ZFIN Publication List

ZFIN ID: ZDB-ATB-081006-2

CITATIONS (50 total)

Antibody Name: Ab-Pax7

Abe, K., Shimada, A., Tayama, S., Nishikawa, H., Kaneko, T., Tsuda, S., Karaiwa, A., Matsui, T., Ishitani, T., Takeda, H. (2019) Horizontal Boundary Cells, a Special Group of Somitic Cells, Play Crucial Roles in the Formation of Dorsoventral Compartments in Teleost Somite. Cell Reports. 27:928-939.e4

Alexander, M.S., Kawahara, G., Kho, A.T., Howell, M.H., Pusack, T.J., Myers, J.A., Montanaro, F., Zon, L.I., Guyon, J.R., and Kunkel, L.M. (2011) Isolation and transcriptome analysis of adult zebrafish cells enriched for skeletal muscle progenitors. Muscle & nerve. 43(5):741-750

Bennett, A.H., O'Donohue, M.F., Gundry, S.R., Chan, A.T., Widrick, J., Draper, I., Chakraborty, A., Zhou, Y., Zon, L.I., Gleizes, P.E., Beggs, A.H., Gupta, V.A. (2018) RNA helicase, DDX27 regulates skeletal muscle growth and regeneration by modulation of translational processes. PLoS Genetics. 14:e1007226

Berberoglu, M.A., Gallagher, T.L., Morrow, Z.T., Talbot, J.C., Hromowyk, K.J., Tenente, I.M., Langenau, D.M., Amacher, S.L. (2017) Satellite-like cells contribute to pax7-dependent skeletal muscle repair in adult zebrafish. Developmental Biology. 424(2):162-180

Berger, J., Berger, S., Hall, T.E., Lieschke, G.J., and Currie, P.D. (2010) Dystrophin-deficient zebrafish feature aspects of the Duchenne muscular dystrophy pathology. Neuromuscular disorders : NMD. 20(12):826-832

Campinho, M.A., Saraiva, J., Florindo, C., Power, D.M. (2014) Maternal thyroid hormones are essential for neural development in zebrafish. Molecular endocrinology (Baltimore, Md.). 28(7):1136-49

Chen, F., Yuan, W., Mo, X., Zhuang, J., Wang, Y., Chen, J., Jiang, Z., Zhu, X., Zeng, Q., Wan, Y., Li, F., Shi, Y., Cao, L., Fan, X., Luo, S., Ye, X., Chen, Y., Dai, G., Gao, J., Wang, X., Xie, H., Zhu, P., Li, Y., Wu, X. (2018) Role of zebrafish fhl1A in satellite cell and skeletal muscle development. Current Molecular Medicine. 17(9):627-636

Eom, D.S., Bain, E.J., Patterson, L.B., Grout, M.E., Parichy, D.M. (2015) Long-distance communication by specialized cellular projections during pigment pattern development and evolution. eLIFE. 4

Feng, X., Adiarte, E.G., and Devoto, S.H. (2006) Hedgehog acts directly on the zebrafish dermomyotome to promote myogenic differentiation. Developmental Biology. 300(2):736-746

Froehlich, J.M., Galt, N.J., Charging, M.J., Meyer, B.M., and Biga, P.R. (2013) In vitro indeterminate teleost myogenesis appears to be dependent on Pax3. In vitro cellular & developmental biology. Animal. 49(5):371-85

Guner, B., Ozacar, A.T., Thomas, J.E., and Karlstrom, R.O. (2008) Graded hedgehog and fibroblast growth factor signaling independently regulate pituitary cell fates and help establish the pars distalis and pars intermedia of the zebrafish adenohypophysis. Endocrinology. 149(9):4435-4451

Gurevich, D.B., Nguyen, P.D., Siegel, A.L., Ehrlich, O.V., Sonntag, C., Phan, J.M., Berger, S., Ratnayake, D., Hersey, L., Berger, J., Verkade, H., Hall, T.E., Currie, P.D. (2016) Asymmetric division of clonal muscle stem cells coordinates muscle regeneration in vivo. Science (New York, N.Y.). 353(6295):aad9969

Hammond, C.L., Hinits, Y., Osborn, D.P., Minchin, J.E., Tettamanti, G., and Hughes, S.M. (2007) Signals and myogenic regulatory factors restrict pax3 and pax7 expression to dermomyotome-like tissue in zebrafish. Developmental Biology. 302(2):504-521

Hromowyk, K.J., Talbot, J.C., Martin, B.L., Janssen, P.M.L., Amacher, S.L. (2020) Cell fusion is differentially regulated in zebrafish post-embryonic slow and fast muscle. Developmental Biology. 462(1):85-100

Knappe, S., Zammit, P.S., Knight, R.D. (2015) A population of Pax7-expressing muscle progenitor cells show differential responses to muscle injury dependent on developmental stage and injury extent. Frontiers in aging neuroscience. 7:161

