Maternally controlled (beta)-catenin-mediated signaling is required for organizer formation in the zebrafish.

We have identified and characterized a zebrafish recessive maternal effect mutant, ichabod, that results in severe anterior and dorsal defects during early development. The ichabod mutation is almost completely penetrant, but exhibits variable expressivity. All mutant embryos fail to form a normal embryonic shield; most fail to form a head and notochord and have excessive development of ventral tail fin tissue and blood. Abnormal dorsal patterning can first be observed at 3.5 hpf by the lack of nuclear accumulation of (beta)-catenin in the dorsal yolk syncytial layer, which also fails to express bozozok/dharma/nieuwkoid and znr2/ndr1/squint. At the onset of gastrulation, deficiencies in expression of dorsal markers and expansion of expression of markers of ventral tissues indicate a dramatic alteration of dorsoventral identity. Injection of (beta)-catenin RNA markedly dorsalized ichabod embryos and often completely rescued the phenotype, but no measurable dorsalization was obtained with RNAs encoding upstream Wnt pathway components. In contrast, dorsalization was obtained when RNAs encoding either Bozozok/Dharma/Nieuwkoid or Znr2/Ndr1/Squint were injected. Moreover, injection of (beta)-catenin RNA into ichabod embryos resulted in activation of expression of these two genes, which could also activate each other. RNA injection experiments strongly suggest that the component affected by the ichabod mutation acts on a step affecting (beta)-catenin nuclear localization that is independent of regulation of (beta)-catenin stability. This work demonstrates that a maternal gene controlling localization of (beta)-catenin in dorsal nuclei is necessary for dorsal yolk syncytial layer gene activity and formation of the organizer in the zebrafish.

[1]  T. Hirano,et al.  Cooperative roles of Bozozok/Dharma and Nodal-related proteins in the formation of the dorsal organizer in zebrafish , 2000, Mechanisms of Development.

[2]  D. M. Ferkey,et al.  Interaction among Gsk-3, Gbp, Axin, and APC in Xenopus Axis Specification , 2000, The Journal of cell biology.

[3]  I. Dominguez,et al.  Dorsal downregulation of GSK3beta by a non-Wnt-like mechanism is an early molecular consequence of cortical rotation in early Xenopus embryos. , 2000, Development.

[4]  W. Birchmeier,et al.  Requirement for β-Catenin in Anterior-Posterior Axis Formation in Mice , 2000, The Journal of cell biology.

[5]  E. Ober,et al.  Signals from the yolk cell induce mesoderm, neuroectoderm, the trunk organizer, and the notochord in zebrafish. , 1999, Developmental biology.

[6]  Kathleen E. Rankin,et al.  Regulation of Glycogen Synthase Kinase 3β and Downstream Wnt Signaling by Axin , 1999, Molecular and Cellular Biology.

[7]  S. Sokol,et al.  Wnt signaling and dorso-ventral axis specification in vertebrates. , 1999, Current opinion in genetics & development.

[8]  Allan Bradley,et al.  Requirement for Wnt3 in vertebrate axis formation , 1999, Nature Genetics.

[9]  C. Larabell,et al.  Establishment of the Dorsal–Ventral Axis inXenopus Embryos Coincides with the Dorsal Enrichment of Dishevelled That Is Dependent on Cortical Rotation , 1999, The Journal of cell biology.

[10]  Bruce A. Yankner,et al.  β-Trcp couples β-catenin phosphorylation-degradation and regulates Xenopus axis formation , 1999 .

[11]  W. Talbot,et al.  The EGF-CFC Protein One-Eyed Pinhead Is Essential for Nodal Signaling , 1999, Cell.

[12]  M. Gates,et al.  The zebrafish bozozok locus encodes Dharma, a homeodomain protein essential for induction of gastrula organizer and dorsoanterior embryonic structures. , 1999, Development.

[13]  R Abagyan,et al.  A genetic linkage map for zebrafish: comparative analysis and localization of genes and expressed sequences. , 1999, Genome research.

[14]  A. Kuroiwa,et al.  Removal of vegetal yolk causes dorsal deficencies and impairs dorsal-inducing ability of the yolk cell in zebrafish , 1999, Mechanisms of Development.

