures) or in the absence (CM- cultures) of a culture medium conditioned by rat skeletal muscle cells. Neuron numbers, total protein, and lactate dehydrogenase activities were identical in CM+ and CM- cultures. Choline acetyltransferase activity was 27- to 100-fold higher in homogenates of CM+ than CM- cultures, whereas acetylcholinesterase activity was 2.5-fold lower. The activities of tyrosine hydroxylase (TOH), DOPA decarboxylase, and dopamine beta-hydroxylase were all about twofold lower in homogenates from CM+ cultures. All these effects were also observed in homogenates of sympathetic neuron cultures grown with and without a macromolecular factor partially purified from CM (Weber, J. (1981). Biol. Chem. 256, 3447-3453.). Experiments of mixing homogenates from CM+ and CM- cultures suggested that the differences in each of the enzyme activities did not result from differences in the concentrations of hypothetical reversible enzyme activators and/or inhibitors. In addition, the deficit in TOH activity in CM+ cultures resulted from a decrease in the enzymatic Vmax with no significant variation in the apparent Km's for the substrate and the cofactor. An identical decrease in the Vmax was observed if TOH was assayed under phosphorylating or nonphosphorylating conditions, suggesting that this decrease did not result from differences in the state of enzyme phosphorylation. Immunoprecipitation curves of TOH activity by an anti-TOH antiserum were parallel when performed on homogenates from CM+ and CM- cultures, suggesting a difference in the number of enzyme molecules without detectable alteration of their kinetic properties.     

Regulation of neurotransmitter synthesis: from neuron to gene.

We are interested in the molecular mechanisms of the regulation of neurotransmitter related gene expression by neurotrophic factors and neuronal activity. Previous work has shown that conditioned medium of muscle cells induces choline acetyltransferase (CAT) activity and represses tyrosine hydroxylase, dopamine-beta-hydroxylase and aromatic L-amino acid decarboxylase (AADC) activities in cultured sympathetic neurons. Here, we show that a new muscle-derived cell line secretes two factors which induce CAT activity in spinal cord cultures; one of those is related to LIF, a CAT inducing factor for sympathetic neurons. Preliminary data are presented on the structure of the human AADC and CAT genes. Putative promoter regions have been coupled to reporter genes; transient transfection experiments will allow us to determine the promoter elements responsible for the regulation by neurotrophic factors. We also summarize the distribution of AADC-immunoreactive cells in rat and cat brain, which will be used as a reference for the study of the specificity of expression of AADC promoter in transgenic mice.     

Non-neuronal cell conditioned medium stimulates peptidergic expression in sympathetic and sensory neurons in vitro

Regulation of peptide neurotransmitter metabolism was examined in dissociated cell cultures of neonatal rat sympathetic and sensory ganglia. Previous studies have shown that pineal gland conditioned medium (PCM) influences substance P (SP) and somatostatin (SS) metabolism in sympathetic neurons in vitro. The present study examines mechanisms mediating these effects, and compares the actions of PCM on sympathetic and sensory neurons. PCM treatment increased SP levels in a dose-dependent manner without altering SS content of sympathetic neurons cultured in the presence of ganglion non-neuronal cells. Conversely, treatment of pure sympathetic neuron cultures resulted in a dose-dependent increase in SS, while SP was virtually undetectable at all doses. By contrast, dorsal root ganglion, trigeminal ganglion, and nondose ganglion sensory neurons contained SP both in the presence and absence of ganglion non-neuronal cells. Moreover, in each of these neuronal populations treatment with PCM increased SP levels both in the presence and in the absence of ganglion non-neuronal cells. These observations suggest that ganglion non-neuronal cells are necessary for sympathetic but not sensory neuron expression of SP. Moreover, PCM apparently stimulates SP in neurons which already contain the peptide, but the factor cannot foster de novo expression of the phenotype. PCM also influenced other transmitter traits in sympathetic neurons, suggesting linkage between mechanisms regulating peptides and other transmitters. In cultures containing both sympathetic neurons and non-neuronal cells, PCM treatment increased cholineacetyltransferase (CHAC) activity as well as SP, and decreased tyrosine hydroxylase (TOH) activity. By contrast, PCM treatment of pure sympathetic neuron cultures led to parallel increases in SS and TOH activity with negligible levels of SP and CHAC. These observations suggest that in sympathetic neurons, SS may be linked with noradrenergic expression, while SP is associated with cholinergic development, although more data are required to confirm this relationship. Moreover, there may be a reciprocal relationship between SP and SS expression by sympathetic neurons analogous to previous observations regarding cholinergic-noradrenergic expression (P. H. Patterson and L. L. Y. Chun, Proc. Natl. Acad. Sci. USA 71, 3607-3610, 1974; Dev. Biol. 56, 263-280, 1977). Consequently, neurotransmitter phenotypic expression is a complex process in which the environment regulates a balance among multiple transmitters.     

