ZFIN ID: ZDB-TGCONSTRCT-070117-12
CITATIONS (152 total)
Transgenic Construct Name: Tg(-5.1myl7:DsRed2-NLS)
Transgenic Construct Symbol: Tg(-5.1myl7:DsRed2-NLS)
Martin, K.E., Ravisankar, P., Beerens, M., MacRae, C.A., Waxman, J.S. (2023) Nr2f1a maintains atrial nkx2.5 expression to repress pacemaker identity within venous atrial cardiomyocytes of zebrafish. eLIFE. 12:
Bruton, F.A., Kaveh, A., Ross-Stewart, K.M., Matrone, G., Oremek, M.E.M., Solomonidis, E.G., Tucker, C.S., Mullins, J.J., Lucas, C.D., Brittan, M., Taylor, J.M., Rossi, A.G., Denvir, M.A. (2022) Macrophages trigger cardiomyocyte proliferation by increasing epicardial vegfaa expression during larval zebrafish heart regeneration. Developmental Cell. 57(12):1512-1528.e5
Perl, E., Ravisankar, P., Beerens, M.E., Mulahasanovic, L., Smallwood, K., Sasso, M.B., Wenzel, C., Ryan, T.D., Komár, M., Bove, K.E., MacRae, C.A., Weaver, K.N., Prada, C.E., Waxman, J.S. (2022) Stx4 is required to regulate cardiomyocyte Ca2+ handling during vertebrate cardiac development. HGG advances. 3:100115
Winter, M.J., Ono, Y., Ball, J.S., Walentinsson, A., Michaelsson, E., Tochwin, A., Scholpp, S., Tyler, C.R., Rees, S., Hetheridge, M.J., Bohlooly-Y, M. (2022) A Combined Human in Silico and CRISPR/Cas9-Mediated in Vivo Zebrafish Based Approach to Provide Phenotypic Data for Supporting Early Target Validation. Frontiers in pharmacology. 13:827686
Chen, J. (2021) NF-Y is critical for the proper growth of zebrafish embryonic heart and its cardiomyocyte proliferation. Genesis (New York, N.Y. : 2000). 59(1-2):e23408
Derrick, C.J., Pollitt, E.J.G., Sevilla Uruchurtu, A.S., Hussein, F., Grierson, A.J., Noël, E.S. (2021) Lamb1a regulates atrial growth by limiting second heart field addition during zebrafish heart development. Development (Cambridge, England). 148(20)
Honkoop, H., Nguyen, P.D., van der Velden, V.E.M., Sonnen, K.F., Bakkers, J. (2021) Live imaging of adult zebrafish cardiomyocyte proliferation ex vivo. Development (Cambridge, England). 148(18):
Joshi, B., Wagh, G., Kaur, H., Patra, C. (2021) Zebrafish Model to Study Angiotensin II-Mediated Pathophysiology. Biology. 10(11):
Kaveh, A., Bruton, F.A., Oremek, M.E.M., Tucker, C.S., Taylor, J.M., Mullins, J.J., Rossi, A.G., Denvir, M.A. (2021) Selective CDK9 inhibition resolves neutrophilic inflammation and enhances cardiac regeneration in larval zebrafish. Development (Cambridge, England). 149(8):
Koopman, C.D., De Angelis, J., Iyer, S.P., Verkerk, A.O., Da Silva, J., Berecki, G., Jeanes, A., Baillie, G.J., Paterson, S., Uribe, V., Ehrlich, O.V., Robinson, S.D., Garric, L., Petrou, S., Simons, C., Vetter, I., Hogan, B.M., de Boer, T.P., Bakkers, J., Smith, K.A. (2021) The zebrafish grime mutant uncovers an evolutionarily conserved role for Tmem161b in the control of cardiac rhythm. Proceedings of the National Academy of Sciences of the United States of America. 118(9):
Park, D.D., Gahr, B.M., Krause, J., Rottbauer, W., Zeller, T., Just, S. (2021) Long-Chain Acyl-Carnitines Interfere with Mitochondrial ATP Production Leading to Cardiac Dysfunction in Zebrafish. International Journal of Molecular Sciences. 22(16):
Parvez, S., Herdman, C., Beerens, M., Chakraborti, K., Harmer, Z.P., Yeh, J.J., MacRae, C.A., Yost, H.J., Peterson, R.T. (2021) MIC-Drop: A platform for large-scale in vivo CRISPR screens. Science (New York, N.Y.). 373(6559):1146-1151
Sarvari, P., Rasouli, S.J., Allanki, S., Stone, O.A., Sokol, A., Graumann, J., Stainier, D.Y.R. (2021) The E3 ubiquitin-protein ligase Rbx1 regulates cardiac wall morphogenesis in zebrafish. Developmental Biology. 480:1-12
Tsedeke, A.T., Allanki, S., Gentile, A., Jimenez-Amilburu, V., Rasouli, S.J., Guenther, S., Lai, S.L., Stainier, D.Y.R., Marín-Juez, R. (2021) Cardiomyocyte heterogeneity during zebrafish development and regeneration. Developmental Biology. 476:259-271
Zhou, Q., Lei, L., Zhang, H., Chiu, S.C., Gao, L., Yang, R., Wei, W., Peng, G., Zhu, X., Xiong, J.W. (2021) Proprotein Convertase Furina Is Required for Heart Development in Zebrafish. Journal of Cell Science. 134(21):
Beisaw, A., Kuenne, C., Günther, S., Dallmann, J., Wu, C.C., Bentsen, M., Looso, M., Stainier, D. (2020) AP-1 Contributes to Chromatin Accessibility to Promote Sarcomere Disassembly and Cardiomyocyte Protrusion during Zebrafish Heart Regeneration. Circulation research. 126(12):1760-1778
Bertozzi, A., Wu, C.C., Nguyen, P.D., Vasudevarao, M.D., Mulaw, M.A., Koopman, C.D., de Boer, T.P., Bakkers, J., Weidinger, G. (2020) Is zebrafish heart regeneration "complete"? Lineage-restricted cardiomyocytes proliferate to pre-injury numbers but some fail to differentiate in fibrotic hearts. Developmental Biology. 471:106-118
