Culture conditions affect the cholinergic development of an isolated subpopulation of chick mesencephalic neural crest cells

HoxB8 in noradrenergic specification and differentiation of the autonomic nervous system

Different prespecification of mesencephalic and trunk neural crest cells determines their response to environmental differentiation signals and contributes to the generation of different autonomic neuron subtypes, parasympathetic ciliary neurons in the head and trunk noradrenergic sympathetic neurons. The differentiation of ciliary and sympathetic neurons shares many features, including the initial BMP-induced expression of noradrenergic characteristics that is, however, subsequently lost in ciliary but maintained in sympathetic neurons. The molecular basis of specific prespecification and differentiation patterns has remained unclear. We show here that HoxB gene expression in trunk neural crest is maintained in sympathetic neurons. Ectopic expression of a single HoxB gene, HoxB8, in mesencephalic neural crest results in a strongly increased expression of sympathetic neuron characteristics like the transcription factor Hand2, tyrosine hydroxylase (TH) and dopamine-beta-hydroxylase (DBH) in ciliary neurons. Other subtype-specific properties like RGS4 and RCad are not induced. HoxB8 has only minor effects in postmitotic ciliary neurons and is unable to induce TH and DBH in the enteric nervous system. Thus, we conclude that HoxB8 acts by maintaining noradrenergic properties transiently expressed in ciliary neuron progenitors during normal development. HoxC8, HoxB9, HoxB1 and HoxD10 elicit either small and transient or no effects on noradrenergic differentiation, suggesting a selective effect of HoxB8. These results implicate that Hox genes contribute to the differential development of autonomic neuron precursors by maintaining noradrenergic properties in the trunk sympathetic neuron lineage.

Restricted response of mesencephalic neural crest to sympathetic differentiation signals in the trunk

Lineage diversification in the vertebrate neural crest may occur via instructive signals acting on pluripotent cells, and/or via early specification of subpopulations towards particular lineages. Mesencephalic neural crest cells normally form cholinergic parasympathetic neurons in the ciliary ganglion, while trunk neural crest cells normally form both catecholaminergic and cholinergic neurons in sympathetic ganglia. In contrast to trunk neural crest cells, mesencephalic neural crest cells apparently fail to express the catecholaminergic transcription factor dHAND in response to BMPs in the head environment. Here, we show that migrating quail mesencephalic neural crest cells grafted into the trunk of host chick embryos colonise the sympathetic ganglia. While many express dHAND and form tyrosine hydroxylase (TH)-positive catecholaminergic neurons, the proportion that expresses either dHAND or TH is significantly smaller than that of quail trunk neural crest cells under the same conditions. Furthermore, the proportion of quail mesencephalic neural crest cells that is TH+ in the sympathetic ganglia decreases with time, while the proportion of TH+ quail trunk neural crest-derived cells increases. Thus, a subset of mesencephalic neural crest cells fails to express dHAND or TH in the sympathetic ganglia, while a further subset initiates but fails to maintain TH expression. Taken together, our results suggest that a subpopulation of migrating mesencephalic neural crest cells is refractory to catecholaminergic differentiation signals in the trunk. We suggest that this heterogeneity, together with local signals that repress catecholaminergic differentiation, may ensure that most ciliary neurons adopt a cholinergic fate.

Both neural crest and placode contribute to the ciliary ganglion and oculomotor nerve

The chick ciliary ganglion is a neural crest-derived parasympathetic ganglion that innervates the eye. Here, we examine its axial level of origin and developmental relationship to other ganglia and nerves of the head. Using small, focal injections of DiI, we show that neural crest cells arising from both the caudal half of the midbrain and the rostral hindbrain contribute to the ciliary as well as the trigeminal ganglion. Precursors to both ganglia have overlapping migration patterns, moving first ventrolaterally and then rostrally toward the optic vesicle. At the level of the midbrain/forebrain junction, precursors to the ciliary ganglion separate from the main migratory stream, turn ventromedially, and condense in the vicinity of the rostral aorta and Rathke's pouch. Ciliary neuroblasts first exit the cell cycle at early E2, prior to and during ganglionic condensation, and neurogenesis continues through E5.5. By E3, markers of neuronal differentiation begin to appear in this population. By labeling the ectoderm with DiI, we discovered a new placode, caudal to the eye and possibly contiguous to the trigeminal placode, that contributes a few early differentiating neurons to the ciliary ganglion, oculomotor nerve, and connecting branches to the ophthalmic nerve. These results suggest for the first time a dual neural crest and placodal contribution to the ciliary ganglion and associated nerves.

