Project description:While the salutary effects of exercise training on conduit artery endothelial cells have been reported in animals and humans with cardiovascular risk factors or disease, whether a healthy endothelium is alterable with exercise training is less certain. The purpose of this study was to evaluate the impact of exercise training on transcriptional profiles in normal endothelial cells using a genome-wide microarray analysis. Brachial and internal mammary endothelial gene expression was compared between a group of healthy pigs that exercise-trained for 16-20 weeks (n=8) and a group that remained sedentary (n=8). We found that a total of 130 genes were up regulated and 84 genes down regulated in brachial artery endothelial cells with exercise training. In contrast, a total of 113 genes were up regulated and 31 genes down regulated in internal mammary artery endothelial cells (>1.5-fold and false discovery rate<15%). Although there was an overlap of 66 genes (59 up regulated and 7 down regulated with exercise training) between the brachial and internal mammary arteries, the identified endothelial gene networks and biological processes influenced by exercise training were distinctly different between the brachial and internal mammary arteries. These data indicate that a healthy endothelium is indeed responsive to exercise training and support the concept that the influence of physical activity on endothelial gene expression is not homogenously distributed throughout the vasculature. Brachial and internal mammary endothelial gene expression was compared between a group of healthy pigs that exercise-trained for 16-20 weeks (n=8) and a group that remained sedentary (n=8). The arteries were taken from the same animals, and after quality assessment, so there were 29 total arrays (15 unique pigs), 14 with an array for both the brachial artery and the internal mammary artery (IMA), and the remaining 1 having only brachial. One pig had bad RNA quality and is missing from both IMA and brachical. Therefore, there were 15 IMA (7 SED, 8 EX) and 14 brachial arrays (7 SED, 7 EX) that were used in this study.

Project description:Currently, it is well established that human endothelial cells (ECs) are characterised by a significant heterogeneity between distinct blood vessels, e.g., arteries, veins, capillaries, and lymphatic vessels. Further, even ECs belonging to the same lineage but grown under different flow patterns (e.g., laminar and oscillatory or turbulent flow) ostensibly have distinct molecular profiles defining their physiological behaviour. Human coronary artery endothelial cells (HCAEC) and human internal thoracic artery endothelial cells (HITAEC) represent two cell lines inhabiting atheroprone and atheroresistant blood vessels (coronary artery and internal thoracic artery, respectively). Resistance of the internal mammary artery to atherosclerosis has been largely attributed to the protective phenotype of HITAEC which reportedly produce higher amounts of vasodilators including nitric oxide (NO) through the respective signaling pathways. However, this hypothesis has not been adequately addressed hitherto as proteomic profiling of HCAEC and HITAEC in a head-to-head comparison setting has not been performed.

Project description:The age groups were used to investigate how gene expression differences between the brachial and the femoral artery effect the heterogeneous atherosclerotic disease initiation and progression. Total RNA was isolated from brachial and femoral arteries of four one week, six one year, and five two year old Rapacz HC swine.

Project description:Coronary artery disease (CAD) is a leading cause of death in women. Although exercise mitigates CAD, the mechanisms by which exercise impacts epicardial adipose tissue (EAT) are unknown. We hypothesized that exercise promotes an anti-inflammatory microenvironment in EAT from female pigs. Female Yucatan pigs (n=7) were assigned to sedentary (SED) or exercise (EX) treatments and coronary arteries were occluded (O vs N) with an ameroid to mimic CAD. EAT was collected for bulk and single-nucleus transcriptomic sequencing (snRNA-seq). Clustering analysis revealed nine cell types in EAT with the fibroblast and macrophage populations predominantly from O-EX EAT and the T cell population predominantly from the N-EX EAT. Exercise upregulated G-protein coupled receptor, S100 family, and FAK pathways and downregulated the coagulation pathway. Exercise caused increased interaction between immune cells and endothelial and mesenchymal cells in the insulin-like growth factor pathway and between endothelial cells and other cell types except B cells in the platelet endothelial cell adhesion molecule pathway 1. Coronary occlusion impacted the largest number of genes in T and endothelial cells. Genes related to fatty acid metabolism were the most highly upregulated in non-immune cells from O-EX EAT. Sub-clustering of endothelial cells revealed that N-EX EAT separated from other treatments. In conclusion, exercise training increased interaction amongst immune and mesenchymal and endothelial cells in female EAT. Exercise was minimally effective at reversing alterations in gene expression in endothelial and mesenchymal cells in EAT surrounding occluded coronary arteries. These findings lay the foundation for future work focused on the impact of exercise on cell types in EAT from women.

