Jeffrey F. Bray scite author profile

Jeffrey F. Bray

3Publications

3Citation Statements Received

34Citation Statements Given

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Texas A&M University

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Endothelial nitric oxide synthase protein distribution and nitric oxide production in endothelial cells along the coronary vascular tree

Heaps

Bray

McIntosh

et al. 2019

Microvascular Research

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Objective: Freshly isolated endothelial cells from both conduit arteries and microvasculature were used to test the hypothesis that eNOS protein content and nitric oxide production in coronary endothelial cells increases with vessel radius.Methods: Porcine hearts were obtained from a local abattoir. Large and small arteries as well as arterioles were dissected free of myocardium and homogenized as whole vessels. Additionally, endothelial cells were isolated from both conduit arteries and left ventricular myocardium by tissue digestion with collagenase, followed by endothelial cell isolation using biotinylated-anti-CD31 and streptavidin-coated paramagnetic beads. Purity of isolated endothelial cells was confirmed by immunofluorescence and immunoblot. Results:In whole vessel lysate, immunoblot analysis revealed that protein content for eNOS was greater in arterioles compared to small and large arteries. Nitric oxide metabolites (nitrite plus nitrate; NOx) levels measured from whole vessel lysate decreased as vessel size increased, with both arterioles and small arteries displaying significantly greater NOx content than conduit. Consistent with our hypothesis, both eNOS protein level and NOx were significantly greater in endothelial cells isolated from conduit arteries compared with those from coronary microvasculature. Furthermore, confocal microscopy revealed that eNOS protein was present in all conduit and microvascular endothelial cells, although eNOS staining was less intense in microvascular cells than those of conduit artery. Conclusions:These findings demonstrate increased eNOS protein and NOx content in endothelial cells of conduit arteries compared with the microcirculation and underscore the importance of comparing endothelial-specific molecules in freshly isolated endothelial cells, rather than whole lysate of different sized vessels.

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Exercise Training Restores K⁺ Channel Contributions to Hydrogen Peroxide‐Mediated Dilation Independent of PKG Dimerization in Collateral‐Dependent Coronary Arterioles

Johnson¹,

Ramirez²,

Bray³

et al. 2020

The FASEB Journal

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In coronary artery disease (CAD), the ability of the coronary circulation to deliver blood to meet oxygen demands of the heart is often impaired. Exercise training has been established to mitigate the negative effects of CAD by preserving reactivity of the coronary microcirculation. We have previously reported that exercise increases the contribution of hydrogen peroxide (H2O2) to enhanced endothelium‐dependent vasodilation in collateral‐dependent coronary arterioles. Others have shown that cGMP‐dependent protein kinase (PKG) can be activated via oxidation by H2O2, inducing dimer formation. The PKG dimer has been shown to act on substrates, such as K+ channels, to contribute to vascular smooth muscle relaxation and vasodilation. In the current study, we tested the hypothesis that exercise training‐enhanced H2O2‐induced vasodilation is mediated through enhanced PKG dimerization and subsequent activation of Kv and BKca channels in coronary arterioles isolated from ischemic myocardium. An ameroid occluder was surgically placed on the proximal left circumflex coronary artery of female Yucatan miniature swine to induce gradual occlusion while the left anterior descending artery was left unoccluded to serve as a control. Eight weeks postoperatively, pigs were assigned to sedentary (n=14) or exercise training (n=13; progressive treadmill training for 13 weeks) regimens. Coronary arterioles (75–150 μm) and small arteries (250–400 um) were isolated from myocardium of the left circumflex and left anterior descending regions. Immunoblot analysis indicated that H2O2 induced PKG dimer formation in both porcine coronary arterioles and small arteries. Chronic coronary artery occlusion appeared to diminish H2O2‐mediated PKG dimer formation in collateral‐dependent arterioles and the reduced dimerization persisted with exercise training. H2O2‐mediated vasodilation tended to be impaired in arterioles isolated from the collateral‐dependent regions of sedentary pigs and was partially restored with exercise training. It also appears that both Kv and BKCa channels contributed to H2O2‐mediated dilation after exercise training. Our data demonstrate that H2O2 stimulates PKG dimer formation in both porcine coronary arterioles and small arteries. Contrary to our hypothesis, H2O2‐induced PKG dimerization is not enhanced by exercise training in either nonoccluded or collateral‐dependent arterioles. However, both Kv and BKCa channels appear to contribute to exercise training‐enhanced H2O2‐mediated dilation in collateral‐dependent coronary arterioles. Support or Funding Information National Institutes of Health R01‐HL139903

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Endothelial nitric oxide synthase protein distribution in endothelial cells along the coronary vascular tree

et al. 2016

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Previous investigations have compared the levels of endothelial nitric oxide synthase (eNOS) protein among different branch orders of the coronary arterial tree. In these studies, eNOS protein levels were determined in whole vessels and thus were likely influenced by variable amounts of non‐endothelial cell types in the lysate as vessel wall thickness varied. For the current study, we isolated endothelial cells from both coronary conduit arteries and microvasculature to test the hypothesis that the content of eNOS protein remains similar in coronary endothelial cells regardless of vessel radius. Porcine hearts were obtained from a local abattoir and transported to the lab in iced Krebs solution. Large (conduit) and small arteries as well as arterioles were dissected free of myocardium and homogenized as whole vessels. Additionally, endothelial cells were isolated from both conduit arteries and left ventricular myocardium by mincing the tissue into small pieces, digesting with collagenase, followed by endothelial cell isolation using biotinylated‐anti‐CD31 and streptavidin‐coated paramagnetic beads. Purity of isolated coronary endothelial cells was confirmed by immunofluorescence and immunoblot. In whole vessel lysate, immunoblot analysis revealed that protein content for eNOS was significantly greater in arterioles compared to small arteries and large arteries. In contrast, eNOS protein levels in endothelial cells isolated from coronary microvasculature were not significantly different from those isolated from large conduit arteries. Taken together, these data indicate that endothelial cell eNOS protein content is comparable regardless of whether endothelial cells are isolated from the coronary microcirculation or conduit arteries. Furthermore, use of whole vessel lysate among different branch orders to compare levels of endothelium‐specific proteins may be unsuitable due to variable contamination by other cell types.Support or Funding InformationNIH R01‐HL064931

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Jeffrey F. Bray

Endothelial nitric oxide synthase protein distribution and nitric oxide production in endothelial cells along the coronary vascular tree

Exercise Training Restores K⁺ Channel Contributions to Hydrogen Peroxide‐Mediated Dilation Independent of PKG Dimerization in Collateral‐Dependent Coronary Arterioles

Endothelial nitric oxide synthase protein distribution in endothelial cells along the coronary vascular tree

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Jeffrey F. Bray

Endothelial nitric oxide synthase protein distribution and nitric oxide production in endothelial cells along the coronary vascular tree

Exercise Training Restores K+ Channel Contributions to Hydrogen Peroxide‐Mediated Dilation Independent of PKG Dimerization in Collateral‐Dependent Coronary Arterioles

Endothelial nitric oxide synthase protein distribution in endothelial cells along the coronary vascular tree

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Exercise Training Restores K⁺ Channel Contributions to Hydrogen Peroxide‐Mediated Dilation Independent of PKG Dimerization in Collateral‐Dependent Coronary Arterioles