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NameEmailPhD ProgramResearch InterestPublications
Morris, John
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pharmacology

RESEARCH INTEREST
Cancer Biology, Developmental Biology, Genetics, Genomics, Metabolism

The Morris lab leverages flexible mouse models of hard to treat cancers of the pancreas and liver to identify how cancer drivers perturb evolutionarily selected developmental programs and how such programs may be re-normalized. We focus on (1) the relationship between tumor suppressor pathways and the epigenetic determinants of cell plasticity, (2) evolutionary routes unleashed by specific tumor suppressor loss, and (3) how diversification at both the epigenetic and genomic level contribute to cancer development and therapeutic response.

Smith, Keriayn
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Genetics & Molecular Biology

RESEARCH INTEREST
Cancer Biology, Cell Biology, Genetics, Genomics, Molecular Biology

We are interested in elucidating context-specific functions of products from single long noncoding RNA (lncRNA) loci. Since lncRNAs have been implicated in many cellular processes, it is critical to delineate specific roles for each lncRNA. Moreover, as they are increasingly associated with diseases including developmental disorders, degenerative diseases, and cancers, defining their functions will be an important precursor to their use as diagnostics and therapeutics. We specialize in adopting -omics approaches including genomics, transcriptomics and proteomics, combined with single molecule methods to study the intermolecular interactions – RNA-protein, RNA-RNA and RNA-chromatin that lncRNAs use to execute their functions in normal stem cells and cancer.

Rau, Christoph
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Bioinformatics & Computational Biology, Cell Biology & Physiology, Genetics & Molecular Biology, Pathobiology & Translational Science

RESEARCH INTEREST
Bioinformatics, Cardiovascular Biology, Computational Biology, Genetics, Genomics, Molecular Biology, Systems Biology, Translational Medicine

Heart failure is an increasingly prevalent cause of death world-wide, but the genetic and epigenetic underpinnings of this disease remain poorly understood. Our laboratory is interested in combining in vitro, in vivo and computational techniques to identify novel markers and predictors of a failing heart. In particular, we leverage mouse populations to perform systems-level analyses with a focus on co-expression network modeling and DNA methylation, following up in primary cell culture and CRISPR-engineered mouse lines to validate our candidate genes and identify potential molecular mechanisms of disease progression and amelioration.

Shpargel, Karl
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Genetics & Molecular Biology

RESEARCH INTEREST
Cancer Biology, Developmental Biology, Genetics, Genomics, Organismal Biology

Our laboratory studies the coordination of histone-modifying enzymes in regulating chromatin structure, enhancer activation, and transcription. We utilize mouse genetics and cell culture model systems to study the mechanisms of enhancer activation in neural crest cell epigenetics, craniofacial development, and altered enhancer regulation in cancer. This is accomplished through a variety of techniques including mouse mutagenesis, fluorescent reporters to isolate primary cells of interest, low cell number genomics, and proteomic approaches.

Milner, Justin
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Cell Biology & Physiology, Genetics & Molecular Biology, Microbiology & Immunology, Pharmacology

RESEARCH INTEREST
Cancer Biology, Computational Biology, Genomics, Immunology, Pathogenesis & Infection, Translational Medicine

The overall focus of our lab is to develop new and exciting approaches for enhancing the efficacy of cancer immunotherapies. We utilize cutting-edge techniques to identify transcriptional and epigenetic regulators controlling T cell differentiation and function in the tumor microenvironment, and we seek to leverage this insight to reprogram or tailor the activity of T cells in cancer. Our group is also interested in understanding how to harness or manipulate T cell function to improve vaccines and immunotherapies for acute and chronic infections.

Heinzen, Erin
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Bioinformatics & Computational Biology, Cell Biology & Physiology, Pharmaceutical Sciences

RESEARCH INTEREST
Genetics, Genomics, Neurobiology, Systems Biology, Translational Medicine

Matute, Daniel
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Bioinformatics & Computational Biology, Biology, Genetics & Molecular Biology

RESEARCH INTEREST
Computational Biology, Evolutionary Biology, Genetics, Genomics, Organismal Biology

My research program studies how species form. We use a combination of approaches that range from field biology, behavior, and computational biology.

Raab, Jesse
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Genetics & Molecular Biology

RESEARCH INTEREST
Bioinformatics, Cancer Biology, Computational Biology, Genetics, Genomics

We are interested in the links between epigenetics and gene regulation. Our primary focus is on understanding how changes to the composition of chromatin remodeling complexes are regulated, how their disruption affects their function, and contributes to disease. We focus on the SWI/SNF complex, which is mutated in 20% of all human tumors. This complex contains many variable subunits that can be assembled in combination to yield thousands of biochemically distinct complexes. We use a variety of computational and wet-lab techniques in cell culture and animal models to address these questions.

Dowen, Rob
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Biology, Cell Biology & Physiology, Genetics & Molecular Biology

RESEARCH INTEREST
Cell Biology, Cell Signaling, Computational Biology, Genetics, Genomics, Metabolism

Appropriate allocation of cellular lipid stores is paramount to maintaining organismal energy homeostasis. Dysregulation of these pathways can manifest in human metabolic syndromes, including cardiovascular disease, obesity, diabetes, and cancer. The goal of my lab is to elucidate the molecular mechanisms that govern the storage, metabolism, and intercellular transport of lipids; as well as understand how these circuits interface with other cellular homeostatic pathways (e.g., growth and aging). We utilize C. elegans as a model system to interrogate these evolutionarily conserved pathways, combining genetic approaches (forward and reverse genetic screens, CRISPR) with genomic methodologies (ChIP-Seq, mRNA-Seq, DNA-Seq) to identify new components and mechanisms of metabolic regulation.

Azcarate-Peril, M. Andrea
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Nutrition

RESEARCH INTEREST
Bacteriology, Bioinformatics, Genomics, Molecular Biology, Systems Biology

We are interested in determining the mechanisms involved in the beneficial modulation of the gut microbiota by prebiotics (functional foods that stimulate growth of gut native beneficial bacteria) and probiotics (live bacteria that benefit their host). Specifically, we aim to develop prebiotic and probiotic interventions as alternatives to traditional treatments for microbiota-health related conditions, and to advance microbiota-based health surveillance methods.