Bise, T., Sallin, P., Pfefferli, C., Jaźwińska, A. (2020) Multiple cryoinjuries modulate the efficiency of zebrafish heart regeneration. Scientific Reports. 10:11551
Carlantoni, C., Allanki, S., Kontarakis, Z., Rossi, A., Piesker, J., Günther, S., Stainier, D.Y.R. (2020) Tie1 regulates zebrafish cardiac morphogenesis through tolloid-like 1 expression. Developmental Biology. 469:54-67
Chu, L., Yin, H., Gao, L., Gao, L., Xia, Y., Zhang, C., Chen, Y., Liu, T., Huang, J., Boheler, K.R., Zhou, Y., Yang, H.T. (2020) Cardiac Na+-Ca2+ exchanger 1 (ncx1h) is critical for the ventricular cardiomyocyte formation via regulating the expression levels of gata4 and hand2 in zebrafish. Science China. Life sciences. 64(2):255-268
Gu, J., Wang, H., Zhou, L., Fan, D., Shi, L., Ji, G., Gu, A. (2020) Oxidative stress in bisphenol AF-induced cardiotoxicity in zebrafish and the protective role of N-acetyl N-cysteine. The Science of the total environment. 731:139190
Holowiecki, A., Linstrum, K., Ravisankar, P., Chetal, K., Salomonis, N., Waxman, J.S. (2020) Pbx4 limits heart size and fosters arch artery formation through partitioning second heart field progenitors and restricting proliferation. Development (Cambridge, England). 147(5):
Kaveh, A., Bruton, F.A., Buckley, C., Oremek, M.E.M., Tucker, C.S., Mullins, J.J., Taylor, J.M., Rossi, A.G., Denvir, M.A. (2020) Live Imaging of Heart Injury in Larval Zebrafish Reveals a Multi-Stage Model of Neutrophil and Macrophage Migration. Frontiers in cell and developmental biology. 8:579943
Kula-Alwar, D., Marber, M.S., Hughes, S.M., Hinits, Y. (2020) Mef2c factors are required for early but not late addition of cardiomyocytes to the ventricle. Developmental Biology. 470:95-107
Mukherjee, D., Wagh, G., Mokalled, M.H., Kontarakis, Z., Dickson, A.L., Rayrikar, A., Günther, S., Poss, K.D., Stainier, D.Y.R., Patra, C. (2020) Ccn2a/Ctgfa is an injury-induced matricellular factor that promotes cardiac regeneration in zebrafish. Development (Cambridge, England). 148(2):
Peng, X., Lai, K.S., She, P., Kang, J., Wang, T., Li, G., Zhou, Y., Sun, J., Jin, D., Xu, X., Liao, L., Liu, J., Lee, E., Poss, K.D., Zhong, T.P. (2020) Induction of Wnt signaling antagonists and p21-activated kinase enhances cardiomyocyte proliferation during zebrafish heart regeneration. Journal of molecular cell biology. 13(1):41-58
Priya, R., Allanki, S., Gentile, A., Mansingh, S., Uribe, V., Maischein, H.M., Stainier, D.Y.R. (2020) Tension heterogeneity directs form and fate to pattern the myocardial wall. Nature. 588(7836):130-134
Sam, J., Mercer, E.J., Torregroza, I., Banks, K.M., Evans, T. (2020) Specificity, redundancy and dosage thresholds among gata4/5/6 genes during zebrafish cardiogenesis. Biology Open. 9(6):
Ye, S., Zhao, T., Zhang, W., Tang, Z., Gao, C., Ma, Z., Xiong, J.W., Peng, J., Tan, W.Q., Chen, J. (2020) p53 isoform Δ113p53 promotes zebrafish heart regeneration by maintaining redox homeostasis. Cell Death & Disease. 11:568
Yin, H.M., Yan, L.F., Liu, Q., Peng, Z., Zhang, C.Y., Xia, Y., Su, D., Gu, A.H., Zhou, Y. (2020) Activating transcription factor 3 coordinates differentiation of cardiac and hematopoietic progenitors by regulating glucose metabolism. Science advances. 6:eaay9466
Bise, T., de Preux Charles, A.S., Jaźwińska, A. (2019) Ciliary neurotrophic factor stimulates cardioprotection and the proliferative activity in the adult zebrafish heart. NPJ Regenerative medicine. 4:2
Burczyk, M.S., Burkhalter, M.D., Tena, T.C., Grisanti, L.A., Kauk, M., Matysik, S., Donow, C., Kustermann, M., Rothe, M., Cui, Y., Raad, F., Laue, S., Moretti, A., Zimmermann, W.H., Wess, J., Kühl, M., Hoffmann, C., Tilley, D.G., Philipp, M. (2019) Muscarinic receptors promote pacemaker fate at the expense of secondary conduction system tissue in zebrafish. JCI insight. 4(20):
Capasso, T.L., Li, B., Volek, H.J., Khalid, W., Rochon, E.R., Anbalagan, A., Herdman, C., Yost, H.J., Villanueva, F.S., Kim, K., Roman, B.L. (2019) BMP10-mediated ALK1 signaling is continuously required for vascular development and maintenance. Angiogenesis. 23(2):203-220
Fukuda, R., Aharonov, A., Ong, Y.T., Stone, O.A., El-Brolosy, M., Maischein, H.M., Potente, M., Tzahor, E., Stainier, D.Y. (2019) Metabolic modulation regulates cardiac wall morphogenesis in zebrafish. eLIFE. 8:
