Research Interest: Genetics
| Name | PhD Program | Research Interest | Publications |
|---|---|---|
| Liu, Jiandong WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Congenital heart diseases are one of the most common birth defects in humans, and these arise from developmental defects during embryogenesis. Many of these diseases have a genetic component, but they might also be affected by environmental factors such as mechanical forces. The Liu Lab combines genetics, molecular and cell biology to study cardiac development and function, focusing on the molecular mechanisms that link mechanical forces and genetic factors to the morphogenesis of the heart. Our studies using zebrafish as a model system serve as the basic foundation to address the key questions in cardiac development and function, and could provide novel therapeutic interventions for cardiac diseases. |
| Gupton, Stephanie WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
During cell shape change and motility, a dynamic cytoskeleton produces the force to initiate plasma membrane protrusion, while vesicle trafficking supplies phospholipids and membrane proteins to the expanding plasma membrane. Extracellular cues activate intracellular signaling pathways to elicit specific cell shape changes and motility responses through coordinated cytoskeletal dynamics and vesicle trafficking. In my lab we are investigating the role of two ubiquitin ligases, TRIM9 and TRIM67, in the cell shape changes that occur during neuronal development. We utilize a variety techniques including high resolution live cell microscopy, gene disruption, mouse models, and biochemistry to understand the complex coordination of cytoskeletal dynamics and membrane trafficking driving neuronal shape change and growth cone motility in primary neurons. |
| Gordon-Larsen, Penny WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Gordon-Larsen’s work integrates biology, behavior, and environment to understand, prevent and treat obesity, cardiovascular and cardiometabolic diseases. She works with biomarker, microbiome, metabolome, genetic, weight, diet, and environment data using multilevel modeling and pathway-based analyses. She works with several longitudinal cohorts that span more than 30 years. Most of her work uses data from the US and China. Her research teams include a wide variety of scientists working in areas such as genetics, medicine, bioinformatics, biostatistics, microbiology, nutrition, and epidemiology. |
| Goldstein, Bob WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We address fundamental issues in cell and developmental biology, issues such as how cells move to specific positions, how the orientations of cell divisions are determined, how the mitotic spindle is positioned in cells, and how cells respond to cell signaling – for example Wnt signaling, which is important in development and in cancer biology. We are committed to applying whatever methods are required to answer important questions. As a result, we use diverse methods, including methods of cell biology, developmental biology, forward and reverse genetics including RNAi, biochemistry, biophysics, mathematical and computational modeling and simulations, molecular biology, and live microscopy of cells and of the dynamic components of the cytoskeleton – microfilaments, microtubules, and motor proteins. Most experiments in the lab use C. elegans embryos, and we have also used Drosophila and Xenopus recently. C. elegans is valuable as a model system because of the possibility of combining the diverse techniques above to answer a wide array of interesting questions. We also have a long-term project to develop a new model system for studying how biological materials can survive extremes, using little-studied organisms called tardigrades. Rotating graduate students learn to master existing techniques, and students who join the lab typically grow their rotation projects into larger, long term projects, and/or develop creative, new projects. |
| Gilmore, John WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Dr. Gilmore’s research group is applying state-of–the-art magnetic resonance imaging and image analysis techniques to study human brain development in 0-6 year olds. Approaches include structural, diffusion tensor, and resting state functional imaging, with a focus on cortical gray and white matter development and its relationship to cognitive development. Studies include normally developing children, twins, and children at high risk for schizophrenia and bipolar illness. We also study the contributions of genetic and environmental risk factors to early brain development in humans. A developing collaborative project with Flavio Frohlich, PhD will use imaging to study white and gray matter development in ferrets and its relationship with cortical oscillatory network development. |
| Fry, Rebecca WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The lab focuses on understanding how environmental exposures are associated with human disease with a particular focus on genomic and epigenomic perturbations. Using environmental toxicogenomics and systems biology approaches, we aim to identify key molecular pathways that associate environmental exposure with diseases. A current focus in the lab is to study prenatal exposure to various types of metals including arsenic, cadmium, and lead. We aim to understand molecular mechanisms by which such early exposures are associated with long-term health effects in humans. For example, we are examining DNA methylation (epigenetic) profiles in humans exposed to metals during the prenatal period. This research will enable the identification of gene and epigenetic biomarkers of metal exposure. The identified genes can serve as targets for study to unravel potential molecular bases for metal-induced disease. Ultimately, we aim to identify mechanisms of metal -induced disease and the basis for inter-individual disease susceptibility. |
| Errede, Beverly WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Yeast molecular genetics; MAP-Kinease activation pathways; regulation of cell differentiation. |
| Erie, Dorothy WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The research in my lab is divided into two main areas – 1) Atomic force microscopy and fluorescence studies of protein-protein and protein-nucleic acid interactions, and 2) Mechanistic studies of transcription elongation. My research spans the biochemical, biophysical, and analytical regimes. |
| Duronio, Bob WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
My lab studies how cell proliferation is controlled during animal development, with a focus on the genetic and epigenetic mechanisms that regulate DNA replication and gene expression throughout the cell cycle. Many of the genes and signaling pathways that we study are frequently mutated in human cancers. Our current research efforts are divided into three areas: 1) Plasticity of cell cycle control during development 2) Histone mRNA biosynthesis and nuclear body function 3) Epigenetic control of genome replication and function. |
| Diaz-Sanchez, David WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The work focuses on how air pollutants affect human health, the role of genetics and epigenetic factors in determining susceptibility and clinical/dietary strategies to mitigate these effects. There is a strong emphasis on translational research projects using a multi-disciplinary approach. Thus, by using human in vivo models (such as clinical studies) we validate in vitro, epidemiology, and animal findings. |