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ZFIN ID:
ZDB-MRPHLNO-050906-2
CITATIONS
(15 total)
Morpholino Name:
MO1-kdrl
Morpholino Symbol:
MO1-kdrl
Anton, H., Harlepp, S., Ramspacher, C., Wu, D., Monduc, F., Bhat, S., Liebling, M., Paoletti, C., Charvin, G., Freund, J.B., and Vermot, J. (2013) Pulse propagation by a capacitive mechanism drives embryonic blood flow. Development (Cambridge, England). 140(21):4426-34
Ba, Q., Duan, J., Tian, J.Q., Wang, Z.L., Chen, T., Li, X.G., Chen, P.Z., Wu, S.J., Xiang, L., Li, J.Q., Chu, R.A., and Wang, H. (2013) Dihydroartemisinin promotes angiogenesis during the early embryonic development of zebrafish. Acta Pharmacologica Sinica. 34(8):1101-7
Bussmann, J., Bos, F.L., Urasaki, A., Kawakami, K., Duckers, H.J., and Schulte-Merker, S. (2010) Arteries provide essential guidance cues for lymphatic endothelial cells in the zebrafish trunk. Development (Cambridge, England). 137(16):2653-2657
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
Hamm, M.J., Kirchmaier, B.C., Herzog, W. (2016) Sema3d controls collective endothelial cell migration by distinct mechanisms via Nrp1 and PlxnD1. The Journal of cell biology. 215(3):415-430
Hasan, S.S., Tsaryk, R., Lange, M., Wisniewski, L., Moore, J.C., Lawson, N.D., Wojciechowska, K., Schnittler, H., Siekmann, A.F. (2017) Endothelial Notch signalling limits angiogenesis via control of artery formation. Nature cell biology. 19(8):928-940
Jensen, L.D., Nakamura, M., Bräutigam, L., Li, X., Liu, Y., Samani, N.J., Cao, Y. (2015) VEGF-B-Neuropilin-1 signaling is spatiotemporally indispensable for vascular and neuronal development in zebrafish. Proceedings of the National Academy of Sciences of the United States of America. 112(44):E5944-53
Lee, S.L., Rouhi, P., Jensen, L.D., Zhang, D., Ji, H., Hauptmann, G., Ingham, P., and Cao, Y. (2009) Hypoxia-induced pathological angiogenesis mediates tumor cell dissemination, invasion, and metastasis in a zebrafish tumor model. Proceedings of the National Academy of Sciences of the United States of America. 106(46):19485-19490
Mitra, S., Devi, S., Lee, M.S., Jui, J., Sahu, A., Goldman, D. (2022) Vegf signaling between Müller glia and vascular endothelial cells is regulated by immune cells and stimulates retina regeneration. Proceedings of the National Academy of Sciences of the United States of America. 119:e2211690119e2211690119
Qiu, J., Fan, X., Wang, Y., Jin, H., Song, Y., Han, Y., Huang, S., Meng, Y., Tang, F., Meng, A. (2016) Embryonic hematopoiesis in vertebrate somites gives rise to definitive hematopoietic stem cells. Journal of molecular cell biology. 8(4):288-301
Rottbauer, W., Just, S., Wessels, G., Trano, N., Most, P., Katus, H.A., and Fishman, M.C. (2005) VEGF-PLC{gamma}1 pathway controls cardiac contractility in the embryonic heart. Genes & Development. 19(13):1624-1634
Toselli, C.M., Wilkinson, B.M., Paterson, J., Kieffer, T.J. (2019) Vegfa/vegfr2 signaling is necessary for zebrafish islet vessel development, but is dispensable for beta-cell and alpha-cell formation. Scientific Reports. 9:3594
Tsao, K.C., Lin, Y.C., Chen, Y.T., Lai, S.L., Yang, R.B. (2021) Zebrafish scube1 and scube2 cooperate in promoting Vegfa signaling during embryonic vascularization. Cardiovascular research. 118(4):1074-1087
Wang, Z.L., Xu, X.P., He, B.L., Weng, S.P., Xiao, J., Wang, L., Lin, T., Liu, X., Wang, Q., Yu, X.Q., and He, J.G. (2008) Infectious Spleen and Kidney Necrosis Virus ORF48R Functions as a New Viral Vascular Endothelial Growth Factor. Journal of virology. 82(9):4371-4383
Yin, C., Evason, K.J., Maher, J.J., and Stainier, D.Y. (2012) The basic helix-loop-helix transcription factor, heart and neural crest derivatives expressed transcript 2, marks hepatic stellate cells in zebrafish: Analysis of stellate cell entry into the developing liver. Hepatology (Baltimore, Md.). 56(5):1958-1970
