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Prof. Bevin P Engelward
Professor of Biological Engineering
Deputy Director, Center for Environmental Health Sciences (CEHS)
Primary DLC
Department of Biological Engineering
MIT Room:
16-743
(617) 258-0260
bevin@mit.edu
Areas of Interest and Expertise
Genetic Toxicology
Mechanisms of DNA Damage and Repair
Environmental and Molecular Pathogens
Biological Imaging and Functional Measurement
Environmental and Endogenous Chemicals
Cell and Tissue Engineering
Genetic Diseases and Diagnostics
DNA Damage Induced Loss of Genomic Integrity
Infectious Diseases: Susceptibility Factors, Indicators of Disease Progression, Interventions
Research Summary
The Engelward Lab studies DNA damage, repair, and homologous recombination. Cells are subjected to an onslaught of DNA lesions every day. One way that cells cope with DNA lesions is to use homology directed repair to exploit sequence information on sister chromatids or homologous chromosomes for the purpose of repairing DNA damage. Although this is a critically important defense against toxicity caused by DNA damaging agents, misalignments during homology directed repair can lead to sequence rearrangements that contribute to cancer (e.g., loss of heterozygosity and deletions). On the other hand, being unable to perform homology directed repair puts cells at risk of other types of tumorigenic rearrangements (e.g., chromosome aberrations). Thus, either too much or too little homology directed repair is potentially threatening to human health.
Homology directed repair is a critical system for maintaining genomic integrity. Indeed, we now know that many cancer-prone diseases are associated with defects in homology directed repair. For example, 55-75% of women who inherit mutations in the BRCA1 gene will get breast cancer before the age of 70, and we now know that BRCA1 is directly involved in homology directed repair. What types of DNA lesions cause homologous recombination in people? How does enzymatic processing of DNA lesions affect the likelihood that a lesion will lead to homologous recombination? The mission is to reveal how excision repair affects cellular susceptibility to homologous recombination in eukaryotes, and to develop novel tools for studying homologous recombination in mammals.
The first transgenic mice in which somatic cells that have undergone homologous recombination become fluorescent have been recently developed in the laboratory. The Fluorescent Yellow Direct Repeat (FYDR) mice are being used to compare recombination susceptibility among different cell types and to evaluate the effects of specific genetic defects on recombination susceptibility. Thus, the FYDR mice offer a novel approach for revealing the underlying causes of homologous recombination in mammals.
Recent Work
Projects
November 1, 2018
Department of Biological Engineering
MIT Superfund Research Program (MIT SRP): Revealing the Impact of Genetic Susceptibility Factors for Carcinogenic Alkylating Agents in the Environment, with a Focus on Benzo[a]pyrene and N-Nitrosodimethylamine
Principal Investigator
Bevin Engelward
November 1, 2018
Department of Biological Engineering
MIT Superfund Research Program (MIT SRP)
Principal Investigator
Bevin Engelward
July 8, 2010
Department of Biological Engineering
Revealing the Underlying Mechanisms of DNA Sequence Rearrangements
Principal Investigator
Bevin Engelward
July 8, 2010
Department of Biological Engineering
Understanding Natural Causes of Homologous Recombination
Principal Investigator
Bevin Engelward
July 8, 2010
Department of Biological Engineering
Revealing New Mechanisms of Exposure-Induced Homologous Recombination
Principal Investigator
Bevin Engelward
September 10, 2009
Department of Biological Engineering
Developing New Tools for Studying Homologous Recombination
Principal Investigator
Bevin Engelward
May 20, 2008
Department of Biological Engineering
Developing a High-Throughput In Vitro DNA Damage Assay
Principal Investigator
Bevin Engelward
November 8, 1998
Department of Biological Engineering
Engelward Lab: DNA Damage Induced Loss of Genomic Integrity
Principal Investigator
Bevin Engelward
Related Faculty
Eike-Christian Wamhoff
Postdoctoral Fellow
Hadi Tavakoli Nia
Research Affiliate
Prof. Hanry Yu
Visiting Professor of Biological Engineering