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3. Expanding the genetic toolkit in Xenopus: Approaches and opportunities for human disease modeling

Author

Tandon, Panna, Conlon, Frank, Furlow, J David, and Horb, Marko E

Subjects
Biological Sciences, Genetics, Human Genome, Biotechnology, Generic health relevance, Animal Husbandry, Animals, Base Pairing, CRISPR-Cas Systems, Disease Models, Animal, Gene Editing, Gene Knock-In Techniques, Gene Knockout Techniques, Genome, Humans, Laboratory Animal Science, Selective Breeding, Tetraploidy, Transcription Activator-Like Effector Nucleases, Xenopus, Xenopus laevis, CRISPR-Cas, TALENs, J strain, Xenopus tropicalis, Knock-in, Human disease model, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences, Health sciences
Abstract

The amphibian model Xenopus, has been used extensively over the past century to study multiple aspects of cell and developmental biology. Xenopus offers advantages of a non-mammalian system, including high fecundity, external development, and simple housing requirements, with additional advantages of large embryos, highly conserved developmental processes, and close evolutionary relationship to higher vertebrates. There are two main species of Xenopus used in biomedical research, Xenopus laevis and Xenopus tropicalis; the common perception is that both species are excellent models for embryological and cell biological studies, but only Xenopus tropicalis is useful as a genetic model. The recent completion of the Xenopus laevis genome sequence combined with implementation of genome editing tools, such as TALENs (transcription activator-like effector nucleases) and CRISPR-Cas (clustered regularly interspaced short palindromic repeats-CRISPR associated nucleases), greatly facilitates the use of both Xenopus laevis and Xenopus tropicalis for understanding gene function in development and disease. In this paper, we review recent advances made in Xenopus laevis and Xenopus tropicalis with TALENs and CRISPR-Cas and discuss the various approaches that have been used to generate knockout and knock-in animals in both species. These advances show that both Xenopus species are useful for genetic approaches and in particular counters the notion that Xenopus laevis is not amenable to genetic manipulations.

Published
2017

4. Adeno-Associated Viral Tools to Trace Neural Development and Connectivity Across Amphibians

Author

Jaeger, Eliza C.B., primary, Vijatovic, David, additional, Deryckere, Astrid, additional, Zorin, Nikol, additional, Nguyen, Akemi L., additional, Ivanian, Georgiy, additional, Woych, Jamie, additional, Arnold, Rebecca C., additional, Ortega Gurrola, Alonso, additional, Shvartsman, Arik, additional, Barbieri, Francesca, additional, Toma, Florina A., additional, Gorbsky, Gary J., additional, Horb, Marko E., additional, Cline, Hollis T., additional, Shay, Timothy F., additional, Kelley, Darcy B., additional, Yamaguchi, Ayako, additional, Shein-Idelson, Mark, additional, Tosches, Maria Antonietta, additional, and Sweeney, Lora B., additional

Published
2024
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5. Functional dissection and assembly of a small, newly evolved, W chromosome-specific genomic region of the African clawed frog Xenopus laevis

Author

Cauret, Caroline M. S., primary, Jordan, Danielle C., additional, Kukoly, Lindsey M., additional, Burton, Sarah R., additional, Anele, Emmanuela U., additional, Kwiecien, Jacek M., additional, Gansauge, Marie-Theres, additional, Senthillmohan, Sinthu, additional, Greenbaum, Eli, additional, Meyer, Matthias, additional, Horb, Marko E., additional, and Evans, Ben J., additional

Published
2023
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7. Evolutionarily conserved Tbx5–Wnt2/2b pathway orchestrates cardiopulmonary development

Author

Steimle, Jeffrey D., Rankin, Scott A., Slagle, Christopher E., Bekeny, Jenna, Rydeen, Ariel B., Chan, Sunny Sun-Kin, Kweon, Junghun, Yang, Xinan H., Ikegami, Kohta, Nadadur, Rangarajan D., Rowton, Megan, Hoffmann, Andrew D., Lazarevic, Sonja, Thomas, William, Anderson, Erin A. T. Boyle, Horb, Marko E., Luna-Zurita, Luis, Ho, Robert K., Kyba, Michael, Jensen, Bjarke, Zorn, Aaron M., Conlon, Frank L., and Moskowitz, Ivan P.

Published
2018

18. Developing immortal cell lines from Xenopus embryos, four novel cell lines derived from Xenopus tropicalis

Author

Gorbsky, Gary J., Daum, John R., Sapkota, Hem, Summala, Katja, Yoshida, Hitoshi, Georgescu, Constantin, Wren, Jonathan D., Peshkin, Leonid, Horb, Marko E., Gorbsky, Gary J., Daum, John R., Sapkota, Hem, Summala, Katja, Yoshida, Hitoshi, Georgescu, Constantin, Wren, Jonathan D., Peshkin, Leonid, and Horb, Marko E.

Abstract

© The Author(s), 2022. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Gorbsky, G. J., Daum, J. R., Sapkota, H., Summala, K., Yoshida, H., Georgescu, C., Wren, J. D., Peshkin, L., & Horb, M. E. Developing immortal cell lines from Xenopus embryos, four novel cell lines derived from Xenopus tropicalis. Open Biology, 12(7), (2022): 220089, https://doi.org/10.1098/rsob.220089., The diploid anuran Xenopus tropicalis has emerged as a key research model in cell and developmental biology. To enhance the usefulness of this species, we developed methods for generating immortal cell lines from Nigerian strain (NXR_1018, RRID:SCR_013731) X. tropicalis embryos. We generated 14 cell lines that were propagated for several months. We selected four morphologically distinct lines, XTN-6, XTN-8, XTN-10 and XTN-12 for further characterization. Karyotype analysis revealed that three of the lines, XTN-8, XTN-10 and XTN-12 were primarily diploid. XTN-6 cultures showed a consistent mixed population of diploid cells, cells with chromosome 8 trisomy, and cells containing a tetraploid content of chromosomes. The lines were propagated using conventional culture methods as adherent cultures at 30°C in a simple, diluted L-15 medium containing fetal bovine serum without use of a high CO2 incubator. Transcriptome analysis indicated that the four lines were distinct lineages. These methods will be useful in the generation of cell lines from normal and mutant strains of X. tropicalis as well as other species of Xenopus., This work was supported by Whitman fellowships to G.J.G. from the Marine Biological Laboratory, by grant no. 1645105 to G.J.G. and MEH from the National Science Foundation and by grant no. P40OD010997 from the Office of the Director, National Institutes of Health. L.P. has been supported by grant no. R01HD073104 from the National Institute of Child Health and Development.

