Aamar, E., and Dawid, I.B. (2008) Protocadherin-18a has a role in cell adhesion, behavior and migration in zebrafish development. Developmental Biology. 318(2):335-346

Ahmed, M.U., Maurya, A.K., Cheng, L., Jorge, E.C., Schubert, F.R., Maire, P., Basson, M.A., Ingham, P.W., Dietrich, S. (2017) Engrailed controls epaxial-hypaxial muscle innervation and the establishment of vertebrate three-dimensional mobility. Developmental Biology. 430(1):90-104

Altbürger, C., Holzhauser, J., Driever, W. (2023) CRISPR/Cas9-based QF2 knock-in at the tyrosine hydroxylase (th) locus reveals novel th-expressing neuron populations in the zebrafish mid- and hindbrain. Frontiers in Neuroanatomy. 17:11968681196868

Amores, A., Force, A., Yan, Y.-L. Joly, L., Amemiya, C., Fritz, A., Ho, R., Langeland, J., Prince, V., Wang, Y.-L., Westerfield, M., Ekker, M., and Postlethwait, J.H. (1998) Zebrafish hox clusters and vertebrate genome evolution. Science (New York, N.Y.). 282:1711-1714

Baldera, D., Baxendale, S., van Hateren, N.J., Marzo, M., Glendenning, E., Geng, F.S., Yokoya, K., Knight, R.D., Whitfield, T.T. (2023) Enhancer trap lines with GFP driven by smad6b and frizzled1 regulatory sequences for the study of epithelial morphogenesis in the developing zebrafish inner ear. Journal of anatomy. 243(1):78-89

Belting, H.G., Hauptmann, G., Meyer, D., Abdelilah-Seyfried, S., Chitnis, A., Eschbach, C., Söll, I., Thisse, C., Thisse, B., Artinger, K., Lunde, K., and Driever, W. (2001) spiel ohne grenzen/pou2 is required during establishment of the zebrafish midbrain-hindbrain boundary organizer. Development (Cambridge, England). 128(21):4165-4176

Bertrand, C., Chatonnet, A., Takke, C., Yan, Y.-L., Postlethwait, J., Toutant, J.P., and Cousin, X. (2001) Zebrafish Acetylcholinesterase Is Encoded by a Single Gene Localized on Linkage Group 7: Gene structure and polymorphism; molecular forms and expression pattern during development. The Journal of biological chemistry. 276(1):464-474

Chen, Q., Takada, R., and Takada, S. (2012) Loss of Porcupine impairs convergent extension during gastrulation in zebrafish. Journal of Cell Science. 125(9):2224-2234

Clements, W.K., and Kimelman, D. (2005) LZIC regulates neuronal survival during zebrafish development. Developmental Biology. 283(2):322-334

Corallo, D., Schiavinato, A., Trapani, V., Moro, E., Argenton, F., and Bonaldo, P. (2013) Emilin3 is required for notochord sheath integrity and interacts with Scube2 to regulate notochord-derived Hedgehog signals. Development (Cambridge, England). 140(22):4594-4601

D'Aniello, E., Ravisankar, P., Waxman, J.S. (2015) Rdh10a Provides a Conserved Critical Step in the Synthesis of Retinoic Acid during Zebrafish Embryogenesis. PLoS One. 10:e0138588

Dolez, M., Nicolas, J.F., and Hirsinger, E. (2011) Laminins, via heparan sulfate proteoglycans, participate in zebrafish myotome morphogenesis by modulating the pattern of Bmp responsiveness. Development (Cambridge, England). 138(1):97-106

Dorsky, R.I., Itoh, M., Moon, R.T., and Chitnis, A. (2003) Two tcf3 genes cooperate to pattern the zebrafish brain. Development (Cambridge, England). 130(9):1937-1947

Ekker, M., Akimenko, M.-A., Allende, M.L., Smith, R., Drouin, G., Langille, R.M., Weinberg, E.S., and Westerfield, M. (1997) Relationships among msx gene structure and function in zebrafish and other vertebrates. Mol. Biol. Evol.. 14:1008-1022

Ellies, D.L., Langille, R.M., Martin, C.C., Akimenko, M.A., and Ekker, M. (1997) Specific craniofacial cartilage dysmorphogenesis coincides with a loss of dlx gene expression in retinoic acid-treated zebrafish embryos. Mechanisms of Development. 61(1-2):23-36

Erickson, T., Scholpp, S., Brand, M., Moens, C.B., and Waskiewicz, A. Jan (2007) Pbx proteins cooperate with Engrailed to pattern the midbrain-hindbrain and diencephalic-mesencephalic boundaries. Developmental Biology. 301(2):504-517

Eroglu, B., Wang, G., Tu, N., Sun, X., and Mivechi, N.F. (2006) Critical role of Brg1 member of the SWI/SNF chromatin remodeling complex during neurogenesis and neural crest induction in zebrafish. Developmental Dynamics : an official publication of the American Association of Anatomists. 235(10):2722-2735

Fjose, A., Eiken, H.G., Njolstad, P.R., Molven, A., and Hordvik, I. (1988) A zebrafish engrailed-like homeobox sequence expressed during embryogenesis. FEBS letters. 231:355-360

