Project description:Laminar shear stress due to constant blood flow is known to play a critical role in maintaining vascular health. In contrast, endothelial cell senescence appears to be closely associated with the incidence of vascular disorder. In an attempt to identify functional biomarkers for age-related vascular health/disease, the present study investigated differential gene expression of young and senescent human umbilical vein endothelial cells (HUVECs) under static and laminar shear stress. We used a cDNA microarray method to compare gene expression profiles of young and senescent HUVECs under static and laminar shear stress conditions. Experiment Overall Design: Senescent cells were prepared by continuous subculture in vitro, and a cone-and-plate device was used to impose laminar shear stress onto cells. Young and senescent cells were exposed to laminar shear stress or maintained under static conditions. Total mRNA was extracted and gene expression profiles were analyzed by cDNA microarray.

Project description:Laminar shear stress due to constant blood flow is known to play a critical role in maintaining vascular health. In contrast, endothelial cell senescence appears to be closely associated with the incidence of vascular disorder. In an attempt to identify functional biomarkers for age-related vascular health/disease, the present study investigated differential gene expression of young and senescent human umbilical vein endothelial cells (HUVECs) under static and laminar shear stress. We used a cDNA microarray method to compare gene expression profiles of young and senescent HUVECs under static and laminar shear stress conditions. Keywords: stress response, age state analysis

Project description:Transcription profiling by array of human young and senescent HUVECs under static and laminar shear stress conditions

Project description:Laminar shear stress (LSS) suppresses endothelial inflammation and protects the arteries from atherosclerosis. Circular RNAs (circRNAs) are powerful regulators of vascular homeostasis and atherosclerosis; however, their roles in mediating the effects of LSS remain unexplored. To identify the changes in circRNA expression patterns after shear stress stimulation, we conducted circRNA microarray analysis using RNA extracted from HUVECs cultured for 24 h under static or LSS conditions.

Project description:Giantsos-Adams2013 - Growth of glycocalyx under static conditions This model is described in the article: Heparan Sulfate Regrowth Profiles Under Laminar Shear Flow Following Enzymatic Degradation. Giantsos-Adams KM, Koo AJ, Song S, Sakai J, Sankaran J, Shin JH, Garcia-Cardena G, Dewey CF. Cell Mol Bioeng 2013 Jun; 6(2): 160-174 Abstract: The local hemodynamic shear stress waveforms present in an artery dictate the endothelial cell phenotype. The observed decrease of the apical glycocalyx layer on the endothelium in atheroprone regions of the circulation suggests that the glycocalyx may have a central role in determining atherosclerotic plaque formation. However, the kinetics for the cells' ability to adapt its glycocalyx to the environment have not been quantitatively resolved. Here we report that the heparan sulfate component of the glycocalyx of HUVECs increases by 1.4-fold following the onset of high shear stress, compared to static cultured cells, with a time constant of 19 h. Cell morphology experiments show that 12 h are required for the cells to elongate, but only after 36 h have the cells reached maximal alignment to the flow vector. Our findings demonstrate that following enzymatic degradation, heparan sulfate is restored to the cell surface within 12 h under flow whereas the time required is 20 h under static conditions. We also propose a model describing the contribution of endocytosis and exocytosis to apical heparan sulfate expression. The change in HS regrowth kinetics from static to high-shear EC phenotype implies a differential in the rate of endocytic and exocytic membrane turnover. This model is hosted on BioModels Database and identified by: MODEL1609100001. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Giantsos-Adams2013 - Growth of glycocalyx under static conditions This model is described in the article: Heparan Sulfate Regrowth Profiles Under Laminar Shear Flow Following Enzymatic Degradation. Giantsos-Adams KM, Koo AJ, Song S, Sakai J, Sankaran J, Shin JH, Garcia-Cardena G, Dewey CF. Cell Mol Bioeng 2013 Jun; 6(2): 160-174 Abstract: The local hemodynamic shear stress waveforms present in an artery dictate the endothelial cell phenotype. The observed decrease of the apical glycocalyx layer on the endothelium in atheroprone regions of the circulation suggests that the glycocalyx may have a central role in determining atherosclerotic plaque formation. However, the kinetics for the cells' ability to adapt its glycocalyx to the environment have not been quantitatively resolved. Here we report that the heparan sulfate component of the glycocalyx of HUVECs increases by 1.4-fold following the onset of high shear stress, compared to static cultured cells, with a time constant of 19 h. Cell morphology experiments show that 12 h are required for the cells to elongate, but only after 36 h have the cells reached maximal alignment to the flow vector. Our findings demonstrate that following enzymatic degradation, heparan sulfate is restored to the cell surface within 12 h under flow whereas the time required is 20 h under static conditions. We also propose a model describing the contribution of endocytosis and exocytosis to apical heparan sulfate expression. The change in HS regrowth kinetics from static to high-shear EC phenotype implies a differential in the rate of endocytic and exocytic membrane turnover. This model is hosted on BioModels Database and identified by: MODEL1609100001. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Many studies have characterized the results of shear stress changes on cultured endothelial cells in different bioreactor systems. However it is still unclear how an invasive intervention like stent procedure may influence the transcriptional response of endothelium. To study the simultaneous effects of shear stress changes and stent application on endothelial gene expression, we have used an experimental apparatus of laminar flow bioreactor (LFB) system with human cultured endothelial cells exposed or not exposed to stent procedure with different flow conditions. Microarray analysis was evaluated in each experimental protocol. HUVECs (2nd and 5th passage) covered on Thermanox slides were submitted to static, low and physiological (0, 1, 5 and 10 dyne/cm2) shear stress in absence (AS) or presence (PS) of stent in LFB system for 24h. Affymetryx analysis has been performed in duplicate by Consortium for Genomic Technologies (Cogentech; Milan, Italy)

Project description:HUVECs cultured under normal or high laminar shear stress

Project description:The goal of this study was to identify gene signatures in HUVECs exposed to atheroprone low laminar shear stress (LSS) or atheroprotective high laminar shear stress (HSS). The obtained data was used to verify that HSS and LSS application induces gene expression patterns similar to more complex pulsatile and oscillatory flow, respectively.

Project description:To profile shear stress-regulated endothelial transcriptomes, we performed RNA-seq with HUVECs subjected to different shear flow conditions, including atheroprotective pulsatile shear (PS, 12±4 dyn/cm2) and atheroprone oscillatory shear (OS, 0.5±4 dyn/cm2), or kept as static control (ST) for four time periods (1, 4, 12 and 24 hours)