Published
2022

19. Normal table of Xenopus development: a new graphical resource

Author

Zahn, Natalya, James-Zorn, Christina, Ponferrada, Virgilio G., Adams, Dany S., Grzymkowski, Julia, Buchholz, Daniel R., Nascone-Yoder, Nanette M., Horb, Marko E., Moody, Sally A., Vize, Peter D., Zorn, Aaron M., Zahn, Natalya, James-Zorn, Christina, Ponferrada, Virgilio G., Adams, Dany S., Grzymkowski, Julia, Buchholz, Daniel R., Nascone-Yoder, Nanette M., Horb, Marko E., Moody, Sally A., Vize, Peter D., and Zorn, Aaron M.

Abstract

© The Author(s), 2022. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Zahn, N., James-Zorn, C., Ponferrada, V. G., Adams, D. S., Grzymkowski, J., Buchholz, D. R., Nascone-Yoder, N. M., Horb, M., Moody, S. A., Vize, P. D., & Zorn, A. M. Normal table of Xenopus development: a new graphical resource. Development, 149(14), (2022): dev200356, https://doi.org/10.1242/dev.200356., Normal tables of development are essential for studies of embryogenesis, serving as an important resource for model organisms, including the frog Xenopus laevis. Xenopus has long been used to study developmental and cell biology, and is an increasingly important model for human birth defects and disease, genomics, proteomics and toxicology. Scientists utilize Nieuwkoop and Faber's classic ‘Normal Table of Xenopus laevis (Daudin)’ and accompanying illustrations to enable experimental reproducibility and reuse the illustrations in new publications and teaching. However, it is no longer possible to obtain permission for these copyrighted illustrations. We present 133 new, high-quality illustrations of X. laevis development from fertilization to metamorphosis, with additional views that were not available in the original collection. All the images are available on Xenbase, the Xenopus knowledgebase (http://www.xenbase.org/entry/zahn.do), for download and reuse under an attributable, non-commercial creative commons license. Additionally, we have compiled a ‘Landmarks Table’ of key morphological features and marker gene expression that can be used to distinguish stages quickly and reliably (https://www.xenbase.org/entry/landmarks-table.do). This new open-access resource will facilitate Xenopus research and teaching in the decades to come., This work was supported by grants from the Eunice Kennedy Shriver National Institute of Child Health and Human Development [P41 HD064556 to A.M.Z. and P.D.V. (Xenbase)] and the National Institute of Child Health and Human Development [P40-OD010997 and R24-OD030008 to M.H. (National Xenopus Resource)]. Open Access funding provided by Cincinnati Children's Hospital Medical Center. Deposited in PMC for immediate release.

Published
2022

20. Advances in genome editing tools

Author

Horb, Marko E., Abu-Daya, Anita, Wlizla, Marcin, Noble, Anna, Guille, Matthew, Horb, Marko E., Abu-Daya, Anita, Wlizla, Marcin, Noble, Anna, and Guille, Matthew

Abstract

© The Author(s), 2022. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Horb, M., Abu-Daya, A., Wlizla, M., Noble, A., & Guille, M. “Advances in genome editing tools.” In Xenopus, edited by Abraham Fainsod, Sally A. Moody, 207–221. Boca Raton: CRC Press, 2022, https://doi.org/10.1201/9781003050230-16., This book focuses on the amphibian, Xenopus, one of the most commonly used model animals in the biological sciences. Over the past 50 years, the use of Xenopus has made possible many fundamental contributions to our knowledge in cell biology, developmental biology, molecular biology, and neurobiology. In recent years, with the completion of the genome sequence of the main two species and the application of genome editing techniques, Xenopus has emerged as a powerful system to study fundamental disease mechanisms and test treatment possibilities. Xenopus has proven an essential vertebrate model system for understanding fundamental cell and developmental biological mechanisms, for applying fundamental knowledge to pathological processes, for deciphering the function of human disease genes, and for understanding genome evolution. Key Features Provides historical context of the contributions of the model system Includes contributions from an international team of leading scholars Presents topics spanning cell biology, developmental biology, genomics, and disease model Describes recent experimental advances Incorporates richly illustrated diagrams and color images, The NXR is funded by grants from the National Institutes of Health (P40OD010997, R24OD030008, and R01HD084409). The EXRC is supported by grants from the Wellcome Trust (212942/Z/18/Z) and BBSRC (BB/R014841/1).

Published
2022

21. Endogenous retroviruses augment amphibian (Xenopus laevis) tadpole antiviral protection

Author

Kalia, Namarta, Hauser, Kelsey A., Burton, Sarah, Hossainey, Muhammad Riadul Haque, Zelle, Mira, Horb, Marko E., Grayfer, Leon, Kalia, Namarta, Hauser, Kelsey A., Burton, Sarah, Hossainey, Muhammad Riadul Haque, Zelle, Mira, Horb, Marko E., and Grayfer, Leon

Abstract

Author Posting. © American Society for Microbiology , 2022. This article is posted here by permission of American Society for Microbiology for personal use, not for redistribution. The definitive version was published in Kalia, N., Hauser, K., Burton, S., Hossainey, M., Zelle, M., Horb, M., & Grayfer, L. Endogenous retroviruses augment amphibian (Xenopus laevis) tadpole antiviral protection. Journal of Virology, 96(11), (2022): e00634-22, https://doi.org/10.1128/jvi.00634-22., The global amphibian declines are compounded by infections with members of the Ranavirus genus such as Frog Virus 3 (FV3). Premetamorphic anuran amphibians are believed to be significantly more susceptible to FV3 while this pathogen targets the kidneys of both pre- and postmetamorphic animals. Paradoxically, FV3-challenged Xenopus laevis tadpoles exhibit lower kidney viral loads than adult frogs. Presently, we demonstrate that X. laevis tadpoles are intrinsically more resistant to FV3 kidney infections than cohort-matched metamorphic and postmetamorphic froglets and that this resistance appears to be epigenetically conferred by endogenous retroviruses (ERVs). Using a X. laevis kidney-derived cell line, we show that enhancing ERV gene expression activates cellular double-stranded RNA-sensing pathways, resulting in elevated mRNA levels of antiviral interferon (IFN) cytokines and thus greater anti-FV3 protection. Finally, our results indicate that large esterase-positive myeloid-lineage cells, rather than renal cells, are responsible for the elevated ERV/IFN axis seen in the tadpole kidneys. This conclusion is supported by our observation that CRISPR-Cas9 ablation of colony-stimulating factor-3 results in abolished homing of these myeloid cells to tadpole kidneys, concurrent with significantly abolished tadpole kidney expression of both ERVs and IFNs. We believe that the manuscript marks an important step forward in understanding the mechanisms controlling amphibian antiviral defenses and thus susceptibility and resistance to pathogens like FV3., This work was supported by grants from NSF-IOS 1749427 to L.G. and NIH R24OD030008 and P40OD010997 to M.E.H., 2022-11-16