Li, Y.H., Chen, H.Y., Li, Y.W., Wu, S.Y., Wangta, L., Lin, G.H., Hu, S.Y., Chang, Z.K., Gong, H.Y., Liao, C.H., Chiang, K.Y., Huang, C.W., and Wu, J.L. (2013) Progranulin regulates zebrafish muscle growth and regeneration through maintaining the pool of myogenic progenitor cells. Scientific Reports. 3:1176

Lobbardi, R., Lambert, G., Zhao, J., Geisler, R., Kim, H.R., and Rosa, F.M. (2011) Fine-tuning of Hh signaling by the RNA-binding protein Quaking to control muscle development. Development (Cambridge, England). 138(9):1783-1794

Manohar, M., Mei, H., Franklin, A.J., Sweet, E.M., Shigaki, T., Riley, B.B., Macdiarmid, C.W., and Hirschi, K.D. (2010) A Zebrafish (Danio rerio) Endomembrane Antiporter Similar to a Yeast Cation/H+ Transporter is Required for Neural Crest Development. Biochemistry. 49(31):6557-6566

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

Minchin, J.E., and Hughes, S.M. (2008) Sequential actions of Pax3 and Pax7 drive xanthophore development in zebrafish neural crest. Developmental Biology. 317(2):508-522

Minchin, J.E., Williams, V.C., Hinits, Y., Low, S., Tandon, P., Fan, C.M., Rawls, J.F., and Hughes, S.M. (2013) Oesophageal and sternohyal muscle fibres are novel Pax3-dependent migratory somite derivatives essential for ingestion. Development (Cambridge, England). 140(14):2972-2984

Moore, S., Ribes, V., Terriente, J., Wilkinson, D., Relaix, F., Briscoe, J. (2013) Distinct regulatory mechanisms act to establish and maintain Pax3 expression in the developing neural tube. PLoS Genetics. 9:e1003811

Mukherjee, K., Ishii, K., Pillalamarri, V., Kammin, T., Atkin, J.F., Hickey, S.E., Xi, Q.J., Gusella, J.F., Talkowski, M.E., Morton, C.C., Maas, R.L., Liao, E.C. (2016) Actin capping protein CAPZB regulates cell morphology, differentiation, and neural crest migration in craniofacial morphogenesis. Human molecular genetics. 25(7):1255-70

Nord, H., Dennhag, N., Muck, J., von Hofsten, J. (2016) Pax7 is required for establishment of the xanthophore lineage in zebrafish embryos. Molecular biology of the cell. 27(11):1853-62

Nord, H., Kahsay, A., Dennhag, N., Pedrosa Domellöf, F., von Hofsten, J. (2021) Genetic compensation between Pax3 and Pax7 in zebrafish appendicular muscle formation. Developmental Dynamics : an official publication of the American Association of Anatomists. 251(9):1423-1438

Nord, H., Skalman, L.N., and von Hofsten, J. (2013) Six1 regulates proliferation of Pax7-positive muscle progenitors in zebrafish. Journal of Cell Science. 126(Pt 8):1868-80

Otten, C., van der Ven, P.F., Lewrenz, I., Paul, S., Steinhagen, A., Busch-Nentwich, E., Eichhorst, J., Wiesner, B., Stemple, D., Strähle, U., Fürst, D.O., and Abdelilah-Seyfried, S. (2012) Xirp proteins mark injured skeletal muscle in zebrafish. PLoS One. 7(2):e31041

Pascoal, S., Esteves de Lima, J., Leslie, J.D., Hughes, S.M., and Saúde, L. (2013) Notch signalling is required for the formation of structurally stable muscle fibres in zebrafish. PLoS One. 8(6):e68021

Patterson, S.E., Bird, N.C., and Devoto, S.H. (2010) BMP regulation of myogenesis in zebrafish. Developmental Dynamics : an official publication of the American Association of Anatomists. 239(3):806-817

Patterson, S.E., Mook, L.B., and Devoto, S.H (2008) Growth in the larval zebrafish pectoral fin and trunk musculature. Developmental Dynamics : an official publication of the American Association of Anatomists. 237(2):307-315

Petratou, K., Spencer, S.A., Kelsh, R.N., Lister, J.A. (2021) The MITF paralog tfec is required in neural crest development for fate specification of the iridophore lineage from a multipotent pigment cell progenitor. PLoS One. 16:e0244794

Pipalia, T.G., Koth, J., Roy, S.D., Hammond, C.L., Kawakami, K., Hughes, S.M. (2016) Cellular dynamics of regeneration reveals role of two distinct Pax7 stem cell populations in larval zebrafish muscle repair. Disease models & mechanisms. 9(6):671-84

Pistocchi, A., Gaudenzi, G., Foglia, E., Monteverde, S., Moreno-Fortuny, A., Pianca, A., Cossu, G., Cotelli, F., and Messina, G. (2013) Conserved and divergent functions of Nfix in skeletal muscle development during vertebrate evolution. Development (Cambridge, England). 140(7):1528-1536

