Adachi, N., Robinson, M., Goolsbee, A., Shubin, N.H. (2016) Regulatory evolution of Tbx5 and the origin of paired appendages. Proceedings of the National Academy of Sciences of the United States of America. 113(36):10115-20

Aman, A., and Piotrowski, T. (2008) Wnt/beta-catenin and Fgf signaling control collective cell migration by restricting chemokine receptor expression. Developmental Cell. 15(5):749-761

Bian, W.P., Pu, S.Y., Xie, S.L., Wang, C., Deng, S., Strauss, P.R., Pei, D.S. (2021) Loss of mpv17 affected early embryonic development via mitochondria dysfunction in zebrafish. Cell death discovery. 7:250

Breau, M.A., Wilkinson, D.G., and Xu, Q. (2013) A Hox gene controls lateral line cell migration by regulating chemokine receptor expression downstream of Wnt signaling. Proceedings of the National Academy of Sciences of the United States of America. 110(42):16892-16897

Camarata, T., Snyder, D., Schwend, T., Klosowiak, J., Holtrup, B., and Simon, H.G. (2010) Pdlim7 is required for maintenance of the mesenchymal/epidermal Fgf signaling feedback loop during zebrafish pectoral fin development. BMC Developmental Biology. 10:104

Chen, H.J., Barske, L., Talbot, J.C., Dinwoodie, O.M., Roberts, R.R., Farmer, D.T., Jimenez, C., Merrill, A.E., Tucker, A.S., Crump, J.G. (2023) Nuclear receptor Nr5a2 promotes diverse connective tissue fates in the jaw. Developmental Cell. 58(6):461-473.e7

Chen, X., Lou, Q., He, J., and Yin, Z. (2011) Role of zebrafish lbx2 in embryonic lateral line development. PLoS One. 6(12):e29515

Colak-Champollion, T., Lan, L., Jadhav, A.R., Yamaguchi, N., Venkiteswaran, G., Patel, H., Cammer, M., Meier-Schellersheim, M., Knaut, H. (2019) Cadherin-Mediated Cell Coupling Coordinates Chemokine Sensing across Collectively Migrating Cells. Current biology : CB. 29:2570-2579.e7

Cui, Y., Lv, S., Liu, J., Nie, S., Chen, J., Dong, Q., Huang, C., Yang, D. (2017) Chronic perfluorooctanesulfonic acid exposure disrupts lipid metabolism in zebrafish. Human & Experimental Toxicology. 36(3):207-217

Don, E.K., de Jong-Curtain, T.A., Doggett, K., Hall, T.E., Heng, B., Badrock, A.P., Winnick, C., Nicholson, G.A., Guillemin, G.J., Currie, P.D., Hesselson, D., Heath, J.K., Cole, N.J. (2016) Genetic basis of hindlimb loss in a naturally occurring vertebrate model. Biology Open. 5(3):359-66

Durdu, S., Iskar, M., Revenu, C., Schieber, N., Kunze, A., Bork, P., Schwab, Y., Gilmour, D. (2014) Luminal signalling links cell communication to tissue architecture during organogenesis. Nature. 515(7525):120-4

Feng, Y., and Xu, Q. (2010) Pivotal role of hmx2 and hmx3 in zebrafish inner ear and lateral line development. Developmental Biology. 339(2):507-518

Fischer, S., Filipek-Gorniok, B., and Ledin, J. (2011) Zebrafish Ext2 is necessary for Fgf and Wnt signaling, but not for Hh signaling. BMC Developmental Biology. 11(1):53

Ghosh, T.K., Aparicio-Sánchez, J.J., Buxton, S., Ketley, A., Mohamed, T., Rutland, C.S., Loughna, S., David Brook, J. (2017) Acetylation of TBX5 by KAT2B and KAT2A regulates heart and limb development. Journal of Molecular and Cellular Cardiology. 114:185-198

Gibert, Y., Gajewski, A., Meyer, A., and Begemann, G. (2006) Induction and prepatterning of the zebrafish pectoral fin bud requires axial retinoic acid signaling. Development (Cambridge, England). 133(14):2649-2659

Harding, M.J., and Nechiporuk, A.V. (2012) Fgfr-Ras-MAPK signaling is required for apical constriction via apical positioning of Rho-associated kinase during mechanosensory organ formation. Development (Cambridge, England). 139(17):3130-3135

Harvey, S.A., and Logan, M.P. (2006) sall4 acts downstream of tbx5 and is required for pectoral fin outgrowth. Development (Cambridge, England). 133(6):1165-1173

