PhD Program: Bioinformatics & Computational 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. |
| Dangl, Jeff WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We use the premier model plant species, Arabidopsis thaliana, and real world plant pathogens like the bacteria Pseudomonas syringae and the oomycete Hyaloperonospora parasitica to understand the molecular nature of the plant immune system, the diversity of pathogen virulence systems, and the evolutionary mechanisms that influence plant-pathogen interactions. All of our study organisms are sequenced, making the tools of genomics accessible. |
| Carter, Charles WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Molecular evolution and mechanistic enzymology find powerful synergy in our study of aminoacyl-tRNA synthetases, which translate the genetic code. Class I Tryptophanyl-tRNA Synthetase stores free energy as conformational strain imposed by long-range, interactions on the minimal catalytic domain (MCD) when it binds ATP. We study how this allostery works using X-ray crystallography, bioinformatics, molecular dynamics, enzyme kinetics, and thermodynamics. As coding sequences for class I and II MCDs have significant complementarity, we also pursuing their sense/antisense ancestry. Member of the Molecular & Cellular Biophysics Training Program. |
| Bloom, Kerry WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our objective is to understand the dynamic and structural properties of chromosomes during mitosis. We use live cell imaging techniques to address how kinetochores are assembled, capture microtubules and promote faithful segregation of chromosomes. |
| 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. |
| Jones, Corbin WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The goal of my research is to identify, clone, and characterize the evolution of genes underlying natural adaptations in order to determine the types of genes involved, how many and what types of genetic changes occurred, and the evolutionary history of these changes. Specific areas of research include: 1) Genetic analyses of adaptations and interspecific differences in Drosophila, 2) Molecular evolution and population genetics of new genes and 3) Evolutionary analysis of QTL and genomic data. |
| Kelada, Samir WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
While both genes and environment are thought to influence human health, most investigations of complex disease only examine one of these risk factors in isolation. Accounting for both types of risk factors and their complex interactions allows for a more holistic view of complex disease causation. The Kelada lab is focused on the identification and characterization of these gene-environment interactions in airway diseases, particularly asthma, a disorder of major public health importance. / / Additionally, to gain insight into how the airway responds to relevant exposures (e.g., allergens or pathogens), we study gene expression in the lung (particularly airway epithelia). Our goal is identify the genetic determinants of gene expression by measuring gene expression across many individuals (genotypes). / This “systems genetics” approach allows us to identify master regulators of gene expression that may underlie disease susceptibility or represent novel therapeutic targets. / |
| Kuhlman, Brian WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We focus on a variety of design goals including the creation of novel protein-protein interactions, protein structures, vaccine antigens and light activatable protein switches. Central to all of our projects is the Rosetta program for protein modeling. In collaboration with developers from a variety of universities, we are continually adding new features to Rosetta as well as testing it on new problems. |
| Laederach, Alain WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The Laederach Lab is interested in better understanding the relationship between RNA structure and folding and human disease. We use a combination of computational and experimental approaches to study the process of RNA folding and in the cells. In particular, we develop novel approaches to analyze and interpret chemical and enzymatic mapping data on a genomic scale. We aim to fundamentally understand the role of RNA structure in controlling post-transcriptional regulatory mechanisms, and to interpret structure as a secondary layer of information (http://www.nature.com/nature/journal/v505/n7485/full/505621a.html). We are particularly interested in how human genetic variation affects RNA regulatory structure. We investigate the relationship between disease-associated Single Nucleotide Polymorphisms occurring in Human UTRs and their effect on RNA structure to determine if they form a RiboSNitch. |
| Gladfelter, Amy WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We study large multinucleate cells such as fungi, muscle and placenta to understand how cells are organized in time and space. Using quantitative live cell microscopy, biochemical reconstitution and computational approaches we examine how the physical properties of molecules generate spatial patterning of cytosol and scaling of cytoskeleton scaffolds in the cell cycle. |