Changes in competence determine the timing of two sequential glucocorticoid effects on sympathoadrenal progenitors

Distribution of glucocorticoid receptor immunoreactivity and mRNA in the rat brain: an immunohistochemical and in situ hybridization study

The localization of glucocorticoid receptor (GR) immunoreactivity and mRNA in the adult rat brain was examined by light microscopic and electron microscopic immunohistochemistries, and in situ hybridization. For the purpose of detailed investigation of the distribution and comparison of GR immunoreactivities and mRNAs, specific polyclonal antibodies against a part of the transcription modulation (TR) domain of rat GR were used in the immunohistochemistry, whereas fluorescein-labeled RNA probes, complementary to the TR domain in the GR cDNA were used in the in situ hybridization. In the rat brain, GR immunoreactivity was predominantly localized in the cell nucleus, and the expression of GR mRNA was detected in the cytoplasm. GR-immunoreactive and GR mRNA-containing cells were widely distributed from the olfactory bulb of the forebrain to the gracile-cuneate nuclei of the medulla oblongata. The highest densities of GR-immunoreactive and mRNA-containing cells were observed in the subfields of cerebral cortex, olfactory cortex, hippocampal formation, amygdala, septal region, dorsal thalamus, hypothalamus, trapezoid body, cerebellar cortex, locus coeruleus and dorsal nucleus raphe. The distributional pattern of GR immunoreactivity in many regions was well-correlated with that of GR mRNA, but in the CA3 and CA4 pyramidal layers of the hippocampus, different localization was noted. The present study provides the groundwork for elucidating the role of GRs in brain function.

Selective neural regulation of epinephrine and norepinephrine cells in the adrenal medulla -- cardiovascular implications

The innervation of the adrenal medulla regulates the release of catecholamines from the two, epinephrine (EPI) and norepinephrine (NE), populations of chromaffin cells. Adjustments in the neural output to the adrenal medulla are made by centers in the brain that integrate the sensory input arising from a variety of challenges and the resulting changes in secretion assist in the restoration of homeostasis. Interestingly, the adrenal medullary secretory responses do not simply reflect increments a fixed ratio of EPI to NE as might be expected if release was proportional to the number EPI and NE cells. Instead, the ratio of EPI to NE changes depending on the magnitude and type of stimulus that initiates neural activation of the medulla. The variability in the EPI:NE release ratio implies that the EPI and NE cells can be differentially stimulated. Although the underlying mechanisms are not fully characterized, this review presents an emerging view that the selective control of EPI and NE cells is accounted for, first, by the existence of separate neural circuits between brain centers and the chromaffin cells, and second, through neuromodulation that selectively influences EPI and NE cells. The presence of mechanisms that allow for separate control of the EPI and NE cells may significantly augment the range of cardiovascular and metabolic responses mediated through activation of the adrenal medulla.

Dexamethasone regulates the expression of neuronal properties of a rat insulinoma cell line

Insulin producing cells of the pancreas (beta cells) and neuronal cells share a large number of similarities. For example, different molecules, thought to be specific of neuronal cells, are expressed by beta cells. The factors regulating the expression of these molecules in beta cells are poorly understood. In the present work, we have studied the effect of dexamethasone, a synthetic glucocorticoid, on the expression of three different neuronal traits expressed by INS-1 cells, a highly differentiated beta cell line. We demonstrate that dexamethasone treatment decreases the steady state levels of mRNAs coding for both the low- and the high-affinity NGF receptors and of mRNA coding for NF-H, an intermediate neurofilament specific of neurons. This effect was time-dependent, the decrease being detectable after 4-8 h treatment. The decrease in NGF receptors mRNAs steady state levels was paralleled by a decrease in the number of NGF binding sites as demonstrated after Scatchard analysis. We further focused on the mechanisms by which dexamethasone affects the expression of the low affinity NGF receptor. The effect is countered by the glucocorticoid antagonist RU486, indicating that it is mediated by the glucocorticoid receptor. Finally, the decrease in the low-affinity nerve growth factor receptor mRNA steady state level after dexamethasone treatment is not due to mRNA destabilization but can be rather explained through a change in gene transcription.

