The specification of sympathetic neurotransmitter phenotype depends on gp130 cytokine receptor signaling

Sympathetic ganglia are composed of noradrenergic and cholinergic neurons. The differentiation of cholinergic sympathetic neurons is characterized by the expression of choline acetyltransferase (ChAT) and vasoactive intestinal peptide (VIP), induced in vitro by a subfamily of cytokines, including LIF, CNTF, GPA, OSM and cardiotrophin-1 (CT-1). To interfere with the function of these neuropoietic cytokines in vivo, antisense RNA for gp130, the common signal-transducing receptor subunit for neuropoietic cytokines, was expressed in chick sympathetic neurons, using retroviral vectors. A strong reduction in the number of VIP-expressing cells, but not of cells expressing ChAT or the adrenergic marker tyrosine hydroxylase (TH), was observed. These results reveal a physiological role of neuropoietic cytokines for the control of VIP expression during the development of cholinergic sympathetic neurons.

A transient role for ciliary neurotrophic factor in chick photoreceptor development

Previous studies suggest that ciliary neurotrophic factor (CNTF) may represent one of the extrinsic signals controlling the development of vertebrate retinal photoreceptors. In dissociated cultures from embryonic chick retina, exogenously applied CNTF has been shown to act on postmitotic rod precursor cells, resulting in an two- to fourfold increase in the number of cells acquiring an opsin-positive phenotype. We now demonstrate that the responsiveness of photoreceptor precursors to CNTF is confined to a brief phase between their final mitosis and their terminal differentiation owing to the temporally restricted expression of the CNTF receptor (CNTFR alpha). As shown immunocytochemically, CNTFR alpha expression in the presumptive photoreceptor layer of the chick retina starts at embryonic day 8 (E8) and is rapidly down-regulated a few days later prior to the differentiation of opsin-positive photoreceptors, both in vivo and in dissociated cultures from E8. We further show that the CNTF-dependent in vitro differentiation of rods is followed by a phase of photoreceptor-specific apoptotic cell death. The loss of differentiated rods during this apoptotic phase can be prevented by micromolar concentrations of retinol. Our results provide evidence that photoreceptor development depends on the sequential action of different extrinsic signals. The time course of CNTFR alpha expression and the in vitro effects suggest that CNTF or a related molecule is required during early stages of rod differentiation, while differentiated rods depend on additional protective factors for survival.

Differential regulation of ciliary neurotrophic factor receptor-alpha expression in all major neuronal cell classes during development of the chick retina

Ciliary neurotrophic factor (CNTF) exerts a multiplicity of effects on a broad spectrum of target cells, including retinal neurons. To investigate how this functional complexity relates to the regulation of CNTF receptor alpha (CNTFR alpha) expression, we have studied the developmental expression of the receptor protein in chick retina by using immunocytochemistry. During the course of development, the receptor is expressed in all retinal layers, but three levels of specificity can be observed. First, the expression is regulated temporally with immunoreactivity observed in ganglion cells (embryonic day 8 [E8] to adult), photoreceptor precursors (E8-E12), amacrine cells (E10 to adult), bipolar cells (E12-E18), differentiated rods (E18 to adult), and horizontal cells (adult). Second, expression is restricted to distinct subpopulations of principal retinal neurons: preferentially, large ganglion cells; subpopulations of amacrine cells, including a particular type of cholinergic neuron; a distinctly located type of bipolar cell; and rod photoreceptors. Third, expression exhibits subcellular restriction: it is confined largely to dendrites in mature amacrine cells and is restricted entirely to outer segments in mature rods. These data correlate with CNTF effects on the survival of ganglion cells and mature photoreceptors, the in vitro differentiation of photoreceptor precursors and cholinergic amacrine cells, and the number of bipolar cells in culture described here or in previous studies. Thus, our results demonstrate an exceptional degree of complexity with respect to the regulation of neuronal CNTFR alpha expression in a defined model system. This suggests that the same signaling pathway is used to mediate a variety of regulatory influences, depending on the developmental stage and cell type.