Flynt, A.S., Li, N., Thatcher, E.J., Solnica-Krezel, L., and Patton, J.G. (2007) Zebrafish miR-214 modulates Hedgehog signaling to specify muscle cell fate. Nature Genetics. 39(2):259-263

Fritz, A., Rozowski, M., Walker, C., and Westerfield, M. (1996) Identification of selected gamma-ray induced deficiencies in zebrafish using multiplex polymerase chain reaction. Genetics. 144(4):1735-1745

Gates, M.A., Kim, L., Egan, E.S., Cardozo, T., Sirotkin, H.I., Dougan, S.T., Lashkari, D., Abagyan, R., Schier, A.F., and Talbot, W.S. (1999) A genetic linkage map for zebrafish: comparative analysis and localization of genes and expressed sequences. Genome research. 9(4):334-347

Giraldez, A.J., Cinalli, R.M., Glasner, M.E., Enright, A.J., Thomson, M.J., Baskerville, S., Hammond, S.M., Bartel, D.P., and Schier, A.F. (2005) MicroRNAs Regulate Brain Morphogenesis in Zebrafish. Science (New York, N.Y.). 308(5723):833-838

Green, D.G., Whitener, A.E., Mohanty, S., Mistretta, B., Gunaratne, P., Yeh, A.T., Lekven, A.C. (2020) Wnt signaling regulates neural plate patterning in distinct temporal phases with dynamic transcriptional outputs. Developmental Biology. 462(2):152-164

Guillon, E., Bretaud, S., Ruggiero, F. (2016) Slow Muscle Precursors Lay Down a Collagen XV Matrix Fingerprint to Guide Motor Axon Navigation. The Journal of neuroscience : the official journal of the Society for Neuroscience. 36:2663-76

Hammond, K.L., Baxendale, S., McCauley, D.W., Ingham, P.W., and Whitfield, T.T. (2009) Expression of patched, prdm1 and engrailed in the lamprey somite reveals conserved responses to Hedgehog signaling. Evolution & development. 11(1):27-40

Hatta, K., BreMiller, R.A., Westerfield, M., and Kimmel, C.B. (1991) Diversity of expression of engrailed-like antigens in zebrafish. Development (Cambridge, England). 112:821-832

Hellemont, R.V., Blomme, T., Van de Peer, Y., and Marchal, K. (2007) Divergence of regulatory sequences in duplicated fish genes. Genome dynamics. 3:81-100

Hinits, Y., Osborn, D.P., and Hughes, S.M. (2009) Differential requirements for myogenic regulatory factors distinguish medial and lateral somitic, cranial and fin muscle fibre populations. Development (Cambridge, England). 136(3):403-414

Hinits, Y., Williams, V.C., Sweetman, D., Donn, T.M., Ma, T.P., Moens, C.B., and Hughes, S.M. (2011) Defective cranial skeletal development, larval lethality and haploinsufficiency in Myod mutant zebrafish. Developmental Biology. 358(1):102-12

Holland, P.W. and Williams, N.A. (1990) Conservation of engrailed-like homeobox sequences during vertebrate evolution. FEBS letters. 277:250-252

Huang, P., and Schier, A.F. (2009) Dampened Hedgehog signaling but normal Wnt signaling in zebrafish without cilia. Development (Cambridge, England). 136(18):3089-3098

Joly, J.S., Maury, M., Joly, C., Duprey, P., Boulekbache, H., and Condamine, H. (1992) Expression of a zebrafish caudal homeobox gene correlates with the establishment of posterior cell lineages at gastrulation. Differentiation; research in biological diversity. 50:75-87

Kim, C.H., Oda, T., Itoh, M., Jiang, D., Artinger, K.B., Chandrasekharappa, S.C., Driever, W., and Chitnis, A.B. (2000) Repressor activity of Headless/Tcf3 is essential for vertebrate head formation. Nature. 407(6806):913-916

Kim, S.-H., Shin, J., Park, H.-C., Yeo, S.-Y., Hong, S.-K., Han, S., Rhee, M., Kim, C.-H., Chitnis, A.B., and Huh, T.-L. (2002) Specification of an anterior neuroectoderm patterning by Frizzled8a-mediated Wnt8b signalling during late gastrulation in zebrafish. Development (Cambridge, England). 129(19):4443-4455

Kjaer-Sorensen, K., Engholm, D.H., Kamei, H., Morch, M.G., Kristensen, A.O., Zhou, J., Conover, C.A., Duan, C., and Oxvig, C. (2013) Pregnancy-associated plasma protein-A (PAPP-A) modulates early developmental rate in zebrafish independent of its proteolytic activity. The Journal of biological chemistry. 288(14):9982-92

Knight, R.D., Mebus, K., and Roehl, H.H. (2008) Mandibular arch muscle identity is regulated by a conserved molecular process during vertebrate development. Journal of experimental zoology. Part B, Molecular and developmental evolution. 310(4):355-369

Krauss, S., Maden, M., Holder, N., and Wilson, S.W. (1992) Zebrafish pax[b] is involved in the formation of the midbrain-hindbrain boundary. Nature. 360:87-89