He, J., Zheng, Z., Luo, X., Hong, Y., Su, W., Cai, C. (2020) Histone Demethylase PHF8 Is Required for the Development of the Zebrafish Inner Ear and Posterior Lateral Line. Frontiers in cell and developmental biology. 8:566504

He, Y., Lu, X., Qian, F., Liu, D., Chai, R., Li, H. (2017) Insm1a Is Required for Zebrafish Posterior Lateral Line Development.. Frontiers in molecular neuroscience. 10:241

He, Y., Tang, D., Li, W., Chai, R., Li, H. (2016) Histone deacetylase 1 is required for the development of the zebrafish inner ear. Scientific Reports. 6:16535

Hodkovicova, N., Sehonova, P., Blahova, J., Faldyna, M., Marsalek, P., Mikula, P., Chloupek, P., Dobsikova, R., Vecerek, V., Vicenova, M., Vosmerova, P., Svobodova, Z. (2019) The effect of the antidepressant venlafaxine on gene expression of biotransformation enzymes in zebrafish (Danio rerio) embryos. Environmental science and pollution research international. 27(2):1686-1696

Hulsey, C.D., Fraser, G.J., Meyer, A. (2016) Biting into the Genome to Phenome Map: Developmental Genetic Modularity of Cichlid Fish Dentitions. Integrative and Comparative Biology. 56(3):373-88

Jackman, W.R., Davies, S.H., Lyons, D.B., Stauder, C.K., Denton-Schneider, B.R., Jowdry, A., Aigler, S.R., Vogel, S.A., Stock, D.W. (2013) Manipulation of Fgf and Bmp signaling in teleost fishes suggests potential pathways for the evolutionary origin of multicuspid teeth. Evolution & development. 15:107-18

Jiang, X., Zhao, K., Sun, Y., Song, X., Yi, C., Xiong, T., Wang, S., Yu, Y., Chen, X., Liu, R., Yan, X., Antos, C.L. (2024) The scale of zebrafish pectoral fin buds is determined by intercellular K+ levels and consequent Ca2+-mediated signaling via retinoic acid regulation of Rcan2 and Kcnk5b. PLoS Biology. 22:e3002565e3002565

Kantarci, H., Edlund, R.K., Groves, A.K., Riley, B.B. (2015) Tfap2a Promotes Specification and Maturation of Neurons in the Inner Ear through Modulation of Bmp, Fgf and Notch Signaling. PLoS Genetics. 11:e1005037

Knutsdottir, H., Zmurchok, C., Bhaskar, D., Palsson, E., Dalle Nogare, D., Chitnis, A., Edelstein-Keshet, L. (2017) Polarization and migration in the zebrafish posterior lateral line system. PLoS Computational Biology. 13:e1005451

Kozlovskaja-Gumbrienė, A., Yi, R., Alexander, R., Aman, A., Jiskra, R., Nagelberg, D., Knaut, H., McClain, M., Piotrowski, T. (2017) Proliferation-independent regulation of organ size by Fgf/Notch signaling. eLIFE. 6

Lalonde, R.L., Akimenko, M.A. (2018) Effects of fin fold mesenchyme ablation on fin development in zebrafish. PLoS One. 13:e0192500

Lee, B.C., and Roy, S. (2006) Blimp-1 is an essential component of the genetic program controlling development of the pectoral limb bud. Developmental Biology. 300(2):623-634

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

Li, M., Page-McCaw, P., Chen, W. (2016) FGF1 Mediates Overnutrition-Induced Compensatory β-Cell Differentiation. Diabetes. 65(1):96-109

Lush, M.E., Piotrowski, T. (2014) ErbB expressing Schwann cells control lateral line progenitor cells via non-cell-autonomous regulation of Wnt/beta-catenin. eLIFE. 3:e01832

Ma, W.R., Zhang, J. (2015) Jag1b is essential for patterning inner ear sensory cristae by regulating anterior morphogenetic tissue separation and preventing posterior cell death. Development (Cambridge, England). 142(4):763-73

Manfroid, I., Ghaye, A., Naye, F., Detry, N., Palm, S., Pan, L., Ma, T.P., Huang, W., Rovira, M., Martial, J.A., Parsons, M.J., Moens, C.B., Voz, M.L., and Peers, B. (2012) Zebrafish sox9b is crucial for hepatopancreatic duct development and pancreatic endocrine cell regeneration. Developmental Biology. 366(2):268-278

