NBP, a zebrafish homolog of human Kank3, is a novel Numb interactor essential for epidermal integrity and neurulation.

Numb is an adaptor protein implicated in diverse basic cellular processes. Using the yeast-two hybrid system we isolated a novel Numb interactor in zebrafish called NBP which is an ortholog of human renal tumor suppressor Kank. NBP interacts with the PTB domain of Numb through a region well conserved among vertebrate Kanks containing the NGGY sequence.

Hedgehog signalling controls zebrafish neural keel morphogenesis via its level-dependent effects on neurogenesis.

We investigated the role of hedgehog (Hh) signalling on zebrafish neurulation, focusing on the intimate relationship between neurogenesis and morphogenesis during the neural keel stage. Through the analyses of Hh loss- and gain-of-function phenotypes, we found that Hh signalling controls the neural keel morphogenesis. To investigate underlying mechanisms, we examined cellular elongation polarity in the neural keel of Hh loss- and gain-of-function phenotypes and compared this with the deficient phenotype of a planar cell polarity (PCP) molecule, Trilobite/Strabismus.

Asymmetric localization of Numb:EGFP in dividing neuroepithelial cells during neurulation in Danio rerio.

In the neural plate and tube of the zebrafish embryo, cells divide with their mitotic spindles oriented parallel to the plane of the neuroepithelium, whilst in the neural keel and rod, the spindle is oriented perpendicular to it. This change is achieved by a 90 degrees rotation of the mitotic spindle. We cloned zebrafish homologues of the gene for the Drosophila cell fate determinant Numb, and analyzed the localization of EGFP fusion proteins in vivo in dividing neuroepithelial cells during neurulation.

Apical localization of ASIP/PAR-3:EGFP in zebrafish neuroepithelial cells involves the oligomerization domain CR1, the PDZ domains, and the C-terminal portion of the protein.

Neurulation in zebrafish (Danio rerio) embryos is characterized by oriented cell divisions and the progressive establishment of cellular polarity. Mitoses in the neural plate and neural tube are planar, but in the neural keel/rod stage, the mitotic spindle rotates by 90 degrees, causing cell divisions to occur perpendicular to the plane of the neuroepithelium. The mechanisms and molecules that establish cellular polarity and cause the stereotypic orientation of the mitotic spindle during neurulation are largely unknown.

her3, a zebrafish member of the hairy-E(spl) family, is repressed by Notch signalling.

her3 encodes a zebrafish bHLH protein of the Hairy-E(Spl) family. During embryogenesis, the gene is transcribed exclusively in the developing central nervous system, according to a fairly simple pattern that includes territories in the mesencephalon/rhombencephalon and the spinal cord. In all territories, the her3 transcription domain encompasses regions in which neurogenin 1 (neurog1) is not transcribed, suggesting regulatory interactions between the two genes.

A 90-degree rotation of the mitotic spindle changes the orientation of mitoses of zebrafish neuroepithelial cells.

In the neural plate and neural tube in the trunk region of the zebrafish embryo, dividing cells are oriented parallel to the plane of the neuroepithelium, while in neural keel/rod, cells divide perpendicular to it. This change in the orientation of mitosis is brought about by a 90 degrees rotation of the mitotic spindle. As the two halves of the neural primordium in keel/rod stage are in apposition, the perpendicular orientation of mitoses in this stage determines that daughter cells become allocated to both sides of the neural tube.

On the organisation of the regulatory region of the zebrafish deltaD gene.

DeltaD is one of the four zebrafish Delta homologues presently known. Experimental evidence indicates that deltaD participates in a number of important processes during embryogenesis, including early neurogenesis and somitogenesis, whereby the protein it encodes acts as a ligand for members of the Notch receptor family. In accordance with its functional role, deltaD is transcribed in several domains of mesodermal and ectodermal origin during embryogenesis.

A quantitative analysis of the kinetics of Gal4 activator and effector gene expression in the zebrafish.

Using a temperature-inducible hsp70:Gal4 activator and UAS:myc-notch1a-intra as effector, we determined quantitatively the kinetics of expression of both transgenes and analysed the effects of varying their expressivity on several phenotypic traits in the developing zebrafish. hsp70:Gal4 is transcribed within 15 min after temperature-mediated induction, but Gal4 RNA decays rapidly. The Gal4 protein was found to be quite stable, as functional Gal4, which was detectable 1.

