Rudolf Jaenisch
Affiliations: | Massachusetts Institute of Technology, Cambridge, MA, United States |
Area:
Mouse developmentWebsite:
http://www.wi.mit.edu/research/faculty/jaenisch.htmlGoogle:
"Rudolf Jaenisch"Bio:
http://www.pnas.org/content/101/39/13982.full
Cross-listing: Neurotree - Cell Biology Tree
Parents
Sign in to add mentor| Peter Hans Hofschneider | grad student | Max Planck Institute für Biochemie, Martinsried, Germany (Microtree) | |
| Arnold Levine | post-doc | 1970-1972 | Princeton (Neurotree) |
| Beatrice Mintz | post-doc | 1974 | Fox Chase Cancer Center |
Children
Sign in to add trainee| Chuanyun Xu | research assistant | 2016-2017 | MIT (Neurotree) |
| Alexander Marson | grad student | (Chemistry Tree) | |
| Anne Vassalli | grad student | MIT (Neurotree) | |
| Kevin C. Eggan | grad student | 1998-2002 | MIT (Neurotree) |
| Michael A Lodato | grad student | 2007-2013 | MIT (Neurotree) |
| Laurie A. Boyer | post-doc | Whitehead Institute (MIT) (Chemistry Tree) | |
| Guoping Fan | post-doc | MIT (Neurotree) | |
| Dirk Hockemeyer | post-doc | (Cell Biology Tree) | |
| Laurie Jackson-Grusby | post-doc | Whitehead Institute (Neurotree) | |
| Vikram Khurana | post-doc | Whitehead Institute (Neurotree) | |
| Jordan Kreidberg | post-doc | Whitehead Institute (MIT) | |
| Barbara Panning | post-doc | (Cell Biology Tree) | |
| Kathrin Plath | post-doc | MIT (Cell Biology Tree) | |
| Fangfei Qin | post-doc | MIT (Chemistry Tree) | |
| Marius Wernig | post-doc | MIT (Cell Biology Tree) | |
| Antonius J.M. Berns | post-doc | 1976 | Salk Institute (Chemistry Tree) |
| Philippe Soriano | post-doc | 1984-1987 | University of Hamburg; Whitehead Institute (MIT) |
| Jerold Chun | post-doc | 1988-1991 | MIT (Neurotree) |
| Reinhard Fässler | post-doc | 1988-1992 | Whitehead Institute (MIT) (Cell Biology Tree) |
| Paul Soloway | post-doc | 1990-1994 | (Neurotree) |
| Jeannie T. Lee | post-doc | 1995 | Whitehead Institute (MIT) |
| Peter W. Laird | post-doc | 1991-1996 | Whitehead Institute for Biomedical Research (MIT) (Cell Biology Tree) |
| Volker H. Haase | post-doc | 1996-2001 | MIT (Cell Biology Tree) |
| Yun Li | post-doc | 2009-2017 | MIT (Neurotree) |
| Julien Muffat | post-doc | 2009-2017 | Whitehead Institute for Biomedical Research (Neurotree) |
| X Shawn Liu | post-doc | 2014-2019 | MIT (Neurotree) |
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Publications
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| Lasry R, Maoz N, Cheng AW, et al. (2023) Complex haploinsufficiency in pluripotent cells yields somatic cells with DNA methylation abnormalities and pluripotency induction defects. Stem Cell Reports |
| Qian J, Guan X, Xie B, et al. (2023) Multiplex epigenome editing of to rescue Rett syndrome neurons. Science Translational Medicine. 15: eadd4666 |
| Dall'Agnese A, Platt JM, Zheng MM, et al. (2022) The dynamic clustering of insulin receptor underlies its signaling and is disrupted in insulin resistance. Nature Communications. 13: 7522 |
| Ma H, Zwaan E, Guo YE, et al. (2022) The nuclear receptor THRB facilitates differentiation of human PSCs into more mature hepatocytes. Cell Stem Cell. 29: 1611 |
| Ma H, de Zwaan E, Guo YE, et al. (2022) The nuclear receptor THRB facilitates differentiation of human PSCs into more mature hepatocytes. Cell Stem Cell |
| Zhang L, Richards A, Barrasa MI, et al. (2021) Reply to Briggs et al.: Genomic integration and expression of SARS-CoV-2 sequences can explain prolonged or recurrent viral RNA detection. Proceedings of the National Academy of Sciences of the United States of America. 118 |
| Huang X, Park KM, Gontarz P, et al. (2021) OCT4 cooperates with distinct ATP-dependent chromatin remodelers in naïve and primed pluripotent states in human. Nature Communications. 12: 5123 |
| Zhang L, Richards A, Barrasa MI, et al. (2021) Response to Parry et al.: Strong evidence for genomic integration of SARS-CoV-2 sequences and expression in patient tissues. Proceedings of the National Academy of Sciences of the United States of America. 118 |
| Zhang L, Richards A, Barrasa MI, et al. (2021) Reverse-transcribed SARS-CoV-2 RNA can integrate into the genome of cultured human cells and can be expressed in patient-derived tissues. Proceedings of the National Academy of Sciences of the United States of America. 118 |
| Trapecar M, Wogram E, Svoboda D, et al. (2021) Human physiomimetic model integrating microphysiological systems of the gut, liver, and brain for studies of neurodegenerative diseases. Science Advances. 7 |