Fukuda, R., Gunawan, F., Ramadass, R., Beisaw, A., Konzer, A., Mullapudi, S.T., Gentile, A., Maischein, H.M., Graumann, J., Stainier, D.Y.R. (2019) Mechanical Forces Regulate Cardiomyocyte Myofilament Maturation via the VCL-SSH1-CFL Axis. Developmental Cell. 51(1):62-77.e5
Grassini, D.R., Da Silva, J., Hall, T.E., Baillie, G.J., Simons, C., Parton, R.G., Hogan, B.M., Smith, K.A. (2019) Myosin Vb is required for correct trafficking of N-cadherin and cardiac chamber ballooning. Developmental Dynamics : an official publication of the American Association of Anatomists. 248(4):284-295
Harrison, M.R., Feng, X., Mo, G., Aguayo, A., Villafuerte, J., Yoshida, T., Pearson, C.A., Schulte-Merker, S., Lien, C.L. (2019) Late developing cardiac lymphatic vasculature supports adult zebrafish heart function and regeneration. eLIFE. 8:
Huang, M., Zhu, F., Jiao, J., Wang, J., Zhang, Y. (2019) Exposure to acrylamide disrupts cardiomyocyte interactions during ventricular morphogenesis in zebrafish embryos. The Science of the total environment. 656:1337-1345
Jiménez-Amilburu, V., Stainier, D.Y.R. (2019) The transmembrane protein Crb2a regulates cardiomyocyte apicobasal polarity and adhesion in zebrafish. Development (Cambridge, England). 146(9):
Maerz, L.D., Burkhalter, M.D., Schilpp, C., Wittekindt, O.H., Frick, M., Philipp, M. (2019) Pharmacological cholesterol depletion disturbs ciliogenesis and ciliary function in developing zebrafish. Communications biology. 2:31
Song, Y.C., Dohn, T.E., Rydeen, A.B., Nechiporuk, A.V., Waxman, J.S. (2019) HDAC1-mediated repression of the retinoic acid-responsive gene ripply3 promotes second heart field development. PLoS Genetics. 15:e1008165
Voleti, V., Patel, K.B., Li, W., Perez Campos, C., Bharadwaj, S., Yu, H., Ford, C., Casper, M.J., Yan, R.W., Liang, W., Wen, C., Kimura, K.D., Targoff, K.L., Hillman, E.M.C. (2019) Real-time volumetric microscopy of in vivo dynamics and large-scale samples with SCAPE 2.0. Nature Methods. 16:1054-1062
Grassini, D.R., Lagendijk, A.K., De Angelis, J.E., Da Silva, J., Jeanes, A., Zettler, N., Bower, N.I., Hogan, B.M., Smith, K.A. (2018) Nppa and Nppb act redundantly during zebrafish cardiac development to confine AVC marker expression and reduce cardiac jelly volume. Development (Cambridge, England). 145(12)
Guerra, A., Germano, R.F., Stone, O., Arnaout, R., Guenther, S., Ahuja, S., Uribe, V., Vanhollebeke, B., Stainier, D.Y., Reischauer, S. (2018) Distinct myocardial lineages break atrial symmetry during cardiogenesis in zebrafish. eLIFE. 7
Hofsteen, P., Robitaille, A.M., Strash, N., Palpant, N., Moon, R.T., Pabon, L., Murry, C.E. (2018) ALPK2 Promotes Cardiogenesis in Zebrafish and Human Pluripotent Stem Cells. iScience. 2:88-100
Huang, M., Jiao, J., Wang, J., Xia, Z., Zhang, Y. (2018) Characterization of acrylamide-induced oxidative stress and cardiovascular toxicity in zebrafish embryos. Journal of hazardous materials. 347:451-460
Lai, J.K.H., Collins, M.M., Uribe, V., Jiménez-Amilburu, V., Günther, S., Maischein, H.M., Stainier, D.Y.R. (2018) The Hippo pathway effector Wwtr1 regulates cardiac wall maturation in zebrafish. Development (Cambridge, England). 145(10)
Ma, X., Ding, Y., Wang, Y., Xu, X. (2018) A Doxorubicin-induced Cardiomyopathy Model in Adult Zebrafish. Journal of visualized experiments : JoVE. (136):
Saydmohammed, M., Vollmer, L.L., Onuoha, E.O., Maskrey, T.S., Gibson, G., Watkins, S.C., Wipf, P., Vogt, A., Tsang, M. (2018) A High-Content Screen Reveals New Small-Molecule Enhancers of Ras/Mapk Signaling as Probes for Zebrafish Heart Development. Molecules. 23(7)
Sánchez-Iranzo, H., Galardi-Castilla, M., Minguillón, C., Sanz-Morejón, A., González-Rosa, J.M., Felker, A., Ernst, A., Guzmán-Martínez, G., Mosimann, C., Mercader, N. (2018) Tbx5a lineage tracing shows cardiomyocyte plasticity during zebrafish heart regeneration. Nature communications. 9:428
Zhang, H., Dvornikov, A.V., Huttner, I.G., Ma, X., Santiago, C.F., Fatkin, D., Xu, X. (2018) A Langendorff-like system to quantify cardiac pump function in adult zebrafish. Disease models & mechanisms. 11(9):
Brown, D., Samsa, L.A., Ito, C., Ma, H., Batres, K., Arnaout, R., Qian, L., Liu, J. (2017) Neuregulin-1 is essential for nerve plexus formation during cardiac maturation. Journal of Cellular and Molecular Medicine. 22(3):2007-2017
Colombo, S., de Sena-Tomás, C., George, V., Werdich, A.A., Kapur, S., MacRae, C.A., Targoff, K.L. (2017) nkx genes establish SHF cardiomyocyte progenitors at the arterial pole and pattern the venous pole through Isl1 repression. Development (Cambridge, England). 145(3)
