Using forward genetics, we have identified the genes mutated in two classes of zebrafish fin mutants. The mutants of the first class are characterized by defects in embryonic fin morphogenesis, which are due to mutations in a Laminin subunit or an Integrin alpha receptor, respectively. The mutants of the second class display characteristic blistering underneath the basement membrane of the fin epidermis. Three of them are due to mutations in zebrafish orthologues of FRAS1, FREM1, or FREM2, large basement membrane protein encoding genes that are mutated in mouse bleb mutants and in human patients suffering from Fraser Syndrome, a rare congenital condition characterized by syndactyly and cryptophthalmos. Fin blistering in a fourth group of zebrafish mutants is caused by mutations in Hemicentin1 (Hmcn1), another large extracellular matrix protein the function of which in vertebrates was hitherto unknown. Our mutant and dose-dependent interaction data suggest a potential involvement of Hmcn1 in Fraser complex-dependent basement membrane anchorage. Furthermore, we present biochemical and genetic data suggesting a role for the proprotein convertase FurinA in zebrafish fin development and cell surface shedding of Fras1 and Frem2, thereby allowing proper localization of the proteins within the basement membrane of forming fins. Finally, we identify the extracellular matrix protein Fibrillin2 as an indispensable interaction partner of Hmcn1. Thus we have defined a series of zebrafish mutants modelling Fraser Syndrome and have identified several implicated novel genes that might help to further elucidate the mechanisms of basement membrane anchorage and of the disease's aetiology. In addition, the novel genes might prove helpful to unravel the molecular nature of thus far unresolved cases of the human disease.
Attenuated BMP1 Function Compromises Osteogenesis, Leading to Bone Fragility in Humans and Zebrafish
Bone morphogenetic protein 1 (BMP1) is an astacin metalloprotease with important cellular functions and diverse substrates, including extracellular-matrix proteins and antagonists of some TGFβ superfamily members. Combining whole-exome sequencing and filtering for homozygous stretches of identified variants, we found a homozygous causative BMP1 mutation, c.34G>C, in a consanguineous family affected by increased bone mineral density and multiple recurrent fractures. The mutation is located within the BMP1 signal peptide and leads to impaired secretion and an alteration in posttranslational modification. We also characterize a zebrafish bone mutant harboring lesions in bmp1a, demonstrating conservation of BMP1 function in osteogenesis across species. Genetic, biochemical, and histological analyses of this mutant and a comparison to a second, similar locus reveal that Bmp1a is critically required for mature-collagen generation, downstream of osteoblast maturation, in bone. We thus define the molecular and cellular bases of BMP1-dependent osteogenesis and show the importance of this protein for bone formation and stability.
Epithelial integrity requires the adhesion of cells to each other as well as to an underlying basement membrane. The modulation of adherence properties is crucial to morphogenesis and wound healing, and deregulated adhesion has been implicated in skin diseases and cancer metastasis. Here, we describe zebrafish that are mutant in the serine protease inhibitor Hai1a (Spint1la), which display disrupted epidermal integrity. These defects are further enhanced upon combined loss of hai1a and its paralog hai1b. By applying in vivo imaging, we demonstrate that Hai1-deficient keratinocytes acquire mesenchymal-like characteristics, lose contact with each other, and become mobile and more susceptible to apoptosis. In addition, inflammation of the mutant skin is evident, although not causative of the epidermal defects. Only later, the epidermis exhibits enhanced cell proliferation. The defects of hai1 mutants can be phenocopied by overexpression and can be fully rescued by simultaneous inactivation of the serine protease Matriptase1a (St14a), indicating that Hai1 promotes epithelial integrity by inhibiting Matriptase1a. By contrast, Hepatocyte growth factor (Hgf), a well-known promoter of epithelial-mesenchymal transitions and a prime target of Matriptase1 activity, plays no major role. Our work provides direct genetic evidence for antagonistic in vivo roles of Hai1 and Matriptase1a to regulate skin homeostasis and remodeling.KEY WORDS: Hai1, Spint1, Matriptase1, St14, HGF, Met, Epidermis, Scattering, EMT, Zebrafish Development 134, 3461-3471 (2007) DEVELOPMENT 3462 matriptase1 in the mouse skin was rescued by the concomitant overexpression of Hai1 (List et al., 2005). However, it remains to be demonstrated whether Hai1 repression of Matriptase1 is necessary for normal epidermal development.Here, we describe the roles of two Hai1 and a Matriptase1 homologues during skin development in the zebrafish (Danio rerio), based on mutant and antisense-mediated loss-of-function studies. During embryonic and larval stages, the zebrafish epidermis is bilayered, consisting of a basal and an outer layer of keratinocytes (Le Guellec et al., 2004). As in mammals, basal keratinocytes are attached to the basement membrane via hemi-desmosomes and to each other via desmosomes (Sonawane et al., 2005), and are characterized by the expression of the p53-related transcription factor ⌬Np63 (also known as Tp73l -Zebrafish Information Network) (Bakkers et al., 2002). Zebrafish hai1a (also known as spint1la -Zebrafish Information Network; GenBank accession number NM_213152), hai1b (spint1lb; GenBank accession number EF424430) and matriptase1a are expressed in the developing basal layer of the epidermis. Via live imaging and marker analysis, we describe both epithelial and inflammatory skin phenotypes caused by loss of Hai1 activity, and thus provide direct genetic evidence for an essential role of Hai1 to maintain epithelial integrity of the epidermis during development. Furthermore, by inactivating both Hai1 and Matriptase1a, we demonstrate that ...