Published
2022

22. Deep learning is widely applicable to phenotyping embryonic development and disease

Author

Naert, Thomas, Çiçek, Özgün, Ogar, Paulina, Bürgi, Max, Shaidani, Nikko-Ideen, Kaminski, Michael M., Xu, Yuxiao, Grand, Kelli, Vujanovic, Marko, Prata, Daniel, Hildebrandt, Friedhelm, Brox, Thomas, Ronneberger, Olaf, Voigt, Fabian F., Helmchen, Fritjof, Loffing, Johannes, Horb, Marko E., Rankin Willsey, Helen, Lienkamp, Soeren S., Naert, Thomas, Çiçek, Özgün, Ogar, Paulina, Bürgi, Max, Shaidani, Nikko-Ideen, Kaminski, Michael M., Xu, Yuxiao, Grand, Kelli, Vujanovic, Marko, Prata, Daniel, Hildebrandt, Friedhelm, Brox, Thomas, Ronneberger, Olaf, Voigt, Fabian F., Helmchen, Fritjof, Loffing, Johannes, Horb, Marko E., Rankin Willsey, Helen, and Lienkamp, Soeren S.

Abstract

© The Author(s), 2021. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Naert, T., Çiçek, Ö., Ogar, P., Bürgi, M., Shaidani, N.-I., Kaminski, M. M., Xu, Y., Grand, K., Vujanovic, M., Prata, D., Hildebrandt, F., Brox, T., Ronneberger, O., Voigt, F. F., Helmchen, F., Loffing, J., Horb, M. E., Willsey, H. R., & Lienkamp, S. S. Deep learning is widely applicable to phenotyping embryonic development and disease. Development, 148(21), (2021): dev199664, https://doi.org/10.1242/dev.199664., Genome editing simplifies the generation of new animal models for congenital disorders. However, the detailed and unbiased phenotypic assessment of altered embryonic development remains a challenge. Here, we explore how deep learning (U-Net) can automate segmentation tasks in various imaging modalities, and we quantify phenotypes of altered renal, neural and craniofacial development in Xenopus embryos in comparison with normal variability. We demonstrate the utility of this approach in embryos with polycystic kidneys (pkd1 and pkd2) and craniofacial dysmorphia (six1). We highlight how in toto light-sheet microscopy facilitates accurate reconstruction of brain and craniofacial structures within X. tropicalis embryos upon dyrk1a and six1 loss of function or treatment with retinoic acid inhibitors. These tools increase the sensitivity and throughput of evaluating developmental malformations caused by chemical or genetic disruption. Furthermore, we provide a library of pre-trained networks and detailed instructions for applying deep learning to the reader's own datasets. We demonstrate the versatility, precision and scalability of deep neural network phenotyping on embryonic disease models. By combining light-sheet microscopy and deep learning, we provide a framework for higher-throughput characterization of embryonic model organisms., T.N. received funding from H2020 Marie Skłodowska-Curie Actions (xenCAKUT - 891127). M.M.K. is supported by the Emmy Noether Programme of the Deutsche Forschungsgemeinschaft (KA5060/1-1). F.H. is the William E. Harmon Professor of Pediatrics. This research is supported by grants from the National Institutes of Health to F.H. (DK-076683-13 and RC2-DK122397) and M.E.H. (OD-010997, OD-030008 and HD-084409). H.R.W. is supported by a gift from the Overlook International Foundation and by grant support from the National Institutes of Mental Health Convergent Neuroscience Initiative and by the Psychiatric Cell Map Initiative (pcmi.ucsf.edu, 1U01MH115747-01A1) to Matthew State. S.S.L. is supported by the Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung (310030_189102), the Swiss National Centre of Competence in Research Kidney Control of Homeostasis and the European Union's Horizon 2020 Framework Programme (ERC-StrG DiRECT - 804474).

Published
2022

26. Supplementary methods and figure from Developing immortal cell lines from Xenopus embryos, four novel cell lines derived from Xenopus tropicalis

Author

Gorbsky, Gary J., Daum, John R., Sapkota, Hem, Summala, Katja, Yoshida, Hitoshi, Georgescu, Constantin, Wren, Jonathan D., Peshkin, Leonid, and Horb, Marko E.

Abstract

contains cell culture methods and Supplemental Figure 1. Four pair-wise comparisons of marker gene expression in cell lines. The most highly expressed markers that differ between two lines are labeled using a human symbol of a homologous gene

Published
2022
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27. media summary from Developing immortal cell lines from Xenopus embryos, four novel cell lines derived from Xenopus tropicalis

Author

Gorbsky, Gary J., Daum, John R., Sapkota, Hem, Summala, Katja, Yoshida, Hitoshi, Georgescu, Constantin, Wren, Jonathan D., Peshkin, Leonid, and Horb, Marko E.

Abstract

The diploid anuran, Xenopus tropicalis, has emerged as a key research model in cell and developmental biology. To enhance the usefulness of this species, we developed methods for generating immortal cell lines from Nigerian strain (NXR_1018, RRID:SCR_013731) X. tropicalis embryos. We generated 14 cell lines that were propagated for several months. We selected four morphologically distinct lines, XTN-6, XTN-8, XTN-10 and XTN-12 for further characterization. Karyotype analysis revealed that three of the lines, XTN-8, XTN-10 and XTN-12 were primarily diploid. XTN-6 cultures showed a consistent mixed population of diploid cells, cells with chromosome 8 trisomy, and cells containing a tetraploid content of chromosomes. The lines were propagated using conventional culture methods as adherent cultures at 30 °C in a simple, diluted L-15 medium containing fetal bovine serum without use of a high CO2 incubator. Transcriptome analysis indicated that the four lines were distinct lineages. These methods will be useful in the generation of cell lines from normal and mutant strains of X. tropicalis as well as other species of Xenopus.