Mechanisms of insulin-like growth factor regulation of programmed cell death of developing avian motoneurons

During development of the avian neuromuscular system, lumbar spinal motoneurons (MNs) innervate their muscle targets in the hindlimb coincident with the onset and progression of MN programmed cell death (PCD). Paralysis (activity blockade) of embryos during this period rescues large numbers of MNs from PCD. Because activity blockade also results in enhanced axonal branching and increased numbers of neuromuscular synapses, it has been postulated that following activity blockade, increased numbers of MNs can gain access to muscle-derived trophic agents that prevent PCD. An assumption of the access hypothesis of MN PCD is the presence of an activity-dependent, muscle-derived sprouting or branching agent. Several previous studies of sprouting in the rodent neuromuscular system indicate that insulin-like growth factors (IGFs) are candidates for such a sprouting factor. Accordingly, in the present study we have begun to test whether the IGFs may play a similar role in the developing avian neuromuscular system. Evidence in support of this idea includes the following: (a) IGFs promote MN survival in vivo but not in vitro; (b) neutralizing antibodies against IGFs reduce MN survival in vivo; (c) both in vitro and in vivo, IGFs increase neurite growth, branching, and synapse formation; (d) activity blockade increases the expression of IGF-1 and IGF-2 mRNA in skeletal muscles in vivo; (e) in vivo treatment of paralyzed embryos with IGF binding proteins (IGF-BPs) that interfere with the actions of endogenous IGFs reduce MN survival, axon branching, and synapse formation; (f) treatment of control embryos in vivo with IGF-BPs also reduces synapse formation; and (g) treatment with IGF-1 prior to the major period of cell death (i.e., on embryonic day 6) increases subsequent synapse formation and MN survival and potentiates the survival-promoting actions of brain-derived neurotrophic factor (BDNF) and glial cell line-derived neurotrophic factor (GDNF) administered during the subsequent 4- to 5-day period of PCD. Collectively, these data provide new evidence consistent with the role of the IGFs as activity-dependent, muscle-derived agents that play a role in regulating MN survival in the avian embryo.

NGF-mediated survival depends on p21ras in chick sympathetic neurons from the superior cervical but not from lumbosacral ganglia

In rat embryonic sympathetic neurons from the superior cervical ganglia (SCG) NGF-mediated survival depends on the activation of the trkA receptor tyrosine kinase and on the activity of the intracellular plasmamembrane-anchored small G-protein p21ras. In contrast, chick sympathetic neurons derived from the more caudally located lumbosacral chain ganglia (LSCG) do not respond to activated p21ras (G12V-Ha-ras mutant). In these neurons endogenous p21ras and its downstream effector MAP kinase are activated but are not essential for NGF-dependent survival. Here we show that also in chick sympathetic neurons of the SCG permanently activated p21ras protein does promote neuron survival. Consistently, their NGF-mediated survival is sensitive to Fab fragments blocking endogenous p21ras activity. These results suggest that sympathetic neurons derived from sympathoenteric (SCG) and sympathoadrenal (LSCG) lineages differ in their requirement for p21ras in the NGF-mediated survival pathways.

Glycine receptors in cultured chick sympathetic neurons are excitatory and trigger neurotransmitter release