The induction of acetylcholine synthesis in primary cultures of dissociated rat sympathetic neurons : II. Developmental aspects

Dissociated sympathetic neurons from the neonatal rat, grown in cell culture in the virtual absence of other cell types, can develop many of the properties expected of differentiated adrenergic neurons including the ability to synthesize and accumulate catecholamines (CA)². However, in the presence of high concentrations of appropriately conditioned medium (CM), the cultures develop the ability to synthesize and accumulate acetylcholine (ACh); correspondingly, their ability to synthesize CA decreases. In this paper several developmental aspects of the CM effect are described. The time course of development of cultures grown with or without CM was followed using synthesis and accumulation of [³H]CA from [³H]tyrosine and production of [³H]ACh from [³H]choline as assays for adrenergic and cholinergic differentiation. The ability to produce CA or ACh developed along parallel time courses in the two sets of cultures, rising primarily during the second week in vitro and reaching a plateau during the fourth week. When CM was used as a cholinergic developmental signal, the sympathetic neurons showed a decreasing response to addition of CM as they matured adrenergically; addition of CM during the third or fourth 10 days in vitro was not as effective in inducing ACh production as addition during the first or second 10 days. Similarly, removal of CM at various times from cultures previously grown in CM showed that the cholinergic induction caused by CM was not easily reversible in older cultures. Thus, as with the adrenergic decision, the cholinergic decision becomes less reversible as the phenotype becomes fully expressed.     

Development of the cholinergic neurotransmitter phenotype in postganglionic sympathetic neurons

Sympathetic ganglia are composed of noradrenergic neurons and cholinergic neurons that differ in the expression of neurotransmitter-synthesizing enzymes, neurotransmitter transporters and neuropeptides. The analysis of the cholinergic differentiation during development revealed important principles involved in the generation of neuronal diversity, in particular the importance of signals from the innervated target. Some peripheral targets, such as the sweat glands in the mammalian footpads, are purely cholinergically innervated in the adult, whereas skeletal muscle arteries receive both noradrenergic and cholinergic innervation. For sympathetic neurons innervating sweat glands there is convincing evidence that these neurons are initially noradrenergic and that the interaction of innervating fibers and target tissue induces a shift in the neurotransmitter phenotype from noradrenergic to cholinergic. In addition to this target-dependent differentiation, an earlier expression of cholinergic characters was observed in sympathetic ganglia that occurs before target contact. These data raise the possibility that different subpopulations of cholinergic sympathetic neurons, innervating distinct peripheral targets, may develop along distinct schedules. In vitro studies suggest that growth factors of the family of neuropoietic cytokines are involved in the specification of the cholinergic sympathetic phenotype. Recent in vivo studies that interfered with cytokine receptor expression in developing avian sympathetic ganglia indicate that only the late, target-dependent differentiation depends on cytokine signaling. The signals involved in the early, target-independent expression of cholinergic properties remain to be determined, as well as the identity of the target-derived cytokine. Thus, cholinergic sympathetic differentiation seems to be more complex than expected, involving either both target-independent and target-dependent control or only target-induced differentiation, according to the specific neuronal subpopulation and target.     