Autonomous and non-autonomous phenotypic expression of Notch mutant cells in Drosophila embryogenesis.

 Transplantation of single homozygous Notch cells into the ventral neuroectoderm of Drosophila wild-type embryos reveals a non-autonomous behaviour of these cells. However, mitotic recombination events induced in heterozygous cells in imaginal discs lead to generation of homozygous Notch cells which differentiate cell autonomously. We have tested various possible explanations for the non-autonomous behaviour of Notch mutant cells following transplantation.

A clonal analysis of spinal cord development in the zebrafish.

 We describe the results of a clonal analysis of spinal cord development in the zebrafish. The data were obtained from embryos in which fluorescent lineage tracer was injected into single cells in the neural plate at the two-somite stage. Injected animals were allowed to survive until either 4 days or 2 weeks postfertilization.

Dorso-ventral polarity of the zebrafish embryo is distinguishable prior to the onset of gastrulation.

We describe a set of observations on developing zebrafish embryos and discuss the main conclusions they allow:(1) the embryonic dorso-ventral polarity axis is morphologically distinguishable prior to the onset of gastrulation; and (2) the involution of deep layer cells starts on the prospective dorsal side of the embryo. An asymmetry can be distinguished in the organization of the blastomeres in the zebrafish blastula at the 30% epiboly stage, in that one sector of the blastoderm is thicker than the other. Dye-labelling experiments with DiI and DiO and histological analysis allow us to conclude that the embryonic shield will form on the thinner side of the blastoderm.

On the formation of the neural keel and neural tube in the zebrafishDanio (Brachydanio) rerio.

Morphogenetic movements accompanying formation of the neural keel and neural tube in the zebrafishDanino (Brachydanio) rerio were studied by labelling single neural plate cells with fluoresceinated dextran (FDA) during late gastrula stages (95-100% epiboly) and localizing their progeny with an anti-fluorescein antibody on histological sections throughout neurulation. The mediolateral extent of the neural plate correlates directly with the dorso-ventral extent of the neural tube. That is to say, the progeny of cells located medially in the neural plate come to lie ventrally in the neural tube; cells located laterally in the neural plate give rise to progeny that populate dorsal levels in the neural tube.

Neurulation in the anterior trunk region of the zebrafish Brachydanio rerio.

We have studied the process of neurulation within the anterior trunk region of the zebrafish by means of serial sectioning of staged embryos and labelling cells by applications of the dye Dil and intracellular injections of fluoresceine dextran amine. The first morphological manifestation of the prospective neural plate is a dorsomedial ectodermal thickening which becomes visible immediately after gastrulation. Within 1-2 h, by the time somatogenesis begins, two bilaterally symmetrical thickenings have appeared more laterally, which eventually fuse with the medial thickening to form the neural keel.

A functional analysis of the genes Enhancer of split and HLH-m5 during early neurogenesis in Drosophila melanogaster.

To assess the functional domains of the proteins encoded by E(spl) and HLH-m5, two genes of the Enhancer of split complex [E(SPL)-C] of Drosophila melanogaster, a number of variants have been made by in vitro mutagenesis, transformed into the germ line of the wild-type, and genetically combined with a chromosomal deletion lacking four of the genes of the E(SPL)-C. All constructs used attenuated the neurogenic phenotype associated with this deletion. However, constructs encoding proteins with truncated carboxy-termini exibited in all cases a higher activity than constructs encoding the full length version of the protein.

Second-site modifiers of the Delta wing phenotype in Drosophila melanogaster.

We have screened for dominant enhancers and suppressors of the wing phenotype associated with two Delta alleles: Dl , an amorphic allele, and Dl , an antimorphic allele. The interactions of some of the modifiers with Delta are due to haplo-insufficient expression of the corresponding genes. Although not explicitly shown for the remaining cases, we assume that haploin-sufficiency is also the basis for the relationships of these genes to Delta, since no allele specific interactions were observed.

Regulatory signals and signal molecules in early neurogenesis of Drosophila melanogaster.

The ectodermal germ layer of Drosophila melanogaster gives rise to two major cell lineages, the neural and the epidermal. Progenitor cells for each of these lineages arise from groups of cells, whose elements must decide between taking on either fate. Commitment of the progenitor cells to one of the developmental fates implies two factors.