Roles of steroid hormones and their receptors in structural organization in the nervous system

Due to their chemical properties, steroid hormones cross the blood-brain barrier where they have profound effects on neuronal development and reorganization both in invertebrates and vertebrates, including humans mediated through their receptors. Steroids play a crucial role in the organizational actions of cellular differentiation representing sexual dimorphism and apoptosis, and in the activational effects of phenotypic changes in association with structural plasticity. Their sites of action are primarily the genes themselves but some are coupled with membrane-bound receptor/ion channels. The effects of steroid hormones on gene transcription are not direct, and other cellular components interfere with their receptors through cross-talk and convergence of the signaling pathways in neurons. These genomic and non-genomic actions account for the divergent effects of steroid hormones on brain function as well as on their structure. This review looks again at and updates the tremendous advances made in recent decades on the study of the role of steroid (gonadal and adrenal) hormones and their receptors on developmental processes and plastic changes in the nervous system.

The cellular function of MASH1 in autonomic neurogenesis

Using primary cultures and immortalized multipotential stem cell lines derived from wild-type and Mash1 mutant neural crest cells, we have analyzed the cellular function of MASH1 in autonomic neurogenesis. We present evidence for the existence of a precursor expressing MASH1 and neuronal markers such as neurofilament, neuron-specific tubulin, and tetanus toxin receptor. This cell has a nonneuronal morphology. Differentiation of this precursor to neurons that express markers such as SCG10, peripherin, and neuron-specific enolase is dependent upon MASH1 function. These data imply that the differentiation of autonomic neurons from uncommitted neural crest cells occurs in several sequential steps. Moreover, they suggest that MASH1 does not commit multipotent cells to a neural fate, like its Drosophila achaete-scute counterparts, but rather promotes the differentiation of a committed neuronal precursor.

Phenotypic development of neonatal rat chromaffin cells in response to adrenal growth factors and glucocorticoids: focus on pituitary adenylate cyclase activating polypeptide

We have investigated the regulation of the morphological phenotype of chromaffin cells cultured from 6-day-old rat adrenal glands. We show that pituitary adenylate cyclase activating polypeptide (PACAP), which is present in and released from nerves innervating chromaffin cells, rapidly induces neuritic growth, affecting 25% of tyrosine hydroxylase-positive chromaffin cells after 3 days at an optimal concentration of about 20 nM. PACAP does not synergistically act with other factors known to promote neurite growth, including nerve growth factor (NGF), basic fibroblast growth factor (bFGF, FGF-2), and ciliary neurotrophic factor (CNTF). The neurite promoting effect of PACAP and FGF-2 is entirely overridden by dexamethasone (2 x 10(-8) M) suggesting that, despite the presence of these promoting factors in the adrenal medulla, glucocorticoids from the adrenal cortex are probably sufficient to prevent the development of neuronal traits in adrenal chromaffin cells.

Mice deficient in the orphan receptor steroidogenic factor 1 lack adrenal glands and gonads but express P450 side-chain-cleavage enzyme in the placenta and have normal embryonic serum levels of corticosteroids

The orphan nuclear receptor steroidogenic factor 1 (SF-1) is expressed in the adrenal cortex and gonads and regulates the expression of several P450 steroid hydroxylases in vitro. We examined the role of SF-1 in the adrenal glands and gonads in vivo by a targeted disruption of the mouse SF-1 gene. All SF-1-deficient mice died shortly after delivery. Their adrenal glands and gonads were absent, and persistent Mullerian structures were found in all genotypic males. While serum levels of corticosterone in SF-1-deficient mice were diminished, levels of adrenocorticotropic hormone (ACTH) were elevated, consistent with intact pituitary corticotrophs. Intrauterine survival of SF-1-deficient mice appeared normal, and they had normal serum level of corticosterone and ACTH, probably reflecting transplacental passage of maternal steroids. We tested whether SF-1 is required for P450 side-chain-cleavage enzyme (P450scc) expression in the placenta, which expresses both SF-1 and P450scc, and found that in contrast to its strong activation of the P450scc gene promoter in vitro, the absence of SF-1 had no effect on P450scc mRNA levels in vivo. Although the region targeted by our disruption is shared by SF-1 and by embryonal long terminal repeat-binding protein (ELP), a hypothesized alternatively spliced product, we believe that the observed phenotype reflects absent SF-1 alone, as PCR analysis failed to detect ELP transcripts in any mouse tissue, and sequences corresponding to ELP are not conserved across species. These results confirm that SF-1 is an important regulator of adrenal and gonadal development, but its regulation of steroid hydroxylase expression in vivo remains to be established.

