Radiation hybrid mapping of the zebrafish genome

Conservation of Mhc class III region synteny between zebrafish and human as determined by radiation hybrid mapping

In the HLA, H2, and other mammalian MHC:, the class I and II loci are separated by the so-called class III region comprised of approximately 60 genes that are functionally and evolutionarily unrelated to the class I/II genes. To explore the origin of this island of unrelated loci in the middle of the MHC: 19 homologues of HLA class III genes, we identified 19 homologues of HLA class III genes as well as 21 additional non-class I/II HLA homologues in the zebrafish and mapped them by testing a panel of 94 zebrafish-hamster radiation hybrid cell lines. Six of the HLA class III and eight of the flanking homologues were found to be linked to the zebrafish class I (but not class II) loci in linkage group 19. The remaining homologous loci were found to be scattered over 14 zebrafish linkage groups. The linkage group 19 contains at least 25 genes (not counting the class I loci) that are also syntenic on human chromosome 6. This gene assembly presumably represents the pre-MHC: that existed before the class I/II genes arose. The pre-MHC: may not have contained the complement and other class III genes involved in immune response.

The Translocon-Associated Protein beta (TRAPbeta) in zebrafish embryogenesis. I. Enhanced expression of transcripts in notochord and hatching gland precursors

The normal translocation of nascent polypeptides into the lumen of the endoplasmic reticulum (ER) is thought to be aided in part by a translocon-associated protein (TRAP) complex consisting of 4 protein subunits. The association of mature proteins with the ER and Golgi, or other intracellular locales, such as lysosomes, depends on the initial targeting of the nascent polypeptide to the ER membrane. A similar scenario must also exist for proteins destined for secretion. We have identified a member of the TRAP complex using a two hybrid screen to isolate proteins that bind to zebrafish (Danio) Ran binding protein 1. The polypeptide predicted from the largest open reading frame contains 183 amino acids with a 86 and 87% sequence identity to the TRAPbeta subunits in human and chicken, respectively. Sequence analysis identified a cleavable amino-terminal signal peptide in the zebrafish TRAPbeta subunit and a region of the protein spans the membrane of the endoplasmic reticulum. A reverse transcriptase-polymerase chain reaction assay showed that TRAPbeta mRNA is expressed in the developing zebrafish embryo. TRAPbeta mRNA is maternally supplied to the egg and is expressed constitutively throughout development and in the adult. This pattern of expression indicates that the message encoding part of the machinery targeting nascent polypeptides to the ER lumen is available at the onset of embryogenesis when the rate of translation increases exponentially over that occurring in the oocyte. In situ hybridization was used to test whether or not TRAPbeta transcripts might become localized and/or enriched in the developing embryo. Homogeneous staining is seen in the blastula and early gastrula stages. At mid-to-late gastrula stages, however, the message becomes enriched in the developing notochord and polster, or hatching gland rudiment. The TRAPbeta gene, mapped using the LN54 mouse-zebrafish radiation hybrid panel to linkage group 19, resides next to a gene (Z15451) which has sequence homology to notch2 and vascular endothelial growth factor. TRAPbeta, however, does not appear to belong to a group of genes which are syntenic with orthologues or paralogues on human chromosomes.

A comparative map of the zebrafish genome

Zebrafish mutations define the functions of hundreds of essential genes in the vertebrate genome. To accelerate the molecular analysis of zebrafish mutations and to facilitate comparisons among the genomes of zebrafish and other vertebrates, we used a homozygous diploid meiotic mapping panel to localize polymorphisms in 691 previously unmapped genes and expressed sequence tags (ESTs). Together with earlier efforts, this work raises the total number of markers scored in the mapping panel to 2119, including 1503 genes and ESTs and 616 previously characterized simple-sequence length polymorphisms. Sequence analysis of zebrafish genes mapped in this study and in prior work identified putative human orthologs for 804 zebrafish genes and ESTs. Map comparisons revealed 139 new conserved syntenies, in which two or more genes are on the same chromosome in zebrafish and human. Although some conserved syntenies are quite large, there were changes in gene order within conserved groups, apparently reflecting the relatively frequent occurrence of inversions and other intrachromosomal rearrangements since the divergence of teleost and tetrapod ancestors. Comparative mapping also shows that there is not a one-to-one correspondence between zebrafish and human chromosomes. Mapping of duplicate gene pairs identified segments of 20 linkage groups that may have arisen during a genome duplication that occurred early in the evolution of teleosts after the divergence of teleost and mammalian ancestors. This comparative map will accelerate the molecular analysis of zebrafish mutations and enhance the understanding of the evolution of the vertebrate genome.