Riley, B.B., Sweet, E.M., Heck, R., Evans, A., McFarland, K.N., Warga, R.M., and Kane, D.A. (2010) Characterization of harpy/Rca1/emi1 mutants: patterning in the absence of cell division. Developmental Dynamics : an official publication of the American Association of Anatomists. 239(3):828-843

Rovira, M., Arrey, G., Planas, J.V. (2017) Exercise-Induced Hypertrophic and Oxidative Signaling Pathways and Myokine Expression in Fast Muscle of Adult Zebrafish. Frontiers in Physiology. 8:1063

Roy, S.D., Williams, V.C., Pipalia, T.G., Li, K., Hammond, C.L., Knappe, S., Knight, R.D., Hughes, S.M. (2017) Myotome adaptability confers developmental robustness to somitic myogenesis in response to fibre number alteration. Developmental Biology. 431(2):321-335

Saera-Vila, A., Kasprick, D.S., Junttila, T.L., Grzegorski, S.J., Louie, K.W., Chiari, E.F., Kish, P.E., Kahana, A. (2015) Myocyte Dedifferentiation Drives Extraocular Muscle Regeneration in Adult Zebrafish. Investigative ophthalmology & visual science. 56:4977-4993

Seger, C., Hargrave, M., Wang, X., Chai, R.J., Elworthy, S., and Ingham, P.W. (2011) Analysis of Pax7 expressing myogenic cells in zebrafish muscle development, injury, and models of disease. Developmental Dynamics : an official publication of the American Association of Anatomists. 240(11):2440-51

Sharma, P., Ruel, T.D., Kocha, K.M., Liao, S., Huang, P. (2019) Single cell dynamics of embryonic muscle progenitor cells in zebrafish. Development (Cambridge, England). 146(14):

Skobo, T., Benato, F., Grumati, P., Meneghetti, G., Cianfanelli, V., Castagnaro, S., Chrisam, M., Di Bartolomeo, S., Bonaldo, P., Cecconi, F., Valle, L.D. (2014) Zebrafish ambra1a and ambra1b Knockdown Impairs Skeletal Muscle Development. PLoS One. 9:e99210

Solchenberger, B., Russell, C., Kremmer, E., Haass, C., Schmid, B. (2015) Granulin Knock Out Zebrafish Lack Frontotemporal Lobar Degeneration and Neuronal Ceroid Lipofuscinosis Pathology. PLoS One. 10:e0118956

Stellabotte, F., Dobbs-McAuliffe, B., Fernandez, D.A., Feng, X., and Devoto, S.H. (2007) Dynamic somite cell rearrangements lead to distinct waves of myotome growth. Development (Cambridge, England). 134(7):1253-1257

Sultan, S.H.A., Dyer, C., Knight, R.D. (2021) Notch Signaling Regulates Muscle Stem Cell Homeostasis and Regeneration in a Teleost Fish. Frontiers in cell and developmental biology. 9:726281

Tee, J.M., Sartori da Silva, M., Rygiel, A., Muncan, V., Bink, R., van den Brink, G., van Tijn, P., Zivkovic, D., Kodach, L., Guardavaccaro, D., Diks, S., and Peppelenbosch, M. (2012) asb11 is a regulator of embryonic and adult regenerative myogenesis. Stem cells and development. 21(17):3091-3103

Van Otterloo, E., Li, W., Bonde, G., Day, K.M., Hsu, M.Y., and Cornell, R.A. (2010) Differentiation of zebrafish melanophores depends on transcription factors AP2 alpha and AP2 epsilon. PLoS Genetics. 6(9):pii: e1001122

Windner, S.E., Bird, N.C., Patterson, S.E., Doris, R.A., and Devoto, S.H. (2012) Fss/Tbx6 is required for central dermomyotome cell fate in zebrafish. Biology Open. 1(8):806-814

Windner, S.E., Doris, R.A., Ferguson, C.M., Nelson, A.C., Valentin, G., Tan, H., Oates, A.C., Wardle, F.C., Devoto, S.H. (2015) Tbx6, Mesp-b and Ripply1 regulate the onset of skeletal myogenesis in zebrafish. Development (Cambridge, England). 142(6):1159-68

Yin, J., Lee, R., Ono, Y., Ingham, P.W., Saunders, T.E. (2018) Spatiotemporal Coordination of FGF and Shh Signaling Underlies the Specification of Myoblasts in the Zebrafish Embryo. Developmental Cell. 46:735-750.e4

Zannino, D.A., and Appel, B. (2009) Olig2+ precursors produce abducens motor neurons and oligodendrocytes in the zebrafish hindbrain. The Journal of neuroscience : the official journal of the Society for Neuroscience. 29(8):2322-2333

Additional Citations (1):

ZFIN Staff (2008) Antibody information from supplier. Manually curated data.