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Item Death-Associated Protein Kinase Regulates Vascular Smooth Muscle Cell Signaling and Migration(2011-03-16) Blue, Emily Keller; Gallagher, Patricia J.; Elmendorf, Jeffrey S.; Herring, B. Paul; Rhodes, Simon J.; Thurmond, Debbie C.Cardiovascular disease is the number one cause of death for Americans. New treatments are needed for serious conditions like atherosclerosis, as it can lead to stroke and heart attack. Many types of cells contribute to the progression of cardiovascular disease, including smooth muscle cells that comprise the middle layers of arteries. Inappropriate growth and migration of smooth muscle cells into the lumen of arteries has been implicated in vascular diseases. Death associated protein kinase (DAPK) is a protein that has been found to regulate the survival and migration of cancer cells, but has not been well characterized in vascular cells. The objective of this work was to determine the signaling pathways that DAPK regulates in smooth muscle cells. These studies have focused on smooth muscle cells isolated from human coronary arteries (HCASM cells). We have determined that HCASM cells depleted of DAPK exhibit more rapid migration, showing that DAPK negatively regulates migration of vascular cells. Results from a focused RT-PCR array identified matrix metalloproteinase 9 (MMP9) as a gene that is increased in cells depleted of DAPK. MMP9 is an important enzyme that degrades collagen, a component of the extracellular matrix through which smooth muscle cells migrate during atherosclerosis. We found that DAPK regulates phosphorylation of the NF-kappa B transcription factor p65 at serine 536, a modification previously found to correlate with increased nuclear levels and activity of p65. In DAPK-depleted HCASM cells, there was more phosphorylation of p65, which causes increased MMP9 promoter activity. Additional experiments were conducted using transgenic mice in which the DAPK gene has been deleted. By studying these mice, we have determined that under some circumstances DAPK augments maximal MMP9 levels in mouse carotid arteries which have been injured by ligation surgery via other signaling pathways. MMP9 has been previously implicated as a protein that promotes vascular diseases such as atherosclerosis. Our research in identifying DAPK as a regulator of MMP9 expression identifies a new target for treatment of vascular diseases like atherosclerosis.Item Effect of coronary perivascular adipose tissue on vascular smooth muscle function in metabolic syndrome(2013-12-19) Owen, Meredith Kohr; Tune, Johnathan D.; Considine, Robert V.; March, Keith Leonard, 1963-; Sturek, Michael Stephen; Witzmann, F. A. (Frank A.)Obesity increases cardiovascular disease risk and is associated with factors of the “metabolic syndrome” (MetS), a disorder including hypertension, hypercholesterolemia and/or impaired glucose tolerance. Expanding adipose and subsequent inflammation is implicated in vascular dysfunction in MetS. Perivascular adipose tissue (PVAT) surrounds virtually every artery and is capable of releasing factors that influence vascular reactivity, but the effects of PVAT in the coronary circulation are unknown. Accordingly, the goal of this investigation was to delineate mechanisms by which lean vs. MetS coronary PVAT influences vasomotor tone and the coronary PVAT proteome. We tested the hypothesis that MetS alters the functional expression and vascular contractile effects of coronary PVAT in an Ossabaw swine model of the MetS. Utilizing isometric tension measurements of coronary arteries in the absence and presence of PVAT, we revealed the vascular effects of PVAT vary according to anatomical location as coronary and mesenteric, but not subcutaneous adipose tissue augmented coronary artery contractions to KCl. Factors released from coronary PVAT increase baseline tension and potentiate constriction of isolated coronary arteries relative to the amount of adipose tissue present. The effects of coronary PVAT are elevated in the setting of MetS and occur independent of endothelial function. MetS is also associated with substantial alterations in the coronary PVAT proteome and underlying increases in vascular smooth muscle Ca2+ handling via CaV1.2 channels, H2O2-sensitive K+ channels and/or upstream mediators of these ion channels. Rho-kinase signaling participates in the increase in coronary artery contractions to PVAT in lean, but not MetS swine. These data provide novel evidence that the vascular effects of PVAT vary according to anatomic location and are influenced by the MetS phenotype.Item Regulation of SRF Activity by the ATP-dependent Chromatin Remodeling Enzyme, CHD8(2009-03-18T18:39:57Z) Rodenberg, Jennifer Marie; Herring, B. Paul; Gallagher, Patricia J.; Pavalko, Fredrick M.; Skalnik, DavidUnder normal conditions, smooth muscle cells do not replicate, or proliferate, and provide a means of contraction for many internal organs, including blood vessels and the gut. However, under abnormal or disease conditions, such as congenital heart disease and cancer, smooth muscle cells acquire the ability to replicate, to make extracellular matrix proteins and to migrate. Thus, determining how smooth muscle cells regulate these processes is crucial to understanding how the cells can switch between normal and diseased states. Serum response factor (SRF) is a widely expressed protein that plays a key role in the regulation of smooth muscle differentiation, proliferation and migration. It is generally accepted that one way that SRF can distinguish between these functions is through pathway-specific co-factor interactions. A novel SRF co-factor, chromodomain helicase DNA binding protein 8 (CHD8), was originally isolated from a yeast two-hybrid assay. CHD8 is widely expressed in adult tissues including smooth muscle. Data from in vitro binding assays indicate that the N-terminus of CHD8 can interact directly with the MADS domain of SRF. Co-immunoprecipitation assays verified the ability of these two proteins to interact within cells. Adenoviral-mediated shRNA knockdown of CHD8 in smooth muscle cells resulted in statistically significant 10-20% attenuation of expression of SRF-dependent, smooth muscle-specific genes. Similar experiments revealed that knockdown of CHD8 did not affect the SRF-dependent induction of immediate early genes required to promote proliferation. In contrast, knockdown of CHD8 in A10 vascular smooth muscle cells resulted in a marked induction in of apoptosis, characterized by increases in apoptotic markers such as phospho-H2A.X, cleaved PARP and activated caspase-3. These data suggest that CHD8 may play a specific role in modulating SRF’s activity toward anti-apoptotic genes, thereby regulating smooth muscle cell survival.