Neonatal treatment with nerve growth factor antiserum eliminates cholinergic sympathetic innervation of rat sweat glands

Most mammalian sympathetic neurons are noradrenergic, and their dependence upon nerve growth factor (NGF) for survival during development is well established. A minor population of sympathetic neurons, including those that innervate sweat glands, is cholinergic. To determine whether cholinergic sympathetic neurons, like their noradrenergic counterparts, require NGF during development, neonatal rats were treated with NGF-antiserum and 3 weeks later their sweat glands were examined for the presence of innervation. Acetylcholinesterase (AChE) staining and vasoactive intestinal polypeptide-like immunoreactivity (VIP-IR) which mark the mature sweat gland innervation were absent from the sweat glands of the anti-NGF treated animals. Further, when the glands were examined with the electron microscope, no axons or nerve terminals were evident. These observations indicate that the elaboration of the sweat gland plexus is NGF-dependent and suggest that at least one population of cholinergic sympathetic neurons in the rat requires NGF for survival. Our findings are consistent with the idea that during development NGF is a required trophic factor not only for noradrenergic sympathetic but also for cholinergic sympathetic neurons.     

Target determination of neurotransmitter phenotype in sympathetic neurons

While the majority of sympathetic neurons are noradrenergic, a minority population are cholinergic. At least one population of cholinergic sympathetic neurons arises during development by a target-dependent conversion from an initial noradrenergic phenotype. Evidence for retrograde specification has been obtained from transplantation studies in which sympathetic neurons that normally express a noradrenergic phenotype throughout life were induced to innervate sweat glands, a target normally innervated by cholinergic sympathetic neurons. This was accomplished by transplanting footpad skin containing sweat gland primordia from early postnatal donor rats to the hairy skin region of host rats. The sympathetic neurons innervating the novel target decreased their expression of noradrenergif traints and developed choline acetyltransferase (ChAT) activity. In addition, many sweat gland-associated fibers acquired acetylcholinesterase (AChE) staining and VIP immunoreactivity. These studies indicated that sympathetic neurons in vivo alter their neurotransmitter phenotype in response to novel envronmental signals and that sweat glands play a critical role in the cholinergic and peptidergic differentiation of the sympathetic neurons that innervate them. The sweat gland-derived cholinergic differentiation factor is distinct from leukemia inhibitory factor and ciliary neurotrophic factor, two well-characterized cytokines that alter the neurotransmitter properties of cultured sympathetic neurons in a similar fashion. Recent studies indicate that anterograde signalling is also important for the establishment of functional synapses in this system. We have found that the production of cholinergic differentiation activity by sweat glands required sympathetic innervation, and the acquisition and maintenance of secretory competence by sweat glands depends upon functional cholinergic innervation. 1994 John Wiley & Sons, Inc.     

Regulation of cholinergic expression in cultured spinal cord neurons

Factors regulating development of cholinergic spinal neurons were examined in cultures of dissociated embryonic rat spinal cord. Levels of choline acetyltransferase (CAT) activity in freshly dissociated cells decreased rapidly, remained low for the first week in culture, and then increased. The decrease in enzyme activity was partially prevented by increased cell density or by treatment with spinal cord membranes. CAT activity was also stimulated by treatment with MANS, a molecule solubilized from spinal cord membranes. The effects of MANS were greatest in low-density cultures and in freshly plated cells, suggesting that the molecule may substitute for the effects of elevated density and cell-cell contact. CAT activity in ventral (motor neuron-enriched) spinal cord cultures was similarly regulated by elevated density or treatment with MANS, whereas enzyme activity was largely unchanged in mediodorsal (autonomic neuron-enriched) cultures under these conditions. These observations suggest that development of cholinergic motor neurons and autonomic neurons are not regulated by the same factors. Treatment of ventral spinal cord cultures with MANS did not increase the number of cholinergic neurons detected by immunocytochemistry with a monoclonal CAT antibody, suggesting that MANS did not increase motor neuron survival but rather stimulated levels of CAT activity per neuron. These observations indicate that development of motor neurons can be regulated by cell-cell contact and that the MANS factor may mediate the stimulatory effects of cell-cell contact on cholinergic expression.     