Duong, T.B., Ravisankar, P., Song, Y.C., Gafranek, J.T., Rydeen, A.B., Dohn, T.E., Barske, L.A., Crump, J.G., Waxman, J.S. (2017) Nr2f1a balances atrial chamber and atrioventricular canal size via BMP signaling-independent and -dependent mechanisms. Developmental Biology. 434(1):7-14
Fukuda, R., Gunawan, F., Beisaw, A., Jimenez-Amilburu, V., Maischein, H.M., Kostin, S., Kawakami, K., Stainier, D.Y. (2017) Proteolysis regulates cardiomyocyte maturation and tissue integration. Nature communications. 8:14495
Huang, M., Jiao, J., Wang, J., Xia, Z., Zhang, Y. (2017) Exposure to acrylamide induces cardiac developmental toxicity in zebrafish during cardiogenesis. Environmental pollution (Barking, Essex : 1987). 234:656-666
Liu, X., Yagi, H., Saeed, S., Bais, A.S., Gabriel, G.C., Chen, Z., Peterson, K.A., Li, Y., Schwartz, M.C., Reynolds, W.T., Saydmohammed, M., Gibbs, B., Wu, Y., Devine, W., Chatterjee, B., Klena, N.T., Kostka, D., de Mesy Bentley, K.L., Ganapathiraju, M.K., Dexheimer, P., Leatherbury, L., Khalifa, O., Bhagat, A., Zahid, M., Pu, W., Watkins, S., Grossfeld, P., Murray, S.A., Porter, G.A., Tsang, M., Martin, L.J., Woodrow Benson, D., Aronow, B.J., Lo, C.W. (2017) The complex genetics of hypoplastic left heart syndrome. Nature Genetics. 49(7):1152-1159
Pfefferli, C., Jaźwińska, A. (2017) The careg element reveals a common regulation of regeneration in the zebrafish myocardium and fin. Nature communications. 8:15151
Sawamiphak, S., Kontarakis, Z., Filosa, A., Reischauer, S., Stainier, D.Y.R. (2017) Transient cardiomyocyte fusion regulates cardiac development in zebrafish. Nature communications. 8:1525
Witzel, H.R., Cheedipudi, S., Gao, R., Stainier, D.Y., Dobreva, G.D. (2017) Isl2b regulates anterior second heart field development in zebrafish. Scientific Reports. 7:41043
Zhu, D., Fang, Y., Gao, K., Shen, J., Zhong, T.P., Li, F. (2017) Vegfa Impacts Early Myocardium Development in Zebrafish. International Journal of Molecular Sciences. 18(2)
de Preux Charles, A.S., Bise, T., Baier, F., Marro, J., Jaźwińska, A. (2016) Distinct effects of inflammation on preconditioning and regeneration of the adult zebrafish heart. Open Biology. 6(7)
de Preux Charles, A.S., Bise, T., Baier, F., Sallin, P., Jaźwińska, A. (2016) Preconditioning boosts regenerative programmes in the adult zebrafish heart. Open Biology. 6(7)
Hofsteen, P., Robitaille, A.M., Chapman, D.P., Moon, R.T., Murry, C.E. (2016) Quantitative proteomics identify DAB2 as a cardiac developmental regulator that inhibits WNT/β-catenin signaling. Proceedings of the National Academy of Sciences of the United States of America. 113(4):1002-7
Jahangiri, L., Sharpe, M., Novikov, N., González-Rosa, J.M., Borikova, A., Nevis, K., Paffett-Lugassy, N., Zhao, L., Adams, M., Guner-Ataman, B., Burns, C.E., Burns, C.G. (2016) The AP-1 transcription factor component Fosl2 potentiates the rate of myocardial differentiation from the zebrafish second heart field. Development (Cambridge, England). 143:113-22
Jiménez-Amilburu, V., Rasouli, S.J., Staudt, D.W., Nakajima, H., Chiba, A., Mochizuki, N., Stainier, D.Y. (2016) In Vivo Visualization of Cardiomyocyte Apicobasal Polarity Reveals Epithelial to Mesenchymal-like Transition during Cardiac Trabeculation. Cell Reports. 17:2687-2699
Manalo, T., May, A., Quinn, J., Lafontant, D.S., Shifatu, O., He, W., Gonzalez-Rosa, J.M., Burns, G.C., Burns, C.E., Burns, A.R., Lafontant, P.J. (2016) Differential Lectin Binding Patterns Identify Distinct Heart Regions in Giant Danio (Devario aequipinnatus) and Zebrafish (Danio rerio) Hearts. The journal of histochemistry and cytochemistry : official journal of the Histochemistry Society. 64(11):687-714
Poon, K.L., Liebling, M., Kondrychyn, I., Brand, T., Korzh, V. (2016) Development of the cardiac conduction system in zebrafish. Gene expression patterns : GEP. 21(2):89-96
Rydeen, A.B., Waxman, J.S. (2016) Cyp26 Enzymes Facilitate Second Heart Field Progenitor Addition and Maintenance of Ventricular Integrity. PLoS Biology. 14:e2000504
Sallin, P., Jaźwińska, A. (2016) Acute stress is detrimental to heart regeneration in zebrafish. Open Biology. 6(3)
Wu, C.C., Kruse, F., Vasudevarao, M.D., Junker, J.P., Zebrowski, D.C., Fischer, K., Noël, E.S., Grün, D., Berezikov, E., Engel, F.B., van Oudenaarden, A., Weidinger, G., Bakkers, J. (2016) Spatially Resolved Genome-wide Transcriptional Profiling Identifies BMP Signaling as Essential Regulator of Zebrafish Cardiomyocyte Regeneration. Developmental Cell. 36(1):36-49