A Comparative Map of the Zebrafish Genome

Zebrafish mutations define the functions of hundreds of essential genes in the vertebrate genome. To accelerate the molecular analysis of zebrafish mutations and to facilitate comparisons among the genomes of zebrafish and other vertebrates, we used a homozygous diploid meiotic mapping panel to localize polymorphisms in 691 previously unmapped genes and expressed sequence tags (ESTs). Together with earlier efforts, this work raises the total number of markers scored in the mapping panel to 2119, including 1503 genes and ESTs and 616 previously characterized simple-sequence length polymorphisms. Sequence analysis of zebrafish genes mapped in this study and in prior work identified putative human orthologs for 804 zebrafish genes and ESTs. Map comparisons revealed 139 new conserved syntenies, in which two or more genes are on the same chromosome in zebrafish and human. Although some conserved syntenies are quite large, there were changes in gene order within conserved groups, apparently reflecting the relatively frequent occurrence of inversions and other intrachromosomal rearrangements since the divergence of teleost and tetrapod ancestors. Comparative mapping also shows that there is not a one-to-one correspondence between zebrafish and human chromosomes. Mapping of duplicate gene pairs identified segments of 20 linkage groups that may have arisen during a genome duplication that occurred early in the evolution of teleosts after the divergence of teleost and mammalian ancestors. This comparative map will accelerate the molecular analysis of zebrafish mutations and enhance the understanding of the evolution of the vertebrate genome.

Identification, characterization, and mapping of expressed sequence tags from an embryonic zebrafish heart cDNA library

The generation of expressed sequence tags (ESTs) has proven to be a rapid and economical approach by which to identify and characterize expressed genes. We generated 5102 ESTs from a 3-d-old embryonic zebrafish heart cDNA library. Of these, 57.6% matched to known genes, 14.2% matched only to other ESTs, and 27.8% showed no match to any ESTs or known genes. Clustering of all ESTs identified 359 unique clusters comprising 1771 ESTs, whereas the remaining 3331 ESTs did not cluster. This estimates the number of unique genes identified in the data set to be approximately 3690. A total of 1242 unique known genes were used to analyze the gene expression patterns in the zebrafish embryonic heart. These were categorized into seven categories on the basis of gene function. The largest class of genes represented those involved in gene/protein expression (25.9% of known transcripts). This class was followed by genes involved in metabolism (18.7%), cell structure/motility (16.4%), cell signaling and communication (9.6%), cell/organism defense (7.1%), and cell division (4.4%). Unclassified genes constituted the remaining 17.91%. Radiation hybrid mapping was performed for 102 ESTs and comparison of map positions between zebrafish and human identified new synteny groups. Continued comparative analysis will be useful in defining the boundaries of conserved chromosome segments between zebrafish and humans, which will facilitate the transfer of genetic information between the two organisms and improve our understanding of vertebrate evolution.

Identification, Characterization, and Mapping of Expressed Sequence Tags from an Embryonic Zebrafish Heart cDNA Library