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.

Interactions between beta 2-syntrophin and a family of microtubule-associated serine/threonine kinases

A screen for proteins that interact with beta 2-syntrophin led to the isolation of MAST205 (microtubule-associated serine/threonine kinase-205 kD) and a newly identified homologue, SAST (syntrophin-associated serine/threonine kinase). Binding studies showed that beta 2-syntrophin and MAST205/SAST associated via a PDZ-PDZ domain interaction. MAST205 colocalized with beta 2-syntrophin and utrophin at neuromuscular junctions. SAST colocalized with syntrophin in cerebral vasculature, spermatic acrosomes and neuronal processes. SAST and syntrophin were highly associated with purified microtubules and microtubule-associated proteins, whereas utrophin and dystrophin were only partially associated with microtubules. Our data suggest that MAST205 and SAST link the dystrophin/utrophin network with microtubule filaments via the syntrophins.

The long internal loop of the alpha 3 subunit targets nAChRs to subdomains within individual synapses on neurons in vivo

Different types of neurotransmitter receptors coexist within single neurons and must be targeted to discrete synaptic regions for proper function. In chick ciliary ganglion neurons, nicotinic acetylcholine receptors (nAChRs) containing alpha 3 and alpha 5 subunits are concentrated in the postsynaptic membrane, whereas alpha-bungarotoxin receptors composed of alpha 7 subunits are localized perisynaptically and excluded from the synapse. Using retroviral vector-mediated gene transfer in vivo, we show that the long cytoplasmic loop of alpha 3 targets chimeric alpha 7 subunits to the synapse and reduces endogenous nAChR surface levels, whereas the alpha 5 loop does neither. These results show that a particular domain of one subunit targets specific receptor subtypes to the interneuronal synapse in vivo. Moreover, our findings suggest a difference in the mechanisms that govern assembly of interneuronal synapses as compared to the neuromuscular junction in vertebrates.

Expression of a quail bHLH transcription factor is associated with adrenergic development in trunk neural crest cultures

1. Expression of chick type 1 basic helix-loop-helix transcription factor GbHLH1.4 persists in several embryonic regions, including some where neural crest cells differentiate (Helms, J. A., et al., Mech. Dev. 48:93-108, 1994.) We have cloned portions of the quail homologue (designated QbHLH) in order to investigate its expression and possible function in quail neural crest cultures. Three sets of polymerase chain reaction primers were used to amplify cDNA sequences encompassing much of the coding region outside the bHLH domain. Two of the primer sets amplified a single band from all quail and chick tissues tested. The third set of primers produced two bands, differing by a 72-base pair insertion, both of which which were present in all tissues assayed. 2. The quail sequences showed greater than 97% nucleotide identity with GbHLH1.4. In situ hybridization of cultured quail neural crest cells showed expression in some, but not all, cells throughout the first 2 weeks in culture. 3. Tyrosine hydroxylase immunoreactivity correlated particularly well with QbHLH expression, although substantial subpopulations of cells with other phenotypes also express QbHLH. 4. In some cells, only limited regions of the cytoplasm showed hybridization with QbHLH probes, indicating possible mRNA localization. 5. The expression of QbHLH in neural crest cultures is consistent with its role as a relatively widely expressed helix-loop-helix dimerization partner and suggests that it may function by interacting with cell type-specific partners to regulate expression of genes involved in the development and maintenance of several phenotypes.

