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Zhang, Ying-Yi

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Zhang

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Ying-Yi

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Zhang, Ying-Yi
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    Gasdermin E suppresses tumour growth by activating anti-tumour immunity
    (Springer Science and Business Media LLC, 2020-03-11) Zhang, Zhibin; Zhang, Ying-Yi; Xia, Shiyu; Junqueira, Caroline; Sengupta, Satyaki; Wu, Hao; Lieberman, Judy
    Cleavage of the gasdermins to produce a pore-forming N-terminal fragment causes inflammatory death (pyroptosis)1. Caspase-3 cleaves gasdermin E (GSDME, also known as DFNA5), mutated in familial aging-related hearing loss2, which converts noninflammatory apoptosis to pyroptosis in GSDME-expressing cells3-5. GSDME expression is suppressed in many cancers and reduced GSDME is associated with decreased breast cancer survival2,6, suggesting GSDME might be a tumor suppressor. Here we show reduced GSDME function of 20 of 22 tested cancer-associated mutations. Gsdme knockout in GSDME-expressing tumors enhances, while ectopic expression in Gsdme-repressed tumors inhibits, tumor growth. Tumor suppression is mediated by cytotoxic lymphocyte killing since it is abrogated in perforin-deficient or killer lymphocyte-depleted mice. GSDME expression enhances tumor-associated macrophage phagocytosis and the number and functions of tumor-infiltrating NK and CD8+ T lymphocytes. Killer cell granzyme B also activates caspase-independent pyroptosis in target cells by directly cleaving GSDME at the same site as caspase-3. Non-cleavable or pore-defective GSDME are not tumor suppressive. Thus, tumor GSDME is a tumor suppressor by activating pyroptosis, which enhances anti-tumor immunity.
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    Risk Stratification by Regadenoson Stress Magnetic Resonance Imaging in Patients With Known or Suspected Coronary Artery Disease
    (Elsevier BV, 2014) Abbasi, Siddique Akbar; Heydari, Bobak; Shah, Ravi; Murthy, Venkatesh; Zhang, Ying-Yi; Blankstein, Ron; Steigner, Michael; Jerosch-Herold, Michael; Kwong, Raymond
    The aim of this study was to investigate the association between major adverse cardiovascular events (MACEs) and inducible ischemia on regadenoson cardiac magnetic resonance (CMR) myocardial perfusion imaging (MPI) performed at 3.0 T. Regadenoson stress CMR MPI is increasingly used to assess patients with suspected ischemia; however, its value in patient prognostication and risk reclassification is only emerging. A total of 346 patients with suspected ischemia who were referred for regadenoson CMR were studied. The prognostic association of presence of inducible ischemia by CMR with MACEs was determined. In addition, we assessed the extent of net reclassification improvement by CMR beyond a clinical risk model. There were 52 MACEs during a median follow-up period of 1.9 years. Patients with inducible ischemia were fourfold more likely to experience MACEs (hazard ratio, 4.14, 95% confidence interval 2.37 to 7.24, p <0.0001). In the best overall model, presence of inducible ischemia conferred a 2.6-fold increased hazard for MACEs adjusted to known clinical risk markers (adjusted hazard ratio 2.59, 95% confidence interval 1.30 to 5.18, p = 0.0069). Patients with no inducible ischemia experienced a low rate of cardiac death and myocardial infarction (0.6% per patient-year), whereas those with inducible ischemia had an annual event rate of 3.2%. Net reclassification improvement across risk categories (low <5%, intermediate 5% to 10%, and high >10%) by CMR was 0.29 (95% confidence interval 0.15 to 0.44), and continuous net reclassification improvement was 0.58. In conclusion, in patients with clinical suspicion of myocardial ischemia, regadenoson stress CMR MPI provides robust risk stratification. CMR MPI negative for ischemia was associated with a very low annual rate of hard cardiac events. In addition, CMR MPI provides effective risk reclassification in a substantial proportion of patients.
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    Incorporation of heparin-binding proteins into preformed dextran sulfate-chitosan nanoparticles
    (Dove Medical Press, 2016) Zaman, Paula; Wang, Julia; Blau, Adam; Wang, Weiping; Li, Tina; Kohane, Daniel; Loscalzo, Joseph; Zhang, Ying-Yi
    Incorporation of proteins into dextran sulfate (DS)-chitosan (CS) nanoparticles (DSCS NPs) is commonly performed using entrapment procedures, in which protein molecules are mixed with DS and CS until particle formation occurs. As DS is an analog of heparin, the authors examined whether proteins could be directly incorporated into preformed DSCS NPs through a heparin binding domain-mediated interaction. The authors formulated negatively-charged DSCS NPs, and quantified the amount of charged DS in the outer shell of the particles. The authors then mixed the DSCS NPs with heparin-binding proteins (SDF-1α, VEGF, FGF-2, BMP-2, or lysozyme) to achieve incorporation. Data show that for DSCS NPs containing 100 nmol charged glucose sulfate units in DS, up to ~1.5 nmol of monomeric or ~0.75 nmol of dimeric heparin-binding proteins were incorporated without significantly altering the size or zeta potential of the particles. Incorporation efficiencies of these proteins were 95%–100%. In contrast, serum albumin or serum globulin showed minimal incorporation (8% and 4%, respectively) in 50% physiological saline, despite their large adsorption in water (80% and 92%, respectively). The NP-incorporated SDF-1α and VEGF exhibited full activity and sustained thermal stability. An in vivo aerosolization study showed that NP-incorporated SDF-1α persisted in rat lungs for 72 h (~34% remaining), while free SDF-1α was no longer detectable after 16 h. As many growth factors and cytokines contain heparin-binding sites/domains, incorporation into preformed DSCS NPs could facilitate in vivo applications of these proteins.
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    Increasing Glucose 6-Phosphate Dehydrogenase Activity Restores Redox Balance in Vascular Endothelial Cells Exposed to High Glucose
    (Public Library of Science, 2012) Zhang, Zhaoyun; Yang, Zhihong; Zhu, Bo; Hu, Ji; Liew, Chong-Wee; Leopold, Jane; Handy, Diane; Loscalzo, Joseph; Stanton, Robert; Zhang, Ying-Yi
    Previous studies have shown that high glucose increases reactive oxygen species (ROS) in endothelial cells that contributes to vascular dysfunction and atherosclerosis. Accumulation of ROS is due to dysregulated redox balance between ROS-producing systems and antioxidant systems. Previous research from our laboratory has shown that high glucose decreases the principal cellular reductant, NADPH by impairing the activity of glucose 6-phosphate dehydrogenase (G6PD). We and others also have shown that the high glucose-induced decrease in G6PD activity is mediated, at least in part, by cAMP-dependent protein kinase A (PKA). As both the major antioxidant enzymes and NADPH oxidase, a major source of ROS, use NADPH as substrate, we explored whether G6PD activity was a critical mediator of redox balance. We found that overexpression of G6PD by pAD-G6PD infection restored redox balance. Moreover inhibition of PKA decreased ROS accumulation and increased redox enzymes, while not altering the protein expression level of redox enzymes. Interestingly, high glucose stimulated an increase in NADPH oxidase (NOX) and colocalization of G6PD with NOX, which was inhibited by the PKA inhibitor. Lastly, inhibition of PKA ameliorated high glucose mediated increase in cell death and inhibition of cell growth. These studies illustrate that increasing G6PD activity restores redox balance in endothelial cells exposed to high glucose, which is a potentially important therapeutic target to protect ECs from the deleterious effects of high glucose.