Andersen, N.D., Ramachandran, K.V., Bao, M.M., Kirby, M.L., Pitt, G.S., Hutson, M.R. (2015) Calcium Signaling Regulates Ventricular Hypertrophy During Development Independent of Contraction or Blood Flow. Journal of Molecular and Cellular Cardiology. 80:1-9
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
George, V., Colombo, S., Targoff, K.L. (2015) An early requirement for nkx2.5 Ensures first and Second heart field ventricular identity and cardiac function into adulthood. Developmental Biology. 400(1):10-22
Harrison, M.R., Bussmann, J., Huang, Y., Zhao, L., Osorio, A., Burns, C.G., Burns, C.E., Sucov, H.M., Siekmann, A.F., Lien, C.L. (2015) Chemokine-guided angiogenesis directs coronary vasculature formation in zebrafish. Developmental Cell. 33:442-54
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
Sallin, P., de Preux Charles, A., Duruz, V., Pfefferli, C., Jazwinska, A. (2015) A dual epimorphic and compensatory mode of heart regeneration in zebrafish. Developmental Biology. 399(1):27-40
Strate, I., Tessadori, F., Bakkers, J. (2015) Glypican4 promotes cardiac specification and differentiation by attenuating canonical Wnt and Bmp signaling. Development (Cambridge, England). 142:1767-76
Wu, Q., Zhang, J., Koh, W., Yu, Q., Zhu, X., Amsterdam, A., Davis, G.E., Arnaout, M.A., Xiong, J.W. (2015) Talin1 is required for cardiac Z-disk stabilization and endothelial integrity in zebrafish. FASEB journal : official publication of the Federation of American Societies for Experimental Biology. 29(12):4989-5005
Arnaout, R., Reischauer, S., Stainier, D.Y. (2014) Recovery of Adult Zebrafish Hearts for High-throughput Applications. Journal of visualized experiments : JoVE. (94)
González-Rosa, J.M., Guzmán-Martínez, G., Marques, I.J., Sánchez-Iranzo, H., Jiménez-Borreguero, L.J., Mercader, N. (2014) Use of Echocardiography Reveals Reestablishment of Ventricular Pumping Efficiency and Partial Ventricular Wall Motion Recovery upon Ventricular Cryoinjury in the Zebrafish. PLoS One. 9:e115604
Liu, Y., Asnani, A., Zou, L., Bentley, V.L., Yu, M., Wang, Y., Dellaire, G., Sarkar, K.S., Dai, M., Chen, H.H., Sosnovik, D.E., Shin, J.T., Haber, D.A., Berman, J.N., Chao, W., Peterson, R.T. (2014) Visnagin protects against doxorubicin-induced cardiomyopathy through modulation of mitochondrial malate dehydrogenase. Science Translational Medicine. 6:266ra170
Reischauer, S., Arnaout, R., Ramadass, R., Stainier, D. (2014) Actin Binding GFP Allows 4D In Vivo Imaging of Myofilament Dynamics in the Zebrafish Heart and the Identification of Erbb2 Signaling as a Remodeling Factor of Myofibril Architecture. Circulation research. 115(10):845-56
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
Schindler, Y.L., Garske, K.M., Wang, J., Firulli, B.A., Firulli, A.B., Poss, K.D., Yelon, D. (2014) Hand2 elevates cardiomyocyte production during zebrafish heart development and regeneration. Development (Cambridge, England). 141(16):3112-22
Verduci, L., Loparco, G., Pozzoli, O., Pompilio, G., Capogrossi, M.C. (2014) Identification of Kita (c-Kit) positive cells in the heart of adult zebrafish. International Journal of Cardiology. 175(1):204-5
Zeng, X.X., Yelon, D. (2014) Cadm4 Restricts the Production of Cardiac Outflow Tract Progenitor Cells. Cell Reports. 7(4):951-60
Bennett, J., Stroud, D., Becker, J., and Roden, D. (2013) Proliferation of embryonic cardiomyocytes in zebrafish requires the sodium channel scn5Lab. Genesis (New York, N.Y. : 2000). 51(8):562-74
Choi, W.Y., Gemberling, M., Wang, J., Holdway, J.E., Shen, M.C., Karlstrom, R.O., and Poss, K.D. (2013) In vivo monitoring of cardiomyocyte proliferation to identify chemical modifiers of heart regeneration. Development (Cambridge, England). 140(3):660-666
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
Guner-Ataman, B., Paffett-Lugassy, N., Adams, M.S., Nevis, K.R., Jahangiri, L., Obregon, P., Kikuchi, K., Poss, K.D., Burns, C.E., and Burns, C.G. (2013) Zebrafish second heart field development relies on progenitor specification in anterior lateral plate mesoderm and nkx2.5 function. Development (Cambridge, England). 140(6):1353-1363
Huang, Y., Harrison, M.R., Osorio, A., Kim, J., Baugh, A., Duan, C., Sucov, H.M., and Lien, C.L. (2013) Igf Signaling is Required for Cardiomyocyte Proliferation during Zebrafish Heart Development and Regeneration. PLoS One. 8(6):e67266
Kolpa, H.J., Peal, D.S., Lynch, S.N., Giokas, A.C., Ghatak, S., Misra, S., Norris, R.A., MacRae, C.A., Markwald, R.R., Ellinor, P., Bischoff, J., and Milan, D.J. (2013) miR-21 represses Pdcd4 during cardiac valvulogenesis. Development (Cambridge, England). 140(10):2172-80