The generation of expressed sequence tags (ESTs) has proven to be a rapid and economical approach by which to identify and characterize expressed genes. We generated 5102 ESTs from a 3-d-old embryonic zebrafish heart cDNA library. Of these, 57.6% matched to known genes, 14.2% matched only to other ESTs, and 27.8% showed no match to any ESTs or known genes. Clustering of all ESTs identified 359 unique clusters comprising 1771 ESTs, whereas the remaining 3331 ESTs did not cluster. This estimates the number of unique genes identified in the data set to be approximately 3690. A total of 1242 unique known genes were used to analyze the gene expression patterns in the zebrafish embryonic heart. These were categorized into seven categories on the basis of gene function. The largest class of genes represented those involved in gene/protein expression (25.9% of known transcripts). This class was followed by genes involved in metabolism (18.7%), cell structure/motility (16.4%), cell signaling and communication (9.6%), cell/organism defense (7.1%), and cell division (4.4%). Unclassified genes constituted the remaining 17.91%. Radiation hybrid mapping was performed for 102 ESTs and comparison of map positions between zebrafish and human identified new synteny groups. Continued comparative analysis will be useful in defining the boundaries of conserved chromosome segments between zebrafish and humans, which will facilitate the transfer of genetic information between the two organisms and improve our understanding of vertebrate evolution.

[The sequence data described in this paper have been submitted to the GenBank data library under accession nos.BE693120–BE693210 and BE704450.]

Harnessing the power of forward genetics--analysis of neuronal diversity and patterning in the zebrafish retina

The seven major cell classes of the vertebrate retina are organized with remarkable precision into distinct layers. The appearance of this architecture during embryogenesis raises two questions of general importance. How do individual cell classes acquire their specialized structures and functions if they all originate from a morphologically uniform cell population? What mechanisms are responsible for the formation of such a complex and exact pattern? Recent advances present an opportunity to apply the tools of forward genetic analysis to identify mutations that affect these mechanisms in zebrafish. Molecular characterization will follow, providing insight into the basis of neuronal patterning in the vertebrate CNS.

Hhex and scl function in parallel to regulate early endothelial and blood differentiation in zebrafish

During embryogenesis, endothelial and blood precursors are hypothesized to arise from a common progenitor, the hemangioblast. Several genes that affect the differentiation of, or are expressed early in, both the endothelial and blood lineages may in fact function at the level of the hemangioblast. For example, the zebrafish cloche mutation disrupts the differentiation of both endothelial and blood cells. The transcription factor gene scl is expressed in both endothelial and blood lineages from an early stage and can regulate their differentiation. Here we report that in zebrafish the homeobox gene hhex (previously called hex) is also expressed in endothelial and blood lineages from an early stage. We find that hhex expression in these lineages is significantly reduced in cloche mutant embryos, indicating that hhex functions downstream of cloche to regulate endothelial and blood differentiation. Ectopic expression of hhex through injection of a DNA construct leads to the premature and ectopic expression of early endothelial and blood differentiation genes such as fli1, flk1 and gata1, indicating that Hhex can positively regulate endothelial and blood differentiation. However, analysis of a hhex deficiency allele shows that hhex is not essential for early endothelial and blood differentiation, suggesting that another gene, perhaps scl, compensates for the absence of Hhex function. Furthermore, we find that hhex and scl can induce each other's expression, suggesting that these two genes cross-regulate each other during early endothelial and blood differentiation. Together, these data provide the initial framework of a pathway that can be used to further integrate the molecular events regulating hemangioblast differentiation.

Zebrafish nma is involved in TGFbeta family signaling

Bone morphogenetic proteins (BMP) are members of the TGFbeta superfamily of secreted factors with important regulatory functions during embryogenesis. We have isolated the zebrafish gene, nma, that encodes a protein with high sequence similarity to human NMA and Xenopus Bambi. It is also similar to TGFbeta type I serine/theronine kinase receptors in the extracellular ligand-binding domain but lacks a cytoplasmic kinase domain. During development, nma expression is similar to that of bmp2b and bmp4, and analysis in the dorsalized and ventralized zebrafish mutants swirl and chordino indicates that nma is regulated by BMP signaling. Overexpression of nma during zebrafish and Xenopus development resulted in phenotypes that appear to be based on inhibition of BMP signaling. Biochemically, NMA can associate with TGFbeta type II receptors and bind to TGFbeta ligand. We propose that nma is a BMP-regulated gene whose function is to attenuate BMP signaling during development through interactions with type II receptors and ligands.

