PhD Program: Oral & Craniofacial Biomedicine
| Name | PhD Program | Research Interest | Publications |
|---|---|---|
| Wallet, Shannon PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
My research interests are focused on mechanisms associated with altered innate immune functions, which lead to dysregulated adaptive immunity. Currently my research program has three major arms integrated through with a central philosophy. Specifically, our laboratory focuses on the contribution of epithelial cell biology and signaling to innate and adaptive immune homeostasis and dysfunction. We study the contribution of what I term ‘epithelial cell innate immune (dys)function’ to three major disease conditions: pancreatic cancer, type 1 diabetes (autoimmunity), and periodontal disease (autoinflammation). While appearing to be a diverse research program, we have found that many of the mechanisms and systems in play are surprisingly (or maybe not so surprisingly) similar allowing for rapid translation of our findings. Importantly, previous investigations into the role of epithelial cells in immunobiology have been hindered by a lack of robust primary cell culture techniques, which our laboratory has been able to overcome using both animal and human tissues. Thus, using our novel and unique tools we are able to evaluate our findings in the human conditions, again making translation of our findings that much more feasible. In addition to my primary research objectives, my collaborative research programs, have allowed me to be involved, at some level, in investigating the basic biology of health, multiple autoimmune conditions, autoinflammation, sepsis, and exercise induced inflammation I have been blessed with the opportunities to couple my passions and expertise with that of others to bring together multiple research communities with the goal of advancing human health and hope to be able to continue to do so for years to come. |
| Williams, Scott E. WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Interest areas: Developmental Biology, Cell Biology, Cancer Biology, Stem Cells, Genetics PhD programs: Pathobiology & Translational Sciences, Genetics & Molecular Biology, Cell Biology & Physiology, Oral Biology, Biology Tissue development and homeostasis depend on the precise coordination of self-renewal and differentiation programs. A critical point of regulation of this balance is at the level of cell division. In the Williams lab, we are interested in stratified epithelial development, stem cells, and cancer, with a particular interest in how oriented cell divisions contribute to these processes. Asymmetric cell divisions maintain a stable pool of stem cells that can be used to sustain tissue growth, or mobilized in response to injury. However, dysregulation of this machinery can lead to cancer, particularly in epithelia where tissue turnover is rapid and continuous. Using the mouse epidermis and oral epithelia as model systems, we utilize cell biological, developmental and genetic approaches to study the molecular control of oriented cell divisions and mitotic spindle positioning, and how division orientation impacts cell fate choices in development, homeostasis, injury, and disease. |
| Ko, Ching-Chang WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Ko’s laboratory has focused on bone regeneration using biomaterials and biomechanical approaches. The on-going project is to develop a new synthetic process for biomimetic bone nanocomposites. The new biomaterial and its scaffolds are under development for stem cell-mediated bone regeneration. Biomechanical principles that regulate mineral crystallization are incorporated with the biomaterial approach to translate research outcomes to clinical usage (e.g., immediately loaded dental implants). My lab is also interested in understanding reverse engineering principles of bio-mienralization. |
| Lai, Samuel WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our dynamic group are broadly involve in three topics: (i) prevention of infectious diseases by harnessing interactions between secreted antibodies and mucus, (ii) immune response to biomaterials, and (iii) targeted delivery of nanomedicine. Our group was the first to discover that secreted antibodies can interact with mucins to trap pathogens in mucus. We are now harnessing this approach to engineer improved passive and active immuniation (i.e. vaccines) at mucosal surfaces, as well as understand their interplay with the mucosal microbiome. We are also studying the adaptive immune response to polymers, including anti-PEG antibodies, and how it might impact the efficacy of PEGylated therapeutics. Lastly, we are engineering fusion proteins that can guide targeted delivery of nanomedicine to heterogenous tumors and enable personalized medicine. |
| Matsushima, Glenn K WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our laboratory is interested in innate immune responses during injury to the central nervous system and during inflammation during microbial infections. Our laboratory has a special interest in autoimmune diseases such as multiple sclerosis and systemic lupus erythematosus. We also are pursuing drug discovery projects targeting receptors that may modulate demyelinating disease and immune responses. We use molecular, cellular and biochemical approaches both in vitro and in vivo to identify the function of key mediators during pathogenesis. |
| Moody, Cary WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our lab focuses on the life cycle of cancer-associated human papillomaviruses (HPV); small DNA viruses that exhibit a strict tropism for the epithelium. Several studies in our lab focus on the interface of HPV with cellular DNA damage response (DDR) pathways and how HPV manipulates DNA repair pathways to facilitate viral replication. We are also interested in understanding how the viral life cycle is epigenetically regulated by the DDR as well as by other chromatin modifiers. Additionally, we are investigating how HPV regulates the innate immune response throughout the viral life cycle. |
| 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 |
| 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. |