Published
2022
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28. Deep learning is widely applicable to phenotyping embryonic development and disease

Author

Naert, Thomas, primary, Çiçek, Özgün, additional, Ogar, Paulina, additional, Bürgi, Max, additional, Shaidani, Nikko-Ideen, additional, Kaminski, Michael M., additional, Xu, Yuxiao, additional, Grand, Kelli, additional, Vujanovic, Marko, additional, Prata, Daniel, additional, Hildebrandt, Friedhelm, additional, Brox, Thomas, additional, Ronneberger, Olaf, additional, Voigt, Fabian F., additional, Helmchen, Fritjof, additional, Loffing, Johannes, additional, Horb, Marko E., additional, Willsey, Helen Rankin, additional, and Lienkamp, Soeren S., additional

Published
2021
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30. List of Contributors

Author

Addis, Russell C., primary, Anversa, Piero, additional, Arcidiacono, Judith, additional, Atala, Anthony, additional, Axelman, Joyce, additional, Batra, Ashok, additional, Blau, Helen M., additional, Bonner-Weir, Susan, additional, Brittan, Mairi, additional, Broxmeyer, Hal E., additional, Cananzi, Mara, additional, Cepko, Constance, additional, Cheng, Tao, additional, Chuva de Sousa Lopes, Susana M., additional, Clark, Gregory O., additional, Colehour, Maegen, additional, de Coppi, Paolo, additional, Cossu, Giulio, additional, Daley, George Q., additional, Dang, Jiyoung M., additional, Direkze, Natalie, additional, Dor, Yuval, additional, Dressler, Gregory R., additional, Durfor, Charles N., additional, Ellis, Ewa C.S., additional, Evans, Martin, additional, Fekete, Donna M., additional, Fink, Donald, additional, Fuchs, Elaine, additional, Fuller, Margaret T., additional, Gardner, Richard L., additional, Gazit, Zulma, additional, Gazit, Dan, additional, Gearhart, John D., additional, Goldberg, Victor M., additional, Gonzalez, Rodolfo, additional, Grayeski, Deborah Lavoie, additional, Green, Ronald M., additional, Grompe, Markus, additional, Hilbert, Stephen L., additional, Horb, Marko E., additional, Huang, Jerry I., additional, Imitola, Jaimie, additional, Jones, D. Leanne, additional, Kajstura, Jan, additional, Kaplan, David S., additional, Kaur, Pritinder, additional, Kent, Kathleen C., additional, Kerr, Candace L., additional, Khademhosseini, Ali, additional, Kimelman, Nadav, additional, Klimanskaya, Irina, additional, Kraszewski, Jennifer N., additional, LaBarge, Mark A., additional, Langer, Robert, additional, Lanza, Robert, additional, Lazarus, Ellen, additional, Lee, Jean Pyo, additional, Lee, Mark H., additional, Leri, Annarosa, additional, Levenberg, Shulamit, additional, Levine, S. Robert, additional, Littlefield, John W., additional, McFarland, Richard, additional, McMahon, Jill, additional, Melton, Douglas A., additional, Moore, Mary Tyler, additional, Mueller, Franz-Josef, additional, Mummery, Christine L., additional, Nadal-Ginard, Bernardo, additional, Niwa, Hitoshi, additional, Okita, Keisuke, additional, Ourednik, Jitka, additional, Ourednik, Vaclav, additional, Park, Kook I., additional, Patterson, Ethan S., additional, Pelled, Gadi, additional, Potten, Christopher S., additional, Preston, Sean, additional, Roelandt, Philip R., additional, Roobrouck, Valerie D., additional, Rosenthal, Nadia, additional, Rossant, Janet, additional, Sampaolesi, Maurilio, additional, Santini, Maria Paola, additional, Scadden, David T., additional, Schlüter, Holger, additional, Schuch, Gunter, additional, Shamblott, Michael J., additional, Sheyn, Dima, additional, Sidman, Richard L., additional, Snyder, Evan Y., additional, Soker, Shay, additional, Strom, Stephen C., additional, Studer, Lorenz, additional, Surani, M. Azim, additional, Tedesco, Francesco Saverio, additional, Teng, Yang D., additional, Tosh, David, additional, Trounson, Alan, additional, Tumbar, Tudorita, additional, Upjohn, Edward, additional, Varigos, George, additional, Verfaillie, Catherine M., additional, Wang, Zhan, additional, Weir, Gordon C., additional, Whittlesey, Kevin J., additional, Williams, J. Koudy, additional, Wilson, James W., additional, Witten, Celia, additional, Wright, Nicholas A., additional, Yamanaka, Shinya, additional, and Yoo, Jung U., additional

Published
2014
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32. Deep learning is widely applicable to phenotyping embryonic development and disease

Author

Naert, Thomas; https://orcid.org/0000-0003-3543-2519, Çiçek, Özgün, Ogar, Paulina, Bürgi, Max, Shaidani, Nikko-Ideen, Kaminski, Michael M; https://orcid.org/0000-0003-0429-7027, Xu, Yuxiao, Grand, Kelli, Vujanovic, Marko, Prata, Daniel, Hildebrandt, Friedhelm, Brox, Thomas, Ronneberger, Olaf, Voigt, Fabian F, Helmchen, Fritjof, Loffing, Johannes, Horb, Marko E, Willsey, Helen Rankin; https://orcid.org/0000-0001-8404-3291, Lienkamp, Soeren S; https://orcid.org/0000-0003-2963-6865, Naert, Thomas; https://orcid.org/0000-0003-3543-2519, Çiçek, Özgün, Ogar, Paulina, Bürgi, Max, Shaidani, Nikko-Ideen, Kaminski, Michael M; https://orcid.org/0000-0003-0429-7027, Xu, Yuxiao, Grand, Kelli, Vujanovic, Marko, Prata, Daniel, Hildebrandt, Friedhelm, Brox, Thomas, Ronneberger, Olaf, Voigt, Fabian F, Helmchen, Fritjof, Loffing, Johannes, Horb, Marko E, Willsey, Helen Rankin; https://orcid.org/0000-0001-8404-3291, and Lienkamp, Soeren S; https://orcid.org/0000-0003-2963-6865

Abstract

Genome editing simplifies the generation of new animal models for congenital disorders. However, the detailed and unbiased phenotypic assessment of altered embryonic development remains a challenge. Here, we explore how deep learning (U-Net) can automate segmentation tasks in various imaging modalities, and we quantify phenotypes of altered renal, neural and craniofacial development in Xenopus embryos in comparison with normal variability. We demonstrate the utility of this approach in embryos with polycystic kidneys (pkd1 and pkd2) and craniofacial dysmorphia (six1). We highlight how in toto light-sheet microscopy facilitates accurate reconstruction of brain and craniofacial structures within X. tropicalis embryos upon dyrk1a and six1 loss of function or treatment with retinoic acid inhibitors. These tools increase the sensitivity and throughput of evaluating developmental malformations caused by chemical or genetic disruption. Furthermore, we provide a library of pre-trained networks and detailed instructions for applying deep learning to the reader's own datasets. We demonstrate the versatility, precision and scalability of deep neural network phenotyping on embryonic disease models. By combining light-sheet microscopy and deep learning, we provide a framework for higher-throughput characterization of embryonic model organisms. This article has an associated 'The people behind the papers' interview.