Immortalized cell lines from embryonic avian and murine otocysts: tools for molecular studies of the developing inner ear

Recently, our studies have focused on genes expressed at the earliest stages of inner ear development. Our aim is to identify and characterize genes that are involved in determining the axes of the semicircular canals, in otic crest delamination and in early innervation of the inner ear. Many elegant studies of auditory development have been done in animal models. However, the need for large amounts of well-characterized embryonic material for molecular studies makes the development of otocyst cell lines with different genetic repertoires attractive. We have therefore derived immortalized otocyst cells from two of the most widely used animal models of ear development: avians and mice. Avian cell isolates were produced from quail otocysts (embryonic stage 19) that were transformed with temperature-sensitive variants of the Rous sarcoma virus (RSV). Among the individual transformed cells are those that produce neuron-like derivatives in response to treatment with 10(-9) M retinoic acid. Mammalian cell isolates were derived from otocysts, of 9 day (post coitus) embryos of the H2kbtsA58 transgenic mouse (Immortomouse), which carries a temperature-sensitive variant of the Simian Virus 40 Tumor antigen. The vast majority of cells of the Immortomouse are capable of being immortalized at 33 degrees C, the permissive temperature for transgene expression, in the presence of gamma-interferon. Several putative clones et these cells differentiated into neuron-like cells after temperature shift and withdrawal of gamma-interferon; another isolate of cells assumed a neuron-like morphology on exposure to brain-derived neurotrophic factor even at the permissive temperature. We describe also a cell isolate that expresses the Pax-2 protein product and two putative cell lines that express the protein product of the chicken equivalent of the Drosophila segmentation gene engrailed. These genes and their protein products are expressed in specific subpopulation of otocyst cells at early stages. Both mouse and quail immortalized cell lines will be used to study inner ear development at the molecular level.

Persistent correlation between expression of a sulfated carbohydrate antigen and adrenergic differentiation in cultures of quail trunk neural crest cells

The carbohydrate antigen recognized by monoclonal antibodies such as HNK-1 (first characterized as recognizing human natural killer cells) and NC-1 (raised against quail neural-crest-derived cells) is found on a number of molecules associated with cell differentiation in vertebrates [42]. Previous work has shown that subpopulations of cultured quail trunk neural crest cells can be separated by fluorescence-activated cell sorting (FACS) on the basis of expression of this carbohydrate antigen. When neural crest cells are separated after 2 days in culture, adrenergic cells develop preferentially within the HNK-1-reactive subpopulation [27]. We wished to investigate whether the capacity for adrenergic differentiation remained associated with the HNK-1-positive cell population at later times in vitro, when the percentage of HNK-1-reactive cells has declined. The present study found that neural crest cells separated according to HNK-1-reactivity after 4 days in culture also showed preferential development of adrenergic cells in HNK-1-positive-enriched cultures, indicating that the HNK-1 epitope is persistently expressed in vitro on cells with adrenergic potential after 4 days of culture. To investigate the possible function of this epitope in development of the adrenergic phenotype, HNK-1 was added to unsorted neural crest cell cultures. The presence of antibody resulted in a decrease in the percentage of HNK-1-reactive cells during the initial 24 h after replating, but had no effect on the number of catecholamine-positive cells which developed after 7 days. We conclude that the epitope recognized by the HNK-1 antibody does not appear to function in the induction of the adrenergic phenotype. However, this antigenic determinant is useful as a predictive early marker which defines a subset of neural crest cells that includes those with the ability to undergo adrenergic differentiation.

Number of adrenergic and islet-1 immunoreactive cells is increased in avian trunk neural crest cultures in the presence of human recombinant osteogenic protein-1

OP-1, also known as BMP-7, is a member of the TGF-beta superfamily of proteins and was originally identified on the basis of its ability to induce new bone formation in vivo. OP-1 mRNA is found in the developing kidney and adrenal gland as well as in some brain regions (Ozkaynak et al. [1991] Biochem. Biophys. Res. Commun. 179:116-123). We have tested the effect of recombinant human OP-1 on quail trunk neural crest cultures. The number of catecholamine-positive cells which developed after 7 days in vitro in the presence of OP-1 was increased in a dose-dependent manner, with a greater than 100-fold maximal stimulation observed. The increase in the number of catecholamine-positive cells in the presence of OP-1 was paralleled by an increase in the number of tyrosine hydroxylase (TH)-positive cells. In contrast, total and melanocyte cell number were unaffected by the presence of OP-1. The number of Islet-1-immunoreactive cells was also increased by OP-1, but to only about half the value seen for TH. Double label experiments revealed these Islet-1-positive cells were a subset of the TH-positive cells. Inhibitors of DNA synthesis prevented the OP-1-mediated increase in adrenergic cell number, indicating that OP-1 does not act on a postmitotic cell population. However, labeling studies with bromodeoxyuridine indicated that OP-1 did not increase the proportion of the cell population engaged in DNA synthesis. Thus, the OP-1-mediated increase in adrenergic cell number most likely occurs as a result of the enhanced survival of a subpopulation of adrenergic precursors or an increase in their probability of adrenergic differentiation, but not by increasing the mitotic rate of adrenergic precursors or adrenergic cells themselves. In contrast to OP-1, TGF-beta 1 decreased adrenergic cell number. When OP-1 and TGF-beta 1 were added simultaneously, TGF-beta 1 antagonized the OP-1-mediated increase in adrenergic cell number in a dose-dependent manner.

