Browsing by Subject "Substrate"

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    Effect of shear stress and substrate on endothelial DAPK expression, caspase activity, and apoptosis
    (Springer Nature, 2013-01-10) Rennier, Keith; Ji, Julie Y.; Biomedical Engineering, Purdue School of Engineering and Technology
    Background: In the vasculature, misdirected apoptosis in endothelial cells leads to pathological conditions such as inflammation. Along with biochemical and molecular signals, the hemodynamic forces that the cells experience are also important regulators of endothelial functions such as proliferation and apoptosis. Laminar shear stress inhibits apoptosis induced by serum depletion, oxidative stress, and tumor necrosis factor α (TNFα). Death associated protein kinase (DAPK) is a positive regulator of TNFα induced apoptotic pathway. Here we investigate the effect of shear stress on DAPK in endothelial cells on glass or silicone membrane substrate. We have already shown a link between shear stress and DAPK expression and apoptosis in cells on glass. Here we transition our study to endothelial cells on non-glass substrates, such as flexible silicone membrane used for cyclic strain studies. Results: We modified the classic parallel plate flow chamber to accommodate silicone membrane as substrate for cells, and validated the chamber for cell viability in shear stress experiments. We found that adding shear stress significantly suppressed TNFα induced apoptosis in cells; while shearing cells alone also increased apoptosis on either substrate. We also found that shearing cells at 12 dynes/cm2 for 6 hours resulted in increased apoptosis on both substrates. This shear-induced apoptosis correlated with increased caspase 3/7 activities and DAPK expression and activation via dephosphorylation of serine 308. Conclusion: These data suggest that shear stress induced apoptosis in endothelial cells via increased DAPK expression and activation as well as caspase-3/7 activity. Most in vitro shear stress studies utilize the conventional parallel plate flow chamber where cells are cultured on glass, which is much stiffer than what cells encounter in vivo. Other mechanotransduction studies have utilized the flexible silicone membrane as substrate, for example, in cyclic stretch studies. Thus, this study bridges the gap between shear stress studies on cells plated on glass to studies on different stiffness of substrates or mechanical stimulation such as cyclic strain. We continue to explore the mechanotransduction role of DAPK in endothelial apoptosis, by using substrates of physiological stiffness for shear stress studies, and by using silicone substrate in cyclic stretch devices.
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    Structural basis for regulated inhibition and substrate selection in yeast glycogen synthase
    (2017-02) Mahalingan, Krishna Kishore; Hurley, Thomas D.; Elmendorf, Jeffrey; Georgiadis, Millie M.; Roach, Peter J.
    Glycogen synthase (GS) is the rate limiting enzyme in the synthesis of glycogen. Eukaryotic GS catalyzes the transfer of glucose from UDP-glucose to the non-reducing ends of glycogen and its activity is negatively regulated by phosphorylation and allosterically activated by glucose-6-phosphate (G6P). A highly conserved cluster of six arginine residues on the C-terminal domain controls the responses toward these opposing signals. Previous studies had shown that tetrameric enzyme exists in three conformational states which are linked to specific structural changes in the regulatory helices that carry the cluster of arginines. These helices are found opposite and anti-parallel to one another at one of the subunit interfaces. The binding of G6P beneath the regulatory helices induces large scale conformational changes which open up the catalytic cleft for better substrate access. We solved the crystal structure of the enzyme in its inhibited state and found that the tetrameric and regulatory interfaces are more compacted compared to other states. The structural consequence of the tighter interfaces within the inhibited state of the tetramer is to lower the ability of glycogen chains to access to the catalytic cleft. Based on these observations, we developed a novel regulatory feature in yeast GS by substituting two of its conserved arginine residues on the regulatory helix with cysteines that permits its activity to be controlled by reversible oxidation/reduction of the cysteine residues which mimics the effects of reversible phosphorylation. In addition to defining the structural changes that give rise to the inhibited states, we also used X-ray crystallography to define the mechanism by which the enzyme discriminates between different UDP-sugar donors to be used as substrates in the catalytic mechanism of yeast GS. We found that only donor substrates can adopt the catalytically favorable bent conformation for donor transfer to a growing glycogen chain.