Determination of the zebrafish forebrain: induction and patterning

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Ang, S.-L., Conlon, R. A., Jin, O. and Rossant, J (1994). Positive and negative signals from mesoderm regulate the expression of mouse Otx2 in ectoderm explants. Development 120, 2979-2989.[Abstract]

Aruga, J., Yokota, N., Hashimoto, M., Furuichi, T., Fukuda, M. and Mikoshiba, K (1994). A novel zinc finger protein, Zic, is involved in neurogenesis, especially in the cell lineage for cerebellar granule cells. J. Neurochem 63, 1880-1890.[Medline]

Bally-Cuif, L. and Boncinelli, E (1997). Transcription factors and head formation in vertebrates. BioEssays 19, 127-135.[Medline]

Beddington, R. S. P (1994). Induction of a second neural axis by the mouse node. Development 120, 613-620.[Abstract]

Benedyk, M. J., Mullen, J. R., DiNardo, S (1994). odd-paired: a zinc finger pair-rule protein required for the timely activation of engrailed and wingless in Drosophila embryos. Genes Dev 8, 105-117.[Abstract/Free Full Text]

Blitz, I. L. and Cho, K. W. Y (1995). Anterior neuroectoderm is progressively induced during gastrulation: the role of the Xenopus homeobox gene orthodenticle. Development 121, 993-1004.[Abstract]

Bouwmeester, T., Kim, S., Sasai, Y., Lu, B. and De Robertis, E (1996). Cerberus is a head-inducing secreted factor expressed in the anterior endoderm of Spemann's organizer. Nature 382, 595-601.[Medline]

Bradley, L., Wainstock, D. and Sive, H. L (1996). Positive and negative signals modulate formation of the Xenopus cement gland. Development 122, 2739-2750.[Abstract]

Church, G. M. and Gilbert, W (1984). Genomic sequencing. Proc. Natl. Acad. Sci. USA 81, 1991-1995.[Abstract/Free Full Text]

Driever, W., Stemple, D., Schier, A. and Solnica-Krezel, L (1994). Zebrafish: genetic tools for studying vertebrate development. Trends Genet 10, 152-159.[Medline]

Eyal-Giladi, H (1954). Dynamic aspects of neural induction. Arch. Biol 65, 180-259.

Fisher, S., Amacher, S. and Halpern, M (1997). Loss of cerebum function ventralizes the zebrafish embryo. Development 124, 1301-1311.[Abstract]

Foley, A., Storey, K. and Stern, C (1997). The prechordal region lacks neural inducing ability, but can confer anterior character to more posterior neuroepithelium. Development 124, 2983-2996.[Abstract]

Furutani-Seiki, M., Jiang, Y., Brand, M., Heisenberg, C., Houart, C., Beuchle, D., van Eeden, F., Granato, M., Haffter, P., Hammerschmidt, M., Kane, D., Kelsh, R., Mullins, M., Odenthal, J. and Nusslein-Volhard, C (1996). Neural degeneration mutants in the zebrafish, Danio rerio. Development 123, 229-239.[Abstract]

Gerhart, J (1996). Johannes Holtfreter's contributions to ongoing studies of the organizer. Dev. Dyn 205, 245-256.[Medline]

Glinka, A., Wu, W., Delius, H., Monaghan, A., Blumenstock, C. and Niehrs, C (1998). Dickkopf-1 is a member of a new family of secreted proteins and functions in head induction. Nature 391, 357-362.[Medline]

Glinka, A., Wu, W., Onichtchouk, D., Blumenstock, C. and Niehrs, C (1997). Head induction by simultaneous repression of Bmp and Wnt signalling in Xenopus. Nature 389, 517-519.[Medline]

