Research Interest: Bacteriology
Name | PhD Program | Research Interest | Publications |
---|---|---|
Bourret, Bob WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our long-term goal is to define the molecular mechanisms of two-component regulatory systems, which are utilized for signal transduction by bacteria, archaea, eukaryotic microorganisms, and plants. Our current focus is to identify and understand the features that control the rates of several different types of protein phosphorylation and dephosphorylation reactions. The kinetics of phosphotransfer reactions can vary dramatically between different pathways and reflect the need to synchronize biological responses (e.g. behavior, development, physiology, virulence) to environmental stimuli. Member of the Molecular & Cellular Biophysics Training Program. |
Miller, Virginia L. WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Molecular genetic analysis of virulence of Yersinia and Klebsiella: My laboratory uses Yersinia enterocolitica, Y. pestis, and Klebsiella as model systems to study bacterial pathogenesis. The long-term goals of our work are to understand the bacteria-host interaction at the molecular level to learn how this interaction affects the pathogenesis of infections and to understand how these pathogens co-ordinate the expression of virulence determinants during an infection. To do this we use genetic, molecular and immunological approaches in conjunction with the mouse model of infection. |
Nicholas, Robert A. WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
My laboratory has two main interests: 1) Regulation of P2Y receptor signaling and trafficking in epithelial cells and platelets. Our laboratory investigates the cellular and molecular mechanisms by which P2Y receptors are differentially targeted to distinct membrane surfaces of polarized epithelial cells and the regulation of P2Y receptor signaling during ADP-promoted platelet aggregation. 2) Antibiotic resistance mechanisms. We investigate the mechanisms of antibiotic resistance in the pathogenic bacterium, Neisseria gonorrhoeae. Our laboratory investigates how acquisition of mutant alleles of existing genes confers resistance to penicillin and cephalosporins. We also study the biosynthesis of the gonococcal Type IV pilus and its contribution to antibiotic resistance. |
Redinbo, Matt WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We are interested in unraveling the molecular basis for human disease and discover new treatments focused on human and microbial targets. Our work extends from atomic-level studies using structural biology, through chemical biology efforts to identify new drugs, and into cellular, animal and clinical investigations. While we are currently focused on the gut microbiome, past work has examined how drugs are detected and degraded in humans, proteins designed to protect soldiers from chemical weapons, how antibiotic resistance spreads, and novel approaches to treat bacterial infections. The Redinbo Laboratory actively works to increase equity and inclusion in our lab, in science, and in the world. Our lab is centered around collaboration, open communication, and trust. We welcome and support anyone regardless of race, disability, gender identification, sexual orientation, age, financial background, or religion. We aim to: 1) Provide an inclusive, equitable, and encouraging work environment 2) Actively broaden representation in STEM to correct historical opportunity imbalances 3) Respect and support each individual’s needs, decisions, and career goals 4) Celebrate our differences and use them to discover new ways of thinking and to better our science and our community |
Sartor, R. Balfour WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our long term goals are to better define mechanisms of chronic intestinal inflammation and to identify areas for therapeutic intervention. Research in our laboratories is in the following four general areas: 1) Induction and perpetuation of chronic intestinal and extraintestinal inflammation by resident intestinal bacteria and their cell wall polymers, 2) Mechanisms of genetically determined host susceptibility to bacterial product,. 3) Regulation of immunosuppressive molecules in intestinal epithelial cells and 4) Performing clinical trials of novel therapeutic agents in inflammatory bowel disease patients. |
Singleton, Scott WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The Singleton Laboratory is interested in understanding the molecular basis for the develoment and transmission of microbial drug resistance and the discovery and exploitation of new strategies for controlling drug-resistant microorganisms. We develop and adapt synthetic chemistry and synthetic biology methods to provide new molecular tools — both biologically active small molecules and innovative platforms — for hypothesis-driven biological research and pharmaceutical discovery. These foundations of our program offers both chemically-oriented and biologically-oriented researchers new opportunities for the development of integrated, multi-disciplinary knowledge and technologies. |
Tamayo, Rita WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our lab studies the mechanisms facultative pathogens use to adapt to disparate and changing extracellular conditions. Our primary interest is in the ability of Vibrio cholerae, the causative agent of cholera, to persist in its native aquatic environment and also flourish in the host intestinal tract. We are addressing key questions about the role of cyclic diguanylate, a signaling molecule unique to and ubiquitous in bacteria, in the physiological adaptations of V. cholerae as it transits from the aquatic environment into a host. In addition, we are identifying and characterizing factors produced by V. cholerae during growth in a biofilm, a determinant of survival in aquatic environments, that contribute to virulence. I will be accepting rotation students beginning in the winter of 2009. |
Vilen, Barbara WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We are interested in understanding how autoreactive B cells become re-activated to secrete autoantibodies that lead to autoimmune disease. Our research is focused on understanding how signal transduction through the B cell antigen receptor (BCR) and Toll Like Receptors (TLR) lead to secretion of autoantibodies in Systemic Lupus Erythematosus (SLE). |
Wolfgang, Matthew C. WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Pseudomonas aeruginosa is a Gram-negative opportunistic pathogen responsible for a variety of diseases in individuals with compromised immune function. Dr. Wolfgang’s research focuses on the pathogenesis of Pseudomonas aeruginosa infection. The goal of his research is to understand how this opportunistic pathogen coordinates the expression of virulence factors in response to the host environment. Projects in his laboratory focus on the regulation of intracellular cyclic AMP, a second messenger signaling molecule that regulates P. aeruginosa virulence. Dr. Wolfgang’s laboratory uses a combination of molecular genetics and biochemical approaches to understand how P. aeruginosa controls the synthesis, degradation and transport of cAMP in response to extracellular cues. Other related projects focus on the regulation and function of P. aeruginosa Type IV pili (TFP). TFP are cAMP regulated surface organelles that are critical for bacterial colonization of human mucosal tissue. In addition, the Wolfgang lab is actively involved in characterizing the lung microbiome of patients with chronic airway diseases and studying the interactions between P. aeruginosa and other bacterial species during mixed infections. |
Li, Bo WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our research focuses on the discovery and design of new gene-encoded bioactive small molecules from bacteria. We are interested in understanding enzymes involved in their biosynthesis, their therapeutic mechanisms of action, and implications in health and diseases, in particular with respect to the human microbiome. This work is driven by intensive development of new metabolomics and genomics technologies. We subsequently manipulate and engineer these biosynthetic pathways to make new and improved molecules as potential therapeutics such as antibiotics. |