Sequence and expression pattern of ziro7, a novel, divergent zebrafish iroquois homeobox gene.

We have isolated the zebrafish ziro7 gene, a novel, divergent member of the Iroquois family. ziro7 is expressed at early epiboly stages in the dorsal half of the zebrafish embryo, with a higher level in the dorso-lateral margin. From mid-gastrulation stages onward, ziro7 is expressed in a large transversal stripe in the future neural plate, which subsequently divides into thinner stripes located in the diencephalon, midbrain and hindbrain.     

Growth cone guidance in the zebrafish central nervous system.

The accessibility and simplicity of the zebrafish embryo have allowed researchers to make a detailed characterization of pathfinding by identifiable growth cones. The growth cones follow precise cell-specific pathways to their targets. Analyses of pathfinding in mutant and experimentally manipulated wild type embryos have shown that growth cones accomplish this by interacting with specific cellular cues in their environment, many of which are likely to be redundant.     

Olfactomedin-2 mediates development of the anterior central nervous system and head structures in zebrafish

Olfactomedins comprise a diverse family of secreted glycoproteins, which includes noelin, tiarin, pancortin and gliomedin, implicated in development of the nervous system, and the glaucoma-associated protein myocilin. Here we show in zebrafish that olfactomedin-2 (OM2) is a developmentally regulated gene, and that knockdown of protein expression by morpholino antisense oligonucleotides leads to perturbations of nervous system development. Interference with OM2 expression results in impaired development of branchiomotor neurons, specific disruption of the late phase branchiomotor axon guidance, and affects development of the caudal pharyngeal arches, olfactory pits, eyes and optic tectum. Effects of OM2 knockdown on eye development are likely associated with Pax6 signaling in developing eyes, as Pax6.1 and Pax6.2 mRNA expression patterns are altered in the eyes of OM2 morphants. The specific absence of most cartilaginous structures in the pharyngeal arches indicates that the observed craniofacial phenotypes may be due to perturbed differentiation of cranial neural crest cells. Our studies show that this member of the olfactomedin protein family is an important regulator of development of the anterior nervous system.     

Expression of cadherin10, a type II classic cadherin gene, in the nervous system of the embryonic zebrafish

Cadherins are cell surface adhesion molecules that play important roles in development of tissues and organs. In this study, we analyzed expression pattern of cadherin10, a member of the type II classic cadherin subfamily, in the embryonic zebrafish using in situ hybridization methods. cadherin10 message (cdh10) is first and transiently expressed by the notochord. In the developing nervous system, cdh10 was first detected in a subset of the cranial ganglia, then in restricted brain regions and neural retina. As development proceeds, cdh10 expression domain and/or expression levels increased in the embryonic nervous system. Our results show that cdh10 expression in the zebrafish developing nervous system is both spatially and temporally regulated.     

Development of axon pathways in the zebrafish central nervous system

The zebrafish has a number of distinct advantages as an experimental model in developmental biology. For example, large numbers of embryos can be generated in each lay, development proceeds rapidly through a very precise temporal staging which exhibits minimal batch-to-batch variability, embryos are transparent and imaging of wholemounts negates the need for tedious histological preparation while preserving three-dimensional spatial relationships. The zebrafish nervous system is proving a convenient model for studies of axon guidance because of its small size and highly stereotypical trajectory of axons. Moreover, a simple scaffold of axon tracts and nerves is established early and provides a template for subsequent development. The ease with which this template can be visualized as well as the ability to spatially resolve individual pioneer axons enables the role of specific cell-cell and molecular interactions to be clearly deciphered. We describe here the morphology and development of the earliest axon pathways in the embryonic zebrafish central nervous system and highlight the major questions that remain to be addressed with regard to axon guidance.     

Compartmentalized expression of zebrafish ten-m3 and ten-m4, homologues of the Drosophila ten(m)/odd Oz gene, in the central nervous system.

Zebrafish ten-m3 and ten-m4 encode proteins highly similar to the product of Drosophila pair-rule gene ten(m)/odd Oz (odz). Their products contain eight epidermal growth factor (EGF)-like repeats that resemble mostly those of the extracellular matrix molecule tenascin. During segmentation period, ten-m3 is expressed in the somites, notochord, pharyngeal arches, and the brain, while expression of ten-m4 is mainly restricted to the brain. In the developing brain, ten-m3 and ten-m4 expression delineates several compartments. Interestingly, ten-m3 and ten-m4 show expression patterns complementary to each other in the developing forebrain and midbrain along both rostrocaudal and dorsoventral axes, depending on developmental stages and locations.     

Dual function of polysialic acid during zebrafish central nervous system development.

Polysialic acid (PSA), a carbohydrate epitope attached to the neural cell adhesion molecule, serves as a modulator of axonal interactions during vertebrate nervous system development. We have used PSA-specific antibodies and whole-mount immunocytochemistry to describe the spatiotemporal expression pattern of PSA during zebrafish central nervous system development. PSA is transiently expressed on all cell bodies and, except for the posterior commissure, it is not found on axons. Floorplate cells in the spinal cord and hindbrain strongly express PSA throughout development. Enzymatic removal of PSA leads to a defasciculated growth pattern of the posterior commissure and also affects distinct subsets of commissural axons in the hindbrain, which fail to cross the midline. Whereas the disordered growth pattern of hindbrain commissures produced by PSA-removal could be mimicked by injections of soluble PSA, the growth of axons in the posterior commissure was unaffected by such treatment. These results suggest that there are distinct mechanisms for PSA action during axon growth and pathfinding in the developing zebrafish CNS.     

