Developmentally-regulated expression of mNapor encoding an apoptosis-induced ELAV-type RNA binding protein.

Proteins with RNA recognition motifs (RRMs) participate in many aspects of RNA metabolism, and some of them are required for the accomplishment of normal development. The neuroblastoma apoptosis-related RNA binding protein (NAPOR) is an ELAV-type RNA-binding protein with three characteristic RNP2/RNP1-type RRMs, which we identified as a gene induced during apoptosis of neuroblastoma cells. Here we isolated and characterized the cDNA for mNapor, the mouse homolog of NAPOR. The mNapor encodes mRNA sharing striking homology with that of NAPOR, not only in its open reading frame (98.5%) but also in the 3'-untranslated region (80.1%), and is mapped to chromosome 2 A2-A3, a region syntenic to the human NAPOR locus. In situ hybridization analysis revealed that the expression pattern of mNapor is spatially and temporally coincident with the occurrence of programmed cell death, suggesting its involvement in the development of the central nervous system in which apoptosis plays a crucial role.     

Early posterior/ventral fate specification in the vertebrate embryo

Slit is expressed in the midline of the central nervous system both in vertebrates and invertebrates. In Drosophila, it is the midline repellent acting as a ligand for the Roundabout (Robo) protein, the repulsive receptor which is expressed on the growth cones of the commissural neurons. We have isolated cDNA fragments of the zebrafish slit2 and slit3 homologues and found that both genes start to be expressed by the midgastrula stage well before the axonogenesis begins in the nervous system, both in the axial mesoderm, and slit2 in the anterior margin of the neural plate and slit3 in the polster at the anterior end of the prechordal mesoderm. Later, expression of slit2 mRNA is detected mainly in midline structures such as the floor plate cells and the hypochord, and in the anterior margins of the neural plates in the zebrafish embryo, while slit3 expression is observed in the anterior margin of the prechordal plate, the floorplate cells in the hindbrain, and the motor neurons both in the hindbrain and the spinal cord. To study the role of Slit in early embryos, we overexpressed Slit2 in the whole embryos either by injection of its mRNA into one-cell stage embryos or by heat-shock treatment of the transgenic embryos which carries the slit2 gene under control of the heat-shock promoter. Overexpression of Slit2 in such ways impaired the convergent extension movement of the mesoderm and the rostral migration of the cells in the dorsal diencephalon and resulted in cyclopia. Our results shed light on a novel aspect of Slit function as a regulatory factor of mesodermal cell movement during gastrulation.     

Cloning and embryonic expression of zebrafish neuropilin genes

Neuropilin (Nrp), a cell surface receptor for class 3 semaphorins and for certain heparin forms of vascular endothelial growth factors, functions in many biological processes including axon guidance, neural cell migration and angiogenesis in the development of the nervous system and the cardiovascular system. To understand the role of neuropilins in zebrafish embryogenesis, we have cloned three zebrafish neuropilin homologues, nrp1b, nrp2a and nrp2b. Based on synteny, zebrafish nrp1b and the previously cloned nrp1a are orthologous to human nrp1, and zebrafish nrp2a and 2b orthologous to human nrp2. We have characterized the expression patterns of these four zebrafish neuropilin genes in wild type embryos from the beginning of somitogenesis to 48 h post-fertilization. Zebrafish nrp1a is expressed in the neural tube including telencephalon, epithalamus, cells along the axonal trajectory of the posterior commissure and the medial longitudinal fascicle, hindbrain neurons, vagus motor neurons and spinal motoneurons. Zebrafish nrp1b is expressed in the nose, the cranial neural crest cell (NCC) derived tissue underlying the hypothalamus, endothelial precursors and the trunk and tail vasculature. Zebrafish nrp2a is expressed in telencephalon, anterior pituitary, oculomotor and trochlear motor neurons, cells along the supra-optic and posterior commissures, hindbrain rhombomere 1, hindbrain neurons, cranial NCCs and sclerotome. Zebrafish nrp2b is expressed in telencephalon, thalamus, hypothalamus, epiphysis, cells along the anterior and posterior commissures, post-optic and supra-optic commissures and the olfactory axonal trajectory, hindbrain neurons, cranial NCCs, somites and spinal cord neurons.     