Leerberg, D.M., Hopton, R.E., Draper, B.W. (2019) Fibroblast Growth Factor Receptors Function Redundantly During Zebrafish Embryonic Development. Genetics. 212(4):1301-1319

Lele, Z., Hartson, S.D., Martin, C.C., Whitesell, L., Matts, R.L., and Krone, P.H. (1999) Disruption of zebrafish somite development by pharmacologic inhibition of hsp90. Developmental Biology. 210(1):56-70

Li, J., Zhao, Y., He, L., Huang, Y., Yang, X., Yu, L., Zhao, Q., Dong, X. (2018) Znfl1s are essential for patterning the anterior-posterior axis of zebrafish posterior hindbrain by acting as direct target genes of retinoic acid. Mechanisms of Development. 155:27-33

LLeras Forero, L., Narayanan, R., Huitema, L.F.A., VanBergen, M., Apschner, A., Peterson-Maduro, J., Logister, I., Valentin, G., Morelli, L.G., Oates, A., Schulte-Merker, S. (2018) Segmentation of the zebrafish axial skeleton relies on notochord sheath cells and not on the segmentation clock. eLIFE. 7

Lunde, K., Belting, H.G., and Driever, W. (2004) Zebrafish pou5f1/pou2, homolog of mammalian Oct4, functions in the endoderm specification cascade. Current biology : CB. 14(1):48-55

Maekawa, M., Saito, S., Isobe, D., Takemoto, K., Miura, Y., Dobashi, Y., Yamasu, K. (2024) The Oct4-related PouV gene, pou5f3, mediates isthmus development in zebrafish by directly and dynamically regulating pax2a. Cells & development. 179:203933

Maurya, A.K., Tan, H., Souren, M., Wang, X., Wittbrodt, J., and Ingham, P.W. (2011) Integration of Hedgehog and BMP signalling by the engrailed2a gene in the zebrafish myotome. Development (Cambridge, England). 138(4):755-765

Miller, C.T., Yelon, D., Stainier, D.Y., and Kimmel, C.B. (2003) Two endothelin 1 effectors, hand2 and bapx1, pattern ventral pharyngeal cartilage and the jaw joint. Development (Cambridge, England). 130(7):1353-1365

Miyake, A., Nakayama, Y., Konishi, M., and Itoh, N. (2005) Fgf19 regulated by Hh signaling is required for zebrafish forebrain development. Developmental Biology. 288(1):259-275

Muto, A., Arai, K.I., and Watanabe, S. (2006) Rab11-FIP4 is predominantly expressed in neural tissues and involved in proliferation as well as in differentiation during zebrafish retinal development. Developmental Biology. 292(1):90-102

Nair, S., Li, W., Cornell, R., and Schilling, T.F. (2007) Requirements for Endothelin type-A receptors and Endothelin-1 signaling in the facial ectoderm for the patterning of skeletogenic neural crest cells in zebrafish. Development (Cambridge, England). 134(2):335-345

Nguyen-Chi, M.E., Bryson-Richardson, R., Sonntag, C., Hall, T.E., Gibson, A., Sztal, T., Chua, W., Schilling, T.F., and Currie, P.D. (2012) Morphogenesis and Cell Fate Determination within the Adaxial Cell Equivalence Group of the Zebrafish Myotome. PLoS Genetics. 8(10):e1003014

Osborn, D.P., Li, K., Hinits, Y., and Hughes, S.M. (2011) Cdkn1c drives muscle differentiation through a positive feedback loop with Myod. Developmental Biology. 350(2):464-475

Phillips, R.B., Amores, A., Morasch, M.R., Wilson, C., and Postlethwait, J.H. (2006) Assignment of zebrafish genetic linkage groups to chromosomes. Cytogenetic and genome research. 114(2):155-162

Picker, A., Scholpp, S., Bohli, H., Takeda, H., and Brand, M. (2002) A novel positive transcriptional feedback loop in midbrain-hindbrain boundary development is revealed through analysis of the zebrafish pax2.1 promoter in transgenic lines. Development (Cambridge, England). 129(13):3227-3239

Postlethwait, J.H, Yan, Y.-L., Gates, M.A., Horne, S., Amores, A., Brownlie, A., Donovan, A., Egan, E.S., Force, A., Gong, Z., Goutel, C., Fritz, A., Kelsh, R., Knapik, E., Liao, E., Paw, B., Ransom, D., Singer, A., Thomson, M., Abduljabbar, T.S., Yelick, P., Beier, D., Joly, J.-S., Larhammar, D., Rosa, F., Westerfield, M., Zon, L.I., Johnson, S.L., and Talbot, W.S. (1998) Vertebrate genome evolution and the zebrafish gene map. Nature Genetics. 18:345-349

Ramachandran, R., Zhao, X.F., and Goldman, D. (2012) Insm1a-mediated gene repression is essential for the formation and differentiation of Müller glia-derived progenitors in the injured retina. Nature cell biology. 14(10):1013-1023