Segment and cell type lineage restrictions during pharyngeal arch development in the zebrafish embryo

In zebrafish, the segmental series of pharyngeal arches is formed predominantly by two migratory cell types, neural crest and paraxial mesoderm, which arise in the early embryo. Neural crest cells migrate ventrally out of the neuroepithelium and into the arches to form cartilage, neurons, glia and pigment cells. Surrounding mesoderm generates muscles and endothelia. We labeled individual pharyngeal precursor cells with fluorescent dyes and found that their clonal progeny were confined to single segments and generated single cell types. When a neural crest or mesodermal cell was marked before migration into the pharynx, its progeny dispersed but generally remained confined to a single arch primordium. Such segmental restrictions arose first in the most rostral arches, mandibular and hyoid, and progressed caudally. The phenotypes of progeny generated by single cells were examined in the mandibular arch. Clones derived from premigratory neural crest cells generally did not contribute to more than one cell type. Further, the progenitors of some cell types were spatially separated in the premigratory crest. In particular, neurogenic crest cells were situated further laterally than cells that generate cartilage and connective tissues, while pigment and glial cell progenitors were more evenly distributed. Based on these results we suggest that arch precursors may be specified as to their eventual fates before the major morphogenetic movements that form the arch primordia. Further, cell movements are restricted during segmentation establishing a group of arch precursors as a unit of developmental patterning, as in the fashion of vertebrate rhombomeres or segmental lineage compartments in Drosophila.

Regulation of the early development of the nervous system by growth factors

Development of the nervous system, although patterned by intrinsic genetic expression, appears to be dependent on growth factors for many of the differentiation steps that generate the wide variety of neurons and glia found in the both the central and peripheral nervous system. By using in vitro assays, including clonal analysis, the precise function of the various growth factors and the differentiation potential of the various neural populations has begun to be described. This review discusses some of the recent findings and examines how neuronal differentiation may result from the interaction of several growth factors.

Molecular regulation of neural crest development

The neural crest is a transient embryonic structure that gives rise to a multitude of different cell types in the vertebrate. As such, it is an ideal model to study the processes of vertebrate differentiation and development. This review focuses on two major questions related to neural crest development. The first question concerns the degree and time of commitment of the neural crest cells to different cell lineages and the emerging role of the homeobox containing genes in regulating this process. Evidence from the cephalic crest suggests that the commitment process does start before the neural crest cells migrate away from the neural tube and gene ablation experiments suggest that different homeobox genes are required for the development of neural and mesenchymal tissue derivatives. However, clonal analysis of neural crest cells before migration suggests that many of the cells remain multi-potential indicating that the final determinative steps occur progressively during migration and in association with environmental influences. The second question concerns the nature of the environmental factors that determine the differentiation of neural crest cells into discrete lineages. Evidence is provided, mainly from in vitro experiments, that purified growth factors selectively promote the differentiation of neural crest cells down either sympathetic, adrenal, sensory, or melanocytic cell lineages.