1. Total RNA isolated from embryonic chick paravertebral sympathetic ganglia was used in a reverse transcription-polymerase chain reaction (RT-PCR) assay with a pair of degenerate oligonucleotide primers deduced from conserved regions of mammalian glycine receptor alpha-subunits. Three classes of cDNA were identified which encode portions of the chicken homologues of the mammalian glycine receptor alpha 1, alpha 2 and alpha 3 subunits. 2. The presence of functional glycine receptors was investigated in the whole-cell configuration of the patch-clamp technique in neurons dissociated from the ganglia and kept in culture for 7-8 days. In cells voltage clamped to -70 mV, glycine consistently induced inward currents in a concentration-dependent manner and elicited half-maximal peak current amplitudes at 43 microM. 3. The steady-state current-voltage relation for glycine-induced currents was linear between +80 and -60 mV, but showed outward rectification at more hyperpolarized potentials. Reversal potentials of these currents shifted with changes in intracellular chloride concentrations and matched the calculated Nernst potentials for chloride. 4. beta-Alanine and taurine were significantly less potent than glycine in triggering inward currents, with half-maximal responses at 79 and 86 microM, respectively. At maximally active concentrations, beta-alanine-evoked currents were identical in amplitude to those induced by glycine. Taurine-evoked currents, in contrast, never reached the same amplitude as glycine-induced currents. 5. The classical glycine receptor antagonist strychnine reversibly reduced glycine-induced currents, with half-maximal inhibition occurring at 62 nM. Two more recently characterized glycine receptor antagonists, isonipecotic acid (half-maximal inhibition at 2 mM) and 7-trifluoromethyl-4-hydroxyquinoline-3-carboxylic acid (half-maximal inhibition at 67 microM), also blocked glycine-evoked currents in a reversible manner. The chloride channel blocker picrotoxin reduced glycine-evoked currents, with half-maximal effects at 348 microM. Inhibition by the glycine receptor channel blocker cyanotriphenylborate was half-maximal at 4 microM. 6. Apart from evoking inward currents, glycine occasionally triggered short (< 100 ms) spike-like currents which were abolished by hexamethonium and thus reflected synaptic release of endogenous acetylcholine. In addition, glycine caused Ca(2+)-dependent and tetrodotoxin-sensitive tritium overflow from neurons previously labelled with [3H]noradrenaline. This stimulatory action of glycine was reduced in the presence of strychnine and after treatment with the chloride uptake inhibitor furosemide (frusemide). 7. In 65% of neurons loaded with the Ca2+ indicator fura-2 acetoxymethyl ester, glycine increased the ratio of the fluorescence signal obtained with excitation wavelengths of 340 and 380 nm, respectively, which indicates a rise in intracellular Ca2+ concentration. 8. The results show that sympathetic neurons contain transcripts for different glycine receptor alpha-subunits and carry functional heteromeric glycine receptors which depolarize the majority of neurons to trigger transmitter release.

The developmental expression of choline acetyltransferase (ChAT) and the neuropeptide VIP in chick sympathetic neurons: evidence for different regulatory events in cholinergic differentiation

Cholinergic properties in chick sympathetic neurons are detectable early during development of paravertebral ganglia and mature after target contact. The cholinergic marker choline acetyltransferase (ChAT) is first detectable at embryonic day 6 and its expression partly overlaps with that of the noradrenergic marker tyrosine hydroxylase (TH). At late embryonic stages, when sympathetic neurons have established target contact, ganglia consist of two major neuronal populations, TH-positive noradrenergic neurons and cholinergic neurons that at this stage express vasoactive intestinal peptide (VIP) in addition to ChAT. The maturation of sympathetic neurons is paralleled by changes in their response to the neurokine ciliary neurotrophic factor (CNTF). These findings suggest that expression of neurotransmitter properties is controlled differentially before and during target innervation.

Onset of CNTFRalpha expression and signal transduction during neurogenesis in chick sensory dorsal root ganglia

The expression of ciliary neurotrophic factor receptor alpha (CNTFRalpha) was investigated in the developing chick dorsal root ganglion (DRG) using affinity-purified anti-CNTFRalpha antibodies. At thoracic levels, CNTFRalpha-immunoreactivity (CNTFRalpha-IR) was first observed at stage 19 (E3) in cells with neuronal morphology. CNTFRalpha-IR is restricted to the neuronal lineage in the DRG throughout development. CNTFRalpha expression precedes that of neuron-specific beta tubulin, Hu antigen, and Q211 antigen, which are markers expressed in developing sensory neurons. [3H]Thymidine-labeling studies showed the onset of CNTFRalpha expression during terminal mitosis of sensory neuron precursors, making CNTFRalpha the earliest known neuronal marker in the DRG. CNTFRalpha-mediated signal transduction was demonstrated in E7 and E11 DRG neuron cultures by CNTF-induced STAT3 phosphorylation. Although low ligand concentrations (5 pM) elicit STAT3 phosphorylation in E7 and E11 DRG neurons, a survival response is only observed in neurons from E11 DRG. This implicates a complex readout mechanism downstream of STAT3 phosphorylation leading to different cellular responses that depend on the age of the DRG neuron. These results argue against a role of CNTFRalpha ligands in the control of early neuron survival but are compatible with other functions in neurogenesis and sensory neuron development.