Project description:Albeit vascular prostheses for the replacement of large arteries (e.g. aorta) are commercially available for decades, small-diameter vascular grafts (e.g., for coronary artery bypass graft surgery) still remain an unmet clinical need. Biostable polymers commonly used for the fabrication of aortic prostheses (e.g., poly(ethylene terephthalate) or expanded poly(tetrafluoroethylene)) have insufficient haemocompatibility to withstand thrombosis at low blood flow characteristic of small arteries (e.g., coronary artery). Hence, researchers endeavor to develop a biodegradable, tissue-engineered vascular graft (TEVG) to avoid the use of autologous blood vessels, such as saphenous vein or internal mammary artery, as conduits during the bypass surgery. Although a number of promising prototypes have been designed to date, none of them passed the pre-clinical trials successfully. Implantation into the ovine or porcine arteries is associated with thrombosis, neointimal hyperplasia, and aneurysms within one-year postoperation, precluding further clinical translation of TEVGs. Among the reasons of such impediment is that pathophysiology of TEVG implantation remains unclear and the molecular events occurring in the TEVG upon its implantation have not been properly investigated hitherto. Here, we for the first time performed a proteomic profiling of the TEVGs (n = 12) implanted into the ovine carotid arteries for one year and suffered from thrombosis to identify the signatures of TEVG failure in an unbiased manner. Contralateral intact ovine carotid arteries (n = 12) have been selected as a control group.

Project description:Using the Illumina Infinium Human Methylation27 BeadChip, we performed a genome-wide analysis of DNA methylation in right coronary artery in the area of advanced atherosclerotic plaques, atherosclerotic-resistant internal mammary arteries, and great saphenous veins obtained from same patients with coronary heart disease. The resulting DNA methylation patterns were markedly different between all the vascular tissues. The genes hypomethylated in athero-prone arteries to compare with atherosclerotic-resistant arteries were predominately involved in regulation of inflammation and immune processes, as well as development. The great saphenous veins exhibited an increase of the DNA methylation age in comparison to the internal mammary arteries. Gene ontology analysis for genes harboring hypermethylated CpG-sites in veins revealed the enrichment for biological processes associated with the development. Four CpG-sites located within the MIR10B gene sequence and about 1 Kb upstream of the HOXD4 gene were also confirmed as hypomethylated in the independent dataset of right coronary arteries in the area of advanced atherosclerotic plaques in comparison with the other vascular tissues. Bisulfite converted genomic DNA from 24 samples was denatured, whole-genome amplified, fragmented and subsequently hybridized to the Illumina Infinium 27k Human Methylation Beadchip.

Project description:Recently, we showed that disturbed flow caused by a partial ligation ofmouse carotid artery rapidly induces atherosclerosis. Analysis of mechanosenstive microRNA in the mouse carotid endothelium. In this study, we examined the microRNAs that respond differentially to blood flow pattern in the mouse carotid endothelium. We surgically induced disturbed blood flow in the left common carotid cartery (LCA) using partial carotid ligation surgery while the right carotid artery was left undisturbed. The hypothesis tested here is that turbulent or disturbed blood flow across the left carotid artery endothelium will affect endothelial genes and microRNAS. Identifying flow-sensitive microRNAs will provide important information about how endothelium responds to d-flow and regulates endothelial function and progression of atherosclerosis. Deter- mining the functional importance of these novel mechanosensitive microRNAS may provide important insights into understanding vascular biology and atherosclerosis. We used 6- to 8-week-old male C57Bl/6 mice (The Jackson Laboratory) according to the approved Institutional Animal Care and Use Committee protocol by Emory University. Mice were subjected to partial carotid ligation surgery under anesthesia. Briefly, 3 of 4 caudal branches of LCA (left external carotid, internal carotid, and occipital artery) were ligated with 6-0 silk suture, although the superior thyroid artery was left intact. Development of low and oscillatory blood flow in the Left Carotid Artery of each mouse was determined by ultrasound measurements.