Selective modulation of cholinergic properties in cultures of avian embryonic sympathetic ganglia

We have studied the expression of catecholaminergic and cholinergic phenotypes in sympathetic ganglia removed from 7- to 10-day-old quail embryos and grown in vitro under different conditions. Quantitative data were obtained by measuring the conversion of (3H) tyrosine and (3H) choline to catecholamines (CA) and acetylcholine (ACh), respectively. In explant cultures, large amounts of both neurotransmitters were synthesized from the onset, but CA generally predominated, the molar ratios of CA:ACh being, on average, of the order of 2:1. If the ganglia were dissociated before plating, there was a selective increase in ACh synthesis (three- to fivefold) such that the CA:ACh ratio fell strikingly. The early expression of the cholinergic phenotype appears to be species-specific in that, under identical conditions, dissociated cell cultures of newborn mouse superior cervical ganglia were overwhelmingly catecholaminergic (CA:ACh ratio of approximately 40:1) and ACh synthesis was only just detectable. Addition of veratridine (1.5 microM) either to explant or to dissociated cell cultures of embryonic quail sympathetic ganglia barely altered CA-synthesizing ability; in contrast, ACh synthesis and accumulation were stimulated about threefold. This effect, which we found to correspond to a quantitatively similar increase in the activity of choline acetyltransferase (ChAT), was completely blocked by tetrodotoxin, indicating that it was due to Na(+)-dependent depolarization. A preferential stimulation of ACh production was also observed when the concentration of K+ was raised to 20 mM. Veratridine treatment of cultures of presumptive sympathoblasts, in the form of sclerotome-associated neural crest cells, had identical effects. Our results reveal the quantitative importance of ACh-related properties in avian sympathetic ganglia from the earliest stages of their development and suggest that depolarization may be one of the factors selectively enhancing expression of the cholinergic phenotype during ontogeny. In these respects, the neurochemical differentiation of sympathetic neurons unfolds according to dissimilar scenarios in birds and mammals.

Restriction of neurogenic ability during neural crest cell differentiation

Multipotent neural crest cells undergo developmental restrictions during embryogenesis and eventually give rise to the neurons and glia of the peripheral nervous system, melanocytes, and pheochromocytes. To understand how neuronal potential is restricted to a subpopulation of crest-derived cells, we have utilized sensitive markers of early neuronal differentiation to assess neurogenesis in crest-derived cell populations subjected to defined experimental conditions in vitro and in vivo. We describe environmental conditions that either (a) result in the irreversible loss of neurogenic potential over a characteristic time course or (b) maintain neurogenic potential among neural crest cells.

Differentiation of neurogenic precursors within the neural crest cell lineage

It has been suggested that many, if not all crest-derived neurons develop from a limited subpopulation of neurogenic precursors. To develop cell-type specific markers that identify these precursors directly we have used differential screening of crest-derived cell populations known to have, or not to have, neurogenic ability. We have determined that the neuron-specific human auto-antibodies designated Anti-Hu bind to cytoplasmic and nuclear determinants not only in mature avian neurons and neuroendocrine cells but also in subpopulations of morphologically non-neuronal avian crest-derived cells. Significantly, these Anti-Hu+ non-neuronal crest-derived cells are present only in populations that have neurogenic ability and are absent from populations that lack neurogenic ability. Moreover, following additional development in vivo or in vitro, Anti-Hu+ non-neuronal crest-derived cells appear to express other neuronal traits. These results suggest that Anti-Hu-immunoreactivity is an early indicator of neurogenesis among crest-derived cells, and that Anti-Hu+ non-neuronal cells are either neurogenic precursors or immature neurons. Similarly, using the same differential screening paradigm, we have identified two monoclonal antibodies, designated 12E10 and 17F5, which also label both neurons and some apparently nonneuronal cells in neurogenic populations of neural crest cells. Anti-Hu-IR appears to precede expression of either of these two markers.

Phenotypic plasticity of avian embryonic sympathetic neurons grown in a chemically defined medium: direct evidence for noradrenergic and cholinergic properties in the same neurons

