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NameEmailPhD ProgramResearch InterestPublications
Legant, Wesley R.
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pharmacology

RESEARCH INTEREST
Biomaterials, Cancer Biology, Cell Biology, Cell Signaling, Computational Biology

Life is animate and three-dimensional.  Our lab develops tools to better understand living specimens at single molecule, cellular, and tissue level length scales.  Our current efforts comprise three synergistic research areas: 1) development and application of novel fluorescent imaging modalities including: super resolution, light sheet, and adaptive optical microscopy 2) investigation of how mechanical forces and cytoskeletal dynamics drive cancer cell migration through complex three-dimensional environments, and 3) generation of microfabricated platforms to precisely control the cellular microenvironment for tissue engineering and drug screening.

Jiang, Yuchao
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Bioinformatics & Computational Biology

RESEARCH INTEREST
Bioinformatics, Cancer Biology, Computational Biology, Genomics

Dr Jiang’s primary research interests lie in statistical modeling, method development and data analysis in genetics and genomics. His current research is focused on developing statistical methods and computational algorithms to better utilize and analyze different types of next-generation sequencing data under various setting, with application to data from large-scale cohort studies of human health and disease. Special focus is on single-cell transcriptomics, single-cell epigenomics, cancer genomics, tumor phylogeny, data normalization, and copy number variation detection.

Brown, Nicholas
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pharmacology

RESEARCH INTEREST
Biochemistry, Biophysics, Cancer Biology, Pharmacology, Structural Biology

Our research group uses several biochemical and structural techniques (e.g. enzyme assays, X-ray crystallography, and cryo-EM) to understand how molecular machines drive the cell cycle. Dysregulation of these enzymes results in numerous cancer types.

Williams, Scott E.
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Cell Biology & Physiology, Genetics & Molecular Biology, Oral & Craniofacial Biomedicine, Pathobiology & Translational Science

RESEARCH INTEREST
Cancer Biology, Cell Biology, Developmental Biology, Genetics, Pathology, Stem Cells

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.

Williams, David C. Jr.
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pathobiology & Translational Science

RESEARCH INTEREST
Biochemistry, Biophysics, Cancer Biology, Drug Discovery, Structural Biology

The overall objective of our research is to understand the connection between structure of protein-DNA complexes, protein dynamics and function.  We currently focus on the methyl-cytosine binding domain (MBD) family of DNA binding proteins.  The MBD proteins selectively recognize methylated CpG dinucleotides and regulate gene expression critical for both normal development and carcinogenesis.  We use a combination of NMR spectroscopy and biophysical analyses to study protein-DNA and protein-protein complexes involving the MBD proteins.  Building on these studies, we are developing inhibitors of complex formation as potential molecular therapeutics for b-hemoglobinopathies and cancer.

Wang, Greg Gang
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Biochemistry & Biophysics, Genetics & Molecular Biology

RESEARCH INTEREST
Biochemistry, Cancer Biology, Developmental Biology, Genomics, Molecular Biology

With an emphasis on chromatin biology and cancer epigenetics, our group focuses on mechanistic understandings of how chemical modifications of chromatin define distinct patterns of human genome, control gene expression, and regulate cell proliferation versus differentiation during development, and how their deregulations lead to oncogenesis. Multiple on-going projects employ modern biological technologies to: 1) biochemically isolate and characterize novel factors that bind to histone methylation on chromatin, 2) examine the role of epigenetic factors (chromatin-modifying enzymes and chromatin-associated factors) during development and tumorigenesis using mouse knockout models, 3) analyze epigenomic and transcriptome alternation in cancer versus normal cells utilizing next-generation sequencing technologies, 4) identify novel oncogenic or tumor suppressor genes associated with leukemia and lymphoma using shRNA library-based screening. We are also working together with UNC Center of Drug Discovery to develop small-molecule inhibitors for chromatin-associated factors as novel targeted cancer therapies.

Wang, Andrew Z.
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pharmacology

RESEARCH INTEREST
Biomaterials, Cancer Biology, Drug Delivery, Nanomedicine, Translational Medicine

My laboratory has two research directions. One is to utilize nanotechnology to develop novel diagnostics and therapeutics to improve cancer treatment. The other is to use techniques developed in tissue engineering to develop in vitro 3D models of cancer metastasis.

Liu, Pengda
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Biochemistry & Biophysics

RESEARCH INTEREST
Biochemistry, Cancer Biology, Cell Biology, Cell Signaling, Drug Discovery

If you are interested in developing new biochemical/molecular techniques/tools to advance our understanding of biology, and if you are interested in signal transduction pathway analyses and identification of cancer biomarkers, our research group may help you to achieve your goals, as we have the same dreams. We are especially interested in deciphering the molecular mechanisms underlying aberrant signaling events that contribute to tumorigenesis, mediated through protein modifications and protein-protein interactions. Understanding these events may lead to identification of novel drug targets and provide new treatment strategies to combat human cancer.

Wu, Di
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Bioinformatics & Computational Biology

RESEARCH INTEREST
Bioinformatics, Cancer Biology, Computational Biology, Genomics, Translational Medicine

Our group develops novel statistical bioinformatics tools and applies them in biomedical research to help understanding the precision medicine for cancer (e.g., breast cancer and lung cancer) subtypes, the disease associated integrative pathways across multiple genomic regulatory levels, and the genetics based drug repurposing mechanisms. Our recent focus includes pathway analysis, microbiome data analysis, data integration and electronica medical records (EMR). Our application fields include cancer, stem cell, autoimmune disease and oral biology. In the past, we have developed gene set testing methods with high citations, in the empirical Bayesian framework, to take care of small complex design and genewise correlation structure. These have been widely used in the microarray and RNAseq based gene expression analysis. Contamination detection for data analysis for Target DNA sequencing is work in progress. Recently, we also work on single cell sequencing data for pathway analysis with the local collaborators.

Gupton, Stephanie
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Cell Biology & Physiology, Neuroscience

RESEARCH INTEREST
Biochemistry, Cancer Biology, Cell Biology, Cell Signaling, Genetics, Neurobiology, Stem Cells

During cell shape change and motility, a dynamic cytoskeleton produces the force to initiate plasma membrane protrusion, while vesicle trafficking supplies phospholipids and membrane proteins to the expanding plasma membrane. Extracellular cues activate intracellular signaling pathways to elicit specific cell shape changes and motility responses through coordinated cytoskeletal dynamics and vesicle trafficking. In my lab we are investigating the role of two ubiquitin ligases, TRIM9 and TRIM67, in the cell shape changes that occur during neuronal development. We utilize a variety techniques including high resolution live cell microscopy, gene disruption, mouse models, and biochemistry to understand the complex coordination of cytoskeletal dynamics and membrane trafficking driving neuronal shape change and growth cone motility in primary neurons.