ZFIN Publication List

ZFIN ID: ZDB-ATB-081006-9

CITATIONS (37 total)

Antibody Name: Ab1-ins

Antomagesh, F., Jayakumar Rajeswari, J., Vijayan, M.M. (2023) Chronic cortisol elevation restricts glucose uptake but not insulin responsiveness in zebrafish skeletal muscle. General and comparative endocrinology. 336:114231

Carril Pardo, C.A., Massoz, L., Dupont, M.A., Bergemann, D., Bourdouxhe, J., Lavergne, A., Tarifeño-Saldivia, E., Helker, C.S., Stainier, D.Y., Peers, B., Voz, M.M., Manfroid, I. (2022) A δ-cell subpopulation with pro-β cell identity contributes to efficient age-independent recovery in a zebrafish diabetes model. eLIFE. 11:

Hill, J.H., Massaquoi, M.S., Sweeney, E.G., Wall, E.S., Jahl, P., Bell, R., Kallio, K., Derrick, D., Murtaugh, L.C., Parthasarathy, R., Remington, S.J., Round, J.L., Guillemin, K. (2022) BefA, a microbiota-secreted membrane disrupter, disseminates to the pancreas and increases β cell mass. Cell Metabolism. 34(11):1779-1791.e9

Singh, S.P., Chawla, P., Hnatiuk, A., Kamel, M., Silva, L.D., Spanjaard, B., Eski, S.E., Janjuha, S., Olivares-Chauvet, P., Kayisoglu, O., Rost, F., Bläsche, J., Kränkel, A., Petzold, A., Kurth, T., Reinhardt, S., Junker, J.P., Ninov, N. (2022) A single-cell atlas of de novo β-cell regeneration reveals the contribution of hybrid β/δ-cells to diabetes recovery in zebrafish. Development (Cambridge, England). 149(2)

Xu, Y., Tian, J., Kang, Q., Yuan, H., Liu, C., Li, Z., Liu, J., Li, M. (2022) Knockout of Nur77 Leads to Amino Acid, Lipid, and Glucose Metabolism Disorders in Zebrafish. Frontiers in endocrinology. 13:864631

Yang, B., Yang, L., Wang, Y., Maddison, L.A., Tang, Z., Haigh, S., Gong, Y., Zhang, Y., Covington, B.A., Bosma, K.J., Tong, X., Page-McCaw, P., Gannon, M., Deng, Q., Chen, W. (2022) Macrophages and neutrophils are necessary for ER stress-induced β cell loss. Cell Reports. 40:111255

Yang, Y.H.C., Briant, L.J.B., Raab, C.A., Mullapudi, S.T., Maischein, H.M., Kawakami, K., Stainier, D.Y.R. (2022) Innervation modulates the functional connectivity between pancreatic endocrine cells. eLIFE. 11:

Yang, L., Webb, S.E., Jin, N., Lee, H.M., Chan, T.F., Xu, G., Chan, J.C.N., Miller, A.L., Ma, R.C.W. (2021) Investigating the role of dachshund b in the development of the pancreatic islet in zebrafish. Journal of diabetes investigation. 12(5):710-727

Houbrechts, A.M., Beckers, A., Vancamp, P., Sergeys, J., Gysemans, C., Mathieu, C., Darras, V.M. (2019) Age-dependent changes in glucose homeostasis in male deiodinase type 2 knockout zebrafish. Endocrinology. 160(11):2759-2772

Mullapudi, S.T., Boezio, G.L.M., Rossi, A., Marass, M., Matsuoka, R.L., Matsuda, H., Helker, C.S.M., Yang, Y.H.C., Stainier, D.Y.R. (2019) Disruption of the pancreatic vasculature in zebrafish affects islet architecture and function. Development (Cambridge, England). 146(21):

Oh, S., Park, J.T. (2019) Zebrafish model of KRAS-initiated pancreatic endocrine tumor. Animal cells and systems. 23:209-218

Salem, V., Silva, L.D., Suba, K., Georgiadou, E., Neda Mousavy Gharavy, S., Akhtar, N., Martin-Alonso, A., Gaboriau, D.C.A., Rothery, S.M., Stylianides, T., Carrat, G., Pullen, T.J., Singh, S.P., Hodson, D.J., Leclerc, I., Shapiro, A.M.J., Marchetti, P., Briant, L.J.B., Distaso, W., Ninov, N., Rutter, G.A. (2019) Leader β-cells coordinate Ca²⁺ dynamics across pancreatic islets in vivo. Nature metabolism. 1:615-629

Freudenblum, J., Iglesias, J.A., Hermann, M., Walsen, T., Wilfinger, A., Meyer, D., Kimmel, R.A. (2018) In vivo imaging of emerging endocrine cells reveals a requirement for PI3K-regulated motility in pancreatic islet morphogenesis.. Development (Cambridge, England). 145(3)

Janjuha, S., Singh, S.P., Tsakmaki, A., Mousavy-Gharavy, N., Murawala, P., Konantz, J., Birke, S., Hodson, D.J., Rutter, G., Bewick, G., Ninov, N.N. (2018) Age-related islet inflammation marks the proliferative decline of pancreatic beta-cells in zebrafish. eLIFE. 7

Lorincz, R., Emfinger, C.H., Walcher, A., Giolai, M., Krautgasser, C., Remedi, M.S., Nichols, C.G., Meyer, D. (2018) In vivo monitoring of intracellular Ca²⁺ dynamics in the pancreatic β-cells of zebrafish embryos. Islets. 10(6):221-238