Avian embryonic sympathetic ganglia possess both catecholaminergic and cholinergic features and can synthesize noradrenaline (NAd) and acetylcholine (ACh) simultaneously. In the present study we sought to determine (1) whether or not this coproduction of NAd and ACh corresponds to the existence of two non-overlapping populations, and (2) to what extent the levels of synthesis are influenced by non-neuronal ganglion cells. We have focused on the correlation between the immunocytochemically demonstrable presence of the noradrenergic and cholinergic enzymes tyrosine hydroxylase (TH) and choline acetyltransferase (ChAT), respectively, and the synthesis of the corresponding neurotransmitters in embryonic quail sympathetic neuronal and non-neuronal cells purified by fluorescence-activated cell sorting. We show that (1) freshly sorted neurons synthesize both NAd and ACh, whereas non-neuronal cells produce neither; (2) the overwhelming majority of the sympathetic neurons display TH immunoreactivity; (3) about half of the TH-positive neurons are recognized by an anti-ChAT antibody in an artificial medium that selectively enhances synthesis and/or accumulation of ACh; (4) the non-neuronal cells are important for survival of the neurons and potentiate their synthesis of ACh in this medium, and (5) finally, we present evidence that expression of TH in noradrenergic neurons and in small intensely fluorescent cells of sympathetic ganglia is differentially regulated.

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.

The role of growth factors in the embryogenesis and differentiation of the eye

The vertebrate eye is composed of a variety of tissues that, embryonically, have their derivation from surface ectoderm, neural ectoderm, neural crest, and mesodermal mesenchyme. During development, these different types of cells are subjected to complex processes of induction and suppressive interactions that bring about their final differentiation and arrangement in the fully formed eye. With the changing concept of ocular development, we present a new perspective on the control of morphogenesis at the cellular and molecular levels by growth factors that include fibroblast growth factors, epidermal growth factor, nerve growth factor, platelet-derived growth factor, transforming growth factors, mesodermal growth factors, transferrin, tumor necrosis factor, neuronotrophic factors, angiogenic factors, and antiangiogenic factors. Growth factors, especially transforming growth factor-beta, have a crucial role in directing the migration and developmental patterns of the cranial neural-crest cells that contribute extensively to the structures of the eye. Some growth factors also exert an effect on the developing ocular tissues by influencing the synthesis and degradation of the extracellular matrix. The mRNAs for the growth factors that are involved in the earliest aspects of the growth and differentiation of the fertilized egg are supplied from maternal sources until embryonic tissues are able to synthesize them. Subsequently, the developing eye tissues are exposed to both endogenous and exogenous growth factors that are derived from nonocular tissues as well as from embryonic fluids and the systemic circulation. The early interaction between the surface head ectoderm and the underlying chordamesoderm confers a lens-forming bias on the ectoderm; later, the optic vesicle elicits the final phase of determination and enhances differentiation by the lens. After the blood-ocular barrier is established, the internal milieu of the eye is controlled by the interactions among the intraocular tissues; only those growth factors that selectively cross the barrier or that are synthesized by the ocular tissues can influence further development and differentiation of the cells. An understanding of the tissue interactions that are regulated by growth factors could clarify the precise mechanism of normal and abnormal ocular development.

Co-expression of multiple neurotransmitter enzyme genes in normal and immortalized sympathoadrenal progenitor cells

We have examined the expression of mRNAs encoding five major neurotransmitter-synthesizing enzymes in MAH cells, a clonal cell line derived by retroviral immortalization of a rat embryonic sympathoadrenal progenitor cell. These mRNAs include tyrosine hydroxylase (TH), choline acetyltransferase (ChAT), tryptophan hydroxylase (TpH), and glutamic acid decarboxylases (GADs) 1 and 2. We find that MAH cells express high levels of TH mRNA and low levels of ChAT and TpH mRNAs. Neither GAD1 nor GAD2 mRNAs are detectable using an RNase protection assay with a detection limit of less than one transcript per cell. A similar pattern of mRNA expression is observed in postnatal superior cervical ganglia, adrenal medulla, and in PC12 cells. Transmitter synthesis and accumulation assays indicate that MAH cells can synthesize both catecholamines and acetylcholine. Thus the TH and ChAT mRNAs detected in these cells are likely to be translated into active enzyme. To corroborate these data obtained using MAH cells, we performed similar transmitter synthesis and accumulation assays on sympathoadrenal progenitors directly isolated from E14.5 fetal adrenal glands by fluorescence-activated cell sorting. These progenitor cells also synthesize and accumulate both catecholamines and acetylcholine, albeit to different extents than MAH cells. Both MAH cells and their nonimmortal counterparts are able to increase slightly their cholinergic function upon short-term exposure to CDF/LIF, a factor known to induce acetylcholine synthesis in postmitotic sympathetic neurons. Taken together, these data suggest that progenitor cells in the sympathoadrenal lineage acquire the ability to simultaneously transcribe several different neurotransmitter enzyme genes early in development, prior to their choice of final cell fate. At the same time, the progenitors possess receptors which regulate expression of these genes in response to environmental factors. This ability may permit the cells to choose from several different transmitter phenotypes in response to different environments, as they migrate through the embryo. The persistent transcription of these genes in adult cells, moreover, may in part account for the phenotypic plasticity of cells in this lineage.