Matsuda, M., and Chitnis, A.B. (2010) Atoh1a expression must be restricted by Notch signaling for effective morphogenesis of the posterior lateral line primordium in zebrafish. Development (Cambridge, England). 137(20):3477-3487

Mazzolini, J., Le Clerc, S., Morisse, G., Coulonges, C., Zagury, J.F., Sieger, D. (2022) Wasl is crucial to maintain microglial core activities during glioblastoma initiation stages. Glia. 70(6):1027-1051

McGraw, H.F., Culbertson, M.D., Nechiporuk, A.V. (2014) Kremen1 restricts Dkk activity during posterior lateral line development in zebrafish. Development (Cambridge, England). 141(16):3212-21

Mercader, N., Fischer, S., and Neumann, C.J. (2006) Prdm1 acts downstream of a sequential RA, Wnt and Fgf signaling cascade during zebrafish forelimb induction. Development (Cambridge, England). 133(15):2805-2815

Muto, A., Ikeda, S., Lopez-Burks, M.E., Kikuchi, Y., Calof, A.L., Lander, A.D., Schilling, T.F. (2014) Nipbl and Mediator Cooperatively Regulate Gene Expression to Control Limb Development. PLoS Genetics. 10:e1004671

Nakamura, T., Klomp, J., Pieretti, J., Schneider, I., Gehrke, A.R., Shubin, N.H. (2015) Molecular mechanisms underlying the exceptional adaptations of batoid fins. Proceedings of the National Academy of Sciences of the United States of America. 112(52):15940-5

Nechiporuk, A., and Raible, D.W. (2008) FGF-Dependent Mechanosensory Organ Patterning in Zebrafish. Science (New York, N.Y.). 320(5884):1774-1777

Nomura, R., Kamei, E., Hotta, Y., Konishi, M., Miyake, A., and Itoh, N. (2006) Fgf16 is essential for pectoral fin bud formation in zebrafish. Biochemical and Biophysical Research Communications. 347(1):340-346

Pi-Roig, A., Martin-Blanco, E., Minguillón, C. (2014) Distinct tissue-specific requirements for the zebrafish tbx5 genes during heart, retina and pectoral fin development. Open Biology. 4:140014

Rabinowitz, J.S., Robitaille, A.M., Wang, Y., Ray, C.A., Thummel, R., Gu, H., Djukovic, D., Raftery, D., Berndt, J.D., Moon, R.T. (2017) Transcriptomic, proteomic, and metabolomic landscape of positional memory in the caudal fin of zebrafish. Proceedings of the National Academy of Sciences of the United States of America. 114(5):E717-E726

Sang, Q., Zhang, J., Feng, R., Wang, X., Li, Q., Zhao, X., Xing, Q., Chen, W., Du, J., Sun, S., Chai, R., Jin, L., He, L., Li, H., Wang, L. (2014) Ildr1b is essential for semicircular canal development, migration of the posterior lateral line primordium, and hearing ability in zebrafish: Implications for a role in the recessive hearing impairment DFNB42. Human molecular genetics. 23(23):6201-11

Shibata, E., Yokota, Y., Horita, N., Kudo, A., Abe, G., Kawakami, K., Kawakami, A. (2016) Fgf signalling controls diverse aspects of fin regeneration. Development (Cambridge, England). 143:2920-9

Shin, D., Weidinger, G., Moon, R.T., and Stainier, D.Y. (2012) Intrinsic and extrinsic modifiers of the regulative capacity of the developing liver. Mechanisms of Development. 128(11-12):525-535

Sun, H., Chen, M., Wang, Z., Zhao, G., Liu, J.X. (2019) Transcriptional profiles and copper stress responses in zebrafish cox17 mutants. Environmental pollution (Barking, Essex : 1987). 256:113364

Tan, A.L., Mohanty, S., Guo, J., Lekven, A.C., Riley, B.B. (2022) Pax2a, Sp5a and Sp5l act downstream of Fgf and Wnt to coordinate sensory-neural patterning in the inner ear. Developmental Biology. 492:139-153

Tang, D., Lin, Q., He, Y., Chai, R., Li, H. (2016) Inhibition of H3K9me2 Reduces Hair Cell Regeneration after Hair Cell Loss in the Zebrafish Lateral Line by Down-Regulating the Wnt and Fgf Signaling Pathways. Frontiers in molecular neuroscience. 9:39