Published
2021

33. BrunoL1 regulates endoderm proliferation through translational enhancement of cyclin A2 mRNA

Author

Horb, Lori Dawn and Horb, Marko E.

Subjects
Messenger RNA, Protein binding, Binding proteins, Amphibians, Biological sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.ydbio.2010.07.005 Byline: Lori Dawn Horb, Marko E. Horb Keywords: Xenopus; Pancreas; Proliferation; Endoderm; RNA binding protein; BrunoL1; Cyclin A2; Translational enhancement Abstract: Developmental control of proliferation relies on tight regulation of protein expression. Although this has been well studied in early embryogenesis, how the cell cycle is regulated during organogenesis is not well understood. Bruno-Like RNA binding proteins bind to consensus sequences in the 3'UTR of specific mRNAs and repress protein translation, but much of this functional information is derived from studies on mainly two members, Drosophila Bruno and vertebrate BrunoL2 (CUGBP1). There are however, six vertebrate and three Drosophila Bruno family members, but less is known about these other family members, and none have been shown to function in the endoderm. We recently identified BrunoL1 as a dorsal pancreas enriched gene, and in this paper we define BrunoL1 function in Xenopus endoderm development. We find that, in contrast to other Bruno-Like proteins, BrunoL1 acts to enhance rather than repress translation. We demonstrate that BrunoL1 regulates proliferation of endoderm cells through translational control of cyclin A2 mRNA. Specifically BrunoL1 enhanced translation of cyclin A2 through binding consensus Bruno Response Elements (BREs) in its 3'UTR. We compared the ability of other Bruno-Like proteins, both vertebrate and invertebrate, to stimulate translation via the cyclin A2 3'UTR and found that only Drosophila Bru-3 had similar activity. In addition, we also found that both BrunoL1 and Bru-3 enhanced translation of mRNAs containing the 3'UTRs of Drosophila oskar or cyclin A, which have been well characterized to mediate repression. Lastly, we show that it is the Linker region of BrunoL1 that is both necessary and sufficient for this activity. These results are the first example of BRE-dependent translational enhancement and are the first demonstration in vertebrates of Bruno-Like proteins regulating translation through BREs. Article History: Received 22 March 2010; Revised 12 June 2010; Accepted 2 July 2010

Published
2010

34. Remodeling of insulin producing [beta]-cells during Xenopus laevis metamorphosis

Author

Mukhi, Sandeep, Horb, Marko E., and Brown, Donald D.

Subjects
Messenger RNA, Developmental biology, Pancreatic beta cells, Insulin, Amphibians, Biological sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.ydbio.2009.01.038 Byline: Sandeep Mukhi (a), Marko E. Horb (b)(c), Donald D. Brown (a) Keywords: Amphibian metamorphosis; Pancreas; [beta] cells; Thyroid hormone; Organ remodeling Abstract: Insulin-producing [beta]-cells are present as single cells or in small clusters distributed throughout the pancreas of the Xenopus laevis tadpole. During metamorphic climax when the exocrine pancreas dedifferentiates to progenitor cells, the [beta]-cells undergo two changes. Insulin mRNA is down regulated at the beginning of metamorphic climax (NF62) and reexpressed again near the end of climax. Secondly, the [beta]-cells aggregate to form islets. During climax the increase in insulin cluster size is not caused by cell proliferation or by acinar-to-[beta]-cell transdifferentiation, but rather is due to the aggregation of pre-existing [beta]-cells. The total number of [beta]-cells does not change during the 8 days of climax. Thyroid hormone (TH) induction of premetamorphic tadpoles causes an increase in islet size while prolonged treatment of tadpoles with the goitrogen methimazole inhibits this increase. Expression of a dominant negative form of the thyroid hormone receptor (TRDN) driven by the elastase promoter not only protects the exocrine pancreas of a transgenic tadpole from TH-induced dedifferentiation but also prevents aggregation of [beta]-cells at climax. These transgenic tadpoles do however undergo normal loss and resynthesis of insulin mRNA at the same stage as controls. In contrast transgenic tadpoles with the same TRDN transgene driven by an insulin promoter do not undergo down regulation of insulin mRNA, but do aggregate [beta]-cells to form islets like controls. These results demonstrate that TH controls the remodeling of [beta]-cells through cell-cell interaction with dedifferentiating acinar cells and a cell autonomous program that temporarily shuts off the insulin gene. Author Affiliation: (a) Department of Embryology, Carnegie Institution, 3520 San Martin Drive, Baltimore, MD 21218, USA (b) Laboratory of Molecular Organogenesis, Institut de Recherches Cliniques de Montreal, Montreal, Quebec, Canada (c) Departement de Medecine, Universite de Montreal, Canada Article History: Received 10 October 2008; Revised 13 January 2009; Accepted 28 January 2009

Published
2009

36. Differential ability of Ptf1a and Ptf1a-VP16 to convert stomach, duodenum and liver to pancreas

Author

Jarikji, Zeina H., Vanamala, Sandeep, Beck, Caroline W., Wright, Chris V.E., Leach, Steven D., and Horb, Marko E.