The expression of dopamine beta-hydroxylase, tyrosine hydroxylase, and Phox2 transcription factors in sympathetic neurons: evidence for common regulation during noradrenergic induction and diverging regulation later in development

During differentiation of sympathetic neurons in chick embryos, tyrosine hydroxylase (TH) and dopamine beta-hydroxylase (DBH) mRNAs become detectable during the same developmental period and are both induced by BMP 4. Later during sympathetic ganglion development, DBH is detectable in TH-positive and -negative cells. Moreover, BMPs reduce DBH mRNA in cultures of sympathetic neurons while leaving TH unaffected. The data provide evidence for a common regulation of TH and DBH early during sympathetic neuron differentiation and indicate that BMPs promote their initial expression but not the maintenance during later development. The time course of Phox2a and 2b expression suggests an evolutionary conserved role in noradrenergic induction. In addition, Phox2a, Phox2b, and c-ret may be involved in the differentiation of cholinergic sympathetic neurons.     

Cell interactions that determine sympathetic neuron transmitter phenotype and the neurokines that mediate them

The transmitter properties of both developing and mature sympathetic neurons are plastic and can be modulated by a number of environmental cues. Cell culture studies demonstrate that noradrenergic neurons can be induced to become cholinergic and that the expression of neuropeptides can be altered. Similar changes in transmitter phenotype occur in vivo. During development, noradrenergic neurons that innervate eccrine sweat glands acquire cholinergic and peptidergic function. This change is dependent upon interactions with the target tissue. Following injury of sympathetic neurons in developing and adult animals, striking alterations take place in peptide expression. Ciliary neurotrophic factor and cholinergic differentiation factor/leukemia inhibitory factor, members of a family that includes several hematopoeitic cytokines, induce cholinergic function and modulate neuropeptide expression in cultured sympathetic neurons. Studies in progress provide evidence that members of this new cytokine family influence the transmitter phenotype of sympathetic neurons not only in vitro but also in vivo. © 1993 John Wiley & Sons, Inc.     

Head and trunk neural crest in vitro: Autonomic neuron differentiation

Isolated cultures of premigratory neural crest cells were used to study the initial stages of autonomic neuron development. Autonomic neurons are phenotypically characterized on the basis of their neurotransmitter synthetic enzymes, dopamine β-hydroxylase (DBH) and choline acetyltransferase (CAT). DBH converts dopamine to norepinephrine in noradrenergic neurons while CAT synthesizes acetylcholine from choline in cholinergic neurons. Activities of both enzymes were detected in isolated cultures of trunk neural crest and head neural crest. DBH was detected at all culture ages examined (from 1 to 20 days) whereas CAT activity was first detected only after 5 days in vitro. While specific enzyme activity of DBH peaks on Day 6 and specific enzyme activity of CAT peaks on Day 10, absolute activity for both enzymes increases throughout the 20-day culture period. DBH and CAT develop in vitro without any spinal presynaptic input, without typical target tissue interactions (such as blood vascular elements or heart tissue), and without addition of conditioned medium factors.     

The neuropeptide VIP modulates the neurotransmitter phenotype of cultured chick sympathetic neurons.

The present report provides evidence for a novel function for the neuropeptide vasoactive intestinal peptide (VIP). We demonstrate that VIP increases the cholinergic and the noradrenergic properties of cultured chick sympathetic neurons without changing neuronal survival and metabolism. VIP induces a 10- to 15-fold increase in the activity of choline acetyltransferase and an approximately twofold increase in the activity of tyrosine hydroxylase. Forskolin, an activator of adenylate cyclase, mimics all the effects of VIP on these cells. In addition, the effects of forskolin and VIP at optimal concentrations are not additive. Furthermore, VIP induces a rapid increase in the intracellular cAMP levels. Thus VIP acts via a cAMP-dependent pathway to enhance the cholinergic and noradrenergic properties of cultured chick sympathetic neurons.     

