Role of Embryonic Stem Cell Pluripotency Gene Networks and Epigenetic Control Mechanisms in Control of SMC Plasticity In Development, Tissue Repair, and Disease

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• Dr. Gary K. Owens - Professor of Molecular Physiology and Biological Physics
• Thursday 21 February 2013, 13:00-14:00
• Seminar room 3, Clinical School, Addenbrookes.

If you have a question about this talk, please contact Eve Dillon.

Sandwich Lunch provided at 12:30

Research interests and thematic emphasis Dr. Owens research is focused on the molecular regulation of differentiation of vascular smooth muscle cells (SMC) during development, and how transitions in the differentiated state of these cells, or so-called SMC phenotypic switching contribute to the pathogenesis of major human diseases including atherosclerosis, cancer, hypertension, and aneurysms. A major area of current focus is studying the role of epigenetic mechanisms (e.g. histone modifications and chromatin structure) and embryonic stem cell (ESC) [and induced pluripotential stem (iPS) cell] pluripotency gene networks in regulating transitions in SMC phenotype during development of atherosclerosis as well as in tissue repair and regeneration. Remarkably, using novel mouse model systems developed by his group, they have evidence showing that perivascular cells including SMC and pericytes represent a source of multi-potential MSC -like cells that play a key role in tissue regeneration and repair, and that phenotypic transitions of these cells are mediated via the ESC pluripotency genes Oct4 and Klf4. Another project in the lab is focused on identification of mechanisms that lead to abnormal maturation of tumor blood vessels (i.e. defective SMC /pericyte investment and differentiation), a process linked with high rates of tumor cell shedding and metastasis. Finally, he has a series of projects focused on investigating mechanisms that regulate the stability of advanced atherosclerotic plaques, a process of critical importance in determining if a plaque is likely to rupture and initiate a heart attack.

This talk is part of the CCCRR Vascular Biology Research Seminars series.

This talk is included in these lists:

• CCCRR Vascular Biology Research Seminars
• Seminar room 3, Clinical School, Addenbrookes

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