Characterization of the retinoic acid receptor genes raraa, rarab and rarg during zebrafish development

Retinoic acid signaling is important for patterning the central nervous system, paired appendages, digestive tract, and other organs. To begin to investigate retinoic acid signaling in zebrafish, we determined orthologies between zebrafish and tetrapod retinoic acid receptors (Rars) and examined the expression patterns of rar genes during embryonic development. Analysis of phylogenies and conserved syntenies showed that the three cloned zebrafish rar genes include raraa and rarab, which are co-orthologs of tetrapod Rara, and rarg, which is the zebrafish ortholog of tetrapod Rarg. We did not, however, find an ortholog of Rarb. RNA in situ hybridization experiments showed that rarab and rarg, are maternally expressed. Zygotic expression of raraa occurs predominantly in the hindbrain, lateral mesoderm, and tailbud. Zygotic expression of rarab largely overlaps that of raraa, except that in later stages rarab is expressed more broadly in the brain and in the pectoral fin bud and pharyngeal arches. Zygotic expression of zebrafish rarg also overlaps the other two genes, but it is expressed more strongly in the posterior hindbrain beginning in late somitogenesis as well as in neural crest cells in the pharyngeal arches. Thus, these three genes have largely overlapping expression patterns and a few gene-specific expression domains. Knowledge of these expression patterns will guide the interpretation of the roles these genes play in development.     

Expression of protocadherin 18 in the CNS and pharyngeal arches of zebrafish embryos

Here, we report the results of molecular cloning and expression analyses of a non-clustered protocadherin (pcdh), pcdh18 in zebrafish embryos. The predicted zebrafish pcdh18 protein shows 6566% identity and 7879% homology with its mammalian and Xenopus counterparts. It has a Disabled-1 binding motif in its cytoplasmic domain, which is characteristic of pcdh18. Zebrafish embryos expressed pcdh18 by the early gastrula stage, 6 h post-fertilization (hpf), in their animal cap but not in the germ ring or the shield. pcdh18 was expressed in the neural tube and the central nervous system (CNS) from 12 hpf. Some populations of cells in the lateral neural tube and spinal cord of 1218 hpf embryos expressed pcdh18, but expression in these cells disappeared by 24 hpf. The hindbrain of embryos at 2456 hpf expressed pcdh18 in cells closely adjacent to the rostral and caudal rhombomeric boundaries in a thread-like pattern running in the dorsoventral direction. The pcdh18-positive cells were localized in the ventral part of the hindbrain at 24 hpf and in the dorsal part from 36 hpf. pcdh18 was also expressed in the telencephalon, diencephalon, tectum, upper rhombic lip, retina and otic vesicle. Expression in the CNS decreased markedly before hatching. Pharyngeal arch primordia, arches, jaws and gills expressed pcdh18, and the molecule was also expressed in some endodermal cells in late embryos.     

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.     

The biphasic expression of IMP/Vg1-RBP is conserved between vertebrates and Drosophila

The human IGF-II mRNA-binding proteins (IMPs) 1-3, and their Xenopus homologue Vg1 RNA-binding protein (Vg1-RBP) are RNA-binding proteins implicated in mRNA localization and translational control in vertebrate development. We have sequenced the Drosophila homologue (dIMP) of these genes, and examined its expression pattern in Drosophila embryos by in situ hybridization. The study shows that dIMP exhibits a biphasic expression pattern. In the early stages of development, a maternal pool of dIMP mRNA is evenly distributed in the embryo and degraded by the end of stage 4. Expression reappears in the developing central nervous system, where dIMP is expressed throughout neurogenesis. In addition, dIMP is present in the pole cells.     

CEPU-1 expression in the early embryonic chick brain

We describe the expression pattern of CEPU-1, a cell adhesion molecule of the immunoglobulin superfamily, in the early chick embryo brain. An initially broad domain of expression, encompassing forebrain, midbrain and anterior hindbrain, is subsequently narrowed down to a ring-shaped domain at the midbrain-hindbrain boundary, co-localizing precisely with the expression of Wnt1 at the isthmus. In addition, CEPU-1 is expressed in the dorsal aspect of rhombomere 4 and its emigrating neural crest cells. Later in development, we also find CEPU-1 expression in other parts of the developing nervous system such as sensory ganglia and in the ventral aspect of forebrain, midbrain and hindbrain.     