Nevis, K., Obregon, P., Walsh, C., Guner-Ataman, B., Burns, C.G., and Burns, C.E. (2013) Tbx1 is required for second heart field proliferation in zebrafish. Developmental Dynamics : an official publication of the American Association of Anatomists. 242(5):540-549
Novikov, N., and Evans, T. (2013) Tmem88a mediates GATA-dependent specification of cardiomyocyte progenitors by restricting WNT signaling. Development (Cambridge, England). 140(18):3787-98
Parente, V., Balasso, S., Pompilio, G., Verduci, L., Colombo, G.I., Milano, G., Guerrini, U., Squadroni, L., Cotelli, F., Pozzoli, O., and Capogrossi, M.C. (2013) Hypoxia/Reoxygenation cardiac injury and regeneration in zebrafish adult heart. PLoS One. 8(1):e53748
Parrie, L.E., Renfrew, E.M., Vander Wal, A., Mueller, R.L., and Garrity, D.M. (2013) Zebrafish tbx5 paralogs demonstrate independent essential requirements in cardiac and pectoral fin development. Developmental Dynamics : an official publication of the American Association of Anatomists. 242(5):485-502
Rosenfeld, G.E., Mercer, E.J., Mason, C.E., and Evans, T. (2013) Small heat shock proteins Hspb7 and Hspb12 regulate early steps of cardiac morphogenesis. Developmental Biology. 381(2):389-400
Samson, S.C., Ferrer, T., Jou, C.J., Sachse, F.B., Shankaran, S.S., Shaw, R.M., Chi, N.C., Tristani-Firouzi, M., and Yost, H.J. (2013) 3-OST-7 regulates BMP-dependent cardiac contraction. PLoS Biology. 11(12):e1001727
Sorrell, M.R., Dohn, T.E., D'Aniello, E., and Waxman, J.S. (2013) Tcf7l1 proteins cell autonomously restrict cardiomyocyte and promote endothelial specification in zebrafish. Developmental Biology. 380(2):199-210
Targoff, K.L., Colombo, S., George, V., Schell, T., Kim, S.H., Solnica-Krezel, L., and Yelon, D. (2013) Nkx genes are essential for maintenance of ventricular identity. Development (Cambridge, England). 140(20):4203-4213
Wang, X., Yu, Q., Wu, Q., Bu, Y., Changm, N.N., Yan, S., Zhou, X.H., Zhu, X., and Xiong, J.W. (2013) Genetic Interaction between pku300 and fbn2b Controls Endocardial Cell Proliferation and Valve Development in Zebrafish. Journal of Cell Science. 126(Pt 6):1381-91
Yan, L., Zhou, Y., Yu, S., Ji, G., Wang, L., Liu, W., and Gu, A. (2013) 8-Oxoguanine DNA glycosylase 1 (ogg1) maintains the function of cardiac progenitor cells during heart formation in zebrafish. Experimental cell research. 319(19):2954-63
Chablais, F., and Jazwinska, A. (2012) The regenerative capacity of the zebrafish heart is dependent on TGFβ signaling. Development (Cambridge, England). 139(11):1921-1930
Chablais, F., and Jazwinska, A. (2012) Induction of myocardial infarction in adult zebrafish using cryoinjury. Journal of visualized experiments : JoVE. (62)
Chernyavskaya, Y., Ebert, A.M., Milligan, E., and Garrity, D.M. (2012) The voltage-gated calcium channel CACNB2 (β2.1) protein is required in the heart for control of cell proliferation and heart tube integrity. Developmental Dynamics : an official publication of the American Association of Anatomists. 241(4):648-662
de Pater, E., Ciampricotti, M., Priller, F., Veerkamp, J., Strate, I., Smith, K., Lagendijk, A.K., Schilling, T.F., Herzog, W., Abdelilah-Seyfried, S., Hammerschmidt, M., and Bakkers, J. (2012) Bmp Signaling Exerts Opposite Effects on Cardiac Differentiation. Circulation research. 110(4):578-587
Dohn, T.E., and Waxman, J.S. (2012) Distinct phases of Wnt/β-catenin signaling direct cardiomyocyte formation in zebrafish. Developmental Biology. 361(2):364-76
Gupta, V., and Poss, K.D. (2012) Clonally dominant cardiomyocytes direct heart morphogenesis. Nature. 484(7395):479-484
Hinits, Y., Pan, L., Walker, C., Dowd, J., Moens, C.B., and Hughes, S.M. (2012) Zebrafish Mef2ca and Mef2cb are essential for both first and second heart field cardiomyocyte differentiation. Developmental Biology. 369(2):199-210
Huang, H., Jin, T., He, J., Ding, Q., Xu, D., Wang, L., Zhang, Y., Pan, Y., Wang, Z., and Chen, Y. (2012) Progesterone and AdipoQ Receptor 11 Links Ras Signaling to Cardiac Development in Zebrafish. Arterioscler. Thromb. Vasc. Biol.. 32(9):2158-2170
Lam, N.T., Currie, P.D., Lieschke, G.J., Rosenthal, N.A., and Kaye, D.M. (2012) Nerve Growth Factor Stimulates Cardiac Regeneration via Cardiomyocyte Proliferation in Experimental Heart Failure. PLoS One. 7(12):e53210
Manuel González-Rosa, J., Peralta, M., and Mercader, N. (2012) Pan-epicardial lineage tracing reveals that epicardium derived cells give rise to myofibroblasts and perivascular cells during zebrafish heart regeneration. Developmental Biology. 370(2):173-186