Reifers, F., Bohli, H., Walsh, E.C., Crossley, P.H., Stainier, D.Y., and Brand, M. (1998) Fgf8 is mutated in zebrafish acerebellar (ace) mutants and is required for maintenance of midbrain-hindbrain boundary development and somitogenesis. Development (Cambridge, England). 125:2381-2395

Rhinn, M., Lun, K., Ahrendt, R., Geffarth, M., and Brand, M. (2009) Zebrafish gbx1 refines the midbrain-hindbrain boundary border and mediates the Wnt8 posteriorization signal. Neural Development. 4:12

Rost, F., Eugster, C., Schröter, C., Oates, A.C., Brusch, L. (2014) Chevron formation of the zebrafish muscle segments. The Journal of experimental biology. 217(Pt 21):3870-82

Rydeen, A.B., Waxman, J.S. (2014) Cyp26 enzymes are required to balance the cardiac and vascular lineages within the anterior lateral plate mesoderm. Development (Cambridge, England). 141:1638-48

Schier, A.F., Neuhauss, S.C., Harvey, M., Malicki, J., Solnica-Krezel, L., Stainier, D.Y., Zwartkruis, F., Abdelilah, S., Stemple, D.L., Rangini, Z., Yang, H., and Driever, W. (1996) Mutations affecting the development of the embryonic zebrafish brain. Development (Cambridge, England). 123:165-178

Scholpp, S. and Brand, M. (2001) Morpholino-induced knockdown of zebrafish engrailed genes eng2 and eng3 reveals redundant and unique functions in midbrain–hindbrain boundary development. Genesis (New York, N.Y. : 2000). 30(3):129-133

Scholpp, S., Lohs, C., and Brand, M. (2003) Engrailed and Fgf8 act synergistically to maintain the boundary between diencephalon and mesencephalon. Development (Cambridge, England). 130(20):4881-4893

Selland, L.G., Koch, S., Laraque, M., Waskiewicz, A.J. (2018) Coordinate regulation of retinoic acid synthesis by pbx genes and fibroblast growth factor signaling by hoxb1b is required for hindbrain patterning and development. Mechanisms of Development. 150:28-41

Shimizu, N., Ishitani, S., Sato, A., Shibuya, H., Ishitani, T. (2014) Hipk2 and PP1c Cooperate to Maintain Dvl Protein Levels Required for Wnt Signal Transduction. Cell Reports. 8(5):1391-404

Talbot, J.C., Johnson, S.L., and Kimmel, C.B. (2010) hand2 and Dlx genes specify dorsal, intermediate and ventral domains within zebrafish pharyngeal arches. Development (Cambridge, England). 137(15):2507-2517

Thorpe, C.J., and Moon, R.T. (2004) nemo-like kinase is an essential co-activator of Wnt signaling during early zebrafish development. Development (Cambridge, England). 131(12):2899-2909

Tse, W.K., Yeung, B.H., Wan, H.T., and Wong, C.K. (2013) Early embryogenesis in zebrafish is affected by bisphenol A exposure. Biology Open. 2(5):466-471

van de Peer, Y., Frickey, T., Taylor, J., and Meyer, A. (2002) Dealing with saturation at the amino acid level: a case study based on anciently duplicated zebrafish genes. Gene. 295(2):205-211

Wang, F., Chen, X., Shi, W., Yao, L., Gao, M., Yang, Y., Hao, A. (2015) Zdhhc15b Regulates Differentiation of Diencephalic Dopaminergic Neurons in Zebrafish. Journal of cellular biochemistry. 116(12):2980-91

Wang, X., Yang, N., Uno, E., Roeder, R.G., and Guo, S. (2006) A subunit of the mediator complex regulates vertebrate neuronal development. Proceedings of the National Academy of Sciences of the United States of America. 103(46):17284-17289

Wilm, T.P., and Solnica-Krezel, L. (2005) Essential roles of a zebrafish prdm1/blimp1 homolog in embryo patterning and organogenesis. Development (Cambridge, England). 132(2):393-404

Woltering, J.M., and Durston, A.J. (2006) The zebrafish hoxDb cluster has been reduced to a single microRNA. Nature Genetics. 38(6):601-602

Wu, S., Adams, B.A., Fradinger, E.A., and Sherwood, N.M. (2006) Role of Two Genes Encoding PACAP in Early Brain Development in Zebrafish. Annals of the New York Academy of Sciences. 1070:602-621

Xu, X., He, Y., Sun, L., Ma, S., Luo, C. (2014) Maternal Vsx1 plays an essential role in regulating prechordal mesendoderm and forebrain formation in zebrafish. Developmental Biology. 394(2):264-76

Yoder, J.A., Mueller, M.G., Wei, S., Corliss, B.C., Prather, D.M., Willis, T., Litman, R.T., Djeu, J.Y., and Litman, G.W. (2001) Immune-type receptor genes in zebrafish share genetic and functional properties with genes encoded by the mammalian leukocyte receptor cluster. Proceedings of the National Academy of Sciences of the United States of America. 98(12):6771-6776

Zhang, X., Jia, S., Chen, Z., Chong, Y.L., Xie, H., Feng, D., Wu, X., Song, D.Z., Roy, S., Zhao, C. (2018) Cilia-driven cerebrospinal fluid flow directs expression of urotensin neuropeptides to straighten the vertebrate body axis. Nature Genetics. 50(12):1666-1673

