Loss-of-function mutations in the EGF-CFC gene CFC1 are associated with human left-right laterality defects.

All vertebrates display a characteristic asymmetry of internal organs with the cardiac apex, stomach and spleen towards the left, and the liver and gall bladder on the right. Left-right (L-R) axis abnormalities or laterality defects are common in humans (1 in 8,500 live births). Several genes (such as Nodal, Ebaf and Pitx2) have been implicated in L-R organ positioning in model organisms. In humans, relatively few genes have been associated with a small percentage of human situs defects. These include ZIC3 (ref. 5), LEFTB (formerly LEFTY2; ref. 6) and ACVR2B (encoding activin receptor IIB; ref. 7). The EGF-CFC genes, mouse Cfc1 (encoding the Cryptic protein; ref. 9) and zebrafish one-eyed pinhead (oep; refs 10, 11) are essential for the establishment of the L-R axis. EGF-CFC proteins act as co-factors for Nodal-related signals, which have also been implicated in L-R axis development. Here we identify loss-of-function mutations in human CFC1 (encoding the CRYPTIC protein) in patients with heterotaxic phenotypes (randomized organ positioning). The mutant proteins have aberrant cellular localization in transfected cells and are functionally defective in a zebrafish oep-mutant rescue assay. Our findings indicate that the essential role of EGF-CFC genes and Nodal signalling in left-right axis formation is conserved from fish to humans. Moreover, our results support a role for environmental and/or genetic modifiers in determining the ultimate phenotype in humans.

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.

A nodal signaling pathway regulates the laterality of neuroanatomical asymmetries in the zebrafish forebrain.

Animals show behavioral asymmetries that are mediated by differences between the left and right sides of the brain. We report that the laterality of asymmetric development of the diencephalic habenular nuclei and the photoreceptive pineal complex is regulated by the Nodal signaling pathway and by midline tissue. Analysis of zebrafish embryos with compromised Nodal signaling reveals an early role for this pathway in the repression of asymmetrically expressed genes in the diencephalon. Later signaling mediated by the EGF-CFC protein One-eyed pinhead and the forkhead transcription factor Schmalspur is required to overcome this repression. When expression of Nodal pathway genes is either absent or symmetrical, neuroanatomical asymmetries are still established but are randomized. This indicates that Nodal signaling is not required for asymmetric development per se but is essential to determine the laterality of the asymmetry.

Axis formation and patterning in zebrafish.

A large collection of mutations affecting zebrafish embryogenesis was described in 1996. The cloning of the affected genes has now provided novel insights into the role and regulation of signaling by BMP, Nodal, Wnt, FGF, Hedgehog, Delta, Slit, retinoic acid and lipids. Detailed analyses have revealed a complex genetic network that patterns the early embryo.

The zebrafish organizer.

Signals from the organizer play a crucial role in patterning the vertebrate embryo. Recent molecular analysis of zebrafish mutations has established an essential role for BMP2 and chordin in organizer function and has identified one-eyed pinhead as a novel EGF-like gene involved in prechordal plate and endoderm formation. In addition, embryological studies have suggested that the zebrafish organizer is induced by extraembryonic cues and have defined two novel organizing centers that pattern the nervous system along the anterior-posterior axes.

Single-cell internalization during zebrafish gastrulation.

During gastrulation, germ layers are formed as prospective mesodermal and endodermal cells internalize and come to underlie the ectoderm [1-9]. Despite the pivotal role of gastrulation in animal development, the cellular interactions underlying this process are poorly understood. In zebrafish, mesoderm and endoderm formation requires the Nodal signals Cyclops and Squint and their cofactor One-eyed pinhead (Oep) [10-14]. We found that marginal cells in maternal-zygotic oep (MZoep) mutants do not internalize during gastrulation and acquire neural and tail fates at the expense of head and trunk mesendoderm. The lack of internalization in MZoep embryos and the cell-autonomous requirement for oep in Nodal signaling enabled us to test whether internalization can be achieved by individual cells or whether it depends on interactions within a group of cells. We found that individual MZoep mutant cells transplanted to the margin of wild-type blastula embryos initially internalize with their neighbors but are unable to contribute to the mesendoderm. In the reciprocal experiment, single wild-type cells transplanted to the margin of MZoep mutant embryos autonomously internalize and can express the mesendodermal markers axial/foxA2 and sox17. These results suggest that internalization and mesendoderm formation in zebrafish can be attained autonomously by single cells.

Nodal-related signals establish mesendodermal fate and trunk neural identity in zebrafish.