Hammerschmidt, M., Pelegri, F., Mullins, M., Kane, D., Brand, M., van Eeden, F., Furutani-Seiki, M., Granato, M., Haffter, P., Heisenberg, C., Jiang, Y., Kelsh, R., Odenthal, J., Warga, R. and Nusslein-Volhard, C (1996). Mutations affecting morphogenesis during gastrulation and tail formation in the zebrafish, Danio rerio. Development 123, 143-151.[Abstract]

Hammerschmidt, M., Pelegri, F., Mullins, M., Kane, D., van Eeden, F., Granato, M., Brand, M., Furutani-Seiki, M., Haffter, P., Heisenberg, C., Jiang, Y., Kelsh, R., Odenthal, J., Warga, R. and Nusslein-Volhard, C (1996). dino and mercedes, two genes regulating dorsal development in the zebrafish embryo. Development 123, 95-102.[Abstract]

Hammerschmidt, M., Serbedzija, G. and McMahon, A (1996). Genetic analysis of dorsoventral pattern formation in the zebrafish: requirement of a BMP-like ventralizing activity and its dorsal repressor. Genes Dev 10, 2452-2461.[Abstract/Free Full Text]

Hawley, S. H., Wunnenberg-Stapleton, K., Hashimoto, C., Laurent, M. N., Watabe, T., Blumberg, B. W. and Cho, K. W (1995). Disruption of BMP signals in embryonic Xenopus ectoderm leads to direct neural induction. Genes Dev 9, 2923-2935.[Abstract/Free Full Text]

Houart, C., Westerfield, M. and Wilson, S. W (1998). A small population of anterior cells patterns the forebrain during zebrafish gastrulation. Nature 391, 788-792.[Medline]

Kaestner, K., Schutz, G. and Monaghan, A (1996). Expression of the winged helix genes fkh-4 and fkh-5 defines domains in the central nervous system. Mech Dev 55, 221-230.[Medline]

Kimmel, C. B (1989). Genetics and early development of zebrafish. Trends Genet 5, 283-288.[Medline]

Kimmel, C. B (1993). Patterning the brain of the zebrafish embryo. Annu. Rev. Neurosci 16, 707-732.[Medline]

Kimmel, C. B. and Warga, R. M (1987). Indeterminate cell lineage of the zebrafish embryo. Dev. Biol 124, 269-280.[Medline]

Kimmel, C. B., Warga, R. M. and Schilling, T. F (1990). Origin and organization of the zebrafish fate map. Development 108, 581-594.[Abstract/Free Full Text]

Kishimoto, Y., Lee, K.-H., Zon, L., Hammerschmidt, M. and Schulte-Merker, S (1997). The molecular nature of zebrafish swirl: BMP2 function is essential during early dorsoventral patterning. Development 124, 4457-4466.[Abstract]

Knecht, A. K. and Harland, R. M (1997). Mechanisms of dorsal-ventral patterning in noggin-induced neural tissue. Development 124, 2477-2488.[Abstract]

Kolm, P. J. and Sive, H. L (1997). Retinoids and posterior neural induction: a reevaluation of Nieuwkoop's two-step hypothesis. Cold Spring Harbor Symp. Quant. Biol 62, 511-521.[Abstract/Free Full Text]

Krauss, S., Johansen, T., Korzh, V., Moens, U., Ericson, J. U. and Fjose, A (1991). Zebrafish pax [zf-a]: A paired box-containing gene expressed in the neural tube. EMBO J 10, 3609-3619.[Medline]

Kuo, J., Patel, M., Gamse, J., Merzdorf, C., Apekin, V., Liu, X. and Sive, H. L (1998). opl: a zinc finger protein that regulates neural determination and patterning in Xenopus. Development 125, 2867-2882.[Abstract]

Labosky, P. A., Winnier, G. E., Jetton, T. L., Hargett, L., Ryan, A. K., Rosenfeld, M. G., Parlow, A. F. and Hogan, B. L. M (1997). The winged helix gene, Mf3, is required for normal development of the diencephalon and midbrain, postnatal growth and the milk-ejection reflex. Development 124, 1263-1274.[Abstract]