Le, Y., Rajasekhar, K., Loo, T.Y.J., Saunders, T.E., Wohland, T., Winkler, C. (2025) Midkine-a interacts with Ptprz1b to regulate neural plate convergence and midline formation in the developing zebrafish hindbrain. Developmental Biology. :

Maekawa, M., Saito, S., Isobe, D., Takemoto, K., Miura, Y., Dobashi, Y., Yamasu, K. (2024) The Oct4-related PouV gene, pou5f3, mediates isthmus development in zebrafish by directly and dynamically regulating pax2a. Cells & development. 179:203933

Baldera, D., Baxendale, S., van Hateren, N.J., Marzo, M., Glendenning, E., Geng, F.S., Yokoya, K., Knight, R.D., Whitfield, T.T. (2023) Enhancer trap lines with GFP driven by smad6b and frizzled1 regulatory sequences for the study of epithelial morphogenesis in the developing zebrafish inner ear. Journal of anatomy. 243(1):78-89

Zhou, J., Yang, Y.J., Gan, R.H., Wang, Y., Li, Z., Zhang, X.J., Gui, J.F., Zhou, L. (2022) Foxl2a and Foxl2b are involved in midbrain-hindbrain boundary development in zebrafish. Gene expression patterns : GEP. 46:119286

Amblard, I., Thauvin, M., Rampon, C., Queguiner, I., Pak, V.V., Belousov, V., Prochiantz, A., Volovitch, M., Joliot, A., Vriz, S. (2020) H₂O₂ and Engrailed 2 paracrine activity synergize to shape the zebrafish optic tectum. Communications biology. 3:536

Gonzalez-Munoz, E., Arboleda-Estudillo, Y., Chanumolu, S.K., Otu, H.H., Cibelli, J.B. (2019) Zebrafish macroH2A variants have distinct embryo localization and function. Scientific Reports. 9:8632

Li, J., Zhao, Y., He, L., Huang, Y., Yang, X., Yu, L., Zhao, Q., Dong, X. (2018) Znfl1s are essential for patterning the anterior-posterior axis of zebrafish posterior hindbrain by acting as direct target genes of retinoic acid. Mechanisms of Development. 155:27-33

Ma, R.C., Jacobs, C.T., Sharma, P., Kocha, K.M., Huang, P. (2018) Stereotypic generation of axial tenocytes from bipartite sclerotome domains in zebrafish. PLoS Genetics. 14:e1007775

Zhang, X., Jia, S., Chen, Z., Chong, Y.L., Xie, H., Feng, D., Wu, X., Song, D.Z., Roy, S., Zhao, C. (2018) Cilia-driven cerebrospinal fluid flow directs expression of urotensin neuropeptides to straighten the vertebrate body axis. Nature Genetics. 50(12):1666-1673

Albuixech-Crespo, B., López-Blanch, L., Burguera, D., Maeso, I., Sánchez-Arrones, L., Moreno-Bravo, J.A., Somorjai, I., Pascual-Anaya, J., Puelles, E., Bovolenta, P., Garcia-Fernàndez, J., Puelles, L., Irimia, M., Ferran, J.L. (2017) Molecular regionalization of the developing amphioxus neural tube challenges major partitions of the vertebrate brain. PLoS Biology. 15:e2001573

Miles, L.B., Darido, C., Kaslin, J., Heath, J.K., Jane, S.M., Dworkin, S. (2017) Mis-expression of grainyhead-like transcription factors in zebrafish leads to defects in enveloping layer (EVL) integrity, cellular morphogenesis and axial extension. Scientific Reports. 7:17607

Piatek, M.J., Henderson, V., Fearn, A., Chaudhry, B., Werner, A. (2017) Ectopically expressed Slc34a2a sense-antisense transcripts cause a cerebellar phenotype in zebrafish embryos depending on RNA complementarity and Dicer. PLoS One. 12:e0178219

Han, R., Wang, R., Zhao, Q., Han, Y., Zong, S., Miao, S., Song, W., Wang, L. (2016) Trim69 regulates zebrafish brain development by ap-1 pathway. Scientific Reports. 6:24034

D'Aniello, E., Ravisankar, P., Waxman, J.S. (2015) Rdh10a Provides a Conserved Critical Step in the Synthesis of Retinoic Acid during Zebrafish Embryogenesis. PLoS One. 10:e0138588

Rydeen, A., Voisin, N., D'Aniello, E., Ravisankar, P., Devignes, C.S., Waxman, J.S. (2015) Excessive feedback of Cyp26a1 promotes cell non-autonomous loss of retinoic acid signaling. Developmental Biology. 405(1):47-55

Eroglu, B., Min, J.N., Zhang, Y., Szurek, E., Moskophidis, D., Eroglu, A., and Mivechi, N.F. (2014) An essential role for heat shock transcription factor binding protein 1 (HSBP1) during early embryonic development. Developmental Biology. 386(2):448-460

