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Item Kinetic vasculogenic analyses of endothelial colony forming cells exposed to intrauterine diabetes(2017-05-11) Varberg, Kaela Margaret; Haneline, Laura S.; Clauss, Matthias A.; Day, Richard N.; Harrington, Maureen A.; Srour, Edward F.Vasculogenesis is a complex process by which endothelial stem and progenitor cells undergo de novo vessel formation. Quantitative assessment of vasculogenesis is a central readout of endothelial progenitor cell functionality. However, current assays lack kinetic measurements. To address this issue, new approaches were developed to quantitatively assess in vitro endothelial colony forming cell (ECFC) network formation in real time. Eight parameters of network structure were quantified using novel Kinetic Analysis of Vasculogenesis (KAV) software. KAV assessment of structure complexity identified two phases of network formation. This observation guided the development of additional vasculogenic readouts, including a tissue cytometry approach to quantify the frequency and localization of dividing ECFCs within cell networks. Additionally, FIJI TrackMate was used to quantify ECFC displacement and speed at the single cell level during network formation. These novel approaches were then applied to determine how intrauterine exposure to maternal type 2 diabetes mellitus (T2DM) impairs fetal ECFC vasculogenesis, and whether increased Transgelin 1 (TAGLN) expression in ECFCs from pregnancies complicated by gestational diabetes (GDM) was sufficient to impair vasculogenesis. Fetal ECFCs exposed to maternal T2DM formed fewer initial network structures, which were not stable over time. Correlation analyses identified that ECFC samples with greater division in branches formed fewer closed network structures and that reductions in ECFC movement decreased structural connectivity. To identify specific cellular mechanisms and signaling pathways altered in ECFCs following intrauterine GDM exposure, these new techniques were also applied in TAGLN expression studies. Similarly, ECFCs from GDM pregnancies and ECFCs overexpressing TAGLN exhibited impaired vasculogenesis and decreased migration. Both ECFCs from GDM pregnancies as well as ECFCs over expressing TAGLN exhibited increased phosphorylation of myosin light chain. Reduction of myosin light chain phosphorylation via Rho kinase inhibition increased ECFC migration; therefore, increased TAGLN was sufficient to impair ECFC vasculogenic function. Overall, identification of these novel phenotypes provides evidence for the molecular mechanisms contributing to aberrant ECFC vasculogenesis. Determining how intrauterine exposure to maternal T2DM and GDM alters fetal ECFC function will enable greater understanding of the chronic vascular pathologies observed in children from pregnancies complicated by diabetes mellitus.Item Transgelin Induces Dysfunction of Fetal Endothelial Colony-Forming Cells From Gestational Diabetic Pregnancies(American Physiological Society, 2018-10-01) Varberg, Kaela M.; Garretson, Rashell O.; Blue, Emily K.; Chu, Chenghao; Gohn, Cassandra R.; Tu, Wanzhu; Haneline, Laura S.; Cellular and Integrative Physiology, School of MedicineFetal exposure to gestational diabetes mellitus (GDM) predisposes children to future health complications including hypertension and cardiovascular disease. A key mechanism by which these complications occur is through the functional impairment of vascular progenitor cells, including endothelial colony-forming cells (ECFCs). Previously, we showed that fetal ECFCs exposed to GDM have decreased vasculogenic potential and altered gene expression. In this study, we evaluate whether transgelin (TAGLN), which is increased in GDM-exposed ECFCs, contributes to vasculogenic dysfunction. TAGLN is an actin-binding protein involved in the regulation of cytoskeletal rearrangement. We hypothesized that increased TAGLN expression in GDM-exposed fetal ECFCs decreases network formation by impairing cytoskeletal rearrangement resulting in reduced cell migration. To determine if TAGLN is required and/or sufficient to impair ECFC network formation, TAGLN was reduced and overexpressed in ECFCs from GDM and uncomplicated pregnancies, respectively. Decreasing TAGLN expression in GDM-exposed ECFCs improved network formation and stability as well as increased migration. In contrast, overexpressing TAGLN in ECFCs from uncomplicated pregnancies decreased network formation, network stability, migration, and alignment to laminar flow. Overall, these data suggest that increased TAGLN likely contributes to the vasculogenic dysfunction observed in GDM-exposed ECFCs, as it impairs ECFC migration, cell alignment, and network formation. Identifying the molecular mechanisms underlying fetal ECFC dysfunction following GDM exposure is key to ascertain mechanistically the basis for cardiovascular disease predisposition later in life.