Subjects
Developmental biology, Liver, Biological sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.ydbio.2007.01.027 Byline: Zeina H. Jarikji (a)(b), Sandeep Vanamala (a)(c), Caroline W. Beck (d), Chris V.E. Wright (e), Steven D. Leach (f), Marko E. Horb (a)(b)(c)(g) Keywords: Xenopus; Pancreas; Ptf1a; Specification; Transdifferentiation; Endocrine; Exocrine; Organogenesis Abstract: Determining the functional attributes of pancreatic transcription factors is essential to understand how the pancreas is specified distinct from other endodermal organs, such as liver, stomach and duodenum, and to direct the differentiation of other cell types into pancreas. Previously, we demonstrated that Pdx1-VP16 was sufficient to convert liver to pancreas. In this paper, we characterize the functional ability of another pancreatic transcription factor, Ptf1a, in promoting ectopic pancreatic fates at early stages throughout the endoderm and later during organogenesis. Using the transthyretin promoter to drive expression in the early liver region/bud of transgenic Xenopus tadpoles, we find that Ptf1a-VP16 is able to convert liver to pancreas. Overexpression of the unmodified Ptf1a on the other hand has no effect in liver but is able to convert stomach and duodenum to pancreas. When overexpressed at earlier embryonic stages throughout the endoderm, Ptf1a activity is similarly limited, whereas Ptf1a-VP16 has increased activity. Interestingly, in all instances we find that Ptf1a-VP16 is only capable of promoting acinar cell fates, whereas Ptf1a promotes both acinar and endocrine fates. Lastly, we demonstrate that, similar to mouse and zebrafish, Xenopus Ptf1a is essential for the initial specification of both endocrine and exocrine cells during normal pancreas development. Author Affiliation: (a) Laboratory of Molecular Organogenesis, Institut de Recherches Cliniques de Montreal, 110 Pine Avenue West, Montreal, QC, Canada H2W 1R7 (b) Programme de Biologie Moleculaire, Universite de Montreal, Montreal, Canada (c) Department of Anatomy and Cell Biology, McGill University, Montreal, Canada (d) Department of Zoology, University of Otago, P.O. Box 56, Dunedin, New Zealand (e) Program in Developmental Biology and Department of Cell and Developmental Biology, Vanderbilt University School of Medicine, Nashville, TN 37232-2175, USA (f) Departments of Surgery, Oncology and Cell Biology, Johns Hopkins University School of Medicine, Baltimore, MD 21287, USA (g) Departement de medecine, Universite de Montreal, Canada Article History: Received 2 August 2006; Revised 10 January 2007; Accepted 20 January 2007

Published
2007

37. A frog with three sex chromosomes that co-mingle together in nature: Xenopus tropicalis has a degenerate W and a Y that evolved from a Z chromosome

Author

Furman, Benjamin L. S., Cauret, Caroline M. S., Knytl, Martin, Song, Xue-Ying, Premachandra, Tharindu, Ofori-Boateng, Caleb, Jordan, Danielle C., Horb, Marko E., Evans, Ben J., Furman, Benjamin L. S., Cauret, Caroline M. S., Knytl, Martin, Song, Xue-Ying, Premachandra, Tharindu, Ofori-Boateng, Caleb, Jordan, Danielle C., Horb, Marko E., and Evans, Ben J.

Abstract

© The Author(s), 2020. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Furman, B. L. S., Cauret, C. M. S., Knytl, M., Song, X. Y., Premachandra, T., Ofori-Boateng, C., Jordan, D. C., Horb, M. E., & Evans, B. J. (2020). A frog with three sex chromosomes that co-mingle together in nature: Xenopus tropicalis has a degenerate W and a Y that evolved from a Z chromosome. PLoS Genetics, 16(11), e1009121, doi:10.1371/journal.pgen.1009121., In many species, sexual differentiation is a vital prelude to reproduction, and disruption of this process can have severe fitness effects, including sterility. It is thus interesting that genetic systems governing sexual differentiation vary among—and even within—species. To understand these systems more, we investigated a rare example of a frog with three sex chromosomes: the Western clawed frog, Xenopus tropicalis. We demonstrate that natural populations from the western and eastern edges of Ghana have a young Y chromosome, and that a male-determining factor on this Y chromosome is in a very similar genomic location as a previously known female-determining factor on the W chromosome. Nucleotide polymorphism of expressed transcripts suggests genetic degeneration on the W chromosome, emergence of a new Y chromosome from an ancestral Z chromosome, and natural co-mingling of the W, Z, and Y chromosomes in the same population. Compared to the rest of the genome, a small sex-associated portion of the sex chromosomes has a 50-fold enrichment of transcripts with male-biased expression during early gonadal differentiation. Additionally, X. tropicalis has sex-differences in the rates and genomic locations of recombination events during gametogenesis that are similar to at least two other Xenopus species, which suggests that sex differences in recombination are genus-wide. These findings are consistent with theoretical expectations associated with recombination suppression on sex chromosomes, demonstrate that several characteristics of old and established sex chromosomes (e.g., nucleotide divergence, sex biased expression) can arise well before sex chromosomes become cytogenetically distinguished, and show how these characteristics can have lingering consequences that are carried forward through sex chromosome turnovers., This work was supported by the Natural Science and Engineering Research Council of Canada (RGPIN-2017-05770) (BJE), Resource Allocation Competition awards from Compute Canada (BJE), the Whitman Center Fellowship Program at the Marine Biological Laboratory (BJE), the Museum of Comparative Zoology at Harvard University (BJE), and National Institutes of Health grants R01-HD084409 (MEH) and P40-OD010997 (MEH). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Published
2020

38. FXR1 splicing is important for muscle development and biomolecular condensates in muscle cells

Author

Smith, Jean A., Curry, Ennessa G., Blue, R. Eric, Roden, Christine, Dundon, Samantha E.R., Rodríguez-Vargas, Anthony, Jordan, Danielle C., Chen, Xiaomin, Lyons, Shawn M., Crutchley, John M., Anderson, Paul, Horb, Marko E., Gladfelter, Amy S., Giudice, Jimena, Smith, Jean A., Curry, Ennessa G., Blue, R. Eric, Roden, Christine, Dundon, Samantha E.R., Rodríguez-Vargas, Anthony, Jordan, Danielle C., Chen, Xiaomin, Lyons, Shawn M., Crutchley, John M., Anderson, Paul, Horb, Marko E., Gladfelter, Amy S., and Giudice, Jimena