Building the vertebrate vasculature: research is going swimmingly

The vertebrate vasculature develops in remarkably similar fashion in all vertebrates. A cohort of unspecified mesodermal cells differentiates into primitive endothelial cells, which migrate to and occupy positions within the stereotypical blueprint of the primitive vasculature. Once in position, these cells coalesce and form cords, which lumenize and become ensheathed by supporting pericytes and smooth muscle cells. This primitive vascular network is extensively remodeled in some places, and expanded by sprouting in others. Various studies using the mouse, quail/chick, and frog have uncovered a number of signals that guide these complex processes but many gaps still exist in our understanding of the mechanisms by which the embryonic vasculature is built. Because many questions will require in vivo studies to be properly addressed, the zebrafish, with its unique accessibility to analysis by combined embryological, molecular, and genetic methods, should prove invaluable in identifying new molecules involved in blood vessel development and integrating pathways that influence embryonic blood vessel formation.

Characterization of zebrafish full-length prothrombin cDNA and linkage group mapping

In this paper, we report the complete cDNA sequence of zebrafish prothrombin. The cDNA sequence predicts that zebrafish prothrombin is synthesized as a pre-proprotein consisting of a Gla domain, two kringle domains, and a two-chain protease domain. Zebrafish prothrombin is structurally very similar to human and other vertebrate prothrombins. Zebrafish and human prothrombin share 53% amino acid identity whereas zebrafish and hagfish prothrombin share 51% identity. Amino acid alignments of various prothrombins identified conservation of many of the functional/structural motifs suggesting that the vertebrate prothrombins may have similar functions. The three-dimensional structure of prothrombin predicted by homology modeling also revealed that the prothrombin fragment 1 and the catalytic domain structures are well conserved except for the insertion of an extra 7-amino-acid loop in the connecting region (CR) between the Gla and kringle I domain of fragment 1. Linkage analysis revealed that the prothrombin gene locus on linkage group 7 in zebrafish is syntenic to the human chromosome 11-prothrombin region suggesting its preservation through evolution. The availability of this cDNA sequence in zebrafish adds to our knowledge of the zebrafish hemostatic system and provides support for the view that similarities between zebrafish and mammalian coagulation exist, thus underscoring the relevance of the zebrafish model for studying human hemostasis.

The zebrafish scyba gene encodes a novel CXC-type chemokine with distinctive expression patterns in the vestibulo-acoustic system during embryogenesis

Chemokines, in addition to their characterized functions as immune modulators, also play a role in developmental processes such as neural cell migration. Although, chemokines have been described in human, mouse and other vertebrate species, they have yet to be characterized in zebrafish. In this paper, we report the isolation and expression analysis of scyba, a zebrafish gene encoding a CXC-type chemokine protein. During early segmentation, scyba transcripts are detected in the midbrain region and the otic placodes. At later developmental stages, scyba expression is restricted to a subset of hindbrain commissural neurons and to the hair-cell sensory patches of the otic vesicle and lateral-line neuromasts.

Expression of the zinc finger gene fez-like in zebrafish forebrain

Anterior-posterior (A-P) patterning in the neuroectoderm is established during gastrulation in zebrafish and amphibians. We isolated a novel zinc-finger gene fez-like (fezl) from zebrafish, which displays sequence similarities to Xenopus Fez. The fezl transcripts were detected in the anterior edge of neuroectoderm, the prospective dorsal forebrain, from the late gastrula (80% epiboly stage) to the mid-segmentation period. fezl was also expressed in the ventral forebrain overlying the prechordal plate at these stages. The expression of fezl was enhanced in embryos expressing the Wnt inhibitor Dkk1 and reduced in embryos expressing Wnt8b. The expression in the ventral forebrain was eliminated in the one-eyed pinhead mutant and the antivin RNA-injected embryos, which lack the prechordal plate. Radiation hybrid mapping revealed that the fezl gene is localized to linkage group 11.

