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NameEmailPhD ProgramResearch InterestPublications
Homeister, Jonathon W.
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pathobiology & Translational Science

RESEARCH INTEREST
Cardiovascular Biology, Cell Biology, Immunology, Pathology, Physiology

Our research focuses on understanding the molecular and cellular mechanisms of leukocyte (white blood cell) trafficking and homing in vascular inflammation and immune responses. We are interested in the glycobiology of the Selectin leukocyte adhesion molecules and their ligands, and understanding the roles for these glycoproteins in the pathogenesis of inflammatory/immune cardiovascular diseases such as atherosclerosis and vasculitis. We are also interested in the mechanisms whereby the selectins and their ligands link the inflammatory response and coagulation cascade and thereby modulate thrombosis and hemostasis.

Jennette, Charles J.
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pathobiology & Translational Science

RESEARCH INTEREST
Immunology, Pathology, Translational Medicine

My research interests and diagnostic responsibilities center around nephropathology and immunopathology. My laboratory carries out basic, translational and clinicopathologic research on kidney diseases. I am most interested in pathogenic mechanisms and pathologic manifestations of glomerular diseases and vasculitis. A major current research focus is on elucidating the pathogenesis of vascular inflammation caused by anti-neutrophil cytoplasmic autoantibodies (ANCA).

Kakoki, Masao
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pathobiology & Translational Science

RESEARCH INTEREST
Genetics, Pathology

My research aims at prevention and treatment of cardiovascular diseases and focuses on the identification of genes that confer susceptibility or resistance to the diseases with the use of genetically engineered mice. In collaboration with Dr.Oliver Smithies, I very recently developed a new method for altering gene expression by modifying 3’ untranslated regions in mice which enables fine-tuned modification of gene expression. I am now analyzing the phenotypes of several mouse models generated with this method.

Kesimer, Mehmet
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pathobiology & Translational Science

RESEARCH INTEREST
Biochemistry, Cell Biology, Molecular Biology, Pathology, Translational Medicine

One of the main focuses of my work is the characterization of the large mucin gene products (Mr 2-3 million) and the complexes they make (Mr 10-100 million) essential for the formation of the mucus gels vital for epithelial protection and function. My current work is focused around the human lung, where there are many hypersecretory human diseases, including asthma, cystic fibrosis, and chronic bronchitis, in which these glycoconjugates are centrally implicated. Basic understanding of the qualitative and quantitative changes of mucin macromolecules in lung health and diseases is our main task.

Mack, Christopher P.
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Cell Biology & Physiology, Pathobiology & Translational Science

RESEARCH INTEREST
Cardiovascular Biology, Cell Signaling, Developmental Biology, Molecular Biology, Pathology

My research goals are to identify the mechanisms by which environmental factors regulate smooth muscle cell phenotype and to define the transcriptional pathways that regulate SMC-specific gene expression.

Mackman, Nigel
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pathobiology & Translational Science

RESEARCH INTEREST
Cancer Biology, Cardiovascular Biology, Cell Signaling, Pathology, Translational Medicine

The major focus of Mackman lab is the procoagulant protein tissue factor. This is the primary cellular initiator of blood coagulation. We study its role in hemostasis, thrombosis, inflammation, ischemia-reperfusion injury and tumor growth.  We have generated a number of mouse models expressing different levels of both mouse and human tissue factor. These mice have been used to provide new insights into the role of tissue factor in hemostasis and thrombosis. In 2007, we developed a new assay to measure levels of microparticle tissue factor in plasma. We found that elevated levels of microparticle tissue factor are associated with venous thromboembolism in cancer patients.

Nichols, Timothy C.
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Pathobiology & Translational Science

RESEARCH INTEREST
Molecular Biology, Pathology

My research interests include the role of von Willebrand factor in thrombosis and atherosclerosis. Our current lab work focuses on the molecular biology of porcine von Willebrand factor.

Perou, Charles M.
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Bioinformatics & Computational Biology, Genetics & Molecular Biology, Pathobiology & Translational Science

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

The focus of my lab is to characterize the biological diversity of human tumors using genomics, genetics, and cell biology, and then to use this information to develop improved treatments that are specific for each tumor subtype and for each patient. A significant contribution of ours towards the goal of personalized medicine has been in the genomic characterization of human breast tumors, which identified the Intrinsic Subtypes of Breast Cancer. We study many human solid tumor disease types using multiple experimental approaches including RNA-sequencing (RNA-seq), DNA exome sequencing, Whole Genome Sequencing, cell/tissue culturing, and Proteomics, with a particular focus on the Basal-like/Triple Negative Breast Cancer subtype. In addition, we are mimicking these human tumor alterations in Genetically Engineered Mouse Models, and using primary tumor Patient-Derived Xenografts, to investigate the efficacy of new drugs and new drug combinations. All of these genomic and genetic studies generate large volumes of data; thus, a significant portion of my lab is devoted to using genomic data and a systems biology approach to create computational predictors of complex cancer phenotypes.

Qian, Li
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Cell Biology & Physiology, Pathobiology & Translational Science

RESEARCH INTEREST
Cardiovascular Biology, Cell Biology, Developmental Biology, Genetics, Molecular Biology

Our laboratory is interested in developing innovative approaches to regenerate or repair an injured heart. Our goal is to understand the molecular basis of cardiomyocyte specification and maturation and apply this knowledge to improve efficiency and clinical applicability of cellular reprogramming in heart disease. To achieve these goals, we utilize in vivo modeling of cardiac disease in the mouse, including myocardial infarction (MI), cardiac hypertrophy, chronic heart failure and congenital heart disease (CHD). In addition, we take advantage of traditional mouse genetics, cell and molecular biology, biochemistry and newly developed reprogramming technologies (iPSC and iCM) to investigate the fundamental events underlying the progression of various cardiovascular diseases as well as to discover the basic mechanisms of cell reprogramming.

Redinbo, Matt
WEBSITE
EMAIL
PUBLICATIONS

PHD PROGRAM
Biochemistry & Biophysics, Bioinformatics & Computational Biology, Chemistry, Microbiology & Immunology, Oral & Craniofacial Biomedicine, Pathobiology & Translational Science, Pharmaceutical Sciences, Pharmacology

RESEARCH INTEREST
Bacteriology, Biochemistry, Bioinformatics, Biophysics, Cancer Biology, Chemical Biology, Computational Biology, Drug Delivery, Drug Discovery, Metabolism, Microbiology, Molecular Biology, Molecular Medicine, Pharmacology, Plant Biology, Structural Biology, Systems Biology, Toxicology

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