Ciliary neurotrophic factor promotes the terminal differentiation of v-myc immortalized sympathoadrenal progenitor cells in vivo

Survival and differentiation of a sympathoadrenal progenitor cell line (termed MAH), transduced with a v-myc oncogene, was studied subsequent to transplantation in the peripheral and central nervous system of adult rats. In the brain, MAH cell survival depended on the secretion of ciliary neurotrophic factor (CNTF) by co-grafts of genetically modified glioma cells. No trophic factor supplement was required for development of the MAH cells in the peripheral nerve environment. Transplanted progenitor cells withdrew from the cell cycle within 48 h and differentiated into a prominent population of large sympathetic-like neurons. The neurons expressed the alpha subunit of the CNTF receptor and appropriate spatial distributions of cytoskeletal proteins and catecholamine related enzymes. The results identify a role for CNTF in the development of the sympathoadrenal cell lineage and support the concept of immortalized progenitor cells as alternatives to primary cells for cell replacement strategies in the nervous system.

Targeted disruption of the glucocorticoid receptor gene blocks adrenergic chromaffin cell development and severely retards lung maturation

The role of the glucocorticoid receptor (GR) in glucocorticoid physiology and during development was investigated by generation of GR-deficient mice by gene targeting. GR -/- mice die within a few hours after birth because of respiratory failure. The lungs at birth are severely atelectatic, and development is impaired from day 15.5 p.c. Newborn livers have a reduced capacity to activate genes for key gluconeogenic enzymes. Feedback regulation via the hypothalamic-pituitary-adrenal axis is severely impaired resulting in elevated levels of plasma adrenocorticotrophic hormone (15-fold) and plasma corticosterone (2.5-fold). Accordingly, adrenal glands are enlarged because of hypertrophy of the cortex, resulting in increased expression of key cortical steroid biosynthetic enzymes, such as side-chain cleavage enzyme, steroid 11 beta-hydroxylase, and aldosterone synthase. Adrenal glands lack a central medulla and synthesize no adrenaline. They contain no adrenergic chromaffin cells and only scattered noradrenergic chromaffin cells even when analyzed from the earliest stages of medulla development. These results suggest that the adrenal medulla may be formed from two different cell populations: adrenergic-specific cells that require glucocorticoids for proliferation and/or survival, and a smaller noradrenergic population that differentiates normally in the absence of glucocorticoid signaling.

Molecular genetic analysis of glucocorticoid signalling in development

A null mutation of the glucocorticoid receptor was generated by homologous recombination. Mutant newborn mice showed impaired lung development, hypertrophy of the adrenal cortex and a strongly reduced size of the adrenal medulla. Phenylethanolamine N-methyltransferase (PNMT) was undetectable in the adrenals of the mutant mice. Serum levels of corticosterone were moderately and ACTH levels were strongly elevated in the mutants. A weaker but significant increase of corticosterone and ACTH was observed already in heterozygous animals. This points to a dysregulation of the HPA axis due to defective feedback regulation via the glucocorticoid receptor. Liver gluconeogenetic enzymes were reduced to a variable degree. Whereas survival of heterozygous mutants was not affected, most of the homozygous mutant mice died during the perinatal period.

Regulation of regional differences in the differentiation of cerebral cortical neurons by EGF family-matrix interactions

Both lineage-based and epigenetic regulation have been postulated as mechanisms to control the formation of discrete areas in the cerebral cortex, but specific genes or signaling pathways that may be involved have yet to be defined. In this paper, we examine whether progenitors, isolated from the cerebral wall prior to neurogenesis, can respond to exogenous cues by adopting a region-specific phenotype. The expression of the limbic system-associated membrane protein (LAMP), a neuron-specific marker of limbic cortical areas, was monitored in cultured neurons arising from precursors harvested from presumptive perirhinal (limbic) and sensorimotor (nonlimbic) zones at embryonic day 12 in the rat. Neuronal phenotype in all cultures was identified by expression of microtubule-associated protein-2 (MAP2). On a substrate of poly-lysine, over 80% of the precursors from the limbic area that differentiate into neurons express a LAMP+ phenotype. Approximately 20% of the neurons generated from precursors of the sensorimotor region become LAMP+. However, modification of the microenvironment had a significant effect on the differentiation of the sensorimotor precursors. When the nonlimbic precursors are grown on Matrigel, there is a 2-fold increase in the number of MAP2+/LAMP+ double-labeled neurons. Dissection of the Matrigel components reveals that in combination with growth factor-deficient Matrigel or collagen type IV, epidermal growth factor and transforming growth factor-alpha increase LAMP expression in the sensorimotor population. Delaying the addition of growth factor until after most cell division had ceased failed to increase the number of LAMP+ neurons. Another growth factor in Matrigel, platelet-derived growth factor, does not produce the same effect. Our results indicate that local signals can regulate the differentiation of cortical progenitors, providing a potential mechanism for establishing an early commitment to specific regional phenotypes in the developing cerebral wall that relate to future functional domains in the cortex.