Li, Y., Allende, M. L., Finkelstein, R. and Weinberg, E. S (1994). Expression of two zebrafish orthodenticle -related genes in the embryonic brain. Mech. Dev 48, 229-244.[Medline]

Macdonald, R., Xu, Q., Barth, K. A., Mikkola, I., Holder, N., Fjose, A., Krauss, S. and Wilson, S. W (1994). Regulatory gene expression boundaries demarcate sites of neuronal differentiation in the embryonic zebrafish forebrain. Neuron 13, 1039-1053.[Medline]

McGrew, L., Hoppler, S. and Moon, R (1997). Wnt and FGF pathways cooperatively pattern anteroposterior neural ectoderm in Xenopus. Mech Dev 69, 105-114.[Medline]

Miller-Bertoglio, V., Fisher, S., Sanchez, A., Mullins, M. and Halpern, M (1997). Differential regulation of chordin expression domains in mutant zebrafish. Dev Biol 192, 537-550.[Medline]

Mizuno, T., Yamaha, E., Wakahara, M., Kurolwa, A. and Takeda, H (1996). Mesoderm induction in zebrafish. Nature 383, 131-132.

Nagai, T., Aruga, J., Takada, S., Gunther, T., Sporle, R., Schughart, K. and Mikoshiba, K (1997). The expression of the mouse Zic1, Zic2, and Zic3 gene suggests an esssential role for Zic genes in body pattern formation. Dev. Biol 182, 299-313.[Medline]

Nakata, K., Nagai, T., Aruga, J. and Mikoshiba, K (1997). Xenopus Zic3, a primary regulator both in neural and neural crest development. Proc Natl Acad Sci. USA 94, 11980-11985.[Abstract/Free Full Text]

Neave, B., Rodaway, A., Wilson, S. W., Patient, R. and Holder, N (1995). Expression of zebrafish GATA3 (gta3) during gastrulation and neurulation suggests a role in the specification of cell fate. Mech. Dev 51, 169-182.[Medline]

Oppenheimer, J. M (1959). Extraembryonic transplantations of sections of the Fundulus embryonic shield. J. Exp. Zool 140, 247-268.

Oppenheimer, J. M (1936). Transplantation experiments on developing teleosts ( Fundulus and Perca ). J. Exp. Zool 72, 409-437.

Oxtoby, E. and Jowett, T (1993). Cloning of the zebrafish Krox-20 gene (krx20) and its expression during hindbrain development. Nucl. Acids Res 21, 1087-1095.[Abstract/Free Full Text]

Pannese, M., Polo, C., Andreazzoli, M., Vignali, R., Kablar, B., Barsacchi, B. and Boncinelli, B (1995). The Xenopus homologue of Otx2 is a maternal homeobox gene that demarcates and specifies anterior body regions. Development 121, 707-720.[Abstract]

Pera, E. M. and Kessel, M (1997). Patterning of the chick forebrain anlage by the prechordal plate. Development 124, 4153-4162.[Abstract]

Piccolo, S., Sasai, Y., Lu, B. and De Robertis, E. M (1996). Dorsoventral patterning in Xenopus: inhibition of ventral signals by direct binding of chordin to BMP-4. Cell 86, 589-598.[Medline]

Psychoyos, D. and Stern, C (1996). Restoration of the organizer after radicalablation of Hensen's node and the anterior primitive streak in the chick embryo. Development 122, 3263-3273.[Abstract]

Puelles, L. and Rubenstein, J (1993). Expression patterns of homeobox and other putative regulatory genes in the embryonic mouse forebrain suggest a neuromeric organization. Trends Neurosci 16, 472-479.[Medline]

Roberts, C., Platt, N., Streit, A., Schachne, r. M. and Stern, C (1991). The L5 epitope: an early marker for neural induction in the chick embryo and its involvement in inductive interactions. Development 112, 959-970.[Abstract]