In vitro clonal analysis of quail cardiac neural crest development

The developmental potentials of cardiac neural crest cells were investigated by in vitro clonal analysis. Five morphologically distinct types of clones were observed: (1) "pigmented" clones contained melanocytes only; (2) "mixed" clones consisted of pigmented and unpigmented cells; (3) "unpigmented dense" clones consisted of flattened, closely aligned unpigmented cells; (4) "unpigmented loose" clones consisted of a few loosely arranged, flattened cells; and (5) "unpigmented large" clones included a large number of small, stellate cells that were highly proliferative. The binding patterns of antibodies against lineage-specific markers showed that cells in the different clones expressed characteristic phenotypes. The following phenotypes were expressed in addition to pigment cells: smooth muscle cells, connective tissue cells, chondrocytes, and cells in the sensory neuron lineage. Mixed clones expressed all five phenotypes. Unpigmented dense clones contained smooth muscle cells, connective tissue cells, chondrocytes, and sensory neurons. Unpigmented loose clones exclusively consisted of smooth muscle cells, whereas unpigmented large clones contained chondrocytes and sensory neuron precursors. Based on these results, the following conclusions can be drawn: (1) Pigmented and unpigmented loose clones are most likely formed by precursors that are committed to the melanogenic and myogenic cell lineages, respectively. (2) Mixed and unpigmented dense clones are derived from pluripotent cells with the capacity to give rise to four or five phenotypes. (3) Unpigmented large clones originate from progenitor cells that appear to have a partially restricted developmental potential, that is, these cells are capable of generating two phenotypes in clonal cultures. Thus, the data indicate that the early migratory cardiac neural crest is a heterogeneous population of cells, consisting of pluripotent cells, cells with a partially restricted developmental potential, and cells committed to a particular cell lineage.

Development of anomalous rectification (Ih) and of a tetrodotoxin-resistant sodium current in embryonic quail neurones

1. The developmental expression of an inwardly rectifying current activated by membrane hyperpolarization (Ih) and of a tetrodotoxin (TTX)-resistant Na+ current (INa(TR)) was studied using freshly dissociated ganglionic quail neurones of various embryonic ages. This work was carried out on parasympathetic (ciliary) and sensory (trigeminal and dorsal root) ganglion neurones with the whole-cell configuration of the patch-clamp technique. 2. In sensory and parasympathetic neurones, Ih was activated at potentials more negative than -60 mV and displayed strong inward rectification. No sign of time- or voltage-dependent inactivation was apparent. Ih was carried by both Na+ and K+ ions and was selectively and reversibly blocked by extracellular Cs+. 3. During the development of sensory neurones, Ih was observed for the first time between embryonic day 10 (E10) and E11 and the percentage of neurones expressing the current increased subsequently, reaching a plateau level of about 80% at E14. In the parasympathetic neurones of the ciliary ganglion, Ih was already detected at E10 and the percentage of neurones possessing the current increased until E16, a stage at which all neurones were found to express Ih. 4. In the presence of TTX (1 microM), an inward Na+ current, INa(TR), was recorded in sensory neurones after E12. This current was activated at potentials more depolarized than -30 mV and its amplitude was maximal at +5 mV. INa(TR) showed time- and voltage-dependent inactivation. Half-maximal steady-state inactivation was observed at -40 mV. 5. INa(TR) was observed for the first time after E12 in sensory neurones and the percentage of neurones with INa(TR) increased until E14. Thereafter, 80% of the neurones had the current. In contrast, INa(TR) was never observed in the parasympathetic neurones of the ciliary ganglion during embryonic development. 6. Our results with parasympathetic and sensory neurones suggest that the expression of INa(TR) is linked to the phenotype and not to the embryonic origin of a neurone.