Transgenic zebrafish expressing fluorescent proteins in central nervous system neurons

Zebrafish is a powerful model system for investigations of vertebrate neural development. The animal has also become an important model for studies of neuronal function. Both in developmental and functional studies, transgenic zebrafish expressing fluorescent proteins in central nervous system neurons have been playing important roles. We review here the methods for producing transgenic zebrafish. Recent advances in transposon- or bacterial artificial chromosome-based transgenesis greatly facilitate the creation of useful lines. We also present our study on alx -positive neurons to reveal how transgenic zebrafish expressing fluorescent proteins in a specific class of neurons can be used to investigate their development and function.     

Cloning of zebrafish vsx1: Expression of a paired-like homeobox gene during CNS development

vsx1 is a homeobox gene encoding a paired-type homeodomain and a CVC domain that was originally cloned from an adult goldfish retinal library. We previously reported the spatiotemporal expression pattern of vsx1in the adult and developing retina of zebrafish and goldfish, and we suggested that vsx1 plays a role in determining the cell fate and maintenance of retinal interneurons. Other related genes encoding a CVC domain, such as vsx2 (alx) and chx10, are expressed both within and outside the retina during development. In this study, we report the cloning of zebrafish vsx1 and its developmental expression in both retinal and nonretinal regions of the CNS in zebrafish embryos. vsx1expression was detected in a subset of hindbrain and spinal cord neurons before it was expressed in the retina. At about the same time that retinal expression began, the level of vsx1 was decreased in the spinal cord. The expression of vsx1 was progressively restricted, and eventually it was detected only in the inner nuclear layer (INL) of the developing retina. The combined expression patterns of teleost vsx1 and vsx2 (alx) during early zebrafish development encompasses the expression pattern observed for murine Chx10, and indicates a partitioning of function for CVC genes in lower vertebrates. Dev. Genet. 23:128–141, 1998. © 1998 Wiley-Liss, Inc.     

Expression of a homeobox gene product in normal and mutant zebrafish embryos: evolution of the tetrapod body plan

An antibody was used to detect antigens in zebrafish that appear to be homologous to the frog homeodomain-containing protein XlHbox 1. These antigens show a restricted expression in the anteroposterior axis and an anteroposterior gradient in the pectoral fin bud, consistent with the distribution of XlHbox 1 protein in frog and mouse embryos. In the somitic mesoderm, a sharp anterior limit of expression coincides exactly with the boundary between somites 4 and 5, and the protein level fades out posteriorly. A similar, graded expression of the antigen is seen within the series of Rohon-Beard sensory neurons of the CNS. We also immunostained the mutant spt-1 ('spadetail'), in which the trunk mesoderm is greatly depleted and disorganized in the region of XlHbox 1 expression. The defects stem from misdirected cell movements during gastrulation, but nervertheless, newly recruited cells that partially refill the trunk mesoderm express the antigen within the normal span of the anteroposterior axis. This finding suggests that the mutation does not delete positional information required for activation of the XlHbox 1 gene.     

Cloning and developmental expression of a zebrafish meis2 homeobox gene

We show here that a zebrafish meis2 gene homolog has a dynamic expression pattern in the developing mesoderm and central nervous system. Meis family homeodomain proteins are known to act as cofactors with other homeodomain proteins. We find expression of meis2.1 in the developing zebrafish hindbrain and somites, correlating with reported sites of zebrafish hox gene expression, as well as in presumptive cerebellum, midbrain, retina and ventral forebrain. The expression pattern shares some, but not all, features with that of murine Meis2.     

Tissue factor pathway inhibitor-2: A novel gene involved in zebrafish central nervous system development

Tissue factor pathway inhibitor-2 (Tfpi-2) is an important serine protease inhibitor in the extracellular matrix (ECM), but its precise physiological significance remains unknown. This work is part of a series of studies intended to investigate functional roles of Tfpi-2 and explore the underlying molecular mechanisms. First, we cloned and identified zebrafish Tfpi-2 (zTfpi-2) as an evolutionarily conserved protein essential for zebrafish development. We also demonstrated that ztfpi-2 is mainly expressed in the central nervous system (CNS) of zebrafish, and embryonic depletion of ztfpi-2 caused severe CNS defects. In addition, changes of neural markers, including pax2a, egr2b, huC, ngn1, gfap and olig2, confirmed the presence of developmental abnormalities in the relevant regions of ztfpi-2 morphants. Using microarray analysis, we found that members of the Notch pathway, especially her4 and mib, which mediate lateral inhibition in CNS development, were also downregulated. Intriguingly, both her4 and mib were able to partially rescue the ztfpi-2 morphant phenotype. Furthermore, Morpholino knockdown of ztfpi-2 resulted in upregulation of neuronal markers while downregulation of glial markers, providing evidence that the Notch pathway is probably involved in ztfpi-2-mediated CNS development.