The vertebrate body plan arises during gastrulation, when morphogenetic movements form the ectoderm, mesoderm, and endoderm. In zebrafish, mesoderm and endoderm derive from the marginal region of the late blastula, and cells located nearer the animal pole form the ectoderm [1]. Analysis in mouse, Xenopus, and zebrafish has demonstrated that Nodal-related proteins, a subclass of the TGF-beta superfamily, are essential for mesendoderm development [2], but previous mutational studies have not established whether Nodal-related signals control fate specification, morphogenetic movements, or survival of mesendodermal precursors. Here, we report that Nodal-related signals are required to allocate marginal cells to mesendodermal fates in the zebrafish embryo. In double mutants for the zebrafish nodal-related genes squint (sqt) and cyclops (cyc) [3] [4] [5], dorsal marginal cells adopt neural fates, whereas in wild-type embryos, cells at this position form endoderm and axial mesoderm. Involution movements characteristic of developing mesendoderm are also blocked in the absence of Nodal signaling. Because it has been proposed [6] that inhibition of Nodal-related signals promotes the development of anterior neural fates, we also examined anteroposterior organization of the neural tube in sqt;cyc mutants. Anterior trunk spinal cord is absent in sqt;cyc mutants, despite the presence of more anterior and posterior neural fates. These results demonstrate that nodal-related genes are required for the allocation of dorsal marginal cells to mesendodermal fates and for anteroposterior patterning of the neural tube.

Fast1 is required for the development of dorsal axial structures in zebrafish.

Nodal-related signals comprise a subclass of the transforming growth factor-beta (TGF-beta) superfamily and regulate key events in vertebrate embryogenesis, including mesoderm formation, establishment of left-right asymmetry and neural patterning [1-8]. Nodal ligands are thought to act with EGF-CFC protein co-factors to activate activin type I and II or related receptors, which phosphorylate Smad2 and trigger nuclear translocation of a Smad2/4 complex [8-12]. The winged-helix transcription factor forkhead activin signal transducer-1 (Fast-1) acts as a co-factor for Smad2 [12-20]. Xenopus Fast-1 is thought to function as a transcriptional effector of Nodal signals during mesoderm formation [17], but no mutations in the Fast-1 gene have been identified. We report the identification of the zebrafish fast1 gene and show that it is disrupted in schmalspur (sur) mutants, which have defects in the development of dorsal midline cell types and establishment of left-right asymmetry [21-25]. We find that prechordal plate and notochord are strongly reduced in maternal-zygotic sur mutants, whereas other mesendodermal structures are present - a less severe phenotype than that caused by complete loss of Nodal signaling. These results show that fast1 is required for development of dorsal axial structures and left-right asymmetry, and suggest that Nodal signals act through Fast1-dependent and independent pathways.

The EGF-CFC gene family in vertebrate development.

EGF-CFC genes encode extracellular proteins that play key roles in intercellular signaling pathways during vertebrate embryogenesis. Mutations in zebrafish and mouse EGF-CFC genes lead to defects in germ-layer formation, anterior-posterior axis orientation and left-right axis specification. In addition, members of the EGF-CFC family have been implicated in carcinogenesis. Although formerly regarded as signaling molecules that are distant relatives of epidermal growth factor (EGF), recent findings indicate that EGF-CFC proteins act as essential cofactors for Nodal, a member of the transforming growth factor beta (TGF-beta) family. Here, we review molecular genetic evidence from mouse and zebrafish on biological and biochemical roles of the EGF-CFC family, and discuss differing models for EGF-CFC protein function.

Genetics of neural development in zebrafish.

Large-scale mutant screens in zebrafish have led to the identification of more than 50 genes affecting various aspects of neural development and function, including neural induction, anteroposterior and dorsoventral regionalization, axon pathfinding, neuronal differentiation and survival, and behavior. Phenotypic analysis of mutants for some of these genes has already uncovered important genetic and cellular interactions during development. Ongoing molecular analyses promise to further elucidate the mechanisms underlying neural development in vertebrates.

Efficient recovery of ENU-induced mutations from the zebrafish germline.