TrkA expression levels of sympathetic neurons correlate with NGF-dependent survival during development and after treatment with retinoic acid

Sympathetic neurons depend on the classical neurotrophin nerve growth factor (NGF) for survival by the time they innervate their targets, but not before. The acquisition of NGF responsiveness is thought to be controlled by environmental cues in sympathetic neurons. We have investigated the expression of the signal transducing NGF receptor trkA on mRNA and protein level during development of chick sympathetic neurons obtained from lumbosacral, paravertebral chain ganglia between embryonic days (E) 6.5 and 10. We demonstrate that trkA mRNA levels increase between E6.5 and E10, whereas the levels of trkC and p75 do not change. We also observed a similar increase in trkA protein during this time period. This increase correlates with the increase in NGF-dependent survival of sympathetic neurons from the corresponding stages in vitro. To define the correlation between trkA expression and NGF-mediated survival in more detail, trkA expression was adjusted to different levels by treatment with increasing concentrations of retinoic acid. We observed that small changes of trkA mRNA expression levels, below one order of magnitude, are decisive for the ability of immature sympathetic neurons to survive in the presence of NGF. A small and transient increase in trkA mRNA expression was also elicited in vivo by application of retinoids. These data provide evidence that sympathetic neurons upregulate the NGF receptor trkA and in this way acquire NGF-dependency.

Insulin-like growth factor-I stimulates neurogenesis in chick retina by regulating expression of the alpha 6 integrin subunit

Insulin-like growth factor I (IGF-I) strongly stimulates the generation of differentiated neurons in cultures of neuroepithelial cells of the embryonic chick neural retina in the presence of a laminin-1 tissue culture substrate. Treatment of cultured neuroepithelial cells with IGF-I rapidly up-regulated the mRNA coding for the alpha 6 integrin subunit whereas specific reduction of alpha 6 subunit levels by treatment with an alpha 6 integrin antisense oligonucleotide resulted in reduced neuronal differentiation in vitro. Although IGF-I immunoreactivity is seen throughout the neural retina, expression of IGF-I mRNA is confined to the pigment epithelium during the period of neurogenesis in vivo. Neutralization of the endogenous IGF-I with a blocking antibody down-regulated levels of alpha 6 integrin mRNA and reduced the production of differentiated retinal neurons in vivo. These data indicate a role for IGF-I in the generation of retinal neurons mediated by the interaction of laminin with its alpha 6 integrin subunit-containing receptor.

The development of the noradrenergic transmitter phenotype in postganglionic sympathetic neurons

Here we review recent data on molecular aspects of the differentiation of the noradrenergic neurotransmitter phenotype in postganglionic sympathetic neurons during avian and mammalian embryogenesis. By experimental manipulation of the chick embryo, it has been shown that neural tube and notochord are important for noradrenergic differentiation which occurs when migrating neural crest cells, the precursors of sympathetic ganglion cells, reach the dorsal aorta. Bone morphogenetic proteins expressed in the dorsal aorta before and during the time of noradrenergic differentiation are likely candidates for growth factors involved in induction of noradrenergic differentiation, in vivo. To analyze noradrenergic differentiation, enzymes of the noradrenaline bio-synthesis pathway and catecholamine stores have been used as differentiation markers. The molecules involved in neurotransmitter release which are as important for a functional noradrenergic neuron as those required for transmitter synthesis and storage are only recently being studied in this context. For a comprehensive view of the embryonic development of the noradrenergic neurotransmitter phenotype, it will be necessary to understand how the systems for synthesis, storage and release of noradrenaline are assembled during neuronal differentiation.

Involvement of bone morphogenetic protein-4 and bone morphogenetic protein-7 in the differentiation of the adrenergic phenotype in developing sympathetic neurons

The neurotransmitter phenotype of sympathetic neurons is specified by interactions with the surrounding embryonic tissues. Adrenergic differentiation is elicited early during development in the vicinity of notochord and dorsal aorta and the importance of axial midline tissues for adrenergic differentiation has been well documented. We now provide evidence that bone morphogenetic proteins, BMP-4 and BMP-7 are signals produced by the dorsal aorta that direct sympathetic neuron differentiation. BMP-4 and BMP-7 are expressed in the dorsal aorta at critical times during sympathetic neuron differentiation and have the ability to enhance the formation of adrenergic sympathetic neurons both in cultures of neural crest cells and when ectopically expressed in the developing embryo.

