Specific pan-neural crest expression of zebrafish Crestin throughout embryonic development.

Zebrafish crestin was identified in a screen for genes dependent on cyclops function and is a member of a family of retroelements (Rubinstein et al. [2000] Genesis 26:86-97). We report here a detailed description of crestin mRNA expression during zebrafish embryogenesis. Crestin expression was first observed during the onset of somitogenesis in cells of the neural crest domain of the ectoderm. Crestin expression was subsequently observed in premigratory cranial and trunk neural crest cells and then in actively migrating crest cells. Cell counts of crestin-expressing premigratory trunk neural crest cells strongly suggest that crestin is expressed by all neural crest cells at this stage. Crestin expression co-localized with a battery of markers for premigratory neural crest cells, developmentally distinct neural crest-derived precursor sublineages, and overtly differentiated neural crest-derived cell types. Expression of crestin is gradually downregulated in overtly differentiated cells. Our results indicate that crestin is a specific pan-neural crest marker throughout zebrafish embryogenesis.

Avian transitin expression mirrors glial cell fate restrictions during neural crest development.

During development, trunk neural crest cells give rise to three primary classes of derivatives: glial cells, melanocytes, and neurons. As part of an effort to learn how neural crest diversification is regulated, we have produced monoclonal antibodies (MAbs) that recognize antigens expressed by neural crest cells early in development. One of these, MAb 7B3 (7B3), was found to recognize an avian transitin-like protein by co-immunostaining with a series of transitin-specific monoclonal antibodies and by Western blot analysis. In neural crest cell cultures, we found that 7B3 initially recognizes the majority of neural crest cells as they emerge from the neural tube. Subsequently, 7B3-immunoreactivity (IR) is progressively restricted to a smaller subpopulation of cells. In fully differentiated trunk neural crest cell cultures, 7B3-IR is expressed only by cells that do not express neuronal markers and lack melanin granules. During development in vivo, 7B3-IR is evident in neural crest cells on the medial, but not the lateral migration pathway, suggesting that it is not expressed by melanocyte precursors. Later, the antigen is detected in non-neuronal, presumptive glial cells in dorsal root ganglia (DRG) and sympathetic ganglia, as well as along ventral roots. Cultures of E5 DRG confirm that 7B3-IR is restricted to non-neuronal cells of ganglia, many of which closely associate with neuronal processes. Therefore, of the three major classes of differentiated trunk neural crest derivatives, 7B3 exclusively recognizes glial cells, including both satellite glia and Schwann cells. Since the pattern of 7B3 expression in vitro mirrors the pattern of glial cell fate-restrictions in the trunk neural crest lineage, and is expressed by neural crest-derived glia in vivo, we conclude that 7B3 is an early pan-glial marker for neural crest-derived glial cells and their precursors.

Genes dependent on zebrafish cyclops function identified by AFLP differential gene expression screen.

Zebrafish cyclops (cyc) encodes a Transforming Growth Factor beta (TGFbeta) signaling factor closely related to mouse Nodal. By comparing amplified fragment length polymorphisms (AFLP) from cyc mutant and wild-type cDNA pools, we devised a differential gene expression screen to isolate genes whose expression is dependent on Cyc signaling. We report two genes not previously described in the zebrafish that were identified using this approach. The first gene, crestin, is expressed predominantly in premigratory and migrating neural crest cells during somitogenesis stages. crestin expression is reduced in cyc mutants initially but recovers by late somitogenesis. The second gene encodes the zebrafish homologue of the calcium-binding protein, calreticulin. Zebrafish calreticulin is highly expressed in the hatching gland and in the floor plate, tissues that are affected in cyc mutants. During gastrulation, calreticulin transcripts are found in the dorsal mesendoderm, in the same cells that express the cyc gene. Expression is reduced in cyc mutants and is abolished by the one-eyed pinhead (oep) mutation that is presumed to prevent Nodal signaling. The identification of calreticulin suggests that a differential screen between wild-type and mutant cDNA is a useful approach to reveal regulation of unexpected gene expression in response to cellular signals. genesis 26:86-97, 2000.