Tang, D., Zheng, S., Zheng, Z., Liu, C., Zhang, J., Yan, R., Wu, C., Zuo, N., Wu, L., Xu, H., Liu, S., He, Y. (2022) Dnmt1 is required for the development of auditory organs via cell cycle arrest and Fgf signalling. Cell Proliferation. 55(5):e13225

van der Velden, Y.U., Wang, L., van Lohuizen, M., and Haramis, A.P. (2012) The Polycomb group protein Ring1b is essential for pectoral fin development. Development (Cambridge, England). 139(12):2210-2220

Venero Galanternik, M., Kramer, K.L., Piotrowski, T. (2015) Heparan Sulfate Proteoglycans Regulate Fgf Signaling and Cell Polarity during Collective Cell Migration. Cell Reports. 10(30):414-428

Wang, J., Yin, Y., Lau, S., Sankaran, J., Rothenberg, E., Wohland, T., Meier-Schellersheim, M., Knaut, H. (2018) Anosmin1 Shuttles Fgf to Facilitate Its Diffusion, Increase Its Local Concentration, and Induce Sensory Organs. Developmental Cell. 46(6):751-766.e12

Wehner, D., Cizelsky, W., Vasudevaro, M.D., Özhan, G., Haase, C., Kagermeier-Schenk, B., Röder, A., Dorsky, R.I., Moro, E., Argenton, F., Kühl, M., and Weidinger, G. (2014) Wnt/β-Catenin Signaling Defines Organizing Centers that Orchestrate Growth and Differentiation of the Regenerating Zebrafish Caudal Fin. Cell Reports. 6(3):467-481

Wilkins, B.J., and Pack, M. (2013) Zebrafish models of human liver development and disease. Comprehensive Physiology. 3(3):1213-1230

Winata, C.L., Korzh, S., Kondrychyn, I., Zheng, W., Korzh, V., and Gong, Z. (2009) Development of zebrafish swimbladder: the requirement of Hedgehog signaling in specification and organization of the three tissue layers. Developmental Biology. 331(2):222-236

Woods, I.G., Wilson, C., Friedlander, B., Chang, P., Reyes, D.K., Nix, R., Kelly, P.D., Chu, F., Postlethwait, J.H., and Talbot, W.S. (2005) The zebrafish gene map defines ancestral vertebrate chromosomes. Genome research. 15(9):1307-1314

Xu, J., Zhang, R., Zhang, T., Zhao, G., Huang, Y., Wang, H., Liu, J.X. (2017) Copper impairs zebrafish swimbladder development by down-regulating Wnt signaling. Aquatic toxicology (Amsterdam, Netherlands). 192:155-164

Yang, Y., Li, Y., Fu, J., Li, Y., Li, S., Ni, R., Yang, Q., Luo, L. (2022) Intestinal precursors avoid being misinduced to liver cells by activating Cdx-Wnt inhibition cascade. Proceedings of the National Academy of Sciences of the United States of America. 119:e2205110119

Yin, A., Korzh, S., Winata, C.L., Korzh, V., and Gong, Z. (2011) Wnt signaling is required for early development of zebrafish swimbladder. PLoS One. 6(3):e18431

Zhang, J., Wagh, P., Guay, D., Sanchez-Pulido, L., Padhi, B.K., Korzh, V., Andrade-Navarro, M.A., and Akimenko, M.A. (2010) Loss of fish actinotrichia proteins and the fin-to-limb transition. Nature. 466(7303):234-237

Zhao, X., Jiang, B., Hu, H., Mao, F., Mi, J., Li, Z., Liu, Q., Shao, C., Gong, Y. (2015) Zebrafish cul4a, but not cul4b, modulates cardiac and forelimb development by upregulating tbx5a expression. Human molecular genetics. 24(3):853-64

Jiang, X., Zhao, K., Sun, Y., Song, X., Yi, C., Xiong, T., Wang, S., Yu, Y., Chen, X., Liu, R., Yan, X., Antos, C.L. (2024) The scale of zebrafish pectoral fin buds is determined by intercellular K+ levels and consequent Ca2+-mediated signaling via retinoic acid regulation of Rcan2 and Kcnk5b. PLoS Biology. 22:e3002565e3002565

Chen, H.J., Barske, L., Talbot, J.C., Dinwoodie, O.M., Roberts, R.R., Farmer, D.T., Jimenez, C., Merrill, A.E., Tucker, A.S., Crump, J.G. (2023) Nuclear receptor Nr5a2 promotes diverse connective tissue fates in the jaw. Developmental Cell. 58(6):461-473.e7

Truong, B.T., Shull, L.C., Lencer, E., Bend, E.G., Field, M., Blue, E.E., Bamshad, M.J., Skinner, C., Everman, D., Schwartz, C.E., Flanagan-Steet, H., Artinger, K.B. (2023) PRDM1 DNA-binding zinc finger domain is required for normal limb development and is disrupted in split hand/foot malformation. Disease models & mechanisms. 16(4):

