Robert G. Roeder
Affiliations: | 1971-1982 | Washington University School of Medicine, St. Louis, MO, United States | |
| 1982- | Rockefeller University, New York, NY, United States |
Area:
Molecular BiologyWebsite:
https://www.rockefeller.edu/our-scientists/heads-of-laboratories/895-robert-g-roeder/Google:
""Robert G. Roeder Rockefeller""Bio:
http://www.nasonline.org/member-directory/members/8908.html
https://lab.rockefeller.edu/roeder/
Cross-listing: Chemistry Tree - Cell Biology Tree
Parents
Sign in to add mentor| William J. Rutter | grad student | 1969 | University of Washington (Chemistry Tree) |
| Donald D. Brown | post-doc | 1969-1971 | Carnegie Institution of Washington |
Children
Sign in to add trainee| Kivanc birsoy | grad student | Rockefeller (Neurotree) | |
| Ali Cihan | grad student | Rockefeller (Chemistry Tree) | |
| Robert Darnell | grad student | Rockefeller (Neurotree) | |
| Nathaniel Heintz | grad student | Rockefeller (Neurotree) | |
| Alexander Hoffmann | grad student | Rockefeller (Chemistry Tree) | |
| Andrew Lassar | grad student | Washington University (Neurotree) | |
| Danny Reinberg | grad student | Rockefeller (Chemistry Tree) | |
| Hazel Sive | grad student | Rockerfeller University | |
| Gerald H. Thomsen | grad student | ||
| Judith Ann Jaehning | grad student | 1977 | Washington University (Chemistry Tree) |
| Carl S. Parker | grad student | 1977 | Washington University (FlyTree) |
| David Ross Engelke | grad student | 1979 | Washington University (Chemistry Tree) |
| Michael R. Green | grad student | 1981 | Washington University (FlyTree) |
| Richard Alan Bernstein | grad student | 1988-1996 | Rockefeller (Chemistry Tree) |
| Yun Kyoung K. Kang | grad student | 1996-2003 | Rockefeller (Neurotree) |
| Hwa J. Baek | grad student | 2004 | Rockefeller (Chemistry Tree) |
| Murat A. Cevher | post-doc | Brooklyn College (Chemistry Tree) | |
| Alan Gerber | post-doc | Amsterdam UMC (Chemistry Tree) | |
| Keiichi Ito | post-doc | Rockefeller (Chemistry Tree) | |
| Tapas Kundu | post-doc | The Rockefeller Institute (Neurotree) | |
| Giorgio Lagna | post-doc | (Chemistry Tree) | |
| Takashi Onikubo | post-doc | Rockefeller (Chemistry Tree) | |
| Roberto Weinmann | post-doc | (Cell Biology Tree) | |
| Jerry Lee Workman | post-doc | Rockefeller (Chemistry Tree) | |
| Diane K. Hawley | post-doc | 1983-1986 | Rockefeller (Chemistry Tree) |
| Shannon Marie Lauberth | post-doc | 2007-2013 | Rockefeller (Chemistry Tree) |
BETA: Related publications
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Publications
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| Lin R, Roeder RG, Barrows D, et al. (2024) MED1 IDR acetylation reorganizes the transcription preinitiation complex, rewires 3D chromatin interactions and reprograms gene expression. Biorxiv : the Preprint Server For Biology |
| Crump NT, Smith AL, Godfrey L, et al. (2023) MLL-AF4 cooperates with PAF1 and FACT to drive high-density enhancer interactions in leukemia. Nature Communications. 14: 5208 |
| Perlee S, Kikuchi S, Nakadai T, et al. (2023) SETD1A function in leukemia is mediated through interaction with mitotic regulators BuGZ/BUB3. Embo Reports. e57108 |
| Malik S, Roeder RG. (2023) Regulation of the RNA polymerase II pre-initiation complex by its associated coactivators. Nature Reviews. Genetics |
| Liu N, Konuma T, Sharma R, et al. (2023) Histone H3 lysine 27 crotonylation mediates gene transcriptional repression in chromatin. Molecular Cell |
| Nakadai T, Shimada M, Ito K, et al. (2023) Two target gene activation pathways for orphan ERR nuclear receptors. Cell Research. 33: 165-183 |
| Lyons H, Veettil RT, Pradhan P, et al. (2022) Functional partitioning of transcriptional regulators by patterned charge blocks. Cell |
| Sun J, Li X, Hou X, et al. (2022) Structural basis of human SNAPc recognizing proximal sequence element of snRNA promoter. Nature Communications. 13: 6871 |
| Chen Q, Cevher MA, Jiang Q, et al. (2022) LYL1 facilitates AETFC assembly and gene activation by recruiting CARM1 in t(8;21) AML. Proceedings of the National Academy of Sciences of the United States of America. 119: e2213718119 |
| Zhang YF, Wang XL, Xu CH, et al. (2022) A direct comparison between AML1-ETO and ETO2-GLIS2 leukemia fusion proteins reveals context-dependent binding and regulation of target genes and opposite functions in cell differentiation. Frontiers in Cell and Developmental Biology. 10: 992714 |