Timing and pattern of cell fate restrictions in the neural crest lineage.

The trunk neural crest of vertebrate embryos is a transient collection of precursor cells present along the dorsal aspect of the neural tube. These cells migrate on two distinct pathways and give rise to specific derivatives in precise embryonic locations. One group of crest cells migrates early on a ventral pathway and generates neurons and glial cells. A later-dispersing group migrates laterally and gives rise to melanocytes in the skin. These observations raise the possibility that the appearance of distinct derivatives in different embryonic locations is a consequence of lineage restrictions specified before or soon after the onset of neural crest cell migration. To test this notion, we have assessed when and in what order distinct cell fates are specified during neural crest development. We determined the proportions of different types of precursor cells in cultured neural crest populations immediately after emergence from the neural tube and at intervals as development proceeds. We found that the initial neural crest population was a heterogeneous mixture of precursors almost half of which generated single-phenotype clones. Distinct neurogenic and melanogenic sublineages were also present in the outgrowth population almost immediately, but melanogenic precursors dispersed from the neural tube only after many neurogenic precursors had already done so. A discrete fate-restricted neuronal precursor population was distinguished before entirely separate fate-restricted melanocyte and glial precursor populations were present, and well before initial neuronal differentiation. Taken together, our results demonstrate that lineage-restricted subpopulations constitute a major portion of the initial neural crest population and that neural crest diversification occurs well before overt differentiation by the asynchronous restriction of distinct cell fates. Thus, the different morphogenetic and differentiative behavior of neural crest subsets in vivo may result from earlier cell fate-specification events that generate developmentally distinct subpopulations that respond differentially to environmental cues.

Screen for mutations affecting development of Zebrafish neural crest.

The neural crest provides a useful model to learn how cell fate diversification is regulated during vertebrate development. Our approach is to isolate zebrafish mutations in which the development of neural crest derivatives is disrupted, in order to learn about the underlying genetic mechanisms. We describe a screen in which parthenogenetic diploid embryos are examined both for visible phenotypes and for cellular defects in neural crest-derived sensory neurons recognized immunohistochemically. We present preliminary results from this screen and briefly describe a few representative mutations. We also discuss the general utility of our strategy and comment on the future directions of this approach.

trkC-mediated NT-3 signaling is required for the early development of a subpopulation of neurogenic neural crest cells.

Soon after they segregate from the neural tube, trunk neural crest cells disperse on two spatially and temporally distinct pathways. Only crest cells that migrate early and ventromedially give rise to neurons of the peripheral nervous system. It is also known that neural crest cell-derived populations require appropriate environmental cues early in development in order to generate neurons, and for the subsequent survival of differentiated neurons. We examined whether neurotrophin-3 (NT-3), a survival factor for subsets of peripheral neurons, is also involved in the regulation of neurogenesis by neural crest cells. First, we found that premigratory and migrating neural crest cells on the medial migration pathway of Embryonic Day 2.5 (E 2.5) embryos express mRNAs encoding multiple isoforms of the NT-3 receptor, trkC, as do cells in the neural tube and epithelial dermamyotome. On E4, a subpopulation of neurons in nascent sensory ganglia express trkC message. Second, we demonstrate that trkC mRNA is only expressed in neural crest cell populations that possess neurogenic potential. Third, we show that the presence of NT-3, during the initial development of cultured neural crest cells, is required for neurogenesis by a subpopulation of neurogenic neural crest-derived cells. These results suggest that a subpopulation of neurogenic neural crest cells expresses functional trkC receptors and requires the timely availability of NT-3 for their development before reaching their final embryonic locations. We suggest that developmental heterogeneity exists in the identity and requirements of neural crest cell subsets that harbor neurogenic potential. We also suggest that the "paradoxical" expression of trkC receptors by the somitic dermamyotome may, in fact, play a role in the exclusive development of crest-derived neurogenic precursors on the medial pathway by limiting the availability of NT-3 on the lateral pathway.

