Research Interest: Systems Biology
| Name | PhD Program | Research Interest | Publications |
|---|---|---|
| Dohlman, Henrik WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We use an integrated approach (genomics, proteomics, computational biology) to study the molecular mechanisms of hormone and drug desensitization. Our current focus is on RGS proteins (regulators of G protein signaling) and post-translational modifications including ubiquitination and phosphorylation. |
| Dayan, Eran WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our lab studies brain network connectivity in the healthy brain and in neurological and neuropsychiatric patient populations. We focus on the organizational, dynamical, and computational properties of large-scale brain networks and determine how these properties contribute to human behavior in health and disease. We strive to advance the basic understanding of brain structure and function, while making discoveries that can be translated to clinical practice. |
| Davis, Ian WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
With a particular interest in pediatric solid tumors, our lab aims to develop a mechanistic understanding of the role of aberrant or dysregulated transcription factors in oncogenesis. |
| Conlon, Frank WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Males and females differ in their prelevance, treatment, and survival to a diverse set of human disease states. This is exemplified cardiovascular disease, a disease that takes more lives than all forms of cancer combined. In cardiac disease, women almost uniformly fare far worse than men: as of 2007 one woman dying for cardiovascular disease in the US every minute. Our lab focuses on sex disparities in development and disease. For these studies, we use a highly integrated approach that incorporates developmental, genetic, proteomic, biochemical and molecular-based studies in mouse and stem cells. Recent advances by our past students (presently at Harvard, John Hopkins and NIH) include studies that define the cellular and molecular events that lead to cardiac septation, those that explore cardiac interaction networks as determinants of transcriptional specificity, the mechanism and function of cardiac transcriptional repression networks, and the regulatory networks of cardiac sexual dimorphism. Our lab has opening for rotation and PhDs to study these rapidly emerging topics. |
| Clemmons, David R. WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Cross-talk between insulin like growth factor -1 and cell adhesion receptors in the regulation of cardiovascular diseases and complications associated with diabetes. |
| Chen, Xian WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Developing and applying novel mass spectrometry (MS)-based proteomics methodologies for high throughput identification, quantification, and characterization of the pathologically relevant changes in protein expression, post-translational modifications (PTMs), and protein-protein interactions. Focuses in the lab include: 1) technology development for comprehensive and quantitative proteomic analysis, 2) investigation of systems regulation in toll-like receptor-mediated pathogenesis and 3) proteomic-based mechanistic investigation of stress-induced cellular responses/effects in cancer pathogenesis. |
| Carelli, Regina M. WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Research in the Carelli laboratory is in the area of behavioral neuroscience. Our studies focus on the neurobiological basis of motivated behaviors, including drug addiction. Electrophysiology and electrochemistry procedures are used during behavior to examine the role of the brain ‘reward’ circuit in natural (e.g., food) versus drug (e.g., cocaine) reward. Studies incorporate classical and operant conditioning procedures to study the role of the nucleus accumbens (and dopamine) and associated brain regions in learning and memory, as they relate to motivated behaviors. |
| Boettiger, Charlotte WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
My lab uses a cognitive neuroscience approach to understand the neurobiology of drug addiction in humans. The tools we use include fMRI, cognitive testing, physiological monitoring, pharmacology, and genetic testing. We specifically seek to determine 1) how the brain learns new stimulus-response associations and replaces learned associations, 2) the neurobiological mechanisms underlying the tendency to select immediate over delayed rewards, and 3) the neural bases of addiction-related attentional bias. |
| Bear, James E. WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our lab uses a combination of genetics, high-resolution cellular and animal imaging, animal tumor models and microfluidic approaches to study the problems of cell motility and cytoskeletal organization. We are particularly interested in 1) How cells sense cues in their environment and respond with directed migration, 2) How the actin cytoskeleton is organized at the leading edge of migrating cells and 3) How these processes contribute to tumor metastasis. |
| Hodge, Clyde WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our preclinical research is based on the concept that drugs of abuse gain control over behavior by hijacking molecular mechanisms of neuroplasticity within brain reward circuits. Our labĀ focuses on three main research questions: (1) Discover the neural circuits and molecular mechanisms that mediate the reinforcing and pleasurable subjective effects of alcohol and other drugs, (2) Identify the long-term effects of cocaine and alcohol abuse during adolescence, (3) Identify novel neural targets and validate pharmacological compounds that may be used to treat problems associated with alcohol and drug abuse. The lab culture is collaborative and dynamic, innovative, and team-based. We are looking for colleagues who share an interest in understanding how alcohol hijacks reward pathways to produce addiction. |