Research Interest: Cell Signaling
| Name | PhD Program | Research Interest | Publications |
|---|---|---|
| Coleman, Leon WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The overriding goal of Dr. Coleman’s work is to identify novel treatments for alcohol use disorders (AUD) and associated peripheral disease pathologies. Currently, this includes: the role of neuroimmune Signaling in AUD pathology, the role of alcohol-associated immune dysfunction in associated disease states, and novel molecular and subcellular mediators of immune dysfunction such as extracellular vesicles, and regenerative medicine approaches such as microglial repopulation. |
| Axtman, Alison WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
In my lab, we are exploring the roles that kinases play in neurodegeneration through the creation of high-quality, small molecule tools. Our team designs, synthesizes, and evaluates small molecules capable of kinase modulation, sometimes targeting kinase inhibition and sometimes kinase activation. In order to accomplish our aims, we work closely with X-ray crystallographers within the larger SGC and with biologists, including experts in using stem cells to model neurodegenerative diseases. We seek enthusiastic students with an interest in neuroscience who are willing to learn and apply techniques that span chemistry and biology to better understand and address neurodegeneration. |
| 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. |
| Bryant, Kirsten WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The overall goal of our lab is to perform research that contributes to a better understanding of pancreatic cancer biology and leads to improved treatments for this disease. One major focus of our studies is the metabolic activity, autophagy, which is a self-degradation process whereby cells can orderly clear defective organelles and recycle macromolecules as a nutrient source. Current projects are focused on further advancing autophagy inhibition as an anti-RAS therapeutic approach, as well as delineating other metabolic consequences of RAF-MEK-ERK MAPK inhibition. |
| Lu, Zhiyue WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
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| Gladden, Andrew WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The Gladden lab studies how cell adhesion and cell polarity are intertwined in normal tissue development and how these pathways are altered in diseases such as cancer. We use a combination of 3D cell culture, mouse models and protein biochemistry to study how cell polarity and adhesion regulate tissue organization. Our work focuses on the interplay between cell adhesion and cell polarity proteins at the adherens junction and how these proteins regulate tissue organization. We concentrate on the development of the endometrium epithelium in the female reproductive tract and the cell biology of endometrial cancer. |
| Rizvi, Imran WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Dr. Rizvi’s expertise is in imaging and therapeutic applications of light, bioengineered 3D models and animal models for cancer, and targeted drug delivery for inhibition of molecular survival pathways in tumors. His K99/R00 (NCI) develops photodynamic therapy (PDT)-based combinations against molecular pathways that are altered by fluid stress in ovarian cancer. He has co-authored 46 peer-reviewed publications and 5 book chapters with a focus on PDT, biomedical optics, and molecular targeting in cancer. |
| Jiang, Guochun WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Antiretroviral therapy (ART) is effective in suppressing HIV-1 replication in the periphery, however, it fails to eradicate HIV-1 reservoirs in patients. The main barrier for HIV cure is the latent HIV-1, hiding inside the immune cells where no or very low level of viral particles are made. This prevents our immune system to recognize the latent reservoirs to clear the infection. The main goal of my laboratory is to discover the molecular mechanisms how HIV-1 achieves its latent state and to translate our understanding of HIV latency into therapeutic intervention. Several research programs are undertaking in my lab with a focus of epigenetic regulation of HIV latency, including molecular mechanisms of HIV replication and latency establishment, host-virus interaction, innate immune response to viral infection, and the role of microbiome in the gut health. Extensive in vitro HIV latency models, ex vivo patient latency models, and in vivo patient and rhesus macaque models of AIDS are carried out in my lab. Multiple tools are applied in our studies, including RNA-seq, proteomics, metabolomics, highly sensitive digital droplet PCR and tissue RNA/DNAscope, digital ELISA, and modern and traditional molecular biological and biochemical techniques. We are also very interested in how non-CD4 expression cells in the Central Nervous System (CNS) get infected by HIV-1, how the unique interaction among HIV-1, immune cells, vascular cells, and neuron cells contributes to the initial seeding of latent reservoirs in the CNS, and whether we can target the unique viral infection and latency signaling pathways to attack HIV reservoirs in CNS for a cure/remission of HIV-1 and HIV-associated neurocognitive disorders (HAND). We have developed multiple tools to attack HIV latency, including latency reversal agents for “Shock and Kill” strategy, such as histone deacetylase inhibitors and ingenol family compounds of protein kinase C agonists, and latency enforcing agents for deep silencing of latent HIV-1. Several clinical and pre-clinical studies are being tested to evaluate their potential to eradicate latent HIV reservoirs in vivo. We are actively recruiting postdocs, visiting scholars, and technicians. Rotation graduate students and undergraduate students are welcome to join my lab, located in the UNC HIV Cure Center, for these exciting HIV cure research projects. |
| Button, Brian WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
The Button lab in the Department of Biochemistry and Biophysics is part of the Marsico Lung Institute. Our lab is actively involved in projects that are designed to define the pathogenesis of muco-obstructive pulmonary disorders and to identify therapies that could be used to improve the quality of life in persons afflicted by these diseases. In particular, our research works to understand the biochemical and biophysical properties of mucin biopolymers, which give airway mucus its characteristic gel-like properties, and how they are altered in diseases such as Asthma, COPD, and cystic fibrosis. |
| Dowen, Rob WEBSITE PUBLICATIONS |
PHD PROGRAM RESEARCH INTEREST |
Appropriate allocation of cellular lipid stores is paramount to maintaining organismal energy homeostasis. Dysregulation of these pathways can manifest in human metabolic syndromes, including cardiovascular disease, obesity, diabetes, and cancer. The goal of my lab is to elucidate the molecular mechanisms that govern the storage, metabolism, and intercellular transport of lipids; as well as understand how these circuits interface with other cellular homeostatic pathways (e.g., growth and aging). We utilize C. elegans as a model system to interrogate these evolutionarily conserved pathways, combining genetic approaches (forward and reverse genetic screens, CRISPR) with genomic methodologies (ChIP-Seq, mRNA-Seq, DNA-Seq) to identify new components and mechanisms of metabolic regulation. |