Rydeen, A.B., Waxman, J.S. (2014) Cyp26 enzymes are required to balance the cardiac and vascular lineages within the anterior lateral plate mesoderm. Development (Cambridge, England). 141:1638-48

Xu, X., He, Y., Sun, L., Ma, S., Luo, C. (2014) Maternal Vsx1 plays an essential role in regulating prechordal mesendoderm and forebrain formation in zebrafish. Developmental Biology. 394(2):264-76

D'Aniello, E., Rydeen, A.B., Anderson, J.L., Mandal, A., and Waxman, J.S. (2013) Depletion of Retinoic Acid Receptors Initiates a Novel Positive Feedback Mechanism that Promotes Teratogenic Increases in Retinoic Acid. PLoS Genetics. 9(8):e1003689

Miyake, A., and Itoh, N. (2013) Fgf22 regulated by Fgf3/Fgf8 signaling is required for zebrafish midbrain development. Biology Open. 2(5):515-524

Tse, W.K., Yeung, B.H., Wan, H.T., and Wong, C.K. (2013) Early embryogenesis in zebrafish is affected by bisphenol A exposure. Biology Open. 2(5):466-471

Dworkin, S., Darido, C., Georgy, S.R., Wilanowski, T., Srivastava, S., Ellett, F., Pase, L., Han, Y., Meng, A., Heath, J.K., Lieschke, G.J., and Jane, S.M. (2012) Midbrain-hindbrain boundary patterning and morphogenesis are regulated by diverse grainy head-like 2-dependent pathways. Development (Cambridge, England). 139(3):525-536

Ramachandran, R., Zhao, X.F., and Goldman, D. (2012) Insm1a-mediated gene repression is essential for the formation and differentiation of Müller glia-derived progenitors in the injured retina. Nature cell biology. 14(10):1013-1023

Belting, H.G., Wendik, B., Lunde, K., Leichsenring, M., Mössner, R., Driever, W., and Onichtchouk, D. (2011) Pou5f1 contributes to dorsoventral patterning by positive regulation of vox and modulation of fgf8a expression. Developmental Biology. 356(2):323-36

Dolez, M., Nicolas, J.F., and Hirsinger, E. (2011) Laminins, via heparan sulfate proteoglycans, participate in zebrafish myotome morphogenesis by modulating the pattern of Bmp responsiveness. Development (Cambridge, England). 138(1):97-106

Groeneweg, J.W., White, Y.A., Kokel, D., Peterson, R.T., Zukerberg, L.R., Berin, I., Rueda, B.R., and Wood, A.W. (2011) cables1 is required for embryonic neural development: molecular, cellular, and behavioral evidence from the zebrafish. Molecular reproduction and development. 78(1):22-32

Hu, S., Wu, Z., Yan, Y., and Li, Y. (2011) Sox31 is involved in central nervous system anteroposterior regionalization through regulating the organizer activity in zebrafish. Acta biochimica et biophysica Sinica. 43(5):387-399

Maurya, A.K., Tan, H., Souren, M., Wang, X., Wittbrodt, J., and Ingham, P.W. (2011) Integration of Hedgehog and BMP signalling by the engrailed2a gene in the zebrafish myotome. Development (Cambridge, England). 138(4):755-765

Wang, X., Ono, Y., Tan, S.C., Chai, R.J., Parkin, C., and Ingham, P.W. (2011) Prdm1a and miR-499 act sequentially to restrict Sox6 activity to the fast-twitch muscle lineage in the zebrafish embryo. Development (Cambridge, England). 138(20):4399-404

Okuda, Y., Ogura, E., Kondoh, H., and Kamachi, Y. (2010) B1 SOX coordinate cell specification with patterning and morphogenesis in the early zebrafish embryo. PLoS Genetics. 6:e1000936

Talbot, J.C., Johnson, S.L., and Kimmel, C.B. (2010) hand2 and Dlx genes specify dorsal, intermediate and ventral domains within zebrafish pharyngeal arches. Development (Cambridge, England). 137(15):2507-2517

Fauny, J.D., Thisse, B., and Thisse, C. (2009) The entire zebrafish blastula-gastrula margin acts as an organizer dependent on the ratio of Nodal to BMP activity. Development (Cambridge, England). 136(22):3811-3819

Hinits, Y., Osborn, D.P., and Hughes, S.M. (2009) Differential requirements for myogenic regulatory factors distinguish medial and lateral somitic, cranial and fin muscle fibre populations. Development (Cambridge, England). 136(3):403-414

Kim, J.D., Chun, H.S., Kim, S.H., Kim, H.S., Kim, Y.S., Kim, M.J., Shin, J., Rhee, M., Yeo, S.Y., and Huh, T.L. (2009) Normal forebrain development may require continual Wnt antagonism until mid-somitogenesis in zebrafish. Biochemical and Biophysical Research Communications. 381(4):717-721

Rhinn, M., Lun, K., Ahrendt, R., Geffarth, M., and Brand, M. (2009) Zebrafish gbx1 refines the midbrain-hindbrain boundary border and mediates the Wnt8 posteriorization signal. Neural Development. 4:12