Genetic analysis of melanophore development in zebrafish embryos

Vertebrate pigment cells are derived from neural crest, a tissue that also forms most of the peripheral nervous system and a variety of ectomesenchymal cell types. Formation of pigment cells from multipotential neural crest cells involves a number of common developmental processes. Pigment cells must be specified; their migration, proliferation, and survival must be controlled and they must differentiate to the final pigment cell type. We previously reported a large set of embryonic mutations that affect pigment cell development from neural crest (R. N. Kelsh et al., 1996, Development 123, 369-389). Based on distinctions in pigment cell appearance between mutants, we proposed hypotheses as to the process of pigment cell development affected by each mutation. Here we describe the cloning and expression of an early zebrafish melanoblast marker, dopachrome tautomerase. We used this marker to test predictions about melanoblast number and pattern in mutant embryos, including embryos homozygous for mutations in the colourless, sparse, touchdown, sunbleached, punkt, blurred, fade out, weiss, sandy, and albino genes. We showed that in homozygous mutants for all loci except colourless and sparse, melanoblast number and pattern are normal. colourless mutants have a pronounced decrease in melanoblast cell number from the earliest stages and also show poor melanoblast differentiation and migration. Although sparse mutants show normal numbers of melanoblasts initially, their number is reduced later. Furthermore, their distribution indicates a defect in melanoblast dispersal. These observations permit us to refine our model of the genetic control of melanophore development in zebrafish embryos.

The zebrafish forkhead transcription factor FoxH1/Fast1 is a modulator of nodal signaling required for organizer formation

BACKGROUND

Signaling molecules related to the Nodal protein play essential roles in the formation and patterning of the gastrula organizer and the germ layers during vertebrate development. The forkhead transcription factor FoxH1 (also known as Fast1) is a component of the Nodal signaling pathway. Although different roles have been suggested for FoxH1, its specific function during development is still unclear.

RESULTS

We report that the zebrafish locus schmalspur (sur) encodes a member of the FoxH1 family. Maternal sur transcripts were localized to the animal pole during oogenesis. Further expression was detected in a dorsoventral gradient at the onset of gastrulation and in specific domains in the organizer, notochord and lateral plate mesoderm. Embryos lacking zygotic sur function had variable deficiencies of prechordal plate and ventral neuroectoderm. In the absence of both maternal and zygotic sur function, embryos failed to form a morphologically distinct gastrula organizer and, later, developed severe defects in all axial structures. In these embryos, expression of nodal genes was initiated but not maintained. Unlike embryos lacking Nodal signaling, sur mutants formed endoderm and paraxial mesoderm.

CONCLUSIONS

FoxH1 is involved in regulatory feedback loops that control the duration and intensity of Nodal signals in early patterning. In zebrafish, FoxH1 is not essential to induce Nodal-dependent cell fates, but its function is central in modulating and enhancing morphogenetic Nodal signals.

The syntenic relationship of the zebrafish and human genomes

The zebrafish is an important vertebrate model for the mutational analysis of genes effecting developmental processes. Understanding the relationship between zebrafish genes and mutations with those of humans will require understanding the syntenic correspondence between the zebrafish and human genomes. High throughput gene and EST mapping projects in zebrafish are now facilitating this goal. Map positions for 523 zebrafish genes and ESTs with predicted human orthologs reveal extensive contiguous blocks of synteny between the zebrafish and human genomes. Eighty percent of genes and ESTs analyzed belong to conserved synteny groups (two or more genes linked in both zebrafish and human) and 56% of all genes analyzed fall in 118 homology segments (uninterrupted segments containing two or more contiguous genes or ESTs with conserved map order between the zebrafish and human genomes). This work now provides a syntenic relationship to the human genome for the majority of the zebrafish genome.