Neuronal markers, peptides and enzymes in nerves and chromaffin cells in the rat adrenal medulla during postnatal development

Neuronal markers, peptides and enzymes were analyzed in the rat adrenal medulla during the postnatal period, i.e., when the 'functional' splanchnic innervation is assumed to 'mature'. Nerve fibers were present on day 2 as indicated by neurofilament 10 (NF10)- and growth associated protein 43 (GAP43)-like immunoreactivities (LIs). Acetylcholinesterase (AChE)- and enkephalin (ENK)-immunoreactive (IR) fibers, presumably of preganglionic nature, increased in number and intensity during the postnatal period. In contrast, calcitonin gene-related peptide (CGRP)- and galanin (GAL)-IR fibers were almost fully developed on day 2. Thus, the presumably sensory innervation of the adrenal gland seems to precede the development of the autonomic nerves. The AChE- and ENK-IR fibers may exert a suppressive effect on ENK-, CGRP- and neurotensin (NT)-LIs in chromaffin cells, since the levels of these peptides were high in the early postnatal period and then decreased. On the other hand, GAL-LI in chromaffin cells was low also in young rats, while GAP43-IR cells were observed at all stages. Neuropeptide tyrosine (NPY) was expressed in many chromaffin cells at all stages and its turnover rate seemed to decrease towards the adult stage. The expression of the catecholamine synthezising enzymes changed only marginally during development. These results indicate that the preganglionic fibers, but not the sensory axons, in the splanchnic nerve are involved in the developmental control of expression of some, but not all, peptides in the chromaffin cells and that these changes thus may reflect the maturation of a 'functional' transmission.

CNTF, FGF, and NGF collaborate to drive the terminal differentiation of MAH cells into postmitotic neurons

The differentiation of neuronal cell progenitors depends on complex interactions between intrinsic cellular programs and environmental cues. Such interactions have recently been explored using an immortalized sympathoadrenal progenitor cell line, MAH. These studies have revealed that depolarizing conditions, in combination with exposure to FGF, can induce responsiveness to NGF. Here we report that CNTF, which utilizes an intracellular signaling pathway distinct from that of both FGF and NGF, can collaborate with FGF to promote efficiently the differentiation of MAH progenitor cells to a stage remarkably reminiscent of NGF-dependent, postmitotic sympathetic neurons. We also find that similar collaborative interactions can occur during transdifferentiation of normal cultured chromaffin cells into sympathetic neurons.

High levels of expression of neuropeptide Y mRNA in human phaeochromocytomas

1. Neuropeptide Y (NPY) gene expression in human phaeochromocytomas was investigated by measuring the levels of NPY mRNA and NPY-immunoreactivity (NPY-IR) in human phaeochromocytoma tissues in comparison with those in normal human adrenal tissues. 2. The amounts of NPY mRNA and NPY-IR in human phaeochromocytomas were 18 and 93 times higher, respectively, than those in normal adrenal glands. In contrast, beta-actin gene expression was similar in human phaeochromocytomas to that in normal adrenal glands. 3. The amount of NPY mRNA relative to total cellular RNA was 6-fold higher in phaeochromocytoma tissues than in normal human adrenal medulla, suggesting increased NPY gene expression in the tumour cells. 4. Induction of differentiation of PC12 rat phaeochromocytoma cells by compounds, such as dexamethasone and nerve growth factor, resulted in a marked increase in the NPY mRNA level. 5. These findings suggest that NPY gene expression is increased in well-differentiated human phaeochromocytoma cells. Its high level of expression could be responsible for the marked overproduction of NPY by this tumour.

Environmental signals and neural crest cells

Cell lineage analysis in both the central and peripheral nervous system of vertebrates has revealed that many neural progenitor cells are multipotent. These observations have raised the general issue of when and how such multipotent progenitors generate their various differentiated progeny. The environment of these progenitors controls the cell lineage decisions in the neural crest. This review considers the roles of the environmental signals in the context of the development of several different neural crest-derived lineages.