Aamar, E., and Dawid, I.B. (2008) Protocadherin-18a has a role in cell adhesion, behavior and migration in zebrafish development. Developmental Biology. 318(2):335-346

Knight, R.D., Mebus, K., and Roehl, H.H. (2008) Mandibular arch muscle identity is regulated by a conserved molecular process during vertebrate development. Journal of experimental zoology. Part B, Molecular and developmental evolution. 310(4):355-369

Erickson, T., Scholpp, S., Brand, M., Moens, C.B., and Waskiewicz, A. Jan (2007) Pbx proteins cooperate with Engrailed to pattern the midbrain-hindbrain and diencephalic-mesencephalic boundaries. Developmental Biology. 301(2):504-517

French, C.R., Erickson, T., Callander, D., Berry, K.M., Koss, R., Hagey, D.W., Stout, J., Wuennenberg-Stapleton, K., Ngai, J., Moens, C.B., and Waskiewicz, A.J. (2007) Pbx homeodomain proteins pattern both the zebrafish retina and tectum. BMC Developmental Biology. 7(1):85

Hinits, Y., and Hughes, S.M. (2007) Mef2s are required for thick filament formation in nascent muscle fibres. Development (Cambridge, England). 134(13):2511-2519

Jeong, J.Y., Einhorn, Z., Mathur, P., Chen, L., Lee, S., Kawakami, K., and Guo, S. (2007) Patterning the zebrafish diencephalon by the conserved zinc-finger protein Fezl. Development (Cambridge, England). 134(1):127-136

Nair, S., Li, W., Cornell, R., and Schilling, T.F. (2007) Requirements for Endothelin type-A receptors and Endothelin-1 signaling in the facial ectoderm for the patterning of skeletogenic neural crest cells in zebrafish. Development (Cambridge, England). 134(2):335-345

Schlueter, P.J., Peng, G., Westerfield, M., and Duan, C. (2007) Insulin-like growth factor signaling regulates zebrafish embryonic growth and development by promoting cell survival and cell cycle progression. Cell death and differentiation. 14(6):1095-1105

Hirate, Y., and Okamoto, H. (2006) Canopy1, a Novel Regulator of FGF Signaling around the Midbrain-Hindbrain Boundary in Zebrafish. Current biology : CB. 16(4):421-427

Muto, A., Arai, K.I., and Watanabe, S. (2006) Rab11-FIP4 is predominantly expressed in neural tissues and involved in proliferation as well as in differentiation during zebrafish retinal development. Developmental Biology. 292(1):90-102

Phillips, R.B., Amores, A., Morasch, M.R., Wilson, C., and Postlethwait, J.H. (2006) Assignment of zebrafish genetic linkage groups to chromosomes. Cytogenetic and genome research. 114(2):155-162

Wang, X., Yang, N., Uno, E., Roeder, R.G., and Guo, S. (2006) A subunit of the mediator complex regulates vertebrate neuronal development. Proceedings of the National Academy of Sciences of the United States of America. 103(46):17284-17289

Wu, S., Adams, B.A., Fradinger, E.A., and Sherwood, N.M. (2006) Role of Two Genes Encoding PACAP in Early Brain Development in Zebrafish. Annals of the New York Academy of Sciences. 1070:602-621

Corbit, K.C., Aanstad, P., Singla, V., Norman, A.R., Stainier, D.Y., and Reiter, J.F. (2005) Vertebrate Smoothened functions at the primary cilium. Nature. 437(7061):1018-1021

Miyake, A., Nakayama, Y., Konishi, M., and Itoh, N. (2005) Fgf19 regulated by Hh signaling is required for zebrafish forebrain development. Developmental Biology. 288(1):259-275

Wilm, T.P., and Solnica-Krezel, L. (2005) Essential roles of a zebrafish prdm1/blimp1 homolog in embryo patterning and organogenesis. Development (Cambridge, England). 132(2):393-404

Lunde, K., Belting, H.G., and Driever, W. (2004) Zebrafish pou5f1/pou2, homolog of mammalian Oct4, functions in the endoderm specification cascade. Current biology : CB. 14(1):48-55

Thorpe, C.J., and Moon, R.T. (2004) nemo-like kinase is an essential co-activator of Wnt signaling during early zebrafish development. Development (Cambridge, England). 131(12):2899-2909

Dorsky, R.I., Itoh, M., Moon, R.T., and Chitnis, A. (2003) Two tcf3 genes cooperate to pattern the zebrafish brain. Development (Cambridge, England). 130(9):1937-1947

Hammerschmidt, M., Kramer, C., Nowak, M., Herzog, W., and Wittbrodt, J. (2003) Loss of maternal Smad5 in zebrafish embryos affects patterning and morphogenesis of optic primordia. Developmental Dynamics : an official publication of the American Association of Anatomists. 227(1):128-133

Miller, C.T., Yelon, D., Stainier, D.Y., and Kimmel, C.B. (2003) Two endothelin 1 effectors, hand2 and bapx1, pattern ventral pharyngeal cartilage and the jaw joint. Development (Cambridge, England). 130(7):1353-1365

Scholpp, S., Lohs, C., and Brand, M. (2003) Engrailed and Fgf8 act synergistically to maintain the boundary between diencephalon and mesencephalon. Development (Cambridge, England). 130(20):4881-4893