Project description:Using the Illumina Infinium Human Methylation27 BeadChip, we performed a genome-wide analysis of DNA methylation in right coronary artery in the area of advanced atherosclerotic plaques, atherosclerotic-resistant internal mammary arteries, and great saphenous veins obtained from same patients with coronary heart disease. The resulting DNA methylation patterns were markedly different between all the vascular tissues. The genes hypomethylated in athero-prone arteries to compare with atherosclerotic-resistant arteries were predominately involved in regulation of inflammation and immune processes, as well as development. The great saphenous veins exhibited an increase of the DNA methylation age in comparison to the internal mammary arteries. Gene ontology analysis for genes harboring hypermethylated CpG-sites in veins revealed the enrichment for biological processes associated with the development. Four CpG-sites located within the MIR10B gene sequence and about 1 Kb upstream of the HOXD4 gene were also confirmed as hypomethylated in the independent dataset of right coronary arteries in the area of advanced atherosclerotic plaques in comparison with the other vascular tissues.

Project description:Atherosclerotic plaques tend to form in the major arteries at certain predictable locations. As these arteries vary in atherosusceptibility, inter-arterial differences in endothelial cell (EC) biology are of considerable interest. To explore the origin of differences observed between typical atheroprone and atheroresistant arteries, we used DNA microarrays to compare gene expression profiles of harvested porcine coronary (CECs) and iliac (IECs) artery ECs grown in static culture out to passage four. Fewer differences were observed between the transcriptional profiles of CECs and IECs in culture compared to in vivo, suggesting that most differences observed in vivo were due to distinct environmental cues in the two arteries. One-class significance of microarrays revealed that most in vivo interarterial differences disappeared in culture, as fold differences after passaging were not significant for 85% of genes identified as differentially expressed in vivo at a 5% false discovery rate. However, the three homeobox genes HOXA9, HOXA10, and HOXD3 remained under-expressed in coronary endothelium for all passages by at least 9, 8, and 2-fold, respectively. Continued differential expression despite removal from the in vivo environment suggests that primarily heritable or epigenetic mechanism(s) influence transcription of these three genes. Quantitative real-time polymerase chain reaction confirmed expression ratios for seven genes associated with atherogenesis and over- or under-expressed by 3-fold in CECs relative to IECs. The present study provides evidence that both local environment and vascular bed origin modulate gene expression in arterial endothelium. The transcriptional differences observed here may provide new insights into pathways responsible for coronary artery susceptibility. Endothelial cells were freshly harvested from right coronary and iliac arteries from four pigs. Cells were cultured out to passage four. RNA was isolated after each passage and expression profiles were obtained using oligo microarrays.

Project description:The molecular mechanisms of exercise-induced cardiovascular protection are poorly understood. There is growing evidence that reactive oxygen species (ROS) are necessary for some of these adaptations and antioxidants may be used to investigate this effect. This study aimed to determine the effects of exercise and/or antioxidant supplementation on myocardial and vascular endothelium gene expression. Male Wistar rats were divided into four groups: i) endurance exercise (90min of treadmill running 4d/week, 14 weeks); ii) antioxidant-treated; iii) antioxidant and endurance exercise and iv) control. The supplemented animals received Vitamin E (1000 IU/kg diet) and -lipoic acid (1.6 g/kg diet) mixed with rat chow. cDNA microarray analysis was performed using purified endothelial RNA from myocardial and coronary artery endothelial cells and showed that the expression levels of 35, 40 and 40 genes were altered for groups i, ii, and iii respectively compared to control. Differentially expressed genes were analysed using the KEGG pathway database, hierarchical cluster and DAVID analysis. These analyses revealed that a gene involved in cardiovascular disease progression, Ras homolog gene family member A (RhoA) was down-regulated by exercise, upregulated by antioxidant supplementation and the combination of exercise and antioxidant blunted both effects. These findings were confirmed by real-time PCR. In summary, exercise and antioxidant supplementation affect endothelial cell gene expression and ROS appear necessary for some of these adaptations. 48 Male Wistar rats were divided into four groups: i) endurance exercise (90min of treadmill running 4d/week, 14 weeks); ii) antioxidant-treated; iii) antioxidant and endurance exercise and iv) control. The supplemented animals received Vitamin E (1000 IU/kg diet) and -lipoic acid (1.6 g/kg diet) mixed with rat chow. cDNA microarray analysis was performed using purified endothelial RNA from myocardial and coronary artery endothelial cells. Based on the limited material available, it was necessary to combine the RNA into three pools per treatment group for CAEC (approx 400 ng of total RNA), and four pools for LVEC (approx 1 μg of total RNA) with an additional reference pool from each control group.