Mazzolini, J., Le Clerc, S., Morisse, G., Coulonges, C., Zagury, J.F., Sieger, D. (2022) Wasl is crucial to maintain microglial core activities during glioblastoma initiation stages. Glia. 70(6):1027-1051

Tang, D., Zheng, S., Zheng, Z., Liu, C., Zhang, J., Yan, R., Wu, C., Zuo, N., Wu, L., Xu, H., Liu, S., He, Y. (2022) Dnmt1 is required for the development of auditory organs via cell cycle arrest and Fgf signalling. Cell Proliferation. 55(5):e13225

Bian, W.P., Pu, S.Y., Xie, S.L., Wang, C., Deng, S., Strauss, P.R., Pei, D.S. (2021) Loss of mpv17 affected early embryonic development via mitochondria dysfunction in zebrafish. Cell death discovery. 7:250

Zhao, C., Lancman, J.J., Yang, Y., Gates, K.P., Cao, D., Barske, L., Matalonga, J., Pan, X., He, J., Graves, A., Huisken, J., Chen, C., Dong, P.D.S. (2021) Intrahepatic cholangiocyte regeneration from an Fgf-dependent extrahepatic progenitor niche in a zebrafish model of Alagille Syndrome. Hepatology (Baltimore, Md.). 75(3):567-583

He, J., Zheng, Z., Luo, X., Hong, Y., Su, W., Cai, C. (2020) Histone Demethylase PHF8 Is Required for the Development of the Zebrafish Inner Ear and Posterior Lateral Line. Frontiers in cell and developmental biology. 8:566504

Gallegos, T.F., Kamei, C.N., Rohly, M., Drummond, I.A. (2019) Fibroblast growth factor signaling mediates progenitor cell aggregation and nephron regeneration in the adult zebrafish kidney. Developmental Biology. 454(1):44-51

Hodkovicova, N., Sehonova, P., Blahova, J., Faldyna, M., Marsalek, P., Mikula, P., Chloupek, P., Dobsikova, R., Vecerek, V., Vicenova, M., Vosmerova, P., Svobodova, Z. (2019) The effect of the antidepressant venlafaxine on gene expression of biotransformation enzymes in zebrafish (Danio rerio) embryos. Environmental science and pollution research international. 27(2):1686-1696

Li, L., Zhang, J., Akimenko, M.A. (2019) Inhibition of mmp13a during zebrafish fin regeneration disrupts fin growth, osteoblasts differentiation and Laminin organization. Developmental Dynamics : an official publication of the American Association of Anatomists. 249(2):187-198

Sun, H., Chen, M., Wang, Z., Zhao, G., Liu, J.X. (2019) Transcriptional profiles and copper stress responses in zebrafish cox17 mutants. Environmental pollution (Barking, Essex : 1987). 256:113364

Wang, J., Shi, G., Yao, J., Sheng, N., Cui, R., Su, Z., Guo, Y., Dai, J. (2019) Perfluoropolyether carboxylic acids (novel alternatives to PFOA) impair zebrafish posterior swim bladder development via thyroid hormone disruption. Environment International. 134:105317

Lalonde, R.L., Akimenko, M.A. (2018) Effects of fin fold mesenchyme ablation on fin development in zebrafish. PLoS One. 13:e0192500

Wang, J., Yin, Y., Lau, S., Sankaran, J., Rothenberg, E., Wohland, T., Meier-Schellersheim, M., Knaut, H. (2018) Anosmin1 Shuttles Fgf to Facilitate Its Diffusion, Increase Its Local Concentration, and Induce Sensory Organs. Developmental Cell. 46(6):751-766.e12

Cui, Y., Lv, S., Liu, J., Nie, S., Chen, J., Dong, Q., Huang, C., Yang, D. (2017) Chronic perfluorooctanesulfonic acid exposure disrupts lipid metabolism in zebrafish. Human & Experimental Toxicology. 36(3):207-217

He, Y., Lu, X., Qian, F., Liu, D., Chai, R., Li, H. (2017) Insm1a Is Required for Zebrafish Posterior Lateral Line Development.. Frontiers in molecular neuroscience. 10:241

Knutsdottir, H., Zmurchok, C., Bhaskar, D., Palsson, E., Dalle Nogare, D., Chitnis, A., Edelstein-Keshet, L. (2017) Polarization and migration in the zebrafish posterior lateral line system. PLoS Computational Biology. 13:e1005451

