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- All Subjects: Hypertension
- All Subjects: Endothelial Cells
- Creators: Sweazea, Karen
- Member of: Barrett, The Honors College Thesis/Creative Project Collection
Reducing the amount of error and introduced data variability increases the accuracy of Western blot results. In this study, different methods of normalization for loading differences and data alignment were explored with respect to their impact on Western blot results. GAPDH was compared to the LI-COR Revert total protein stain as a loading control. The impact of normalizing data to a control condition, which is commonly done to align Western blot data distributed over several immunoblots, was also investigated. Specifically, this study addressed whether normalization to a small subset of distinct controls on each immunoblot increases pooled data variability compared to a larger set of controls. Protein expression data for NOX-2 and SOD-2 from a study investigating the protective role of the bradykinin type 1 receptor in angiotensin-II induced left ventricle remodeling were used to address these questions but are also discussed in the context of the original study. The comparison of GAPDH and Revert total protein stain as a loading control was done by assessing their correlation and comparing how they affected protein expression results. Additionally, the impact of treatment on GAPDH was investigated. To assess how normalization to different combinations of controls influences data variability, protein data were normalized to the average of 5 controls, the average of 2 controls, or an average vehicle and the results by treatment were compared. The results of this study demonstrated that GAPDH expression is not affected by angiotensin-II or bradykinin type 1 receptor antagonist R-954 and is a less sensitive loading control compared to Revert total protein stain. Normalization to the average of 5 controls tended to reduce pooled data variability compared to 2 controls. Lastly, the results of this study provided preliminary evidence that R-954 does not alter the expression of NOX-2 or SOD-2 to an expression profile that would be expected to explain the protection it confers against Ang-II induced left ventricle remodeling.
Sphingosine-1-phosphate receptors (S1PRs) and their signaling pathways play an important role in mediating vascular health and function. Upon ligand mediated activation, S1PRs 1-5 couple with diverse heterotrimeric G-protein subunits (Gαi, Gαq/11, Gα12/13), initiating multimodal downstream signaling pathways which result in various physiological outcomes in the vasculature, including cell proliferation and migration, barrier integrity preservation or loss, contraction, and inflammation. Specifically, S1PR2 activation has been linked to endothelial activation, barrier integrity loss, and inflammation, whereas S1PR1 activation contributes to barrier integrity preservation, vasodilation, and anti-inflammatory properties. Although the role of S1PRs during pathophysiological conditions such as acute ischemic stroke is under current investigation, the complete S1PR expression profile in the cerebrovasculature following acute ischemic injury has not yet been investigated. Therefore, the present study was aimed to characterize the expression profiles of S1PRs 1-5 in human brain microvascular endothelial cells (HBMECs) and human brain vascular smooth muscle cells (HBVSMCs) following 3h hypoxia plus glucose deprivation (HGD; in vitro ischemic injury) exposure. At the mRNA level, we observed expression of S1PRs 1-5 in HBVSMCs and S1PRs 1-4 in HBMECs. Under basal conditions, we employed real-time RT-PCR and observed that mRNA levels of S1PR1 were highest in expression followed by S1PR3 then S1PR2 in HBMECs. On the other hand, S1PR3 mRNA was the highest followed by S1PR2 then S1PR1 in HBVSMCs. In HBMECs, HGD exposure increased S1PR1 mRNA and protein levels, but decreased S1PR1 mRNA in HBVSMCs. Similarly, HGD induced increased S1PR3 mRNA in HBMECs and decreased S1PR3 mRNA in HBVSMCs. For S1PR2, HGD did not alter mRNA or protein expression in HBMECs but increased mRNA levels in HBVSMCs. These data suggest that acute exposure to HGD appears to differentially regulate expression of S1PRs in HBMECs and HBVSMCs. The differential expression in S1PRs both basally and following HGD exposure may suggest distinct signaling mechanisms at play within the two cerebrovascular cell types, implicating these receptors as potential therapeutic targets following ischemic injury.