Slit proteins prevent midline crossing and determine the dorsoventral position of major axonal pathways in the mammalian forebrain.

We report that Slit proteins, a family of secreted chemorepellents, are crucial for the proper development of several major forebrain tracts. Mice deficient in Slit2 and, even more so, mice deficient in both Slit1 and Slit2 show significant axon guidance errors in a variety of pathways, including corticofugal, callosal, and thalamocortical tracts. Analysis of multiple pathways suggests several generalizations regarding the functions of Slit proteins in the brain, which appear to contribute to (1) the maintenance of dorsal position by prevention of axonal growth into ventral regions, (2) the prevention of axonal extension toward and across the midline, and (3) the channeling of axons toward particular regions.     

Alteration of the neuronal and glial cell profiles in Neu1-deficient zebrafish

Glycoconjugate Journal - Neu1 is a glycosidase that releases sialic acids from the non-reducing ends of glycoconjugates, and its enzymatic properties are conserved among vertebrates. Recently,...     

Regulatory gene expression patterns reveal transverse and longitudinal subdivisions of the embryonic zebrafish forebrain

To shed light on the organization of the rostral embryonic brain of a lower vertebrate, we have directly compared the expression patterns of dlx, fgf, hh, hlx, otx, pax, POU, winged helix and wnt gene family members in the fore- and midbrain of the zebrafish. We show that the analyzed genes are expressed in distinct transverse and longitudinal domains and share expression boundaries at stereotypic positions within the fore- and midbrain. Some of these shared expression boundaries coincide with morphological landmarks like the pathways of primary axon tracts. We identified a series of eight transverse diencephalic domains suggestive of neuromeric subdivisions within the rostral brain. In addition, we identified four molecularly distinct longitudinal subdivisions and provide evidence for a strong bending of the longitudinal rostral brain axis at the cephalic flexure. Our data suggest a strong conservation of early forebrain organization between lower and higher vertebrates.     

Scube2 mediates Hedgehog signalling in the zebrafish embryo

The Hedgehog family of secreted morphogens specifies the fate of a large number of different cell types within invertebrate and vertebrate embryos, including the muscle cell precursors of the embryonic myotome of zebrafish. Formation of Hedgehog-sensitive muscle fates is disrupted within homozygous zebrafish mutants of the "you"-type class, the majority of which disrupt components of the Hedgehog (HH) signal transduction pathway. We have undertaken a phenotypic and molecular characterisation of one of these mutants, you, which we show results from mutations within the zebrafish orthologue of the mammalian gene scube2. This gene encodes a member of the Scube family of proteins, which is characterised by several protein motifs including EGF and CUB domains. Epistatic and molecular analyses position Scube2 function upstream of Smoothened (Smoh), the signalling component of the HH receptor complex, suggesting that Scube2 may act during HH signal transduction prior to, or during, receipt of the HH signal at the plasma membrane. In support of this model we show that scube2 has homology to cubilin, which encodes an endocytic receptor involved in protein trafficking suggesting a possible mode of function for Scube2 during HH signal transduction.     

Hedgehog signaling is required for adult blood stem cell formation in zebrafish embryos

Studies with embryonic explants and embryonic stem cells have suggested a role for Hedgehog (Hh) signaling in hematopoiesis. However, targeted deletion of Hh pathway components in the mouse has so far failed to provide in vivo evidence. Here we show that zebrafish embryos mutant in the Hh pathway or treated with the Hh signaling inhibitor cyclopamine display defects in adult hematopoietic stem cell (HSC) formation but not in primitive hematopoiesis. Hh is required in the trunk at three consecutive stages during vascular development: for the medial migration of endothelial progenitors of the dorsal aorta (DA), for arterial gene expression, and for the formation of intersomitic vessel sprouts. Interference with Hh signaling during the first two stages also interferes with HSC formation. Furthermore, HSC and DA formation also share Vegf and Notch requirements, which further distinguishes them from primitive hematopoiesis and underlines their close relationship during vertebrate development.     

Expanded expression of Sonic Hedgehog in Astyanax cavefish: multiple consequences on forebrain development and evolution

Ventral midline Sonic Hedgehog (Shh) signalling is crucial for growth and patterning of the embryonic forebrain. Here, we report how enhanced Shh midline signalling affects the evolution of telencephalic and diencephalic neuronal patterning in the blind cavefish Astyanax mexicanus, a teleost fish closely related to zebrafish. A comparison between cave- and surface-dwelling forms of Astyanax shows that cavefish display larger Shh expression in all anterior midline domains throughout development. This does not affect global forebrain regional patterning, but has several important consequences on specific regions and neuronal populations. First, we show expanded Nkx2.1a expression and higher levels of cell proliferation in the cavefish basal diencephalon and hypothalamus. Second, we uncover an Nkx2.1b-Lhx6-GABA-positive migratory pathway from the subpallium to the olfactory bulb, which is increased in size in cavefish. Finally, we observe heterochrony and enlarged Lhx7 expression in the cavefish basal forebrain. These specific increases in olfactory and hypothalamic forebrain components are Shh-dependent and therefore place the telencephalic midline organisers in a crucial position to modulate forebrain evolution through developmental events, and to generate diversity in forebrain neuronal patterning.     