[15]  C. Wright,et al.  Zebrafish nodal-related 2 encodes an early mesendodermal inducer signaling from the extraembryonic yolk syncytial layer. , 1998, Developmental biology.

[16]  R. Ho,et al.  The nieuwkoid gene characterizes and mediates a Nieuwkoop-center-like activity in the zebrafish , 1998, Current Biology.

[17]  S. Ekker,et al.  Evidence for a frizzled-mediated wnt pathway required for zebrafish dorsal mesoderm formation. , 1998, Development.

[18]  M. Gates,et al.  Zebrafish organizer development and germ-layer formation require nodal-related signals , 1998, Nature.

[19]  H. Maischein,et al.  Function of zebrafish β-catenin and TCF-3 in dorsoventral patterning , 1998, Mechanisms of Development.

[20]  Jian Zhang,et al.  The Role of Maternal VegT in Establishing the Primary Germ Layers in Xenopus Embryos , 1998, Cell.

[21]  Y. Sasai,et al.  A novel homeobox gene, dharma, can induce the organizer in a non-cell-autonomous manner. , 1998, Genes & development.

[22]  I B Dawid,et al.  Zebrafish nodal-related genes are implicated in axial patterning and establishing left-right asymmetry. , 1998, Developmental biology.

[23]  R. Moon,et al.  From cortical rotation to organizer gene expression: toward a molecular explanation of axis specification in Xenopus , 1998, BioEssays : news and reviews in molecular, cellular and developmental biology.

[24]  Margaret R. Thomson,et al.  Vertebrate genome evolution and the zebrafish gene map , 1998, Nature Genetics.

[25]  D. M. Ferkey,et al.  GBP, an Inhibitor of GSK-3, Is Implicated in Xenopus Development and Oncogenesis , 1998, Cell.

[26]  Margaret R. Thomson,et al.  Vertebrate genome evolution and the zebrafish gene map , 1998, Nature Genetics.

[27]  S. Fisher,et al.  Differential regulation of chordin expression domains in mutant zebrafish. , 1997, Developmental biology.

[28]  R. Nusse,et al.  Wnt signaling: a common theme in animal development. , 1997, Genes & development.

[29]  R. Toyama,et al.  lim6, a novel LIM homeobox gene in the zebrafish: Comparison of its expression pattern with lim1 , 1997, Developmental dynamics : an official publication of the American Association of Anatomists.

[30]  E. Weinberg,et al.  Bone morphogenetic protein-4 expression characterizes inductive boundaries in organs of developing zebrafish , 1997, Development Genes and Evolution.

[31]  P. S. Klein,et al.  Activation of the Wnt signaling pathway: a molecular mechanism for lithium action. , 1997, Developmental biology.

[32]  S. Fisher,et al.  Loss of cerebum function ventralizes the zebrafish embryo. , 1997, Development.

[33]  W. Driever,et al.  Pattern formation in janus-mutant zebrafish embryos. , 1997, Developmental biology.

[34]  C. Larabell,et al.  Establishment of the Dorso-ventral Axis in Xenopus Embryos Is Presaged by Early Asymmetries in β-Catenin That Are Modulated by the Wnt Signaling Pathway , 1997, The Journal of cell biology.

[35]  A. Schier,et al.  Mutations affecting development of the notochord in zebrafish. , 1996, Development.

[36]  S. Neuhauss,et al.  Mutations affecting cell fates and cellular rearrangements during gastrulation in zebrafish. , 1996, Development.

[37]  M. Hosobuchi,et al.  Maternal beta-catenin establishes a 'dorsal signal' in early Xenopus embryos. , 1996, Development.

[38]  C D Stern,et al.  Restoration of the organizer after radical ablation of Hensen's node and the anterior primitive streak in the chick embryo. , 1996, Development.

[39]  A. Kuroiwa,et al.  Mesoderm induction in zebrafish , 1996, Nature.

[40]  H. Steinbeisser,et al.  β-catenin translocation into nuclei demarcates the dorsalizing centers in frog and fish embryos , 1996, Mechanisms of Development.

[41]  R. Moon,et al.  The axis-inducing activity, stability, and subcellular distribution of beta-catenin is regulated in Xenopus embryos by glycogen synthase kinase 3. , 1996, Genes & development.