Mammalian achaete-scute homolog 1 is required for the early development of olfactory and autonomic neurons

The mouse Mash-1 gene, like its Drosophila homologs of the achaete-scute complex (AS-C), encodes a transcription factor expressed in neural precursors. We created a null allele of this gene by homologous recombination in embryonic stem cells. Mice homozygous for the mutation die at birth with apparent breathing and feeding defects. The brain and spinal cord of the mutants appear normal, but their olfactory epithelium and sympathetic, parasympathetic, and enteric ganglia are severely affected. In the olfactory epithelium, neuronal progenitors die at an early stage, whereas the nonneuronal supporting cells are present. In sympathetic ganglia, the mutation arrests the development of neuronal precursors, preventing the generation of sympathetic neurons, but does not affect glial precursor cells. These observations suggest that Mash-1, like its Drosophila homologs of the AS-C, controls a basic operation in development of neuronal progenitors in distinct neural lineages.

Age-dependent survival-promoting activity of vitamin K on cultured CNS neurons

Neurons from the central nervous system (CNS) of rat embryos die within several days when seeded at a low density of 10(4) cells/cm2 and cultured in a serum-free defined medium. Using these culture systems, we searched for agents to promote the survival of these neurons. As a consequence, a fat-soluble vitamin, vitamin K1, was found to possess such kind of activity: more than 50% of the cortical neurons from 19-day-old rat embryos could survive for 4 days in the presence of vitamin K1, whereas almost all neurons died in its absence. The survival-promoting effect of vitamin K1 was found on neurons from not only cortex, but also hippocampus, striatum, and septum. In addition to vitamin K1, vitamin K2 and K3 also showed the same effect on cortical neurons. The effect of vitamins K1 and K2 was observed at concentrations from 10(-8) to 10(-6) M, and that of vitamin K3 was slightly detected at 10(-6) M. Furthermore, we examined the effect on the neurons from 16- and 21-day-old embryos, too. The activity of vitamin K1 was weaker toward the neurons from 21-day-old embryos compared with that toward 19-day-old ones, and was not recognized toward 16-day-old ones. These results suggest the potential role of the K vitamins on the maintenance of the survival of CNS neurons during the later stages of embryogenesis in vivo.

Cell fate determination in the peripheral nervous system: the sympathoadrenal progenitor

Studies of postnatal chromaffin cells, sympathetic neurons and Small Intensely Fluorescent (SIF) cells have suggested that these cells develop from a common progenitor, the sympathoadrenal (SA) progenitor, whose fate is determined by the relative levels of nerve growth factor (NGF) and glucocorticoid (GC) in its environment (Unsicker et al., 1978, Proc. Natl. Acad. Sci. USA 75:3498-3502; Doupe et al., 1985a, J. Neurosci. 5:2119-2142). Recent studies have identified such a bipotential SA progenitor in the rat embryo. Surprisingly, this progenitor is initially unresponsive to NGF; neuronal differentiation is instead promoted by fibroblast growth factor (FGF). However, FGF appears to promote NGF responsiveness, suggesting that neuronal differentiation involves a relay or cascade of growth factor action. Furthermore, chromaffin cell differentiation appears to involve two sequential, GC-dependent events: the inhibition of neuronal differentiation and the induction of epinephrine synthesis. The former event is a prerequisite to the latter. Thus both the chromaffin and neuronal pathways of differentiation follow a series of dependent events, involving changes in the responsiveness of SA progenitors to environmental factors. Such changes correlate with changes in antigenic marker expression that can be observed in vivo. In addition to choosing between neuronal and endocrine fates, SA progenitors must also express an appropriate neurotransmitter phenotype. For example, sympathetic neurons can become either noradrenergic or cholinergic. This cholinergic potential is already present in uncommitted SA progenitors, as evidenced by their ability to synthesize acetylcholine. Recent studies suggest that these cells may have yet other developmental capacities, including the ability to synthesize serotonin. This capacity is consistent with the hypothesis that SA progenitors are closely related to progenitors of enteric neurons, an idea supported by recent observations using novel antigenic markers. The SA progenitor may be, therefore, a "master" neuroendocrine progenitor for the peripheral nervous system.

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 hematopoietic 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.

Cell and molecular biology of neural crest cell lineage diversification

Neural crest cells are multipotent progenitor cells, but it is not understood how these cells generate their diverse differentiated progeny. This review considers the issues of whether neural crest cells self-renew, whether they generate partially committed intermediate progenitors, and how the local embryonic environment may act to control this diversification process. Novel molecular markers for neural crest cells are also discussed.