Rossant, J. and Hopkins, N (1992). Of fin and fur: mutational analysis of vertebrate embryonic development. Genes Dev 6, 1-13.[Free Full Text]

Rubenstein, J. L. R., Nartinez, S., Shimamura, K. and Puelles, L (1994). The embryonic vertebrate forebrain: the prosomeric model. Science 266, 578-580.[Free Full Text]

Sagerstr\232m, C. G., Grinblat, Y. and Sive, H (1996). Anteroposterior patterning in the zebrafish, Danio rerio: an explant assay reveals inductive and suppressive cell interactions. Development 122, 1873-1883.[Abstract]

Sasai, Y. and De Robertis, E. M (1997). Ectodermal patterning in vertebrate embryos. Dev. Biol 182, 5-20.[Medline]

Sasai, Y., Lu, B., Steinbeisser, H., Geissert, D., Gont, L. and De Robertis, E (1994). Xenopus chordin: a novel dorsalizing factor activated by organizer-specific homeobox genes. Cell 79, 779-790.[Medline]

Schmidt, J. E., Suzuki, A., Ueno, N., Kimelman, D (1995). Localized BMP-4 mediates dorsal/ventral patterning in the early Xenopus embryo. Dev. Biol 169, 37-50.[Medline]

Schulte-Merker, S., Lee, K. J., McMahon, A. P. and Hammerschmidt, M (1997). The zebrafish organizer requires chordino. Nature 387, 862-863.[Medline]

Schulte-Merker, S., van Eeden, F., Halpern, M. E., Kimmel, C. B. and Nusslein-Volhard, C (1994). notail ( ntl ) is the zebrafish homologue of the mouse T ( brachyury ) gene. Development 120, 1009-1015.[Abstract]

Shih, J. and Fraser, S. E (1996). Characterizing the zebrafish organizer: microsurgical analysis at the early-shield stage. Development 122, 1313-1322.[Abstract]

Shih, J. and Fraser, S. E (1995). Distribution of tissue progenitors within the shield region of the zebrafish gastrula. Development 121, 2755-2765.[Abstract]

Simeone, A., Acompora, D., Mallamaci, A., Stornaiuolo, A., D'Apice, M. R., Nigro, V. and Boncinelli, E (1993). A vertebrate gene related to orthodenticle contains a homeodomain of the bicoid class and demarcates anterior neuroectoderm of the gastrulating mouse embryo. EMBO J 12, 2735-2747.[Medline]

Sive, H., Draper, B., Harland, R. and Weintraub, H (1990). Identification of a retinoic acid sensitive period during primary axis formation in Xenopus laevis. Genes Dev 4, 932-942.[Abstract/Free Full Text]

Sive, H. L., Hattori, K. and Weintraub, H (1989). Progressive determination during formation of the anteroposterior axis in Xenopus laevis. Cell 58, 171-80.[Medline]

Stachel, S. E., Grunwald, D. J. and Myers, P. Z (1993). Lithium perturbation and goosecoid expression identify a dorsal specification pathway in the pregastrula zebrafish. Development 117, 1261-1274.[Abstract]

Stewart, R. M. and Gerhart, J. C (1990). The anterior extent of dorsal development of the Xenopus embryonic axis depends on the quantity of organizer in the late blastula. Development 109, 363-372.[Abstract]

Storey, K. G., Crossley, J. M., De Robertis, E. M., Norris, W. F. and Stern, C. D (1992). Neural induction and regionalisation in the chick embryo. Development 114, 729-741.[Abstract]

Suzuki, A., Kaneko, E., Ueno, N. and Hemmati-Brivanlou, A (1997). Regulation of epidermal induction by BMP2 and BMP7 signalling. Dev. Biol 189, 112-122.[Medline]

Thisse, C., Thisse, B., Halpern, M. E. and Postlethwait, J. H (1994). goosecoid expression in neurectoderm and mesendoderm is disrupted in zebrafish cyclops gastrula. Dev. Biol 164, 420-429.[Medline]