An ordered comparative map of the cattle and human genomes

A cattle-human whole-genome comparative map was constructed using parallel radiation hybrid (RH) mapping in conjunction with EST sequencing, database mining for unmapped cattle genes, and a predictive bioinformatics approach (COMPASS) for targeting specific homologous regions. A total of 768 genes were placed on the RH map in addition to 319 microsatellites used as anchor markers. Of these, 638 had human orthologs with mapping data, thus permitting construction of an ordered comparative map. The large number of ordered loci revealed > or =105 conserved segments between the two genomes. The comparative map suggests that 41 translocation events, a minimum of 54 internal rearrangements, and repositioning of all but one centromere can account for the observed organizations of the cattle and human genomes. In addition, the COMPASS in silico mapping tool was shown to be 95% accurate in its ability to predict cattle chromosome location from random sequence data, demonstrating this tool to be valuable for efficient targeting of specific regions for detailed mapping. The comparative map generated will be a cornerstone for elucidating mammalian chromosome phylogeny and the identification of genes of agricultural importance."Ought we, for instance, to begin by discussing each separate species-in virtue of some common element of their nature, and proceed from this as a basis for the consideration of them separately?" from Aristotle, On the Parts of Animals, 350 B.C.E.

Genetic analysis of isometric growth control mechanisms in the zebrafish caudal Fin

The body and fins of the zebrafish grow rapidly as juveniles and slower as they reach maturation. Throughout their lives, the fins grow isometrically with respect to the body. Growth of individual fin rays is achieved by the distal addition of bony segments. We have investigated the genetic control of mechanisms that initiate new segments or control size of newly initiated segments. We find that both segment initiation and segment length are regulated during fin growth in wild-type fish. We examined the growth properties of lof and sof fin length mutants for effects on the number and length of fin ray segments. Fins of lof mutants continue to grow rapidly even after wild-type fin growth slows, resulting in positive allometric growth and additional fin ray segments. We suggest that lof mutants bypass mechanisms that limit segment initiation. Isometric growth is retained in sof mutants, resulting in shorter fins one-half the length of wild-type fins. The primary defect in sof mutants is that fin ray segments are shorter than wild-type segments, although segment number is also diminished. Double mutants for sof;lof reveal that segment length and segment number are controlled in different pathways. Our findings suggest that the lof gene product regulates segment initiation and the sof gene product regulates segment length.

Centromere-linked microsatellite markers for linkage groups 3, 4, 6, 7, 13, and 20 of zebrafish (Danio rerio)

A large number of interesting mutations affecting development and organogenesis have been identified through genetic screens in zebrafish. Mapping of these mutations to a chromosomal region can be rapidly accomplished using half-tetrad analysis. However, knowledge of centromere-linked markers on every chromosome is essential to this mapping method. Centromeres on all 25 linkage groups have been mapped on the RAPD zebrafish genetic map. However, species specificity and the lack of codominance make RAPD markers less practical for mapping than microsatellite-based markers. On the microsatellite-based genetic map, centromere-linked markers have been identified for 19 linkage groups. No direct evidence has been published linking microsatellite markers to the centromeres of linkage groups 3, 4, 6, 7, 13, and 20. Therefore, we compared the microsatellite-based genetic map with the RAPD map to identify markers most likely linked to the centromeres of these 6 linkage groups. These candidate markers were tested for potential centromere linkage using four panels of half-tetrad embryos derived by early-pressure treatment of eggs from four different female zebrafish. We have identified microsatellite markers for linkage groups 3, 4, 6, 7, 13, and 20 to within 1.7 cM of their centromeres. These markers will greatly facilitate the rapid mapping of mutations in zebrafish by half-tetrad analysis.

Identification and linkage of the proteasome activator complex PA28 subunit genes in zebrafish

PA28 is an activator of the latent 20S proteasome, a large multisubunit complex involved in intracellular proteolysis. Two forms of hexameric PA28 have been identified, PA28-(alphabeta)3 and PA28-(gamma)6, of which the former is of immunological importance. Both the PA28-alpha and PA28-beta subunits are inducible by interferon-gamma (IFN-gamma) and the PA28-(alphabeta)3 complex enhances the ability of the 20S proteasome to produce peptides suited for binding to major histocompatibility complex (Mhc) class I molecules. To identify the homologues of the PA28 subunits in zebrafish we screened a cDNA library and obtained full-length cDNA sequences of the genes PSME1, PSME2 and PSME3 coding for the PA28-alpha, PA28-beta and PA28-gamma subunits, respectively. Phylogenetic analysis indicates the existence of the ancestors of all three genes prior to the divergence of tetrapods and bony fishes. The IFN-gamma-inducible subunits, PA28-alpha and PA28-beta, evolve faster than the presumably older PA28-gamma subunit. Using zebrafish radiation hybrid panels, the genes PSME2 and PSME3 were mapped to linkage group 12 and shown to be separated by a distance of less than 2.4 cM. This observation suggests that an intrachromosomal duplication event created the precursor of the IFN-gamma-inducible genes from a PA28-gamma-like ancestor prior to their recruitment into the Mhc class I peptide presentation pathway.