Induction of cholinergic function in cultured sympathetic neurons by periosteal cells: cellular mechanisms.

Periosteum, the connective tissue surrounding bone, alters the transmitter properties of its sympathetic innervation during development in vivo and after transplantation. Initial noradrenergic properties are downregulated and the innervation acquires cholinergic and peptidergic properties. To elucidate the cellular mechanisms responsible, sympathetic neurons were cultured with primary periosteal cells or osteoblast cell lines. Both primary cells and an immature osteoblast cell line, MC3T3-E1, induced choline acetyltransferase (ChAT) activity. In contrast, lines representing marrow stromal cells or mature osteoblasts did not increase ChAT. Growth of periosteal cells with sympathetic neurons in transwell cultures that prevent direct contact between the neurons and periosteal cells or addition of periosteal cell-conditioned medium to neuron cultures induced ChAT, indicating that periosteal cells release a soluble cholinergic inducing factor. Antibodies against LIFRbeta, a receptor subunit shared by neuropoietic cytokines, prevented ChAT induction in periosteal cell/neuron cocultures, suggesting that a member of this family is responsible. ChAT activity was increased in neurons grown with periosteal cells or conditioned medium from mice lacking either leukemia inhibitory factor (LIF) or LIF and ciliary neurotrophic factor (CNTF). These results provide evidence that periosteal cells influence sympathetic neuron phenotype by releasing a soluble cholinergic factor that is neither LIF nor CNTF but signals via LIFRbeta.     

Structure and innervation of the pineal gland of the rabbit,Oryctolagus cuniculus (L.)

In the rabbit pineal gland two types of postganglionic nerve endings were found which are characterized by the presence of small dense-core vesicles or small clear vesicles. Pharmacological and cytochemical experiments showed then to be noradrenergic and cholinergic, respectively. Both types were often present in the same nerve bundle, occasionally in close opposition. Intrapineal neurons were only rarely observed. They showed cholinergic synapses on their perikaryon and dendrites as well as noradrenergic axo-dendritic close contacts. Bilateral extirpation of the superior cervical ganglia revealed the postganglionic sympathetic origin of the pineal noradrenergic nerve fibres. Moreover, it appeared that these ganglia are hardly, if at all, involved in the pathway of pineal cholinergic innervation. The results obtained from lesions of both facial nerves, taken together with the results reported in the literature, led to the conclusion that the postganglionic cholinergic nerve fibers in the pineal are of parasympathetic origin. A model for the sympathetic and parasympathetic pineal innervation is proposed.     

Source and target cell specificities of a conditioned medium factor that increases choline acetyltransferase activity in cultured spinal cord cells

A macromolecular factor(s) in muscle conditioned medium (CM), when applied to spinal cord (SC) cells in culture, causes large increases in the activity of choline acetyltransferase (CAT), the enzyme which synthesizes the neurotransmitter acetylcholine. We have found apparent specificity of both species and cell type for the production, release, or action of this CAT stimulation component (CSC). Rat and mouse muscle CMs contained CSC which was active in mouse SC cells; chick muscle CM did not. In addition to muscle CM, the CM from cell cultures of mouse heart, liver, and kidney contained CSC. However, CM from secondary cultures of liver cells contained little if any CSC. These apparent specificities were not due to differences in the protein content of either the cells providing CM or of the CM itself. There was also apparent specificity of response to CSC among cholinergic cells in culture. Cultures of cells from only two of four regions of the mouse central nervous system, and from one of five neuronal cell lines tested, had increased CAT activity after treatment with muscle CM. The response in NG108-15 neuroblastoma-glioma hybrid cells was further characterized, and was used to develop a more convenient and rapid assay for CSC.