Rabinowitz, J.S., Robitaille, A.M., Wang, Y., Ray, C.A., Thummel, R., Gu, H., Djukovic, D., Raftery, D., Berndt, J.D., Moon, R.T. (2017) Transcriptomic, proteomic, and metabolomic landscape of positional memory in the caudal fin of zebrafish. Proceedings of the National Academy of Sciences of the United States of America. 114(5):E717-E726

Adachi, N., Robinson, M., Goolsbee, A., Shubin, N.H. (2016) Regulatory evolution of Tbx5 and the origin of paired appendages. Proceedings of the National Academy of Sciences of the United States of America. 113(36):10115-20

Don, E.K., de Jong-Curtain, T.A., Doggett, K., Hall, T.E., Heng, B., Badrock, A.P., Winnick, C., Nicholson, G.A., Guillemin, G.J., Currie, P.D., Hesselson, D., Heath, J.K., Cole, N.J. (2016) Genetic basis of hindlimb loss in a naturally occurring vertebrate model. Biology Open. 5(3):359-66

He, Y., Tang, D., Li, W., Chai, R., Li, H. (2016) Histone deacetylase 1 is required for the development of the zebrafish inner ear. Scientific Reports. 6:16535

Hulsey, C.D., Fraser, G.J., Meyer, A. (2016) Biting into the Genome to Phenome Map: Developmental Genetic Modularity of Cichlid Fish Dentitions. Integrative and Comparative Biology. 56(3):373-88

Lee, S.G., Huang, M., Obholzer, N.D., Sun, S., Li, W., Petrillo, M., Dai, P., Zhou, Y., Cotanche, D.A., Megason, S.G., Li, H., Chen, Z.Y. (2016) Myc and Fgf Are Required for Zebrafish Neuromast Hair Cell Regeneration. PLoS One. 11:e0157768

Shibata, E., Yokota, Y., Horita, N., Kudo, A., Abe, G., Kawakami, K., Kawakami, A. (2016) Fgf signalling controls diverse aspects of fin regeneration. Development (Cambridge, England). 143:2920-9

Venero Galanternik M., Lush, M.E., Piotrowski, T. (2016) Glypican4 Modulates Lateral Line Collective Cell Migration Non Cell-Autonomously. Developmental Biology. 419(2):321-335

Ariza-Cosano, A., Bensimon-Brito, A., Gómez-Skarmeta, J.L., Bessa, J. (2015) sox21a directs lateral line patterning by modulating FGF signaling. Developmental Neurobiology. 75(1):80-92

Ma, W.R., Zhang, J. (2015) Jag1b is essential for patterning inner ear sensory cristae by regulating anterior morphogenetic tissue separation and preventing posterior cell death. Development (Cambridge, England). 142(4):763-73

Nakamura, T., Klomp, J., Pieretti, J., Schneider, I., Gehrke, A.R., Shubin, N.H. (2015) Molecular mechanisms underlying the exceptional adaptations of batoid fins. Proceedings of the National Academy of Sciences of the United States of America. 112(52):15940-5

Xing, C., Gong, B., Xue, Y., Han, Y., Wang, Y., Meng, A., Jia, S. (2015) TGFβ1a regulates zebrafish posterior lateral line formation via Smad5 mediated pathway. Journal of molecular cell biology. 7(1):48-61

Zhang, H., Wang, X., Lv, K., Gao, S., Wang, G., Fan, C., Zhang, X.A., Yan, J. (2015) Time Point-based Integrative Analyses of Deep-transcriptome Identify Four Signal Pathways in Blastemal Regeneration of Zebrafish Lower Jaw. Stem cells (Dayton, Ohio). 33(3):806-18

Dalle Nogare, D., Somers, K., Rao, S., Matsuda, M., Reichman-Fried, M., Raz, E., Chitnis, A.B. (2014) Leading and trailing cells cooperate in collective migration of the zebrafish Posterior Lateral Line primordium. Development (Cambridge, England). 141(16):3188-96

Kujawski, S., Lin, W., Kitte, F., Börmel, M., Fuchs, S., Arulmozhivarman, G., Vogt, S., Theil, D., Zhang, Y., Antos, C.L. (2014) Calcineurin regulates coordinated outgrowth of zebrafish regenerating fins. Developmental Cell. 28:573-87

McGraw, H.F., Culbertson, M.D., Nechiporuk, A.V. (2014) Kremen1 restricts Dkk activity during posterior lateral line development in zebrafish. Development (Cambridge, England). 141(16):3212-21