[42]  J. Postlethwait,et al.  A homeobox gene essential for zebrafish notochord development , 1995, Nature.

[43]  D. Ransom,et al.  Intraembryonic hematopoietic cell migration during vertebrate development. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[44]  B. Gumbiner,et al.  beta-Catenin has Wnt-like activity and mimics the Nieuwkoop signaling center in Xenopus dorsal-ventral patterning. , 1995, Developmental biology.

[45]  R. Moon,et al.  Induction of a secondary embryonic axis in zebrafish occurs following the overexpression of β-catenin , 1995, Mechanisms of Development.

[46]  P. Gruss,et al.  Targeted mutation of the murine goosecoid gene results in craniofacial defects and neonatal death. , 1995, Development.

[47]  R. Behringer,et al.  Goosecoid is not an essential component of the mouse gastrula organizer but is required for craniofacial and rib development. , 1995, Development.

[48]  R. Moon,et al.  Zebrafish wnt8 and wnt8b share a common activity but are involved in distinct developmental pathways. , 1995, Development.

[49]  N. Perrimon,et al.  Dorsalizing and neuralizing properties of Xdsh, a maternally expressed Xenopus homolog of dishevelled. , 1995, Development.

[50]  S. Pierce,et al.  Regulation of Spemann organizer formation by the intracellular kinase Xgsk-3. , 1995, Development.

[51]  B. Gumbiner,et al.  Embryonic axis induction by the armadillo repeat domain of beta- catenin: evidence for intracellular signaling , 1995, The Journal of cell biology.

[52]  I B Dawid,et al.  Nodal induces ectopic goosecoid and lim1 expression and axis duplication in zebrafish. , 1995, Development.

[53]  P. McCrea,et al.  Overexpression of cadherins and underexpression of β-catenin inhibit dorsal mesoderm induction in early Xenopus embryos , 1994, Cell.

[54]  M. Allende,et al.  Expression of two zebrafish orthodenticle-related genes in the embryonic brain , 1994, Mechanisms of Development.

[55]  E M De Robertis,et al.  Expression of zebrafish goosecoid and no tail gene products in wild-type and mutant no tail embryos. , 1994, Development.

[56]  J. Joly,et al.  The ventral and posterior expression of the zebrafish homeobox gene eve1 is perturbed in dorsalized and mutant embryos. , 1993, Development.

[57]  D. Grunwald,et al.  Lithium perturbation and goosecoid expression identify a dorsal specification pathway in the pregastrula zebrafish. , 1993, Development.

[58]  R. Ho,et al.  The protein product of the zebrafish homologue of the mouse T gene is expressed in nuclei of the germ ring and the notochord of the early embryo. , 1992, Development.

[59]  J. Gerhart,et al.  Cortical rotation of the Xenopus egg: consequences for the anteroposterior pattern of embryonic dorsal development. , 1989, Development.

[60]  J. Gerhart,et al.  Early cellular interactions promote embryonic axis formation in Xenopus laevis. , 1984, Developmental biology.

[61]  D. Kimelman,et al.  Conservation of intracellular Wnt signaling components in dorsal-ventral axis formation in zebrafish , 1999, Development Genes and Evolution.

[62]  N. Ueno,et al.  Conservation of BMP signaling in zebrafish mesoderm patterning , 1997, Mechanisms of Development.

[63]  J. Gerhart,et al.  Formation and function of Spemann's organizer. , 1997, Annual review of cell and developmental biology.

[64]  Uwe Strähle,et al.  Dynamic microtubules and specification of the zebrafish embryonic axis , 1997, Current Biology.

[65]  E. Yamaha,et al.  Localized axis determinant in the early cleavage embryo of the goldfish, Carassius auratus , 1997, Development Genes and Evolution.

[66]  C. Larabell Establishment of the dorsoventral axis in Xenopus embryos is presaged by early asymmetries in β-catenin that are modulated by the Wnt signaling pathway , 1997 .

[67]  M. Westerfield The zebrafish book : a guide for the laboratory use of zebrafish (Danio rerio) , 1995 .

[68]  C. Niehrs,et al.  Vertebrate axis formation. , 1992, Current opinion in genetics & development.