We studied the efficiency with which two chemical mutagens, ethyl methanesulfonate (EMS) and N-ethyl-N-nitrosourea (ENU) can induce mutations at different stages of spermatogenesis in zebrafish (Brachydanio rerio). Both EMS and ENU induced mutations at high rates in post-meiotic germ cells, as indicated by the incidence of F1 progeny mosaic for the albino mutation. For pre-meiotic germ cells, however, only ENU was found to be an effective mutagen, as indicated by the frequencies of non-mosaic mutant progeny at four different pigmentation loci. Several mutagenic regimens that varied in either the number of treatments or the concentration of ENU were studied to achieve an optimal ratio between the mutagenicity and toxicity. For the two most mutagenic regimens: 4 x 1 hr in 3 mM ENU and 6 x 1 hr in 3 mM ENU, the minimum estimate of frequencies of independent mutations per locus per gamete was 0.9-1.3 X 10(-3). We demonstrate that embryonic lethal mutations induced with ENU were transmitted to offspring and that they could be recovered in an F2 screen. An average frequency of specific-locus mutations of 1.1 X 10(-3) corresponded to approximately 1.7 embryonic lethal mutations per single mutagenized genome. The high rates of mutations achievable with ENU allow for rapid identification of large numbers of genes involved in a variety of aspects of zebrafish development.

Analysis of chromosomal rearrangements induced by postmeiotic mutagenesis with ethylnitrosourea in zebrafish.

Mutations identified in zebrafish genetic screens allow the dissection of a wide array of problems in vertebrate biology. Most screens have examined mutations induced by treatment of spermatogonial (premeiotic) cells with the chemical mutagen N-ethyl-N-nitrosourea (ENU). Treatment of postmeiotic gametes with ENU induces specific-locus mutations at a higher rate than premeiotic regimens, suggesting that postmeiotic mutagenesis protocols could be useful in some screening strategies. Whereas there is extensive evidence that ENU induces point mutations in premeiotic cells, the range of mutations induced in postmeiotic zebrafish germ cells has been less thoroughly characterized. Here we report the identification and analysis of five mutations induced by postmeiotic ENU treatment. One mutation, snh(st1), is a translocation involving linkage group (LG) 11 and LG 14. The other four mutations, oep(st2), kny(st3), Df(LG 13)(st4), and cyc(st5), are deletions, ranging in size from less than 3 cM to greater than 20 cM. These results show that germ cell stage is an important determinant of the type of mutations induced. The induction of chromosomal rearrangements may account for the elevated frequency of specific-locus mutations observed after treatment of postmeiotic gametes with ENU.

Nodal signaling and the zebrafish organizer.

Systematic genetic screens in zebrafish have led to the discovery of mutations that affect organizer function and development. The molecular isolation and phenotypic analysis of the affected genes have revealed that TGF-beta signals of the Nodal family play a key role in organizer formation. The activity of the Nodal signals Cyclops and Squint is regulated extracellularly by the EGF-CFC cofactor One-eyed Pinhead and by antagonists belonging to the Lefty family of TGF-beta molecules. In the absence of Nodal signaling, the fate of cells in the organizer is transformed from dorsal mesoderm to neural ectoderm. Differential Nodal signaling also patterns the organizer along the anterior-posterior axis, with high levels required for anterior cell fates and lower levels for posterior fates. In addition, Nodal signaling cooperates with the homeodomain transcription factor Bozozok in organizer formation and neural patterning. The combination of genetic, molecular and embryological approaches in zebrafish has thus provided a framework to understand the mechanisms underlying organizer development.

Loss-of-function mutations in growth differentiation factor-1 (GDF1) are associated with congenital heart defects in humans.

Congenital heart defects (CHDs) are among the most common birth defects in humans (incidence 8-10 per 1,000 live births). Although their etiology is often poorly understood, most are considered to arise from multifactorial influences, including environmental and genetic components, as well as from less common syndromic forms. We hypothesized that disturbances in left-right patterning could contribute to the pathogenesis of selected cardiac defects by interfering with the extrinsic cues leading to the proper looping and vessel remodeling of the normally asymmetrically developed heart and vessels. Here, we show that heterozygous loss-of-function mutations in the human GDF1 gene contribute to cardiac defects ranging from tetralogy of Fallot to transposition of the great arteries and that decreased TGF- beta signaling provides a framework for understanding their pathogenesis. These findings implicate perturbations of the TGF- beta signaling pathway in the causation of a major subclass of human CHDs.

MicroRNA function and mechanism: insights from zebra fish.

MicroRNAs (miRNAs) are small RNAs that bind to the 3 UTR of mRNAs. We are using zebra fish as a model system to study the developmental roles of miRNAs and to determine the mechanisms by which miRNAs regulate target mRNAs. We generated zebra fish embryos that lack the miRNA-processing enzyme Dicer. Mutant embryos are devoid of mature miRNAs and have morphogenesis defects, but differentiate multiple cell types. Injection of miR-430 miRNAs, a miRNA family expressed at the onset of zygotic transcription, rescues the early morphogenesis defects in dicer mutants. miR-430 accelerates the decay of hundreds of maternal mRNAs and induces the deadenylation of target mRNAs. These studies suggest that miRNAs are not obligatory components of all fate specification or signaling pathways but facilitate developmental transitions and induce the deadenylation and decay of hundreds of target mRNAs.