Pi-Roig, A., Martin-Blanco, E., Minguillón, C. (2014) Distinct tissue-specific requirements for the zebrafish tbx5 genes during heart, retina and pectoral fin development. Open Biology. 4:140014

Sang, Q., Zhang, J., Feng, R., Wang, X., Li, Q., Zhao, X., Xing, Q., Chen, W., Du, J., Sun, S., Chai, R., Jin, L., He, L., Li, H., Wang, L. (2014) Ildr1b is essential for semicircular canal development, migration of the posterior lateral line primordium, and hearing ability in zebrafish: Implications for a role in the recessive hearing impairment DFNB42. Human molecular genetics. 23(23):6201-11

Breau, M.A., Wilkinson, D.G., and Xu, Q. (2013) A Hox gene controls lateral line cell migration by regulating chemokine receptor expression downstream of Wnt signaling. Proceedings of the National Academy of Sciences of the United States of America. 110(42):16892-16897

Matsuda, M., Nogare, D.D., Somers, K., Martin, K., Wang, C., and Chitnis, A.B. (2013) Lef1 regulates Dusp6 to influence neuromast formation and spacing in the zebrafish posterior lateral line primordium. Development (Cambridge, England). 140(11):2387-2397

Meyers, J., Planamento, J., Ebrom, P., Krulewitz, N., Wade, E., and Pownall, M.E. (2013) Sulf1 modulates BMP signaling and is required for somite morphogenesis and development of the horizontal myoseptum. Developmental Biology. 378(2):107-21

Wilfinger, A., Arkhipova, V., and Meyer, D. (2013) Cell type and tissue specific function of islet genes in zebrafish pancreas development. Developmental Biology. 378(1):25-37

Breau, M.A., Wilson, D., Wilkinson, D.G., and Xu, Q. (2012) Chemokine and Fgf signalling act as opposing guidance cues in formation of the lateral line primordium. Development (Cambridge, England). 139(12):2246-2253

Manfroid, I., Ghaye, A., Naye, F., Detry, N., Palm, S., Pan, L., Ma, T.P., Huang, W., Rovira, M., Martial, J.A., Parsons, M.J., Moens, C.B., Voz, M.L., and Peers, B. (2012) Zebrafish sox9b is crucial for hepatopancreatic duct development and pancreatic endocrine cell regeneration. Developmental Biology. 366(2):268-278

Shin, D., Weidinger, G., Moon, R.T., and Stainier, D.Y. (2012) Intrinsic and extrinsic modifiers of the regulative capacity of the developing liver. Mechanisms of Development. 128(11-12):525-535

Wiweger, M.I., Zhao, Z., van Merkesteyn, R.J., Roehl, H.H., and Hogendoornm, P.C. (2012) HSPG-Deficient Zebrafish Uncovers Dental Aspect of Multiple Osteochondromas. PLoS One. 7(1):e29734

Chen, X., Lou, Q., He, J., and Yin, Z. (2011) Role of zebrafish lbx2 in embryonic lateral line development. PLoS One. 6(12):e29515

He, X., Yan, Y.L., Eberhart, J.K., Herpin, A., Wagner, T.U., Schartl, M., and Postlethwait, J.H. (2011) miR-196 regulates axial patterning and pectoral appendage initiation. Developmental Biology. 357(2):463-77

Korzh, S., Winata, C.L., Zheng, W., Yang, S., Yin, A., Ingham, P., Korzh, V., and Gong, Z. (2011) The interaction of epithelial Ihha and mesenchymal Fgf10 in zebrafish esophageal and swimbladder development. Developmental Biology. 359(2):262-76

Shin, D., Lee, Y., Poss, K.D., and Stainier, D.Y. (2011) Restriction of hepatic competence by Fgf signaling. Development (Cambridge, England). 138(7):1339-1348

Yin, A., Korzh, S., Winata, C.L., Korzh, V., and Gong, Z. (2011) Wnt signaling is required for early development of zebrafish swimbladder. PLoS One. 6(3):e18431

Feng, Y., and Xu, Q. (2010) Pivotal role of hmx2 and hmx3 in zebrafish inner ear and lateral line development. Developmental Biology. 339(2):507-518

Matsuda, M., and Chitnis, A.B. (2010) Atoh1a expression must be restricted by Notch signaling for effective morphogenesis of the posterior lateral line primordium in zebrafish. Development (Cambridge, England). 137(20):3477-3487