Poon, K.L., Tan, K.T., Wei, Y.Y., Ng, C.P., Colman, A., Korzh, V., and Xu, X.Q. (2012) RNA-binding protein RBM24 is required for sarcomere assembly and heart contractility. Cardiovascular research. 94(3):418-427
Singleman, C., and Holtzman, N.G. (2012) Analysis of post-embryonic heart development and maturation in the zebrafish, Danio rerio. Developmental Dynamics : an official publication of the American Association of Anatomists. 241(12):1993-2004
Witzel, H.R., Jungblut, B., Choe, C.P., Crump, J.G., Braun, T., and Dobreva, G. (2012) The LIM Protein Ajuba Restricts the Second Heart Field Progenitor Pool by Regulating Isl1 Activity. Developmental Cell. 23(1):58-70
Becker, J.R., Deo, R.C., Werdich, A.A., Panàkovà, D., Coy, S., and MacRae, C.A. (2011) Human cardiomyopathy mutations induce myocyte hyperplasia and activate hypertrophic pathways during cardiogenesis in zebrafish. Disease models & mechanisms. 4(3):400-410
Chablais, F., Veit, J., Rainer, G., and Jazwinska, A. (2011) The zebrafish heart regenerates after cryoinjury-induced myocardial infarction. BMC Developmental Biology. 11:21
Cheng, H., Kari, G., Dicker, A.P., Rodeck, U., Koch, W.J., and Force, T. (2011) A Novel Preclinical Strategy for Identifying Cardiotoxic Kinase Inhibitors and Mechanisms of Cardiotoxicity. Circulation research. 109(12):1401-9
Ding, Y., Sun, X., Huang, W., Hoage, T., Redfield, M., Kushwaha, S., Sivasubbu, S., Lin, X., Ekker, S., and Xu, X. (2011) Haploinsufficiency of Target of Rapamycin Attenuates Cardiomyopathies in Adult Zebrafish. Circulation research. 109(6):658-69
Laux, D.W., Febbo, J.A., and Roman, B.L. (2011) Dynamic analysis of BMP-responsive smad activity in live zebrafish embryos. Developmental Dynamics : an official publication of the American Association of Anatomists. 240(3):682-694
Ni, T.T., Rellinger, E.J., Mukherjee, A., Xie, S., Stephens, L., Thorne, C.A., Kim, K., Hu, J., Lee, E., Marnett, L., Hatzopoulos, A.K., and Zhong, T.P. (2011) Discovering Small Molecules that Promote Cardiomyocyte Generation by Modulating Wnt Signaling. Chemistry & Biology. 18(12):1658-1668
Patra, C., Diehl, F., Ferrazzi, F., van Amerongen, M.J., Novoyatleva, T., Schaefer, L., Mühlfeld, C., Jungblut, B., and Engel, F.B. (2011) Nephronectin regulates atrioventricular canal differentiation via Bmp4-Has2 signaling in zebrafish. Development (Cambridge, England). 138(20):4499-4509
Sedletcaia, A., and Evans, T. (2011) Heart chamber size in zebrafish is regulated redundantly by duplicated tbx2 genes. Developmental Dynamics : an official publication of the American Association of Anatomists. 240(6):1548-1557
Sorrell, M.R., and Waxman, J.S. (2011) Restraint of Fgf8 signaling by retinoic acid signaling is required for proper heart and forelimb formation. Developmental Biology. 358(1):44-55
Zhou, Y., Cashman, T.J., Nevis, K.R., Obregon, P., Carney, S.A., Liu, Y., Gu, A., Mosimann, C., Sondalle, S., Peterson, R.E., Heideman, W., Burns, C.E., and Burns, C.G. (2011) Latent TGF-β binding protein 3 identifies a second heart field in zebrafish. Nature. 474(7353):645-8
Chopra, S.S., Stroud, D.M., Watanabe, H., Bennett, J.S., Burns, C.G., Wells, K.S., Yang, T., Zhong, T.P., and Roden, D.M. (2010) Voltage-Gated Sodium Channels Are Required for Heart Development in Zebrafish. Circulation research. 106(8):1342-1350
Deacon, D.C., Nevis, K.R., Cashman, T.J., Zhou, Y., Zhao, L., Washko, D., Guner-Ataman, B., Burns, C.G., and Burns, C.E. (2010) The miR-143-adducin3 pathway is essential for cardiac chamber morphogenesis. Development (Cambridge, England). 137(11):1887-1896
de Pater, E., Clijsters, L., Marques, S.R., Lin, Y.F., Garavito-Aguilar, Z.V., Yelon, D., and Bakkers, J. (2009) Distinct phases of cardiomyocyte differentiation regulate growth of the zebrafish heart. Development (Cambridge, England). 136(10):1633-1641
Marques, S.R., and Yelon, D. (2009) Differential requirement for BMP signaling in atrial and ventricular lineages establishes cardiac chamber proportionality. Developmental Biology. 328(2):472-482
Sun, X., Hoage, T., Bai, P., Ding, Y., Chen, Z., Zhang, R., Huang, W., Jahangir, A., Paw, B., Li, Y.G., and Xu, X. (2009) Cardiac hypertrophy involves both myocyte hypertrophy and hyperplasia in anemic zebrafish. PLoS One. 4(8):e6596
Chen, J., Carney, S.A., Peterson, R.E., and Heideman, W. (2008) Comparative Genomics Identifies Genes Mediating Cardiotoxicity in the Embryonic Zebrafish Heart. Physiological Genomics. 33(2):148-158