Thomas, P. and Beddington, R (1996). Anterior primitive endoderm may be responsible for patterning the anterior neural plate in the mouse embryo. Curr. Biol 6, 1487-1496.[Medline]

Toyama, R., O'Connel, M. L., Wright, C. V. E., Kuehn, M. R. and Dawid, I. B (1995). nodal induces ectopic goosecoid and lim1 expression and axis duplication in zebrafish. Development 121, 383-391.[Abstract]

Varlet, I., Collignon, J. and Robertson, E. J (1997). nodal expression in the primitive endoderm is required for specification of the anterior axis during mouse gastrulation. Development 124, 1033-1044.[Abstract]

Vodicka, M. and Gerhart, J (1995). Blastomere derivation and domains of gene expression in the Spemann Organizer of Xenopuslaevis. Development 121, 3505-3518.[Abstract]

Wehr, R., Mansouri, A., de Maeyer, T. and Gruss, P (1997). Fkh5-deficient mice show dysgenesis in the caudal midbrain and hypothalamic mammillary body. Development 124, 4447-4456.[Abstract]

Wilson, P. A., Lagna, G., Suzuki, A. and Hemmati-Brivanlou, A (1997). Concentration-dependent patterning of the Xenopus ectoderm by BMP4 and its signal transducer Smad1. Development 124, 3177-3184.[Abstract]

Woo, K. and Fraser, S (1997). Specification of the zebrafish nervous system by nonaxial signals. Science 277, 254-257.[Abstract/Free Full Text]

Woo, K. and Fraser, S. E (1995). Order and coherence in the fate map of the zebrafish nervous system. Development 121, 2595-2609.[Abstract]

Zhang, J., Talbot, W. and Schier, A (1998). Positional cloning identifies zebrafish one-eyed pinhead as a permissive EGF-related ligand required during gastrulation. Cell 92, 241-251.[Medline]

Zimmerman, L. B., De Jesus-Escobar, J. M. and Harland, R. M (1996). The Spemann organizer signal noggin binds and inactivates bone morphogenetic protein 4. Cell 86, 599-606.[Medline]

Zoltewicz, J. S. and Gerhart, J. C (1997). The Spemann organizer of Xenopus is patterned along its anteroposterior axis at the earliest gastrula stage. Dev. Biol 192, 482-491.[Medline]

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				L Saude, K Woolley, P Martin, W Driever, and D. Stemple Axis-inducing activities and cell fates of the zebrafish organizer Development, January 8, 2000; 127(16): 3407 - 3417. [Abstract] [PDF]

				A Camus, B. Davidson, S Billiards, P Khoo, J. Rivera-Perez, M Wakamiya, R. Behringer, and P. Tam The morphogenetic role of midline mesendoderm and ectoderm in the development of the forebrain and the midbrain of the mouse embryo Development, January 5, 2000; 127(9): 1799 - 1813. [Abstract] [PDF]

				Z. Varga, J Wegner, and M Westerfield Anterior movement of ventral diencephalic precursors separates the primordial eye field in the neural plate and requires cyclops Development, January 12, 1999; 126(24): 5533 - 5546. [Abstract] [PDF]

				F Ristoratore, M Carl, K Deschet, L Richard-Parpaillon, D Boujard, J Wittbrodt, D Chourrout, F Bourrat, and J. Joly The midbrain-hindbrain boundary genetic cascade is activated ectopically in the diencephalon in response to the widespread expression of one of its components, the medaka gene Ol-eng2 Development, January 9, 1999; 126(17): 3769 - 3779. [Abstract] [PDF]

				K. Mizugishi, J. Aruga, K. Nakata, and K. Mikoshiba Molecular Properties of Zic Proteins as Transcriptional Regulators and Their Relationship to GLI Proteins J. Biol. Chem., January 12, 2001; 276(3): 2180 - 2188. [Abstract] [Full Text] [PDF]