Interplay of pu.1 and gata1 determines myelo-erythroid progenitor cell fate in zebrafish

The zebrafish is a powerful model system for investigating embryonic vertebrate hematopoiesis, allowing for the critical in vivo analysis of cell lineage determination. In this study, we identify zebrafish myeloerythroid progenitor cells (MPCs) that are likely to represent the functional equivalent of mammalian common myeloid progenitors. Utilizing transgenic pu.1-GFP fish, real-time MPC differentiation was correlated with dynamic changes in cell motility, morphology, and gene expression. Unlike mammalian hematopoiesis, embryonic zebrafish myelopoiesis and erythropoiesis occur in anatomically separate locations. Gene knockdown experiments and transplantation assays demonstrated the reciprocal negative regulation of pu.1 and gata1 and their non-cell-autonomous regulation that determines myeloid versus erythroid MPC fate in the distinct blood-forming regions. Furthermore, forced expression of pu.1 in the bloodless mutant cloche resulted in myelopoietic rescue, providing intriguing evidence that this gene can function in the absence of some stem cell genes, such as scl, in governing myelopoiesis.     

Dynamic expression of the Robo ligand Slit2 in bone marrow cell populations

The bone marrow (BM) niche is essential for lifelong hematopoietic stem cell (HSC) maintenance, proliferation and differentiation. Several BM cell types, including osteoblast lineage cells (OBC), mesenchymal stem cells (MSC) and endothelial cells (EC) have been implicated in supporting HSC location and function, but the relative importance of these cell types and their secreted ligands remain controversial. We recently found that the cell surface receptors Robo4 and CXCR4 cooperate to localize HSC to BM niches. We hypothesized that Slit2, a putative ligand for Robo4, cooperates with the CXCR4 ligand SDF1 to direct HSC to specific BM niche sites. Here, we have isolated OBC, MSC and EC by flow cytometry and determined their frequency within the bone marrow and the relative mRNA levels of Slit2, SDF1 and Robo4. We found that expression of Slit2 and SDF1 were dynamically regulated in MSC and OBC-like populations following radiation, while Robo4 expression was restricted to EC. Radiation also significantly affected the cellularity and frequency of both the non-adherent and adherent cells within the BM stroma. These data support a physiological role for Slit2 in regulating the dynamic function of Robo-expressing cells within BM niches at steady state and following radiation.     

Chemorepulsion of neuronal migration by Slit2 in the developing mammalian forebrain.

Newborn cerebral cortical neurons migrate along radial glia to the cortical plate. Experiments using a collagen gel assay revealed that the choroid plexus repelled cerebral cortical neurons and olfactory interneuron precursors, which were mimicked by Neuro-2A cells. Fractionation of Neuro-2A-conditioned medium identified a protein of 190 kDa, equivalent to full-length Slit proteins. Indeed, it cross-reacted with an antibody against Slit2, suggesting that it is either Slit2 or another Slit protein. Further, Slit2, expressed in COS cells, repelled cerebral cortical neurons and olfactory interneuron precursors. Thus, Slit2, which is expressed by the choroid plexus and the septum, acts as a chemorepulsive factor for neuronal migration. These results suggest chemorepulsion as a guidance mechanism for neuronal migration in the developing forebrain.     

Hedgehog signaling patterns the outgrowth of unpaired skeletal appendages in zebrafish

Background  

Little is known about the control of the development of vertebrate unpaired appendages such as the caudal fin, one of the key morphological specializations of fishes. Recent analysis of lamprey and dogshark median fins suggests the co-option of some molecular mechanisms between paired and median in Chondrichthyes. However, the extent to which the molecular mechanisms patterning paired and median fins are shared remains unknown.     

Aminoacyl-histidine dipeptides in the glial cells of the adult rabbit forebrain

The mammalian nervous system contains high amounts of the aminoacyl-histidine dipeptides carnosine and homocarnosine. In the brain, they prevalently occur mainly in glial and ependymal cells, their role(s) still remaining obscure. In vitro studies indicate that these molecules exert diverse protective effects, and in vivo they are frequently associated with extracellular fluid compartments. Recently, carnosine-like immunoreactivity has been found in the subependymal layer (SEL) of adult rodents, a region endowed with persistent cell proliferation and migration. Unlike rodents, the SEL of the rabbit has a persistent olfactory ventricle. We show here that the morphologic organization of the SEL is different in these species, with particular reference to the glial/non glial cell compartments. The distribution of carnosine-like immunoreactivity in the rabbit displays some differences only within the SEL, which could be linked to its arrangement and compartmentalization.     

Migration pathways and behavior of glial progenitors in the postnatal forebrain.

The postnatal subventricular zone (SVZ) gives rise to many of the glial cells in the forebrain. We investigated migration pathways and dynamics of motility of progenitors from the neonatal rat forebrain SVZ by labeling progenitors in vivo with a retrovirus encoding green fluorescent protein (GFP) and then visualizing the dynamics of their movements by time-lapse fluorescence microscopy in slice preparations. Cells within the dorso-lateral SVZ moved in an apparently undirected fashion, but migrated in a directed manner after emigration into white matter and cortex, displaying both radial and tangential migration. Cells in the striatal-SVZ, a region of SVZ along the lateral wall of the ventricle, migrated parallel to the ventricular surface, and entered the striatum, where they migrated both perpendicular and parallel to the ventricular surface. Sometimes, cells in all these regions reversed their migration back toward the SVZ. Migration involved either elongation of the leading process followed by a quick translocation of the nucleus or a synchronous advancement of the nucleus and the leading process. Two distinct patterns of cellular changes were observed at orthogonal turning: one involves the cessation of cell body movement and the formation of a new leading process, and the other involves continuous cell body movement and bending of the leading process. The dynamic behavior of progenitors may reflect local tissue architecture and contribute to the widespread distribution of glia.