Kim, S.-H., Shin, J., Park, H.-C., Yeo, S.-Y., Hong, S.-K., Han, S., Rhee, M., Kim, C.-H., Chitnis, A.B., and Huh, T.-L. (2002) Specification of an anterior neuroectoderm patterning by Frizzled8a-mediated Wnt8b signalling during late gastrulation in zebrafish. Development (Cambridge, England). 129(19):4443-4455

Reim, G. and Brand, M. (2002) spiel-ohne-grenzen/pou2 mediates regional competence to respond to Fgf8 during zebrafish early neural development. Development (Cambridge, England). 129(4):917-933

van de Peer, Y., Frickey, T., Taylor, J., and Meyer, A. (2002) Dealing with saturation at the amino acid level: a case study based on anciently duplicated zebrafish genes. Gene. 295(2):205-211

Belting, H.G., Hauptmann, G., Meyer, D., Abdelilah-Seyfried, S., Chitnis, A., Eschbach, C., Söll, I., Thisse, C., Thisse, B., Artinger, K., Lunde, K., and Driever, W. (2001) spiel ohne grenzen/pou2 is required during establishment of the zebrafish midbrain-hindbrain boundary organizer. Development (Cambridge, England). 128(21):4165-4176

Fürthauer, M., Reifers, F., Brand, M., Thisse, B., and Thisse, C. (2001) sprouty4 acts in vivo as a feedback-induced antagonist of FGF signaling in zebrafish. Development (Cambridge, England). 128(12):2175-2186

Tallafuss, A., Wilm, T.P., Crozatier, M., Pfeffer, P., Wassef, M., and Bally-Cuif, L. (2001) The zebrafish buttonhead-like factor Bts1 is an early regulator of pax2.1 expression during mid-hindbrain development. Development (Cambridge, England). 128(20):4021-4034

Yoder, J.A., Mueller, M.G., Wei, S., Corliss, B.C., Prather, D.M., Willis, T., Litman, R.T., Djeu, J.Y., and Litman, G.W. (2001) Immune-type receptor genes in zebrafish share genetic and functional properties with genes encoded by the mammalian leukocyte receptor cluster. Proceedings of the National Academy of Sciences of the United States of America. 98(12):6771-6776

Yoder, J.A. and Litman, G.W. (2000) The zebrafish fth1, slc3a2, men1, pc, fgf3 and cycd1 genes define two regions of conserved synteny between linkage group 7 and human chromosome 11q13. Gene. 261:5-242

Lele, Z., Hartson, S.D., Martin, C.C., Whitesell, L., Matts, R.L., and Krone, P.H. (1999) Disruption of zebrafish somite development by pharmacologic inhibition of hsp90. Developmental Biology. 210(1):56-70

Amores, A., Force, A., Yan, Y.-L. Joly, L., Amemiya, C., Fritz, A., Ho, R., Langeland, J., Prince, V., Wang, Y.-L., Westerfield, M., Ekker, M., and Postlethwait, J.H. (1998) Zebrafish hox clusters and vertebrate genome evolution. Science (New York, N.Y.). 282:1711-1714

Lun, K. and Brand, M. (1998) A series of no isthmus (noi) alleles of the zebrafish pax2.1 gene reveals multiple signaling events in development of the midbrain-hindbrain boundary. Development (Cambridge, England). 125:3049-3062

Reifers, F., Bohli, H., Walsh, E.C., Crossley, P.H., Stainier, D.Y., and Brand, M. (1998) Fgf8 is mutated in zebrafish acerebellar (ace) mutants and is required for maintenance of midbrain-hindbrain boundary development and somitogenesis. Development (Cambridge, England). 125:2381-2395

Ellies, D.L., Langille, R.M., Martin, C.C., Akimenko, M.A., and Ekker, M. (1997) Specific craniofacial cartilage dysmorphogenesis coincides with a loss of dlx gene expression in retinoic acid-treated zebrafish embryos. Mechanisms of Development. 61(1-2):23-36

Fritz, A., Rozowski, M., Walker, C., and Westerfield, M. (1996) Identification of selected gamma-ray induced deficiencies in zebrafish using multiplex polymerase chain reaction. Genetics. 144(4):1735-1745

Ekker, M., Wegner, J., Akimenko, M.A., and Westerfield, M. (1992) Coordinate embryonic expression of three zebrafish engrailed genes. Development (Cambridge, England). 116:1001-1010

Joly, J.S., Maury, M., Joly, C., Duprey, P., Boulekbache, H., and Condamine, H. (1992) Expression of a zebrafish caudal homeobox gene correlates with the establishment of posterior cell lineages at gastrulation. Differentiation; research in biological diversity. 50:75-87

Püschel, A.W., Gruss, P., and Westerfield, M. (1992) Sequence and expression pattern of pax-6 are highly conserved between zebrafish and mice. Development (Cambridge, England). 114:643-651

Holland, P.W. and Williams, N.A. (1990) Conservation of engrailed-like homeobox sequences during vertebrate evolution. FEBS letters. 277:250-252