Development of the neural crest

Mutations that affect the morphogenetic behaviour and differentiation of neural crest-derived cells in mouse embryos have been shown to alter genes that code for growth factors or growth factor receptors. Identification of these and other gene products provide opportunities to understand when and how developmentally distinct embryonic cell populations arise, and how interactions between localized developmental cues and responsive cell subpopulations can be modulated during development.

Spectrum of in vitro differentiation of quail trunk neural crest cells isolated by cell sorting using the HNK-1 antibody and analysis of the adrenergic development of HNK-1+ sorted subpopulations

Previous work has demonstrated that catecholamine-containing cells differentiate preferentially from populations of quail trunk neural crest cells isolated by cell sorting using the HNK-1 antibody (Maxwell, Forbes, and Christie, 1988). In the present work, we examine several additional features of the differentiation of these sorted cell populations. As one part of this study, the development of subpopulations of the HNK-(1+)-sorted neural crest cells has been investigated. Twice as many catecholamine-positive and total cells developed from the brightest third of the HNK-1+ cells compared to the remaining HNK-1+ cells, but the proportion of catecholamine-containing cells was similar in both populations. When either of these HNK-1+ subpopulations were grown together with HNK-1- cells, no reduction in the number of adrenergic cells was observed. These results indicate that subpopulations of HNK-1+ cells are qualitatively similar and that their adrenergic development is not affected by HNK-1- cells. In the second part of this study, we investigate the specificity of differentiation of HNK-(1+)- and HNK-(1-)-sorted cells by examining several additional phenotypic markers of development. We found that tyrosine hydroxylase and somatostatin immunoreactive cells developed from the HNK-(1+)-sorted population, while few, if any, cells bearing these phenotypic markers appeared in the HNK-(1-)-sorted population. In marked contrast, substantial numbers of cells immunoreactive for A2B5, E/C8, and NF-160 differentiated from both the HNK-(1+)- and the HNK-(1-)-sorted cell populations. The A2B5, E/C8, and NF-160 immunoreactive cells exhibited a variety of morphologies ranging from nonneuronal to neuronal in both sorted populations. Taken together, these results indicate that the presence of the HNK-1 antigen(s) on the trunk neural crest cell surface at 2 days in vitro is rather tightly correlated with the differentiation of adrenergic and some peptidergic cells, but much less so with other classes of neural cells including A2B5, E/C8, and NF-160 immunoreactive cells. Thus, these findings support the view that cell surface differences are correlated with and may contribute to the generation of the phenotypic diversity of neural crest cell derivatives.

Development of cholinergic traits in the quail ciliary ganglion: expression of choline acetyltransferase-like immunoreactivity

The avian ciliary ganglion is a parasympathetic ganglion derived from the neural crest whose neurons provide cholinergic innervation to the eye. Here, we describe the time course of appearance and the morphology of cholinergic cells in the ciliary ganglion, as assessed by antibodies against choline acetyltransferase. Choline acetyltransferase immunoreactivity was first observed in 5.5-day-old quail embryos, 1 day after condensation of the ciliary ganglion. Both the intensity of choline acetyltransferase immunoreactivity and size of the choline acetyltransferase-immunoreactive cells increased with ganglionic age. By 12 days, a second population of choline acetyltransferase-immunoreactive cells, possibly corresponding to choroid neurons, was observed whose cells were smaller and less intensely stained than earlier differentiating choline acetyltransferase-immunoreactive cells. The percentage of choline acetyltransferase-immunoreactive cells was initially high, constituting approximately 50% of the total cell population. As a function of time, the proportion of cholinergic cells decreased, probably due to proliferation of non-neuronal cells and naturally-occurring cell death. Our results confirm the existence of two morphologically distinct populations of cholinergic neurons in the avian ciliary ganglion and demonstrate that these neuronal subpopulations express choline acetyltransferase immunoreactivity at different times in development. Because choroid neurons innervate their targets later than ciliary neurons, this finding is consistent with the hypothesis that target interactions regulate expression of choline acetyltransferase.