Defective ommatidial cell assembly leads to defective morphogenesis: a phenotypic analysis of the E(spl) mutation of Drosophila melanogaster.

The spl mutation of the N gene causes, among other phenotypic traits, the lack of a few ommatidia, roughness and a general reduction in the size of the compound eye; these defects are drastically enhanced by the dominant mutation E(spl) . We have studied cellular and developmental aspects of the phenotypic interaction between spl and E(spl) . We found that the initial clustering of photoreceptor cells is affected in eye imaginal discs of spl larvae causing the defects visible in the adult eye.

Second-site modifiers of the split mutation of Notch define genes involved in neurogenesis in Drosophila melanogaster.

We have searched for dominant modifiers, i.e., enhancers and suppressors, of the compound eye phenotype of split, a recessive viable allele of Notch.

Proliferation pattern and early differentiation of the optic lobes in Drosophila melanogaster.

The larval and early pupal development of the optic lobes in Drosophila is described qualitatively and quantitatively using [H]thymidine autoradiography on 2-μm plastic sections. The optic lobes develop from 30-40 precursor cells present in each hemisphere of the freshly hatched larva. During the first and second larval instars, these cells develop to neuroblasts arranged in two epithelial optic anlagen.

Reversible commitment of neural and epidermal progenitor cells during embryogenesis of Drosophila melanogaster.

Cell-cell interactions are involved in mediating developmental fate. An example is the decision of the neuroectodermal cells of Drosophila to develop as neural or epidermal progenitors, where cellular interactions participate in the process of acquisition of either cell fate. The results of heterochronic cell transplantations we describe here suggest that both neuroblasts and epidermoblasts are not irreversibly committed to a particular developmental fate.

Two groups of interrelated genes regulate early neurogenesis in Drosophila melanogaster.

In Drosophila melanogaster the neuroblasts separate from epidermoblasts to give rise to the neural primordium. This process is under the control of several genes. The group of the so-called neurogenic genes is required for epidermal development; other genes, comprising those of the achaete-scute complex and daughterless, are required for neural development.

The pattern of proliferation of the neuroblasts in the wild-type embryo of Drosophila melanogaster.

The pattern of neuroblast divisions was studied in thoracic and abdominal neuromeres of wild-type Drosophila melanogaster embryos stained with a monoclonal antibody directed against a chromatin-associated antigen. Since fixed material was used, our conclusions are based upon the statistical evaluation of a large number of accurately staged embryos, covering the stages between the formation of the cephalic furrow up to shortened germ band. Our observations point to a rather stereotypic pattern of proliferation, consisting of several parasynchronous cycles of division.

Lineage analysis of transplanted individual cells in embryos of Drosophila melanogaster : IV. Commitment and proliferative capabilities of mesodermal cells.

We describe the results of cell transplantation experiments performed to investigate mesodermal lineages in Drosophila melanogaster, particularly the lineages of the somatic muscles, the visceral muscles and the fat body. Cells to be transplanted were labelled by injecting a mixture of horseradish peroxidase (HRP) and fluorescein-dextran (FITC) in wild-type embryos at the syncytial blastoderm stage. For transplantation cells were removed from the ventral furrow, 8-12 min after the start of gastrulation, and individually transplanted into homotopic or heterotopic locations of unlabelled wild-type hosts of the same age.

Lineage analysis of transplanted individual cells in embryos of Drosophila melanogaster : III. Commitment and proliferative capabilities of pole cells and midgut progenitors.

In this paper experiments concerning some aspects of the development of pole cells and midgut progenitors in Drosophila are reported. Cells were labelled by injecting horseradish-peroxidase (HRP) in embryos before pole bud formation and transplanted at different stages into unlabelled embryos, where the transplanted cells developed together with the unlabelled cells of the host. The hosts were then fixed and stained at different ages in order to demonstrate the presence of HRP in the progenies of transplanted cells.

Lineage analysis of transplanted individual cells in embryos of Drosophila melanogaster : II. Commitment and proliferative capabilities of neural and epidermal cell progenitors.

Some aspects of neural and epidermal cell lineages during embryogenesis of Drosophila melanogaster were studied by transplanting horseradish-peroxidase-(HRP-) labelled ectodermal cells from young gastrula donors into host embryos of similar ages. Heterotopic transplantations permitted us to assess the degree of commitment already attained by the transplanted cells. The resulting cell clones showed normal characteristics of cytodifferentiation and cell number.