A high-resolution radiation hybrid map of the proximal portion of mouse chromosome 5

Radiation hybrid (RH) mapping of the mouse genome provides a useful tool in the integration of existing genetic and physical maps, as well as in the ongoing effort to generate a dense map of expressed sequence tags. To facilitate functional analysis of mouse Chromosome 5, we have constructed a high-resolution RH map spanning 75 cM of the chromosome. During the course of these studies, we have developed RHBase, an RH data management program that provides data storage and an interface to several RH mapping programs and databases. We have typed 95 markers on the T31 RH panel and generated an integrated map, pooling data from several sources. The integrated RH map ranges from the most proximal marker, D5Mit331 (Chromosome Committee offset, 3 cM), to D5Mit326, 74.5 cM distal on our genetic map (Chromosome Committee offset, 80 cM), and consists of 138 markers, including 89 simple sequence length polymorphic markers, 11 sequence-tagged sites generated from BAC end sequence, and 38 gene loci, and represents average coverage of approximately one locus per 0.5 cM with some regions more densely mapped. In addition to the RH mapping of markers and genes previously localized on mouse Chromosome 5, this RH map places the alpha-4 GABA(A) receptor subunit gene (Gabra4) in the central portion of the chromosome, in the vicinity of the cluster of three other GABA(A) receptor subunit genes (Gabrg1-Gabra2-Gabrb1). Our mapping effort has also defined a new cluster of four genes in the semaphorin gene family (Sema3a, Sema3c, Sema3d, and Sema3e) and the Wolfram syndrome gene (Wfs1) in this region of the chromosome.

Genetic linkage mapping of zebrafish genes and ESTs

Genetic screens in zebrafish (Danio rerio) have isolated mutations in hundreds of genes essential for vertebrate development, physiology, and behavior. We have constructed a genetic linkage map that will facilitate the identification of candidate genes for these mutations and allow comparisons among the genomes of zebrafish and other vertebrates. On this map, we have localized 771 zebrafish genes and expressed sequence tags (ESTs) by scoring single-stranded conformational polymorphisms (SSCPs) in a meiotic mapping panel. Of these sequences, 642 represent previously unmapped genes and ESTs. The mapping panel was comprised of 42 homozygous diploid individuals produced by heat shock treatment of haploid embryos at the one-cell stage (HS diploids). This "doubled haploid" strategy combines the advantages of mapping in haploid and standard diploid systems, because heat shock diploid individuals have only one allele at each locus and can survive to adulthood, enabling a relatively large quantity of genomic DNA to be prepared from each individual in the mapping panel. To integrate this map with others, we also scored 593 previously mapped simple-sequence length polymorphisms (SSLPs) in the mapping panel. This map will accelerate the molecular analysis of zebrafish mutations and facilitate comparative analysis of vertebrate genomes.

Sequence, expression, and location of zebrafish frizzled 10

Members of the frizzled gene family encode seven-pass transmembrane proteins that function in the interpretation and reception of Wnt-mediated cell-cell communication events. To investigate frizzled function in early zebrafish development, we isolated the maternally contributed frizzled 10 (fz10) gene and localized it to linkage group 8 using radiation hybrid mapping. The cloned zebrafish fz10 is closely related to the fz10 group from other organisms. Zygotic expression of fz10 is observed in the posterior tail mesenchyme, dorsal neural tube, and different parts of the brain.

