Project description:Fluid Shear Stress Up-regulates Vascular Endothelial Growth Factor Gene

Project description:The effect of hemodynamic shear stress on endothelial gene expression was investigated in the porcine iliac arteries. Computational fluid dynamics simulations identified three anatomical regions likely to experience high, medium, and low shear stress. The expression of genes in endothelial cells recovered from these regions were assessed using microarray. Keywords: shear stress, endothelial cell gene expression, in vivo

Project description:The effect of hemodynamic shear stress on endothelial gene expression was investigated in the porcine iliac arteries. Computational fluid dynamics simulations identified three anatomical regions likely to experience high, medium, and low shear stress. The expression of genes in endothelial cells recovered from these regions were assessed using microarray. Keywords: shear stress, endothelial cell gene expression, in vivo 11 iliac arteries were obtained from 6 animals, total RNA were extracted from high, medium and low shear region. The expression profiles were compared with a reference RNA using dual channel arrays. Samples with low original RNA quality and low hybridization quality were not included.

Project description:Renal epithelial cells are exposed to mechanical forces due to flow-induced shear stress within the nephrons. We applied RNA sequencing to get a comprehensive overview of fluid-shear regulated genes and pathways in the immortalized renal proximal tubular epithelial cell line. Cells were exposed to laminar fluid shear stress (1.9 dyn/cm2) in a cone-plate device and compared to static controls.

Project description:In order to simulate the effects of shear stress in regions of the vasculature prone to developing atherosclerosis, we subjected human umbilical vein endothelial cells to reversing shear stress, in order to mimic hemodynamic conditions at the wall of the carotid sinus, a site of complex, reversing blood flow and commonly observed atherosclerosis. We compared the effects of reversing shear stress (time-average 1 dyne/cm2, maximum +11 dynes/cm2, minimum -11 dynes/cm2, 1 Hz), arterial steady shear stress (15 dynes/cm2), and low steady shear stress (1 dyne/cm2) in terms of gene expression, cell proliferation, and monocyte adhesiveness. Microarray analysis revealed most differentially expressed genes were similarly regulated by all three shear stress regimens when compared to static culture. Comparisons of the three shear stress regimens to each other allowed identification of 138 genes regulated by low average shear stress and 22 by fluid reversal. Functional assays indicated that low average shear stress induces increased cell proliferation as compared to high shear stress. Reversing shear stress was the only condition that induced monocyte adhesion. Monocyte adhesion was partially inhibited by incubation of the endothelial cells with ICAM-1 blocking antibody. Increased surface heparin sulfate proteoglycan expression was observed in cells exposed to reversing shear stress. When these cells were treated with heparinase III monocyte adhesion was significantly reduced. Our results suggest that low steady shear stress is the major impetus for differential gene expression and cell proliferation, while reversing flow regulates monocyte adhesion.

Project description:Pkd1-/- renal epithelial cells are exposed to mechanical forces due to flow-induced shear stress within the nephrons. We applied RNA sequencing to get a comprehensive overview of fluid-shear regulated genes and pathways in the immortalized Pkd1-/- renal proximal tubular epithelial cell line. Cells were exposed to laminar fluid shear stress (1.9 dyn/cm2) in a cone-plate device and compared to static controls.

Project description:Adhesion formation after flexor tendon repair remains a clinical problem. Early postoperative motion after tendon repair has been demonstrated to reduce adhesion formation while increasing tendon strength. It is hypothesized that during mobilization, tendon cells experience mechanical shear forces that alter their biology in a fashion that reduces scar formation but also activates key genes involved in tendon healing. To test this hypothesis, primary intrinsic tenocyte cultures were established from flexor tendons of 20 Sprague-Dawley rats and sheared at 50 rpm (0.41 Pa) using a cone viscometer for 6 and 12 hours. Total RNA was harvested and compared with time-matched unsheared controls using cDNA microarrays and Northern blot analysis. Microarray analysis demonstrated that mechanical shear stress induced an overall "antifibrotic" expression pattern with decreased transcription of collagen type I and collagen type III. Shear stress down-regulated profibrotic molecules in the platelet-derived growth factor, insulin-like growth factor, and fibroblast growth factor signaling pathways. In addition, shear stress induced an overall decrease in transforming growth factor (TGF)-beta signaling pathway molecules with down-regulation of TGF-beta2, TGF-beta3, TGF-RI, and TGF-RII expression. Moreover, sheared tendon cells increased expression of matrix metalloproteinases and decreased expression of tissue inhibitors of metalloproteinase, an expression pattern consistent with an antifibrotic increase in extracellular matrix degradation. However, up-regulation of genes implicated in tendon healing, specifically, vascular endothelial growth factor-A and several bone morphogenetic proteins. Interestingly, the known mechanoresponsive gene, TGF-beta1, also implicated in tendon healing, was differentially up-regulated by shear stress. Northern blot validation of our results for TGF-beta1, TGF-beta2, TGF-beta3, and collagen type I demonstrated direct correlation with microarray data.