Hu neuronal proteins are expressed in proliferating neurogenic cells.

We have utilized immunochemical techniques to investigate the developmental expression of the Hu proteins, a neuron-specific family of RNA binding proteins in vertebrates. Previous work suggests that these proteins may play an important role in neuronal development and maintenance. For the present study, we developed a monoclonal antibody (MAb 16A11) that binds specifically to an epitope present in gene products of all known Hu genes, including HuD, HuC, and Hel-N1. Using brief pulses (1-2 h) of the DNA precursor analog bromodeoxyuridine (BrdU) in conjunction with MAb 16A11, we observed Hu+/BrdU+ cells in nascent sensory and sympathetic ganglia in vivo, and in populations of cultured neural crest cells. In addition, a few Hu+ cells were ambiguously BrdU+ in the neural tube. We conclude that Hu+ cells first appear in avian neurogenic populations immediately before neuronal birthdays in the peripheral nervous system, and at the time of withdrawal from the mitotic cycle in the central nervous system. Consistent with these conclusions, we have also observed neural crest-derived cells that are both Hu+ and in metaphase of the cell cycle. We suggest that Hu proteins function early in neurogenic differentiation.

Retinoic acid selectively promotes the survival and proliferation of neurogenic precursors in cultured neural crest cell populations.

The neural crest produces both neuronal and nonneuronal derivatives in response to a variety of environmental cues. Here, we have analyzed the effects of retinoic acid on the differentiative behavior of quail trunk neural crest cells in vitro. We show that retinoic acid selectively increases neurogenesis in cultured neural crest cell populations, probably by promoting the survival and stimulating the proliferation of neuronal precursors. Our results suggest that neural crest-derived neurogenic precursors are specific targets for retinoic acid in vitro and raise the possibility that retinoic acid promotes the generation of peripheral neurons in vivo.

Modulation of the enkephalinergic phenotype of rat sympathetic neurons by hormonal and transsynaptic mechanisms.

Most sympathetic neurons contain one or more neuropeptides in addition to catecholamines. Although the regulation of catecholamines has been studied extensively, comparatively little is known about the regulation of neuropeptides. Since glucocorticoids and preganglionic innervation regulate catecholaminergic properties in chromaffin cells, we examined the effects of these factors on a co-localized neuropeptide, leucine enkephalin (L-Enk), in adult rat sympathetic neurons in vivo. Lowered serum glucocorticoid levels as a consequence of bilateral adrenalectomy resulted in a reduction of ganglionic L-Enk content that was reversed by exposure of adrenalectomized animals to the synthetic glucocorticoid, dexamethasone. Surgical denervation of the SCG eliminated L-Enk-IR preganglionic fibers and caused a dramatic increase in the number of L-Enk-IR neurons. Inhibition of the enkephalinergic component of the preganglionic innervation by chronic exposure to the opiate receptor antagonist naloxone increases the number of L-Enk-IR cell bodies and total ganglionic L-Enk content. None of the experimental manipulations noticeably altered the number or distribution of NPY-IR neurons, suggesting that the effects of glucocorticoids and the innervation on ganglionic L-Enk levels were specific and not simply an alteration of the biosynthetic state of the cells. These results demonstrate that circulating glucocorticoids and the preganglionic innervation regulate L-Enk levels in sympathetic neurons. Since both glucocorticoid levels and preganglionic activity are known to be altered by stressful stimuli, acute regulation of sympathetic L-Enk levels may constitute an important component of the autonomic response to stress.

Developmental regulation of leucine-enkephalin expression in adrenal chromaffin cells by glucocorticoids and innervation.