Zebrafish: a genetic approach in studying hematopoiesis

The zebrafish (Danio rerio) has emerged in recent years as an exciting animal model system for studying vertebrate organ development and, in particular, the development of the hematopoietic system. The combined advantages of developmental biology and genetic screens for mutations in zebrafish have provided insights into early events in hematopoiesis and identified several genes required for normal blood development in vertebrates. As a result of the large-scale mutagenesis screens for developmental mutants, several zebrafish mutants with defects in blood development have been recovered. This review discusses how these blood mutations in zebrafish have given new perspectives on hematopoietic development.

Characterization of a zebrafish/mouse somatic cell hybrid panel

We have characterized a collection of zebrafish/mouse somatic cell hybrids with 211 genes and markers chosen from the 25 zebrafish linkage groups. Most of the zebrafish genome is represented in this collection with 88% of genes/markers present in at least one hybrid cell line. Although most hybrids contain chromosomal fragments, there are a few instances where a complete or nearly complete zebrafish chromosome has been maintained in a mouse background, based on multiple markers covering the entire chromosome. In addition to their use in mapping studies, this collection of somatic cell hybrids should constitute an important tool as a source of specific chromosome fragments and for assessing the function of genome regions.

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.

Featured organism: Danio rerio, the zebrafish

The zebrafish has long been a favourite model for the study of vertebrate development. Here we provide an overview of the current state of knowledge and resources for the study of this fish, with comments on the future direction of zebrafish genomics from Professor Mark Fishman and Dr Stephen Wilson.

Featured organism: Danio rerio, the zebrafish

The zebrafish has long been a favourite model for the study of vertebrate development. Here we provide an overview of the current state of knowledge and resources for the study of this fish, with comments on the future direction of zebrafish genomics from Professor Mark Fishman and Dr Stephen Wilson.

Characterization of the MEN1 ortholog in zebrafish

Multiple endocrine neoplasia type 1 (MEN1) is an autosomal dominant syndrome predisposing to multiple tumors. The responsible gene, MEN1, has been identified and inactivating mutations reported. It encodes a protein named menin, which lacks homology to any known proteins. Comparative genomics is used to ascertain important functional domains via the identification of evolutionary conserved regions. Here we report the sequencing and characterization of the MEN1 gene in zebrafish (Danio rerio) at the cDNA level. Zebrafish menin is a 617 amino acid protein and, when compared with human and rodent proteins, shows 75% and 76% similarity, respectively. The most conserved region is amino acid residues 41-322 which shows a human/zebrafish similarity of 83%. Amino acids affected by inactivating missense mutations in MEN1 patients in this region are completely conserved between human and zebrafish. Such high correlation between conservation throughout evolution and mutation position strongly emphasizes the importance of this region.

A radiation hybrid map of the zebrafish genome

Recent large-scale mutagenesis screens have made the zebrafish the first vertebrate organism to allow a forward genetic approach to the discovery of developmental control genes. Mutations can be cloned positionally, or placed on a simple sequence length polymorphism (SSLP) map to match them with mapped candidate genes and expressed sequence tags (ESTs). To facilitate the mapping of candidate genes and to increase the density of markers available for positional cloning, we have created a radiation hybrid (RH) map of the zebrafish genome. This technique is based on somatic cell hybrid lines produced by fusion of lethally irradiated cells of the species of interest with a rodent cell line. Random fragments of the donor chromosomes are integrated into recipient chromosomes or retained as separate minichromosomes. The radiation-induced breakpoints can be used for mapping in a manner analogous to genetic mapping, but at higher resolution and without a need for polymorphism. Genome-wide maps exist for the human, based on three RH panels of different resolutions, as well as for the dog, rat and mouse. For our map of the zebrafish genome, we used an existing RH panel and 1,451 sequence tagged site (STS) markers, including SSLPs, cloned candidate genes and ESTs. Of these, 1,275 (87.9%) have significant linkage to at least one other marker. The fraction of ESTs with significant linkage, which can be used as an estimate of map coverage, is 81.9%. We found the average marker retention frequency to be 18.4%. One cR3000 is equivalent to 61 kb, resulting in a potential resolution of approximately 350 kb.