Direct homeodomain-DNA interaction in the autoregulation of the fushi tarazu gene.

A major problem in the elucidation of the molecular mechanisms governing development is the distinction between direct and indirect regulatory interactions among developmental control genes. In vivo studies have indicated that the Drosophila segmentation gene fushi tarazu (ftz) directly or indirectly autoregulates its expression. Here we describe a generally applicable experimental approach which establishes a direct in vivo interaction of the homeodomain protein ftz with the ftz cis-autoregulatory control region. In vitro studies have shown that the DNA-binding specificity of the ftz homeodomain can be changed by a single amino-acid substitution in the recognition helix (Gln 50----Lys). Whereas wild-type ftz homeodomain binds preferentially to a CCATTA motif, the mutant homeodomain (ftzQ50K) recognizes a GGATTA motif. We now find that the in vivo activity of an ftz autoregulatory enhancer element is reduced by mutations of putative ftz-binding sites to GGATTA. This down-regulatory effect is specifically suppressed in vivo by the DNA-binding specificity mutant ftzQ50K. These results establish a direct positive autoregulatory feedback mechanism in the regulation of this homeobox gene.

Analysis of a fushi tarazu autoregulatory element: multiple sequence elements contribute to enhancer activity.

Regulatory sequences or factors involved in the regulation of target genes of Drosophila homeodomain proteins are largely unknown. Here, we identify sequence elements that are involved in the function of the fushi tarazu (ftz) autoregulatory element AE, a direct in vivo target of the homeodomain protein ftz. A systematic deletion analysis of AE in transgenic embryos defines multiple elements that are redundantly involved in enhancer activity. Sequences juxtaposed to ftz binding sites are not strictly required for enhancer function. Several sequence motifs are conserved in other developmentally regulated genes of Drosophila melanogaster and in the AE homologue of Drosophila virilis. The D. virilis AE is functional in D. melanogaster. The sequence motifs identified here are candidate elements contributing to the target specificity of the homeodomain protein ftz.

The zebrafish Nodal signal Squint functions as a morphogen.

Secreted morphogens induce distinct cellular responses in a concentration-dependent manner and act directly at a distance. The existence of morphogens during mesoderm induction and patterning in vertebrates has been highly controversial, and it remains unknown whether endogenous mesoderm inducers act directly as morphogens, function locally or act through relay mechanisms. Here we test the morphogen properties of Cyclops and Squint-two Nodal-related transforming growth factor-beta signals required for mesoderm formation and patterning in zebrafish. Whereas different levels of both Squint and Cyclops can induce different downstream genes, we find that only Squint can function directly at a distance. These results indicate that Squint acts as a secreted morphogen that does not require a relay mechanism.

Functional specificity of the homeodomain protein fushi tarazu: the role of DNA-binding specificity in vivo.

The mechanisms determining the functional specificity of Drosophila homeodomain proteins are largely unknown. Here, the role of DNA-binding specificity for the in vivo function of the homeodomain protein fushi tarazu (ftz) is analyzed. We find that specific DNA binding is an important but not sufficient determinant of the functional specificity of ftz in vivo: The ftz DNA-binding specificity mutant ftzQ50K retains partial ftz wild-type activity in gene activation and phenotypic rescue assays. Furthermore, specificity mutations in a ftz-in vivo binding site only partially reduce enhancer activity as compared to null mutations of this site. Despite bicoid-like DNA-binding specificity ftzQ50K does not activate natural or artificial bcd target genes in the realms of ftz. These results are discussed in the light of recent observations on the mechanism of action of the yeast homeodomain protein alpha 2.

Nodal signalling in vertebrate development.

Communication between cells during early embryogenesis establishes the basic organization of the vertebrate body plan. Recent work suggests that a signalling pathway centering on Nodal, a transforming growth factor beta-related signal, is responsible for many of the events that configure the vertebrate embryo. The activity of Nodal signals is regulated extracellularly by EGF-CFC cofactors and antagonists of the Lefty and Cerberus families of proteins, allowing precise control of mesoderm and endoderm formation, the positioning of the anterior-posterior axis, neural patterning and left-right axis specification.