8 research outputs found

    Protein Phosphatase 1 Beta is Modulated by Chronic Hypoxia and Involved in the Angiogenic Endothelial Cell Migration

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    Background/Aim: Endothelial cell migration is required for physiological angiogenesis, but also contributes to various pathological conditions, including tumour vascularization. The mRNA expression of PP1cĪ², the beta isoform of the catalytic PP1 subunit, was shown to be upregulated in chronic hypoxia. Since hypoxia is a major regulator of angiogenesis, the potential role of PP1cĪ² in angiogenesis was investigated. Methods: We examined PP1cĪ² protein level in pediatric heart following chronic hypoxia and found PP1cĪ² upregulation in cyanotic compared with acyanotic myocardium. By treating HUVEC cells with hypoxia mimicking agent, PP1cĪ² protein level increased with maximum at 8 hours. The effect of PP1cĪ² pharmacological inhibition, knockdown and overexpression, on endothelial cell migration and morphogenesis, was examined using in vitro wound healing scratch assay and endothelial tube formation assay. The PP1cĪ² knockdown effects on F-actin reorganization (phalloidin staining), focal adhesion formation (vinculin) and focal adhesion kinases (FAK) activation, were evaluated by immunocytochemical staining and immunoblotting with specific antibodies. Results: PP1cĪ² knockdown significantly reduces endothelial cell migration, but does not have any significant effect on endothelial tube formation. Endothelial cell migration in the knockdown group is restored to the control level upon consecutive transfection with PP1cĪ² cDNA. PP1cĪ² overexpression does not significantly affect endothelial cell migration. Furthermore, PP1cĪ² knockdown induces profound cytoskeletal reorganization, loss of focal adhesion sites and impairment of focal adhesion kinases (FAK) activation. Conclusions: PP1cĪ² is regulator of endothelial cell migration, which is critical in the angiogenic process. PP1cĪ² inhibition reduces endothelial cell migration through focal adhesion turnover and actin polymerization pathways
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