Formation of the adenohypophysis in mammalian embryos occurs via an invagination of the oral ectoderm to form Rathke's pouch, which becomes exposed to opposing dorsoventral gradients of signaling proteins governing specification of the different hormone-producing pituitary cell types. One signal promoting pituitary cell proliferation and differentiation to ventral cell types is Sonic hedgehog (Shh) from the oral ectoderm. To study pituitary formation and patterning in zebrafish, we cloned four cDNAs encoding different pituitary hormones, prolactin (prl), proopiomelancortin (pomc), thyroid stimulating hormone (tsh), and growth hormone (gh), and analyzed their expression patterns relative to that of the pituitary marker lim3. prl and pomc start to be expressed at the lateral edges of the lim3 expression domain, before pituitary cells move into the head. This indicates that patterning of the pituitary anlage and terminal differentiation of pituitary cells starts while cells are still organized in a placodal fashion at the anterior edge of the developing brain. Following the expression pattern of prl and pomc during development, we show that no pituitary-specific invagination equivalent to Rathke's pouch formation takes place. Rather, pituitary cells move inwards together with stomodeal cells during oral cavity formation, with medial cells of the placode ending up posterior and lateral cells ending up anterior, resulting in an anterior-posterior, rather than a dorsoventral, patterning of the adenohypophysis. Carrying out loss- and gain-of-function experiments, we show that Shh from the ventral diencephalon plays a crucial role during induction, patterning, and growth of the zebrafish adenohypophysis. The phenotypes are very similar to those obtained upon pituitary-specific inactivation or overexpression of Shh in mouse embryo, suggesting that the role of Shh during pituitary development has been largely conserved between fish and mice, despite the different modes of pituitary formation in the two vertebrate classes.
SummaryFgf3 signaling from the ventral diencephalon is required for early specification and subsequent survival of the zebrafish adenohypophysis
Haematopoietic stem cells (HSCs) are self-renewing stem cells capable of replenishing all blood lineages. In all vertebrate embryos that have been studied, definitive HSCs are generated initially within the dorsal aorta (DA) of the embryonic vasculature by a series of poorly understood inductive events. Previous studies have identified that signalling relayed from adjacent somites coordinates HSC induction, but the nature of this signal has remained elusive. Here we reveal that somite specification of HSCs occurs via the deployment of a specific endothelial precursor population, which arises within a sub-compartment of the zebrafish somite that we have defined as the endotome. Endothelial cells of the endotome are specified within the nascent somite by the activity of the homeobox gene meox1. Specified endotomal cells consequently migrate and colonize the DA, where they induce HSC formation through the deployment of chemokine signalling activated in these cells during endotome formation. Loss of meox1 activity expands the endotome at the expense of a second somitic cell type, the muscle precursors of the dermomyotomal equivalent in zebrafish, the external cell layer. The resulting increase in endotome-derived cells that migrate to colonize the DA generates a dramatic increase in chemokine-dependent HSC induction. This study reveals the molecular basis for a novel somite lineage restriction mechanism and defines a new paradigm in induction of definitive HSCs.
Skeletal muscle is an example of a tissue that deploys a self-renewing stem cell, the satellite cell, to effect regeneration. Recent in vitro studies have highlighted a role for asymmetric divisions in renewing rare "immortal" stem cells and generating a clonal population of differentiation-competent myoblasts. However, this model currently lacks in vivo validation. We define a zebrafish muscle stem cell population analogous to the mammalian satellite cell and image the entire process of muscle regeneration from injury to fiber replacement in vivo. This analysis reveals complex interactions between satellite cells and both injured and uninjured fibers and provides in vivo evidence for the asymmetric division of satellite cells driving both self-renewal and regeneration via a clonally restricted progenitor pool.
Skeletal syndromes are among the most common birth defects. Vertebrate skeletogenesis involves two major cell types: cartilage-forming chondrocytes and bone-forming osteoblasts. In vitro, both are under the control of retinoic acid (RA), but its exact in vivo effects remained elusive. Here, based on the positional cloning of the dolphin mutation, we have studied the role of the RA-oxidizing enzyme Cyp26b1 during cartilage and bone development in zebrafish. cyp26b1 is expressed in condensing chondrocytes as well as in osteoblasts and their precursors. cyp26b1 mutants and RA-treated wild-type fish display a reduction in midline cartilage and the hyperossification of facial and axial bones, leading to fusions of vertebral primordia, a defect not previously described in the context of RA signaling. Fusions of cervical vertebrae were also obtained by treating mouse fetuses with the specific Cyp26 inhibitor R115866. Together with data on the expression of osteoblast markers, our results indicate that temporal and spatial restriction of RA signaling by Cyp26 enzymes is required to attenuate osteoblast maturation and/or activity in vivo. cyp26b1 mutants may serve as a model to study the etiology of human vertebral disorders such as Klippel-Feil anomaly.
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