Skip to Main Content

Heads of Laboratories

Head shot of Robert Roeder
Robert G. Roeder, Ph.D.
Arnold and Mabel Beckman Professor
Laboratory of Biochemistry and Molecular Biology

Gene expression is controlled primarily at the level of transcription, the process by which genes are copied into RNA before being translated into proteins. A central question in biology is how the transcription of the human genome’s approximately 25,000 genes is regulated in a gene- and cell type-specific manner. Roeder studies the transcription factors, including epigenetic factors, and underlying mechanisms involved in this regulation.

Differential gene expression, regulated primarily at the level of transcription, underlies key events in an organism’s development, cell growth, differentiation, and homeostasis, as well as in pathologies such as cancer. The transcription programs central to these events are governed by cell-specific master transcription factors bound to specific enhancer and promoter elements. The extraordinary power and significance of such factors is profoundly demonstrated by the ability of very small subsets to reprogram somatic cells to a pluripotent state. Roeder’s major objectives are to determine the mechanisms by which such factors, acting ultimately upon the general transcription machinery, activate or repress specific target genes in various physiological processes.

The lab’s multipronged experimental strategy emphasizes powerful cell-free systems, pioneered by Roeder, that recreate the essence of transcription in a test tube with cloned genes and factors purified from cellular extracts. The structure, function, mechanism of action, and regulation of these factors is then studied by a combination of biochemical, cell-based, and genetic analyses.

The actual transcription of protein-coding genes is mediated by RNA polymerase II and cognate initiation factors (TFIIA, TFIIB, TFIID, TFIIE, TFIIF, and TFIIH) that form functional preinitiation complexes on promoters via an ordered assembly pathway. The process begins with the recognition of common core promoter elements (e.g., TATA box) by the multisubunit TFIID. These initiation factors, which comprise the general transcription machinery, represent the ultimate targets of various gene-specific factors. However, other “cofactors” are essential for functional communication between the gene-specific factors, to which they bind, and the general transcription machinery.

Roeder’s current work is heavily focused on these cofactors, many of which are structurally complex. They include cofactors that alter the structure of the natural chromatin template (e.g., multi-subunit histone acetyl- and methyl-transferase complexes), others that act directly on the general transcription machinery (e.g., the 30-subunit Mediator), and a variety of cell/activator-specific cofactors (e.g., the B cell-specific OCA-B and the inducible PGC-1 implicated in energy metabolism).

The lab’s current activities focus on transcriptional activators important for homeostasis (nuclear hormone receptors); lymphoid cell differentiation (E2A, OCT1/2, OCA-B), lymphoid malignancy (E2A-PBX1, AML1-ETO, and MLL1-AF9 leukemogenic fusion proteins); and tumor suppression (p53).

In addition to detailing the mechanisms by which specific target genes are activated by individual transcriptional activators and associated cofactors, the Roeder laboratory is interested in determining the basis for differential usage of cofactors by individual activators in varied contexts. They are also discovering how variations in cofactor usage can dictate cell fate (e.g., growth arrest versus apoptosis in p53-dependent DNA damage responses), and, in the case of leukemic fusion proteins generated in acute myeloid leukemia, potential therapeutic targets.


B.A. in chemistry, 1964
Wabash College

M.S. in chemistry, 1965
University of Illinois

Ph.D. in biochemistry, 1969
University of Washington


Carnegie Institution of Washington, 1969–1971


Assistant Professor, 1971–1975
Associate Professor, 1975–1976
Professor, 1976–1982
Washington University School of Medicine

Professor, 1982–
The Rockefeller University


National Academy of Sciences U.S. Steel Award, 1986

Louisa Gross Horwitz Prize, 1999

Alfred P. Sloan Prize, General Motors Cancer Research Foundation, 1999

Canada Gairdner International Award, 2000

ASBMB-Merck Award, 2002

Albert Lasker Basic Medical Research Award, 2003

Salk Institute Medal for Research Excellence, 2010

Albany Medical Center Prize, 2012

ASBMB Herbert Tabor Research Award, 2016


National Academy of Sciences
American Academy of Arts and Sciences
Fellow, American Association for the Advancement of Science
Associate Member, European Molecular Biology Organization


Josefowicz, S.Z. et al. Chromatin kinases act on transcription factors and histone tails in regulation of inducible transcription. Mol. Cell 64, 347–361 (2016).

Chen, M. et al. JMJD1C is required for the survival of acute myeloid leukemia by functioning as a coactivator for key transcription factors. Genes Dev. 29, 2123–2139 (2015).

Iida, S. et al. PRDM16 enhances nuclear receptor-dependent transcription of the brown fat-specific Ucp1 gene through interactions with Mediator subunit MED1. Genes Dev. 29, 308–321 (2015).

Tang, Z. et al. SET1 and p300 act synergistically, through coupled histone modifications, in transcriptional activation by p53. Cell 154, 297–310 (2013).

Sun, X.J. et al. A stable transcription factor complex nucleated by oligomeric AML1-ETO controls leukaemogenesis. Nature 500, 93–97 (2013).

Dr. Roeder is a faculty member in the David Rockefeller Graduate Program and the Tri-Institutional M.D.-Ph.D. Program.