Extrinsic signals in the developing nervous system: the role of neurokines during neurogenesis

Vertebrate neurogenesis involves many distinct differentiation stages that are regulated by extrinsic signals. Survival and differentiation effects on cultured neurons of several lineages are elicited by members of the neurokine family of growth factors, ciliary neurotrophic factor (CNTF) and the related avian factor, growth promoting activity (GPA). The selective actions of these factors are mediated through the activation of heteromeric receptor complexes and depend on the presence of the ligand-binding receptor subunits CNTFR alpha and GPAR alpha. The in vivo localization of CNTFR alpha and GPAR alpha is consistent with the previously assigned biological functions but also suggest novel functions for these receptors and their ligands during neurogenesis.

Analysis of function and expression of the chick GPA receptor (GPAR alpha) suggests multiple roles in neuronal development

Growth promoting activity (GPA) is a chick growth factor with low homology to mammalian ciliary neurotrophic factor (CNTF) (47% sequence identity with rat CNTF) but displays similar biological effects on neuronal development. We have isolated a chick cDNA coding for GPA receptor (GPAR alpha), a GPI-anchored protein that is 70% identical to hCNTFR alpha. Functional analysis revealed that GPAR alpha mediates several biological effects of both GPA and CNTF. Soluble GPAR alpha supports GPA- and CNTF-dependent survival of human TF-1 cells. In sympathetic neurons, GPAR alpha mediates effects of both GPA and CNTF on the expression of vasoactive intestinal peptide (VIP) as shown by the inhibition of GPA- and CNTF-mediated VIP induction upon GPAR alpha antisense RNA expression. These results demonstrate that GPAR alpha is able to mediate effects of two neurokines that are only distantly related. GPAR alpha mRNA expression is largely restricted to the nervous system and was detected in all neurons that have been shown to respond to GPA or CNTF by increased survival or differentiation, i.e. ciliary, sympathetic, sensory dorsal root, motoneurons, retinal ganglion cells and amacrine cells. Interestingly, GPAR alpha mRNA was additionally found in neuronal populations and at developmental periods not known to be influenced by GPA or CNTF, suggesting novel functions for GPAR alpha and its ligands during neurogenesis and neuron differentiation.

The expression of tyrosine hydroxylase and the transcription factors cPhox-2 and Cash-1: evidence for distinct inductive steps in the differentiation of chick sympathetic precursor cells

The adrenergic differentiation of sympathetic neurons is controlled by complex interactions with the embryonic environment. To provide a basis for the experimental analysis of these interactions, the expression of the adrenergic marker enzyme tyrosine hydroxylase (TH) was analyzed by immunohistochemistry and in situ hybridization in sympathetic ganglia and the adrenal medulla of chick embryos. In parallel, the developmental expression of the transcription factors cPhox-2 and Cash-1 was analyzed by in situ hybridization. TH protein was first detectable during the third day of development (stage 19) in cells of the primary sympathetic strands. A few hours earlier (stage 18), TH mRNA could be found by in situ hybridization. At the very same time and location, mRNA for the transcription factor cPhox-2 was first observed. In contrast, mRNA for the transcription factor Cash-1 was detected much earlier, at stage 15, dorsal to the aorta where the primary sympathetic ganglia form. High TH mRNA levels are maintained during later embryonic development (stage 35) in both sympathetic ganglia and adrenal chromaffin cells. In contrast, cPhox-2 and Cash-1 mRNA are selectively reduced in chromaffin cells and sympathetic ganglia, respectively. The results show that TH and cPhox-2 are early markers expressed in sympathetic ganglia. Their coordinated expression points towards an inductive event possibly occurring close to the aorta and leading to the expression of an adrenergic phenotype. Cash-1 is detected significantly earlier, suggesting that its expression is induced by a separate event.