Most catecholaminergic cells derived from the sympathoadrenal lineage of the neural crest contain one or more neuropeptides. Although a great deal is known about the development and regulation of catecholaminergic properties in these cells, relatively little is known about the developmental control of their neuropeptidergic properties. We have investigated the possible role of glucocorticoids and preganglionic innervation in the regulation of leucine-enkephalin (L-Enk) expression in cultures of embryonic and neonatal adrenal chromaffin cells and in mature chromaffin cells in vivo. Exposure of embryonic and neonatal chromaffin cells to the synthetic glucocorticoid dexamethasone increases L-Enk content. Neonatal chromaffin cells grown in medium containing elevated levels of potassium to mimic depolarization also exhibited increased L-Enk levels. The depolarization-induced increase in L-Enk was selectively inhibited by treatment with the enkephalin analog [D-Ala, d-Leu]-enkephalin to mimic the enkephalinergic component of the preganglionic innervation. Denervation of the adrenal gland in vivo resulted in a dramatic increase in L-enk expression that could be partially mimicked by selectively blocking enkephalinergic transmission with administration of the opiate receptor antagonist naloxone. Taken together with the developmental time course and pattern of L-Enk expression in vivo, our results suggest that glucocorticoids and the preganglionic innervation regulate the developmental expression of this peptide in adrenal chromaffin cells and therefore participate in the generation of the mature neurochemical phenotypes present in the adrenal medulla. Further, in adult chromaffin cells similar factors appear to regulate the expression of L-Enk, which could in turn participate in physiological responses to stress.

Segregation and early dispersal of neural crest cells in the embryonic zebrafish.

We have exploited our ability to visualize and follow individual cells in situ, in the living embryo, to study the development of trunk neural crest in the embryonic zebrafish. In most respects, the development of zebrafish trunk neural crest is similar to the development of trunk neural crest in other species: zebrafish trunk neural crest cells segregate from the dorsal neural keel in a rostrocaudal sequence, migrate ventrally along two pathways, and give rise to neurons of the peripheral nervous system, Schwann cells, and pigment cells. However, some aspects of the development of zebrafish trunk neural crest differ from those of other vertebrates: zebrafish trunk neural crest cells are significantly larger and fewer in number than those in avian embryos and the locations of their migratory pathways are slightly different. This initial description of neural crest development in the zebrafish embryo provides the foundation for future experimental studies.

Asynchronous appearance and topographic segregation of neuropeptide-containing cells in the developing rat adrenal medulla.

The developmental expression of neuropeptide Y (NPY) and leucine-enkephalin (L-Enk) was examined in embryonic, early postnatal, and adult chromaffin cells with double- and triple-label immunocytochemical techniques and compared to the expression of immunoreactivity for tyrosine hydroxylase (TH) and phenylethanolamine N-methyltransferase (PNMT). In addition, the establishment of preganglionic innervation was assessed by labeling for choline acetyltransferase (ChAT) and L-Enk. NPY-IR was detectable on embryonic (E) day 15 in a clustered subpopulation of TH-IR cells. L-Enk and PNMT-IR cells were initially present on E16 in a separate nonclustered population of TH-IR cells. By late embryonic development, twice as many TH-IR cells expressed NPY and 4 times as many expressed L-Enk as in the adult. In contrast to early embryonic development, NPY-IR was evident in both the clustered and nonclustered subpopulation of TH-IR cells at this time. The proportion of NPY-IR chromaffin cells decreased to adult values during the first postnatal week at the time when obviously clustered TH-IR cells were no longer observed. The embryonic rise in the proportion of L-Enk-IR cells correlates with the developmental increase in glucocorticoid production, while the postnatal decrease corresponds to the appearance of ChAT-IR in the preganglionic innervation of the adrenal medulla. These results indicate that NPY and L-Enk are expressed at different times and in different subpopulations of cells in the embryonic adrenal. Further, the observation that peptide expression by chromaffin cells undergoes marked changes during development raises the possibility that a number of factors including developmental history, environmental signals and impulse activity play a role in the regulation of neuropeptide expression in sympathoadrenal derivatives of the neural crest.