Mullapudi, S.T., Helker, C.S., Boezio, G.L., Maischein, H.M., Sokol, A.M., Guenther, S., Matsuda, H., Kubicek, S., Graumann, J., Yang, Y.H.C., Stainier, D.Y. (2018) Screening for insulin-independent pathways that modulate glucose homeostasis identifies androgen receptor antagonists. eLIFE. 7:

Singh, S.P., Janjuha, S., Hartmann, T., Kayisoglu, Ö., Konantz, J., Birke, S., Murawala, P., Alfar, E.A., Murata, K., Eugster, A., Tsuji, N., Morrissey, E.R., Brand, M., Ninov, N. (2017) Different developmental histories of beta-cells generate functional and proliferative heterogeneity during islet growth. Nature communications. 8:664

Dash, S.N., Hakonen, E., Ustinov, J., Otonkoski, T., Andersson, O., Lehtonen, S. (2016) sept7b is required for the differentiation of pancreatic endocrine progenitors. Scientific Reports. 6:24992

Hill, J.H., Franzosa, E.A., Huttenhower, C., Guillemin, K. (2016) A conserved bacterial protein induces pancreatic beta cell expansion during zebrafish development. eLIFE. 5

Bielczyk-Maczyńska, E., Lam Hung, L., Ferreira, L., Fleischmann, T., Weis, F., Fernández-Pevida, A., Harvey, S.A., Wali, N., Warren, A.J., Barroso, I., Stemple, D.L., Cvejic, A. (2015) The Ribosome Biogenesis Protein Nol9 Is Essential for Definitive Hematopoiesis and Pancreas Morphogenesis in Zebrafish. PLoS Genetics. 11:e1005677

Dalgin, G., Prince, V.E. (2015) Differential levels of Neurod establish zebrafish endocrine pancreas cell fates. Developmental Biology. 402(1):81-97

Delaspre, F., Beer, R.L., Rovira, M., Huang, W., Wang, G., Gee, S., Vitery, M.D., Wheelan, S.J., Parsons, M.J. (2015) Centroacinar cells are progenitors that contribute to endocrine pancreas regeneration. Diabetes. 64(10):3499-509

Kimmel, R.A., Dobler, S., Schmitner, N., Walsen, T., Freudenblum, J., Meyer, D. (2015) Diabetic pdx1-mutant zebrafish show conserved responses to nutrient overload and anti-glycemic treatment. Scientific Reports. 5:14241

Wang, Y.J., Park, J.T., Parsons, M.J., Leach, S.D. (2015) Fate mapping of ptf1a-expressing cells during pancreatic organogenesis and regeneration in zebrafish. Developmental Dynamics : an official publication of the American Association of Anatomists. 244(6):724-35

Huang, W., Wang, G., Delaspre, F., Vitery, M.D., Beer, R.L., Parsons, M.J. (2014) Retinoic acid plays an evolutionarily conserved and biphasic role in pancreas development. Developmental Biology. 394(1):83-93

Eames, S.C., Kinkel, M.D., Rajan, S., Prince, V.E., Philipson, L.H. (2013) Transgenic zebrafish model of the C43G human insulin gene mutation. Journal of diabetes investigation. 4:157-67

Li, M., Maddison, L.A., Crees, Z., and Chen, W. (2013) Targeted Overexpression of CKI-Insensitive Cyclin-Dependent Kinase 4 Increases Functional β-Cell Number Through Enhanced Self-Replication in Zebrafish. Zebrafish. 10(2):170-6

Moss, L.G., Caplan, T.V., and Moss, J.B. (2013) Imaging Beta cell regeneration and interactions with islet vasculature in transparent adult zebrafish. Zebrafish. 10(2):249-257

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

Maddison, L.A., and Chen, W. (2012) Nutrient Excess Stimulates β-Cell Neogenesis in Zebrafish. Diabetes. 61(10):2517-2524

Dalgin, G., Ward, A.B., Hao le, T., Beattie, C.E., Nechiporuk, A., and Prince, V.E. (2011) Zebrafish mnx1 controls cell fate choice in the developing endocrine pancreas. Development (Cambridge, England). 138(21):4597-4608

Mazilu, J.K., Powers, J.W., Lin, S., and McCabe, E.R. (2010) ff1b, the SF1 ortholog, is important for pancreatic islet cell development in zebrafish. Molecular genetics and metabolism. 101(4):391-394

Moro, E., Gnügge, L., Braghetta, P., Bortolussi, M., and Argenton, F. (2009) Analysis of beta cell proliferation dynamics in zebrafish. Developmental Biology. 332(2):299-308

Kinkel, M.D., Eames, S.C., Alonzo, M.R., and Prince, V.E. (2008) Cdx4 is required in the endoderm to localize the pancreas and limit {beta}-cell number. Development (Cambridge, England). 135(5):919-929

Biemar, F., Argenton, F., Schmidtke, R., Epperlein, S., Peers, B., and Driever, W. (2001) Pancreas development in zebrafish: early dispersed appearance of endocrine hormone expressing cells and their convergence to form the definitive islet. Developmental Biology. 230(2):189-203

Additional Citations (2):

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

ZFIN Staff (2002) Scientific Curation. Manually curated data.