Chen, Z., Huang, W., Dahme, T., Rottbauer, W., Ackerman, M.J., and Xu, X. (2008) Depletion of Zebrafish Essential and Regulatory Myosin Light Chains Reduces Cardiac Function Through Distinct Mechanisms. Cardiovascular research. 79(1):97-108
Grimes, A.C., Erwin, K.N., Stadt, H.A., Hunter, G.L., Gefroh, H.A., Tsai, H.J., and Kirby, M.L. (2008) PCB126 Exposure Disrupts Zebrafish Ventricular and Branchial but Not Early Neural Crest Development. Toxicological sciences : an official journal of the Society of Toxicology. 106(1):193-205
Marques, S.R., Lee, Y., Poss, K.D., and Yelon, D. (2008) Reiterative roles for FGF signaling in the establishment of size and proportion of the zebrafish heart. Developmental Biology. 321(2):397-406
Qu, X., Jia, H., Garrity, D.M., Tompkins, K., Batts, L., Appel, B., Zhong, T.P., and Baldwin, H.S. (2008) ndrg4 is required for normal myocyte proliferation during early cardiac development in zebrafish. Developmental Biology. 317(2):486-496
Targoff, K.L., Schell, T., and Yelon, D. (2008) Nkx genes regulate heart tube extension and exert differential effects on ventricular and atrial cell number. Developmental Biology. 322(2):314-321
Thomas, N.A., Koudijs, M., van Eeden, F.J., Joyner, A.L., and Yelon, D. (2008) Hedgehog signaling plays a cell-autonomous role in maximizing cardiac developmental potential. Development (Cambridge, England). 135(22):3789-3799
Waxman, J.S., Keegan, B.R., Roberts, R.W., Poss, K.D., and Yelon, D. (2008) Hoxb5b acts downstream of retinoic Acid signaling in the forelimb field to restrict heart field potential in zebrafish. Developmental Cell. 15(6):923-934
Wills, A.A., Holdway, J.E., Major, R.J., and Poss, K.D. (2008) Regulated addition of new myocardial and epicardial cells fosters homeostatic cardiac growth and maintenance in adult zebrafish. Development (Cambridge, England). 135(1):183-192
Kim, K.H., Antkiewicz, D.S., Yan, L., Eliceir, K.W., Heideman, W., Peterson, R.E., and Lee, Y. (2007) Lrrc10 is required for early heart development and function in zebrafish. Developmental Biology. 308(2):494-506
Schoenebeck, J.J., Keegan, B.R., and Yelon, D. (2007) Vessel and blood specification override cardiac potential in anterior mesoderm. Developmental Cell. 13(2):254-267
Antkiewicz, D.S., Peterson, R.E., and Heideman, W. (2006) Blocking Expression of AHR2 and ARNT1 in Zebrafish Larvae Protects Against Cardiac Toxicity of 2,3,7,8-Tetrachlorodibenzo-p-dioxin. Toxicological sciences : an official journal of the Society of Toxicology. 94(1):175-182
Lepilina, A., Coon, A.N., Kikuchi, K., Holdway, J.E., Roberts, R.W., Burns, C.G., and Poss, K.D. (2006) A Dynamic Epicardial Injury Response Supports Progenitor Cell Activity during Zebrafish Heart Regeneration. Cell. 127(3):607-619
Mably, J.D., Chuang, L.P., Serluca, F.C., Mohideen, M.A., Chen, J.N., and Fishman, M.C. (2006) santa and valentine pattern concentric growth of cardiac myocardium in the zebrafish. Development (Cambridge, England). 133(16):3139-3146
Antkiewicz, D.S., Burns, C.G., Carney, S.A., Peterson, R.E., and Heideman, W. (2005) Heart Malformation is an Early Response to TCDD in Embryonic Zebrafish. Toxicological sciences : an official journal of the Society of Toxicology. 84(2):368-377
Mably, J.D., Mohideen, M.A.P.K., Burns, C.G., Chen, J.-N., and Fishman, M.C. (2003) heart of glass regulates the concentric growth of the heart in zebrafish. Current biology : CB. 13(24):2138-2147
Rottbauer, W., Saurin, A.J., Lickert, H., Shen, X., Burns, C.G., Wo, Z.G., Kemler, R., Kingston, R., Wu, C., and Fishman, M. (2002) Reptin and pontin antagonistically regulate heart growth in zebrafish embryos. Cell. 111(5):661-672
Additional Citations (4):
ZFIN Staff (2015) Data Model Change: Sequence Targeting Reagents Removed from Environment. ZFIN Historical Data.
Zebrafish Nomenclature Committee (2003) Nomenclature Data Curation (2003-2010). Nomenclature Committee Submission.
ZFIN Staff (2003) Submission and Curation of Mutant and Transgenic Lines. ZFIN Direct Data Submission.
ZFIN Staff (2002) Scientific Curation. Manually curated data.
Your Input Welcome
We welcome your input and comments. Please use this form to recommend updates to the information in ZFIN. We appreciate as much detail as possible and references as appropriate. We will review your comments promptly.
Please check the highlighted fields and try again.
Thank you for submitting comments. Your input has been emailed to ZFIN curators who may contact you if additional information is required.
Oops. Something went wrong. Please try again later.