Project description:The lymphatic system removes fluid from the interstitial space and returns it to the blood with a tremendous capacity: during inflammation, lymph flow rates can increase dramatically; however, during chronic lymphedema, there is little or no flow. The ability of lymphatic endothelium to sense and actively regulate this function is unknown, and shear stress is likely a key indicator of lymph flow. We profiled gene expression in human dermal microvascular lymphatic endothelial cells exposed to 0, 2 and 20 dyn/cm2 shear stress as representative of chronic lymphedema, normal, and acute inflammatory conditions, respectively. We found important adaptive responses correlated to multiple aspects of lymphatic function. Importantly, shear stress upregulated intracellular water and solute transporters while decreasing cell-cell adhesion and basement membrane components and increasing cell-matrix interactions. This data indicate that during high loading conditions, both passive and active drainage function increases, while conversely when fluid drainage is blocked, transport function is diminished in the lymphatic endothelium. These data demonstrate the first functional-adaptive response of lymphatic endothelium to flow conditions, thus indicating that the lymphatic endothelium plays an active role in regulating their function. Keywords: Shear stress, dose response, cell type comparison Lymphatic endothelial cells were subjected to 0, 2, or 20 dyn/cm2 shear stress; blood endothelial cells were subjected to 0 or 20 dyn/cm2 shear stress. Four samples were used for each cell type/shear level group for a total of 20 samples. Each sample was independently compared to human universal reference RNA via two-color microarray analysis for a total of 20 arrays. In all cases, the experimental samples were labeled with Cy5 dye while the reference RNA was labeled with Cy3.

Project description:Andrew Koo, David Nordsletten, Renato Umeton, Beracah Yankama, Shiva Ayyadurai, Guillermo García-Cardeña & C. Forbes Dewey. In silico modeling of shear-stress-induced nitric oxide production in endothelial cells through systems biology. Biophysical Journal 104, 10 (2013). Nitric oxide (NO) produced by vascular endothelial cells is a potent vasodilator and an antiinflammatory mediator. Regulating production of endothelial-derived NO is a complex undertaking, involving multiple signaling and genetic pathways that are activated by diverse humoral and biomechanical stimuli. To gain a thorough understanding of the rich diversity of responses observed experimentally, it is necessary to account for an ensemble of these pathways acting simultaneously. In this article, we have assembled four quantitative molecular pathways previously proposed for shear-stress-induced NO production. In these pathways, endothelial NO synthase is activated 1), via calcium release, 2), via phosphorylation reactions, and 3), via enhanced protein expression. To these activation pathways, we have added a fourth, a pathway describing actual NO production from endothelial NO synthase and its various protein partners. These pathways were combined and simulated using CytoSolve, a computational environment for combining independent pathway calculations. The integrated model is able to describe the experimentally observed change in NO production with time after the application of fluid shear stress. This model can also be used to predict the specific effects on the system after interventional pharmacological or genetic changes. Importantly, this model reflects the up-to-date understanding of the NO system, providing a platform upon which information can be aggregated in an additive way.

Project description:Andrew Koo, David Nordsletten, Renato Umeton, Beracah Yankama, Shiva Ayyadurai, Guillermo García-Cardeña & C. Forbes Dewey. In silico modeling of shear-stress-induced nitric oxide production in endothelial cells through systems biology. Biophysical Journal 104, 10 (2013). Nitric oxide (NO) produced by vascular endothelial cells is a potent vasodilator and an antiinflammatory mediator. Regulating production of endothelial-derived NO is a complex undertaking, involving multiple signaling and genetic pathways that are activated by diverse humoral and biomechanical stimuli. To gain a thorough understanding of the rich diversity of responses observed experimentally, it is necessary to account for an ensemble of these pathways acting simultaneously. In this article, we have assembled four quantitative molecular pathways previously proposed for shear-stress-induced NO production. In these pathways, endothelial NO synthase is activated 1), via calcium release, 2), via phosphorylation reactions, and 3), via enhanced protein expression. To these activation pathways, we have added a fourth, a pathway describing actual NO production from endothelial NO synthase and its various protein partners. These pathways were combined and simulated using CytoSolve, a computational environment for combining independent pathway calculations. The integrated model is able to describe the experimentally observed change in NO production with time after the application of fluid shear stress. This model can also be used to predict the specific effects on the system after interventional pharmacological or genetic changes. Importantly, this model reflects the up-to-date understanding of the NO system, providing a platform upon which information can be aggregated in an additive way.