Zhang, J., Wagh, P., Guay, D., Sanchez-Pulido, L., Padhi, B.K., Korzh, V., Andrade-Navarro, M.A., and Akimenko, M.A. (2010) Loss of fish actinotrichia proteins and the fin-to-limb transition. Nature. 466(7303):234-237

Ma, H., Blake, T., Chitnis, A., Liu, P., and Balla, T. (2009) Crucial role of phosphatidylinositol 4-kinase III{alpha} in development of zebrafish pectoral fin is linked to phosphoinositide 3-kinase and FGF signaling. Journal of Cell Science. 122(Pt 23):4303-4310

Aman, A., and Piotrowski, T. (2008) Wnt/beta-catenin and Fgf signaling control collective cell migration by restricting chemokine receptor expression. Developmental Cell. 15(5):749-761

Lecaudey, V., Cakan-Akdogan, G., Norton, W.H., and Gilmour, D. (2008) Dynamic Fgf signaling couples morphogenesis and migration in the zebrafish lateral line primordium. Development (Cambridge, England). 135(16):2695-2705

Nechiporuk, A., and Raible, D.W. (2008) FGF-Dependent Mechanosensory Organ Patterning in Zebrafish. Science (New York, N.Y.). 320(5884):1774-1777

Itoh, N. and Konishi, M. (2007) The Zebrafish fgf Family. Zebrafish. 4(3):179-186

Gibert, Y., Gajewski, A., Meyer, A., and Begemann, G. (2006) Induction and prepatterning of the zebrafish pectoral fin bud requires axial retinoic acid signaling. Development (Cambridge, England). 133(14):2649-2659

Lee, B.C., and Roy, S. (2006) Blimp-1 is an essential component of the genetic program controlling development of the pectoral limb bud. Developmental Biology. 300(2):623-634

Nomura, R., Kamei, E., Hotta, Y., Konishi, M., Miyake, A., and Itoh, N. (2006) Fgf16 is essential for pectoral fin bud formation in zebrafish. Biochemical and Biophysical Research Communications. 347(1):340-346

Woods, I.G., Wilson, C., Friedlander, B., Chang, P., Reyes, D.K., Nix, R., Kelly, P.D., Chu, F., Postlethwait, J.H., and Talbot, W.S. (2005) The zebrafish gene map defines ancestral vertebrate chromosomes. Genome research. 15(9):1307-1314

Habeck, H., Odenthal, J., Walderich, B., Maischein, H.-M., Tübingen 2000 screen consortium, and Schulte-Merker, S. (2002) Analysis of a zebrafish VEGF receptor mutant reveals specific disruption of angiogenesis. Current biology : CB. 12(16):1405-1412

Strausberg,R.L., Feingold,E.A., Grouse,L.H., Derge,J.G., Klausner,R.D., Collins,F.S., Wagner,L., Shenmen,C.M., Schuler,G.D., Altschul,S.F., Zeeberg,B., Buetow,K.H., Schaefer,C.F., Bhat,N.K., Hopkins,R.F., Jordan,H., Moore,T., Max,S.I., Wang,J., Hsieh,F., Diatchenko,L., Marusina,K., Farmer,A.A., Rubin,G.M., Hong,L., Stapleton,M., Soares,M.B., Bonaldo,M.F., Casavant,T.L., Scheetz,T.E., Brownstein,M.J., Usdin,T.B., Toshiyuki,S., Carninci,P., Prange,C., Raha,S.S., Loquellano,N.A., Peters,G.J., Abramson,R.D., Mullahy,S.J., Bosak,S.A., McEwan,P.J., McKernan,K.J., Malek,J.A., Gunaratne,P.H., Richards,S., Worley,K.C., Hale,S., Garcia,A.M., Gay,L.J., Hulyk,S.W., Villalon,D.K., Muzny,D.M., Sodergren,E.J., Lu,X., Gibbs,R.A., Fahey,J., Helton,E., Ketteman,M., Madan,A., Rodrigues,S., Sanchez,A., Whiting,M., Madan,A., Young,A.C., Shevchenko,Y., Bouffard,G.G., Blakesley,R.W., Touchman,J.W., Green,E.D., Dickson,M.C., Rodriguez,A.C., Grimwood,J., Schmutz,J., Myers,R.M., Butterfield,Y.S., Krzywinski,M.I., Skalska,U., Smailus,D.E., Schnerch,A., Schein,J.E., Jones,S.J., and Marra,M.A. (2002) Generation and initial analysis of more than 15,000 full-length human and mouse cDNA sequences. Proceedings of the National Academy of Sciences of the United States of America. 99(26):16899-903