Mitra, S., Devi, S., Lee, M.S., Jui, J., Sahu, A., Goldman, D. (2022) Vegf signaling between Müller glia and vascular endothelial cells is regulated by immune cells and stimulates retina regeneration. Proceedings of the National Academy of Sciences of the United States of America. 119:e2211690119e2211690119
Tsao, K.C., Lin, Y.C., Chen, Y.T., Lai, S.L., Yang, R.B. (2021) Zebrafish scube1 and scube2 cooperate in promoting Vegfa signaling during embryonic vascularization. Cardiovascular research. 118(4):1074-1087
Toselli, C.M., Wilkinson, B.M., Paterson, J., Kieffer, T.J. (2019) Vegfa/vegfr2 signaling is necessary for zebrafish islet vessel development, but is dispensable for beta-cell and alpha-cell formation. Scientific Reports. 9:3594
Hasan, S.S., Tsaryk, R., Lange, M., Wisniewski, L., Moore, J.C., Lawson, N.D., Wojciechowska, K., Schnittler, H., Siekmann, A.F. (2017) Endothelial Notch signalling limits angiogenesis via control of artery formation. Nature cell biology. 19(8):928-940
Hamm, M.J., Kirchmaier, B.C., Herzog, W. (2016) Sema3d controls collective endothelial cell migration by distinct mechanisms via Nrp1 and PlxnD1. The Journal of cell biology. 215(3):415-430
Qiu, J., Fan, X., Wang, Y., Jin, H., Song, Y., Han, Y., Huang, S., Meng, Y., Tang, F., Meng, A. (2016) Embryonic hematopoiesis in vertebrate somites gives rise to definitive hematopoietic stem cells. Journal of molecular cell biology. 8(4):288-301
Jensen, L.D., Nakamura, M., Bräutigam, L., Li, X., Liu, Y., Samani, N.J., Cao, Y. (2015) VEGF-B-Neuropilin-1 signaling is spatiotemporally indispensable for vascular and neuronal development in zebrafish. Proceedings of the National Academy of Sciences of the United States of America. 112(44):E5944-53
Anton, H., Harlepp, S., Ramspacher, C., Wu, D., Monduc, F., Bhat, S., Liebling, M., Paoletti, C., Charvin, G., Freund, J.B., and Vermot, J. (2013) Pulse propagation by a capacitive mechanism drives embryonic blood flow. Development (Cambridge, England). 140(21):4426-34
Ba, Q., Duan, J., Tian, J.Q., Wang, Z.L., Chen, T., Li, X.G., Chen, P.Z., Wu, S.J., Xiang, L., Li, J.Q., Chu, R.A., and Wang, H. (2013) Dihydroartemisinin promotes angiogenesis during the early embryonic development of zebrafish. Acta Pharmacologica Sinica. 34(8):1101-7
Yin, C., Evason, K.J., Maher, J.J., and Stainier, D.Y. (2012) The basic helix-loop-helix transcription factor, heart and neural crest derivatives expressed transcript 2, marks hepatic stellate cells in zebrafish: Analysis of stellate cell entry into the developing liver. Hepatology (Baltimore, Md.). 56(5):1958-1970
Bussmann, J., Bos, F.L., Urasaki, A., Kawakami, K., Duckers, H.J., and Schulte-Merker, S. (2010) Arteries provide essential guidance cues for lymphatic endothelial cells in the zebrafish trunk. Development (Cambridge, England). 137(16):2653-2657
Lee, S.L., Rouhi, P., Jensen, L.D., Zhang, D., Ji, H., Hauptmann, G., Ingham, P., and Cao, Y. (2009) Hypoxia-induced pathological angiogenesis mediates tumor cell dissemination, invasion, and metastasis in a zebrafish tumor model. Proceedings of the National Academy of Sciences of the United States of America. 106(46):19485-19490
Wang, Z.L., Xu, X.P., He, B.L., Weng, S.P., Xiao, J., Wang, L., Lin, T., Liu, X., Wang, Q., Yu, X.Q., and He, J.G. (2008) Infectious Spleen and Kidney Necrosis Virus ORF48R Functions as a New Viral Vascular Endothelial Growth Factor. Journal of virology. 82(9):4371-4383
Rottbauer, W., Just, S., Wessels, G., Trano, N., Most, P., Katus, H.A., and Fishman, M.C. (2005) VEGF-PLC{gamma}1 pathway controls cardiac contractility in the embryonic heart. Genes & Development. 19(13):1624-1634
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
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