Abstract

© The Author(s), 2020. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Smith, J. A., Curry, E. G., Blue, R. E., Roden, C., Dundon, S. E. R., Rodríguez-Vargas, A., Jordan, D. C., Chen, X., Lyons, S. M., Crutchley, J., Anderson, P., Horb, M. E., Gladfelter, A. S., & Giudice, J. FXR1 splicing is important for muscle development and biomolecular condensates in muscle cells. Journal of Cell Biology, 219(4), (2020): e201911129, doi: 10.1083/jcb.201911129., Fragile-X mental retardation autosomal homologue-1 (FXR1) is a muscle-enriched RNA-binding protein. FXR1 depletion is perinatally lethal in mice, Xenopus, and zebrafish; however, the mechanisms driving these phenotypes remain unclear. The FXR1 gene undergoes alternative splicing, producing multiple protein isoforms and mis-splicing has been implicated in disease. Furthermore, mutations that cause frameshifts in muscle-specific isoforms result in congenital multi-minicore myopathy. We observed that FXR1 alternative splicing is pronounced in the serine- and arginine-rich intrinsically disordered domain; these domains are known to promote biomolecular condensation. Here, we show that tissue-specific splicing of fxr1 is required for Xenopus development and alters the disordered domain of FXR1. FXR1 isoforms vary in the formation of RNA-dependent biomolecular condensates in cells and in vitro. This work shows that regulation of tissue-specific splicing can influence FXR1 condensates in muscle development and how mis-splicing promotes disease., We thank the A.S. Gladfelter and J. Giudice laboratories, Nancy Kedersha, and Silvia Ramos for critical discussions; Eunice Y. Lee for technical help; Dr. Stephanie Gupton (University of North Carolina at Chapel Hill, Chapel Hill, NC) for donation of WT C57BL/6J mouse embryos; and Marcin Wlizla and National Xenopus Resource (RRID:SCR_013731) for their help in maintaining adult frogs and other important technical support. This work has been funded by a University of North Carolina at Chapel Hill Junior Faculty Development Award (to J. Giudice); a Nutrition and Obesity Research Center, University of North Carolina at Chapel Hill, Pilot & Feasibility Research grant (P30DK056350 to J. Giudice); University of North Carolina at Chapel Hill startup funds (to J. Giudice); the March of Dimes Foundation (5-FY18-36, Basil O’Connor Starter Scholar Award to J. Giudice); and NCTraCs Pilot Grant (550KR181805) from the National Center for Advancing Translational Sciences (NCATS), National Institutes of Health, through Grant Award Number UL1TR002489 (to J. Giudice), National Institutes of Health National Institute of General Medical Sciences grants (R01-GM130866 to J. Giudice, R01-GM081506 to A.S. Gladfelter, R35-GM126901 to P. Anderson, K99-GM124458 to S.M. Lyons, R25-GM089569 and 2R25-GM055336-20 to E.G. Curry); Howard Hughes Medical Institute Faculty Scholars program (A.S. Gladfelter), and National Institute of Health grants R01-HD084409 and P40-OD010997 (to M.E. Horb). The content is solely the responsibility of the authors and does not necessarily represent the official views of the funding agencies., 2020-09-13

Published
2020

39. Contributors

Author

Addis, Russell C., primary, Ahlstrom, Jon D., additional, Amit, Michal, additional, Andrews, Peter W., additional, Axelman, Joyce, additional, Surani, M. Azim, additional, Benvenisty, Nissim, additional, Bhatia, Mickie, additional, Brivanlou, Ali H., additional, Carnwath, Joseph W., additional, Carpenter, Melissa K., additional, Chang, Howard Y., additional, Chen, Xin, additional, Cheng, Tao, additional, Chuva de Sousa Lopes, Susana M., additional, Clark, Gregory O., additional, Dowell, Joshua D., additional, Draper, Jonathan S., additional, Evans, Martin, additional, Field, Loren J., additional, Fuller, Margaret T., additional, Gardner, Richard L., additional, Gavrilov, Svetlana, additional, Gearhart, John D., additional, Gersbach, Charles A., additional, Horb, Marko E., additional, Itskovitz-Eldor, Joseph, additional, Ji, Junfeng, additional, Johnson, Penny, additional, Jones, D. Leanne, additional, Kent, Kathleen C., additional, Kerr, Candace L., additional, Khademhosseini, Ali, additional, Klimanskaya, Irina, additional, Kraszewski, Jennifer N., additional, Kues, Wilfried A., additional, Landry, Donald W., additional, Langer, Robert, additional, Levenberg, Shulamit, additional, Littlefield, John W., additional, Lucas-Hahn, Andrea, additional, McLaren, Anne, additional, McMahon, Jill, additional, Martins-Green, M., additional, Mayshar, Yoav, additional, Melton, Douglas, additional, Mummery, Christine L., additional, Nagy, Andras, additional, Niemann, Heiner, additional, Nishikawa, Shin-Ichi, additional, Niwa, Hitoshi, additional, Okita, Keisuke, additional, Papaioannou, Virginia E., additional, Patterson, Ethan S., additional, Pébay, Alice, additional, Pera, Martin F., additional, Petreaca, M., additional, Price, Emily N., additional, Rossant, Jane, additional, Rubart, Michael, additional, Scadden, David T., additional, Schulz, Thomas, additional, Shamblott, Michael J., additional, Singh, Harvir, additional, Stocum, David L., additional, Thomson, James A., additional, Tosh, David, additional, Trounson, Alan, additional, Xu, Chunhui, additional, Yamamizu, Kohei, additional, Yamanaka, Shinya, additional, Yamashita, Jun K., additional, Young, Holly, additional, Zhong, Bonan, additional, Zon, Leonard I., additional, Zwaka, Thomas P., additional, and Zweigerdt, Robert, additional

Published
2013
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42. Differential requirement for ptf1a in endocrine and exocrine lineages of developing zebrafish pancreas

Author

Lin, John W., Biankin, Andrew V., Horb, Marko E., Ghosh, Bidyut, Prasad, Nijaguna B., Yee, Nelson S., Pack, Michael A., and Leach, Steven D.

Subjects
Pancreas -- Research, Pancreas -- Genetic aspects, Pancreas -- Physiological aspects, Zebra fish -- Research, Zebra fish -- Genetic aspects, Developmental biology -- Research, Biological sciences
Abstract

Mammalian studies have implicated important roles for the basic helix-loop-helix transcription factor Ptf1a-p48 in the development of both exocrine and endocrine pancreas. We have cloned the Ptf1a-p48 ortholog in Danio rerio. Early zebrafish ptf1a expression is observed in developing hindbrain and in endodermal pancreatic precursors. Analysis of ptf1a and insulin expression reveals a population of exocrine precursors that, throughout early development, are temporally and spatially segregated from endocrine elements. Morpholino-mediated knockdown of ptf1a confirms early divergence of these endocrine and exocrine lineages. Ptf1a morphants lack differentiated exocrine pancreas, but maintain normal differentiation and organization of the principal islet. In addition to the exocrine phenotype, ptf1a knockdown also reduces the prevalence of a small population of anterior endocrine cells normally found outside the principal islet. Together, these findings suggest the presence of distinct ptf1a-dependent and ptf1a-independent precursor populations in developing zebrafish pancreas. Keywords: Morpholino knockdown; Degenerate PCR; Epithelial precursor; Development; Exocrine pancreas; Endocrine pancreas

Published
2004

43. Differential requirement for ptfl a in endocrine and exocrine lineages of developing zebrafish pancreas

Author

Lin, John W., Biankin, Andrew V., Horb, Marko E., Ghosh, Bidyut, Prasad, Nijaguna B., Yee, Nelson S., Pack, Michael A., and Leach, Steven D.