微小染色体维系蛋白3基因在斑马鱼早期胚胎发育过程中的表达

目的:制备地高辛标记的微小染色体维系蛋白3(MCM3)基因的RNA探针,研究MCM3在斑马鱼早期发育中的时空表达。方法:收集并固定受精后24 h时期的野生型斑马鱼胚胎,提取总RNA,制备DIG标记的MCM3 RNA反义探针,整胚原位杂交,研究MCM3在斑马鱼胚胎早期发育过程的表达。结果:斑马鱼的MCM3氨基酸序列与小鼠、人具有高度同源性,通过不同时期胚胎的原位杂交,发现MCM3在早期发育过程中普遍性表达,胚胎受精后0~2 hMCM3在增殖性区域泛表达,受精后14~22 h在中枢神经系统、发育未成熟的眼部、体节及增殖性区域表达,受精后24 h在血液、中枢神经、翼板中脑、视觉盖及增殖性区域表达,受精后48 h在头部及肛门增殖性区域表达。结论:明确了MCM3在斑马鱼胚胎发育过程中的表达模式,证明其与早期斑马鱼发育细胞增殖密切相关,为研究该基因功能提供了一定的理论基础。     

Retinoic acid induces changes in the localization of homeobox proteins in the antero-posterior axis of Xenopus laevis embryos.

We have studied the localization of the proteins of Xeb1 and Xeb2, two homeobox (hbx)-containing genes that are expressed during the early development of Xenopus laevis. Both proteins are expressed in juxtaposed and partially overlapping domains along the antero-posterior axis of Xenopus laevis embryos, with clearly defined anterior boundaries. Xeb2 is predominantly expressed in the caudal region of the hindbrain, whereas the Xeb1 protein is located in the most rostral region of the spinal cord. Furthermore, both proteins are expressed in single cells dispersed in the lateral flanks of the embryo in positions that correlate with the expression domains in the neural tube. We suggest that these cells are migratory neural crest cells that have acquired positional information in the neural tube prior to migration. The Xeb2 protein was also detected in the most posterior branchial arches and the pronephros. In stage 45 embryos, nuclei of the IX-X cranial ganglia, the lung buds and cells spreading into the forelimb rudiment express the Xeb2 antigen. The Xeb1 protein was also detected in the lung buds and the forelimb rudiment. To examine the effect of retinoic acid on expression, gastrula embryos were treated with all-trans retinoic acid (RA). Increasing concentrations of RA caused progressive truncation of anterior structures. The most severely affected embryos lacked eyes, nasal pits, forebrain, midbrain and otic vesicles, and the anterior boundary of the hindbrain seemed to be displaced rostrally. This alteration correlates with a progressive displacement of the anterior boundary of the expression domain of Xeb2. On the other hand, 10(-6) M RA induces an ectopic site of Xeb1 expression at the anterior end of the central nervous system, located just anterior to the extended domain of Xeb2 whereas expression in the spinal cord remains unaffected.     

FGF3 and FGF8 mediate a rhombomere 4 signaling activity in the zebrafish hindbrain

The segmentation of the vertebrate hindbrain into rhombomeres is highly conserved, but how early hindbrain patterning is established is not well understood. We show that rhombomere 4 (r4) functions as an early-differentiating signaling center in the zebrafish hindbrain. Time-lapse analyses of zebrafish hindbrain development show that r4 forms first and hindbrain neuronal differentiation occurs first in r4. Two signaling molecules, FGF3 and FGF8, which are both expressed early in r4, are together required for the development of rhombomeres adjacent to r4, particularly r5 and r6. Transplantation of r4 cells can induce expression of r5/r6 markers, as can misexpression of either FGF3 or FGF8. Genetic mosaic analyses also support a role for FGF signaling acting from r4. Taken together, our findings demonstrate a crucial role for FGF-mediated inter-rhombomere signaling in promoting early hindbrain patterning and underscore the significance of organizing centers in patterning the vertebrate neural plate.     

Expression of the zebrafish Staufen gene in the embryo and adult

Staufen, a double stranded RNA binding protein, has been shown to be involved in creating and maintaining cellular asymmetry in the Drosophila oocyte, neuroblast, and mammalian neuron. Staufen binds to the 3' UTR of specific mRNAs and acts in their localization and anchoring to various subcellular domains. Staufen's molecular interactions during development have been limited to investigations in Drosophila melanogaster. Since a vertebrate Staufen has not been studied in a developmental system, the aim of this study was to clone and characterize a staufen orthologue gene in the vertebrate developmental model, zebrafish. The zebrafish staufen-like sequence shows a 64% homology to the human staufen with a 81.2% homology in the highly conserved double stranded RNA binding domain (dsRBDs). Staufen maps on the LN54 radiation hybrid panel to linkage group 6, 16.25 cR from Z265 between fb22h06 and fi16e01. Northern blot and in situ hybridization showed that staufen is expressed both maternally and zygotically. Zygotically expressed staufen is localized to the developing nervous system and at 24 h is highly concentrated in the subventricular zone of the developing brain. Maternally expressed staufen is dispersed in the mature oocyte and early embryo. In the adult, staufen is expressed in specific brain nuclei, the testis, neurons and Leydig cells.