PhD Program: Microbiology & Immunology
| Name | PhD Program | Research Interest | Publications |
|---|---|---|
| Sheahan, Tim WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Dr. Sheahan is an expert virologist with a primary appointment in the Department of Epidemiology in the Gillings School of Global Public Health and a secondary appointment in Microbiology and Immunology in the School of Medicine. His research is focused on understanding emerging viral diseases and developing new means to stop them with a current focus on coronavirus and hepacivirus. |
| Miller, Brian WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The Miller lab is working to improve the efficacy of immunotherapy to treat cancer. We aim to develop personalized immunotherapy approaches based on a patient’s unique cancer mutations. We have a particular interest in myeloid cells, a poorly understood group of innate immune cells that regulate nearly all aspects of the immune response. Using patient samples, mouse models, single-cell profiling, and functional genomics approaches, we are working to identify novel myeloid-directed therapies that allow us to overcome resistance and successfully treat more patients. |
| Lin, Jessica WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Dr. Lin is an infectious disease physician-scientist whose research lies at the interface of clinical and molecular studies on malaria. My current projects focus on 1) determinants of malaria transmission from human hosts to mosquitos and 2) the epidemiology and relapse patterns of Plasmodium ovale in East Africa. Work in my lab involves applying molecular tools (real-time PCR, amplicon deep sequencing, whole genome sequencing, and to a lesser extent antigen and antibody assays) to samples collected in clinical field studies to learn about malaria epidemiology, transmission, and pathogenesis. |
| Mock, Jason WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our research interests focus on investigating the reparative processes critical to the resolution of acute lung injury. Acute events such as pneumonia, inhalational injury, trauma, or sepsis often damage the lung, impeding its primary function, gas exchange. The clinical syndrome these events can lead to is termed Acute Respiratory Distress Syndrome (ARDS). ARDS is a common pulmonary disease often seen and treated in intensive care units. Despite decades of research into the pathogenesis underlying the development of ARDS, mortality remains high. Our laboratory has built upon exciting observations by our group and others on the importance of how the lung repairs after injury. One type of white blood cell, the Foxp3+ regulatory T cell (Treg), appears essential in resolving ARDS in experimental models of lung injury–through modulating immune responses and enhancing alveolar epithelial proliferation and tissue repair. Importantly, Tregs are present in patients with ARDS, and our lab has found that subsets of Tregs may play a role in recovery from ARDS. |
| Moran, Timothy WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our research focuses on how environmental exposures impact the development of allergic diseases including asthma and food allergy. We are specifically interested in how exposure to environmental pollutants and immunostimulatory molecules (adjuvants) influence allergic sensitization. The goals of our laboratory are to: (1) define the key environmental adjuvants within the indoor exposome that promote allergic sensitization; (2) characterize the molecular mechanisms by which environmental adjuvants and pollutants condition lung antigen presenting cells to induce allergic immune responses; and (3) identify biomarkers of environmental adjuvant exposure that are associated with increased risk for allergic sensitization in children. Through these research endeavors, we hope to identify potential therapeutic targets for environment-mediated allergic diseases, as well as environmental interventions to mitigate the risk for allergic disease development. |
| Vogt, Matthew WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We want to understand why common pediatric respiratory virus infections cause severe disease in some people. Currently we focus on enterovirus D68, which typically causes colds but rarely causes acute flaccid myelitis, a polio-like paralyzing illness in children. We study both the pathogen and the host immune response, as both can contribute to pathogenesis. Projects focus on use of reverse genetic systems to create reporter viruses to infect both human respiratory epithelial cultures and small animal models such as mice. Human monoclonal antibody effects on pathogenesis are also of interest. |
| Joseph, Sarah B. PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We use studies of HIV/SIV evolution to reveal information about viral dynamics in vivo. This typically involves genetic and/or phenotypic analyses of viral populations in samples from HIV-infected humans or SIV-infected nonhuman primates (NHPs). We are currently exploring the mechanisms that contribute to neurocognitive impairment in HIV-infected people by sequencing viral populations in the CNS of humans and NHPs not on antiretroviral therapy. We are also using these approaches to examine viral populations that persist during long-term antiretroviral therapy in an effort to better understand the viral reservoirs that must be targeted in order to cure HIV-infected people. |
| Browne, Edward WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
We study the molecular mechanisms of HIV latency. Transcriptional silencing of HIV is a key mechanism of persistence in patients, and is a barrier to viral eradication, but little is known about the latent reservoir or the molecular mechanisms that regulate it. As such, our repertoire of drugs for targeting latently infected cells is limited. Some latency reversing agents (LRAs) have been developed, but these are typically reactivate only a minor subset of proviruses. This inefficiency is in part due to the reservoir not constituting a uniform target, but instead being a heterogeneous set of cells with diverse characteristics and restrictions to HIV expression. However, most analyses of latency use bulk cell cultures assays in which crucial information about the behavior of individual cells is lost. Also, latently infected cells in patient samples are exceedingly rare, making them very difficult to study directly. New technological breakthroughs in the field of single cell analysis as well as the development of primary cell models for HIV latency now open the possibility of observing how latently infected cells form and are maintained at single cell resolution. Our lab has developed tools to study the establishment, maintenance and reversal of HIV latency at single cell resolution using multi-omics methods. Furthermore, we combine these approaches with genetic perturbation, time-lapse microscopy and novel bioengineering tools to gain insight into how the host cell regulates HIV latency. We have recently discovered using single cell RNAseq (scRNAseq) that latency in primary CD4 T cells is associated with expression of a distinct transcriptional signature (Bradley et al 2018). Our hypothesis is that this signature represents part of a cellular program that regulates latency, and that this program is an exciting novel target for the development of LRAs. Ongoing projects in the lab involve the application of new technologies to our model systems, and testing/validation of the roles of host cell pathways we have identified in HIV latency. Our overall goal is to identify new targets for the development of drugs to clear the HIV reservoir. |
| Milner, Justin WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The overall focus of our lab is to develop new and exciting approaches for enhancing the efficacy of cancer immunotherapies. We utilize cutting-edge techniques to identify transcriptional and epigenetic regulators controlling T cell differentiation and function in the tumor microenvironment, and we seek to leverage this insight to reprogram or tailor the activity of T cells in cancer. Our group is also interested in understanding how to harness or manipulate T cell function to improve vaccines and immunotherapies for acute and chronic infections. |
| Cameron, Craig E. WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Our laboratory now studies mechanisms of genome replication and pathogenesis of respiratory enteroviruses and evolution of neurovirulence using the tools of mechanistic enzymology, cell biology, stem-cell engineering, and virology. Our laboratory is also pioneering the development of tools to monitor viral infection dynamics on the single-cell level, aka “single-cell virology.” |