Browsing by Author "Okyere, Benjamin"

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    Endothelial-Specific EphA4 Negatively Regulates Native Pial Collateral Formation and Re-Perfusion following Hindlimb Ischemia
    Okyere, Benjamin; Giridhar, Kaavya; Hazy, Amanda; Chen, Miao; Keimig, David; Bielitz, Robert C.; Xie, Hehuang; He, Jia-Qiang; Huckle, William R.; Theus, Michelle H. (PLOS, 2016-07-28)
    Leptomeningeal anastomoses play a critical role in regulating vascular re-perfusion following obstruction, however, the mechanisms regulating their development remains under investingation. Our current findings indicate that EphA4 receptor is a novel negative regulator of collaterogenesis. We demonstrate that EphA4 is highly expressed on pial arteriole collaterals at post-natal day (P) 1 and 7, then significantly reduced by P21. Endothelial cell (EC)-specific loss of EphA4, EphA4f/f/Tie2::Cre (KO), resulted in an increase in the density but not diameter of pial collaterals compared to WT mice. ECs isolated from KO mice displayed a 3-fold increase in proliferation, enhanced migration, tube formation and elevated levels of phospho(p)-Akt compared to WT ECs. Attenuating p-Akt, using LY294002, reduced the proliferative and migration effects in the KO ECs. RNAseq analysis also revealed altered expression patterns for genes that regulate cell proliferation, vascular development, extracellular matrix and immune-mediate responses, namely MCP-1, MMP2 and angiopoietin-1. Lastly, we show that induction of hindlimb ischemia resulted in accelerated re-perfusion, collateral remodeling and reduced tissue necrosis in the absence of ECspecific EphA4 compared to WT mice. These findings demonstrate a novel role for EphA4 in the early development of the pial collateral network and suggests a role in regulating vascular remodeling after obstruction.
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    Eph-mediated restriction of cerebrovascular arteriogenesis
    Okyere, Benjamin (Virginia Tech, 2019-04-26)
    Stroke is a leading cause of morbidity and long-term neurological disability in the U.S. Ischemic stroke, which accounts for approximately 90% of all strokes, is the result of an occlusion in the arteriole cerebrovascular network. No effective treatment options exist to provide neuroprotection from occlusion, and limited success has been seen clinically when attempting to restore blood flow to vulnerable neural tissue regions. Enhancement of pial collateral remodeling (Arteriogenesis) has recently been shown to improve blood flow and mitigate neural tissue damage following stroke (1-3). Arteriogenesis is the remodeling of pre-existing arteriole vessel which are able to re-route blood to blood-deprived regions of tissue. Arteriogenesis requires endothelial cell (EC) and smooth muscle cell proliferation, extracellular matrix degradation and recruitment of circulating bone marrow-derived cells (4-6). Unlike spouting angiogenesis, which requires weeks following occlusion to develop, arteriogenesis begins as early as 24-48hrs post-stroke (7, 8) and can expeditiously enhance blood flow to ischemic regions, making it an attractive target for therapeutic intervention. Our preliminary studies, in an EphA4 global knockout mouse model, indicated that EphA4 receptor tyrosine kinase severely limits pial arteriole collateral formation. The preliminary work also showed that activation of EC EphA4 receptor in vitro inhibited vascular formation. Additionally, ECs lining the collateral vessel have been shown to play a role in collateral remodeling (9). Taken together, the objective of this dissertation was to elucidate the cell autonomous role of the EphA4 receptor and given the central role of the EC in collateral remodeling, we postulated that EphA4 receptor on ECs the limits pial collateral formations. Using a cell-specific loss-of-function approach, we tested the hypothesis that EC-specific EphA4 plays an important role in pial collateral development and remodeling after induced stroke. The results from this dissertation show that (1) EphA4 expression on ECs suppress the formation of pial collaterals during development and limits EC growth via suppression of p-Akt in vitro (2) EC-specific EphA4 ablation leads to increased collateral remodeling, enhanced blood flow recovery, tissue protection and improved neurological behavioral outcomes after stroke and (3) Mechanistically, EphA4 limits pial collateral remodeling via attenuation of the Tie2/Angiopoietin-2 signaling pathway. The work presented in this dissertation demonstrate that EphA4 can be targeted therapeutically to increase pial collateral remodeling to alleviate neurological deficits after ischemic stroke.
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    Evaluation of the actin architecture in dysplastic megakaryocytes expressing the NUP98-HOXD13 leukemic fusion gene
    Okyere, Benjamin (Virginia Tech, 2013-08-30)
    Some myelodysplastic syndrome (MDS) patients present with macrothrombocytopenia due to impaired megakaryocyte (MK) differentiation. Transgenic mice that express the NUP98-HOXD13 (NHD13) fusion gene is a model for MDS and recapitulates the key features of MDS. The study investigated the hypothesis that expression of NHD13 disrupts actin architecture during MK differentiation leading to macrothrombocytopenia. To test the hypothesis, sternums were stained with hematoxylin and eosin, and evaluated by light microscopy to analyze MK morphology in vivo. NHD13 bone marrow (BM) contained many dysplastic MK. BM from wild type (WT) and NHD13 mice were also flushed, cultured in media supplemented with thrombopoietin only or with estrogen to induce proplatelet formation, and MK harvested after 5 days. Harvested MK and BM cores were processed and analyzed by transmission electron microscopy (TEM) to detail the ultrastructural features. TEM of MK revealed that NHD13 leads to formation of an irregular demarcation membrane system and fewer proplatelets. Cultured WT and NHD13 MK were also cytospun onto glass slides, labeled with fluorescent-tagged F-actin, α/β-tubulin and myosin IIa, and their cytoskeleton compared. Interestingly WT MK had actin either distributed evenly or predominantly in the periphery of the cytoplasm, NHD13 MK displayed only the former phenotype. Additionally, proplatelets lacked actin cytoplasmic extensions. The results from the present thesis demonstrate actin expression and architecture are impaired in dysplastic MK expressing the NHD13 leukemic fusion gene and leads to macrothromcytopenia. Understanding the molecular mechanisms of abnormal MK differentiation in MDS is important as many MDS patients die of hemorrhagic complications.