Retinoic acid-mediated increase in TrkA expression is sufficient to elicit NGF-dependent survival of sympathetic neurons

Sympathetic neurons depend on the classical neurotrophin NGF for survival by the time they innervate their targets, but the mechanisms controlling the onset of NGF responsiveness in developing neuroblasts have not been defined. Immature chick sympathetic neurons are unresponsive to NGF, but express low mRNA levels of the high-affinity NGF receptor trkA. Treatment with retinoic acid (RA) leads to increased levels of both trkA mRNA and protein, a response mediated through retinoic acid receptor alpha (RAR alpha). Ectopic expression of trkA in these cells results in the ability to survive with NGF, suggesting that RA-induced trkA expression is sufficient to elicit NGF-dependent survival. Our data establish a mechanism controlling NGF responsiveness and implicate a function for RA at defined late stages of neuron development.

Evidence for an important role of IGF-I and IGF-II for the early development of chick sympathetic neurons

The ability of immature neurons from chick lumbosacral sympathetic ganglia to proliferate in vitro was used to identify factors that affect neurogenesis. Under serum-free culture conditions, insulin-like growth factor I (IGF-I), IGF-II, or insulin caused an increase in the proportion of cells that incorporated [3H]thymidine. In addition, IGFs also stimulated neurite outgrowth from these immature sympathetic neurons. IGF-I and IGF-II mRNA was found to be expressed in E7 sympathetic ganglia during the period of neurogenesis. IGF-I was detectable in fibroblasts, whereas IGF-II mRNA was expressed by neurons, glia, and fibroblasts. Elimination of endogenous IGFs by neutralizing antibodies resulted in a reduction of neuron proliferation and neuron number, whereas elevation of IGF levels by treatment with IGF-I increased sympathetic neuron proliferation in vivo. These findings suggest an important role of IGFs for the development of sympathetic neurons and imply a general role of IGFs in the control of neurogenesis and neurite outgrowth.

GPA and CNTF produce similar effects in sympathetic neurones but differ in receptor binding

The effects of growth promoting activity (GPA) on sympathetic neurone development were investigated in vitro and compared with the effects of ciliary neurotrophic factor (CNTF). GPA interfered with sympathetic neurone proliferation and induced the expression of vasoactive intestinal peptide (VIP) in neurones from 7-day-old (E7) chick embryos. The biological effects observed with saturating levels of GPA are indistinguishable from the effects of CNTF. The effects on VIP expression suggest that GPA may be involved in the specification of sympathetic neurone phenotypes. Whereas half maximal effects are achieved at lower concentrations of GPA than CNTF, GPA competes less efficiently than CNTF for the binding of 125I-labelled CNTF. This suggests similar, but not identical interactions of CNTF and GPA with receptors on chick sympathetic neurones.

Synthesis of nerve growth factor mRNA in cultures of developing mouse whisker pad, a peripheral target tissue of sensory trigeminal neurons

The developmental increase in the level of NGF mRNA in mouse maxillary process/whisker pad is paralleled in vivo by the biochemical and morphological differentiation of whisker pad epidermis, i.e., changes in the keratin expression pattern and the appearance of hair follicles. In cultures of maxillary processes, however, depending on the age of explanted tissue, the increase in NGF mRNA levels either precedes or follows the appearance of epithelial differentiation markers. In addition, we found that prevention of epithelial differentiation by retinoic acid did not affect the increase in NGF mRNA levels. Only in explants from E11.5 embryos was the timing of NGF mRNA production comparable to that of the in vivo situation, whereas at earlier stages (E10/10.5) NGF mRNA levels increased slowly but never reached in vivo levels, even after extended culture periods. However, the amount of NGF mRNA in E10/10.5 maxillary processes was strongly increased in the presence of medium conditioned by E11.5 explants. This effect was not mimicked by the factors IL-1 beta and TGF-beta 1 known to induce NGF mRNA in other systems. It is concluded that the developmental increase in NGF mRNA levels in developing mouse whisker pad is not linked to epidermal differentiation. Interestingly, it is strongly stimulated by a soluble factor(s) produced within the tissue.