Subjects
Developmental biology -- Research, Biological sciences
Abstract

Mammalian studies have implicated important roles for the basic helix-loop-helix transcription factor Ptf1a-p48 in the development of both exocrine and endocrine pancreas. We have cloned the Ptf1a-p48 ortholog in Danio rerio. Early zebrafish ptfla expression is observed in developing hindbrain and in endodermal pancreatic precursors. Analysis of ptf1a and insulin expression reveals a population of exocrine precursors that, throughout early development, are temporally and spatially segregated from endocrine elements. Morpholino-mediated knockdown of pf1a confirms early divergence of these endocrine and exocrine lineages. Ptf1a morphants lack differentiated exocrine pancreas, but maintain normal differentiation and organization of the principal islet. In addition to the exocrine phenotype, pf1a knockdown also reduces the prevalence of a small population of anterior endocrine cells normally found outside the principal islet. Together, these findings suggest the presence of distinct ptf1a-dependent and ptf1a-independent precursor populations in developing zebrafish pancreas. Keywords: Morpholino knockdown; Degenerate PCR; Epithelial precursor; Development; Exocrine pancreas; Endocrine pancreas

Published
2004

44. Contributors

Author

Addis, Russell C., primary, Amit, Michal, additional, Andrews, Peter W., additional, Anversa, Piero, additional, Atala, Anthony, additional, Axelman, Joyce, additional, Bang, Anne G., additional, Barrandon, Yann, additional, Bauer, Steven R., additional, Becker, Daniel, additional, Benvenisty, Nissim, additional, Bianco, Paolo, additional, Blau, Helen M., additional, Bonner-Weir, Susan, additional, Brittan, Mairi, additional, Broxmeyer, Hal E., additional, Bultman, Scott, additional, Caplan, Arnold I., additional, Carpenter, Melissa K., additional, Cavaleri, Fatima, additional, Cepko, Connie, additional, Chang, Howard Y., additional, Chen, Xin, additional, Cheng, Tao, additional, Chuva de Sousa Lopes, Susana M., additional, Clark, Gregory O., additional, Clarke, Michael F., additional, Cossu, Giulio, additional, Crabbe, Annelies, additional, Daley, George Q., additional, Dar, Ayelet, additional, Davis, Brian R., additional, Direkze, Natalie C., additional, Dor, Yuval, additional, Draper, Jonathan S., additional, Dressler, Gregory R., additional, Evans, Martin, additional, Farley, Margaret A., additional, Fekete, Donna, additional, Feng, Qiang, additional, Field, Loren J., additional, Fink, Donald W., additional, Finley, K. Rose, additional, Fuchs, Elaine, additional, Fuller, Margaret T., additional, Gardner, Richard L., additional, Gearhart, John D., additional, Robey, Pamela Gehro., additional, Gerecht-Nir, Sharon, additional, Gilbert, Penney M., additional, Goldberg, Victor M., additional, Gonzalez, Rodolfo, additional, Gould, Elizabeth, additional, Graham, Trevor A., additional, Green, Ronald M., additional, Grompe, Markus, additional, Hockemeyer, Dirk, additional, Horb, Marko E., additional, Huang, Jerry I., additional, Humphries, Adam, additional, Itskovitz-Eldor, Joseph, additional, Jaenisch, Rudolf, additional, Johnson, Penny, additional, Jones, D. Leanne, additional, Kajstura, Jan, additional, Karsenty, Gerard, additional, Kaur, Pritinder, additional, Kent, Kathleen C., additional, Kerr, Candace L., additional, Khademhosseini, Ali, additional, Kintner, Chris, additional, Klimanskaya, Irina, additional, Koyano-Nakagawa, Naoko, additional, Kraszewski, Jennifer N., additional, Kunath, Tilo, additional, Langer, Robert, additional, Lanza, Robert, additional, Leri, Annarosa, additional, Levenberg, Shulamit, additional, Levine, S. Robert, additional, Lindvall, Olle, additional, Littlefield, John W., additional, Lu, Shi-Jiang, additional, Magnuson, Terry, additional, Mayshar, Yoav, additional, McDonald, John W., additional, McDonald, Stuart A.C., additional, McLaren, Anne, additional, McMahon, Jill, additional, Melton, Douglas A., additional, Mirescu, Christian, additional, Montgomery, Nathan, additional, Moore, Malcolm A.S., additional, Moore, Mary Tyle., additional, Mummery, Christine L., additional, Nagy, Andras, additional, Nishikawa, Satomi, additional, Nishikawa, Shin-Ichi, additional, Niwa, Hitoshi, additional, Park, Jennifer S., additional, Patterson, Ethan S., additional, Pébay, Alice, additional, Pera, Martin F., additional, Potten, Christopher S., additional, Poudel, Bhawana, additional, Preston, Sean L., additional, Prokopishyn, Nicole L., additional, Pugach, Emily K., additional, Lee, Jean Py., additional, Rochat, Ariane, additional, Rosenthal, Nadia, additional, Rossant, Janet, additional, Rothenberg, Michael, additional, Rubart, Michael, additional, Sacco, Alessandra, additional, Sampaolesi, Maurilio, additional, Santini, Maria Paol., additional, Scadden, David T., additional, Schöler, Hans, additional, Schulz, Tom, additional, Shamblott, Michael J., additional, Slayton, William B., additional, Snyder, Evan Y., additional, Soldner, Frank, additional, Spangrude, Gerald J., additional, Studer, Lorenz, additional, Surani, M. Azim, additional, Thomson, James A., additional, Tosh, David, additional, Tumbar, Tudorita, additional, Upjohn, Edward, additional, Varigos, George, additional, Verfaillie, Catherine M., additional, Weir, Gordon C., additional, Wilson, J.W., additional, Wright, Nicholas A., additional, Yamashita, Jun K., additional, Young, Holly, additional, Yu, Junying, additional, Zon, Leonard I., additional, and Zwaka, Thomas P., additional

Published
2009
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49. FXR1 splicing is important for muscle development and biomolecular condensates in muscle cells

Author

Smith, Jean A., primary, Curry, Ennessa G., additional, Blue, R. Eric, additional, Roden, Christine, additional, Dundon, Samantha E.R., additional, Rodríguez-Vargas, Anthony, additional, Jordan, Danielle C., additional, Chen, Xiaomin, additional, Lyons, Shawn M., additional, Crutchley, John, additional, Anderson, Paul, additional, Horb, Marko E., additional, Gladfelter, Amy S., additional, and Giudice, Jimena, additional

Published
2020
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