Project description:Vein graft failure (VGF) following cardiovascular bypass surgery results in significant patient morbidity and cost to the healthcare system. Vein graft injury can occur during autogenous vein harvest and preparation, as well as after implantation into the arterial system, leading to the development of intimal hyperplasia, vein graft stenosis, and, ultimately, bypass graft failure. While previous studies have identified maladaptive pathways that occur shortly after implantation, the specific signaling pathways that occur during vein graft preparation are not well defined and may result in a cumulative impact on VGF. We, therefore, aimed to elucidate the response of the vein conduit wall during harvest and following implantation, probing the key maladaptive pathways driving graft failure with the overarching goal of identifying therapeutic targets for biologic intervention to minimize these natural responses to surgical vein graft injury. Employing a novel approach to investigating vascular pathologies, we harnessed both single-nuclei RNA-sequencing (snRNA-seq) and spatial transcriptomics (ST) analyses to profile the genomic effects of vein grafts after harvest and distension, then compared these findings to vein grafts obtained 24 hours after carotid-cartoid vein bypass implantation in a canine model (n=4). Collectively, we find that vein conduit harvest and distension elicit a prompt genomic response facilitated by distinct cellular subpopulations heterogeneously distributed throughout the vein wall. This response was found to be further exacerbated following vein graft implantation, resulting in a cascade of maladaptive gene regulatory networks. Together, these results suggest that distension initiates the upregulation of pathological pathways that may ultimately contribute to bypass graft failure and presents potential early targets warranting investigation for targeted therapies.

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:Occlusive artery disease (CAD) is the leading cause of death worldwide. Bypass graft surgery remains the prevalently performed treatments for occlusive arterial disease, and veins are the most frequently used conduits for surgical revascularization. However, clinical efficacy is highly affected by the long-term potency rates of vein grafts, and no optimal treatments are available for prevention of vein graft restenosis (VGR) until today. Therefore, it is urgent to improve the understanding of molecular mechanisms involved in mediating VGR, and thereby provide potential potent therapeutic targets for prevention of vein graft failure. In this study, we aim to explore potential crucial genes and pathways associated with VGR and provide valid biological information for further investigation of VGR.

Project description:To further development of our gene expression approach to cardiovascular disease, we have employed microarray expression profiling as a discovery platform to identify genes with the potential to distinguish the therapeutic target of the vein graft restenosis following coronary artery bypass grafting. Vein graft samples were obtained from model rats which received external jugular vein-carotid bypass grafting at different postoperative timepoints (n=3/group; day 7, 14 and 28, respectively). Vein samples were also obtained from control rats without vascular grafting (n=3/group; day 0). Time-dependent gene expression profiles were described with microarray analysis. Expression of three lncRNA-mRNA pairs (AF062402-Src, BC091437-Edg1 and BC166461- Mcam) from this signature were quantified in the same RNA samples by real-time PCR, confirming the accuracy of the microarray data.

Project description:Serum-starved, quieced HSVSMC (human saphenous vein smooth muscle cells, isolated from the great saphenous vein of coronary artery bypass graft patients) were treated with recombinant human TGFbeta-1 (10ng/mL) in the presence or absence of ALK5 kinase inhibitor SB-525334 (10uM) or ALK1/2 kinase inhibitor KO2288, https://doi.org/10.1371/journal.pone.0062721, (10uM). Gene expression analysis was performed on RNA extracted from cells at the 24h timepoint. RNA samples from three independent experiments (performed on cells from three different patients) were analysed. Quiesced, unstimulated cells were used as a negative control.

Project description:To further understand the mechanism approach to occlusive vein grafts, we have employed RNA-seq to identify key genes in occlusive venin grafts following CABG in human. The occluded vein graft and intraoperative spare great saphenous vein of patients undergoing clinical re-coronary artery bypass grafting were obtained for RNA-seq. The sequencing results were cleaned and bioinformatics annlysis was conducted by using WGCNA and a variety of online databases and software. The key genes or proteins affecting the occurrence of vein graft restenosis were screened out(ITGB2), and the expression level of the target genes or proteins was verified by real-time PCR and Western blot. And to further learn the effect of ITGB2 in human primary venous smooth muscle cells, ITGB2 gene was silenced by SiRNA. The effect of ITGB2 silencing on proliferation, migration and invasion of venous smooth muscle cells after PDGF-BB-stimulation were detected by Edu assay, scrathch experiment and transwell experiment. And Edu assay showed that ITGB2 silencing could inhibit the proliferation of PDGF-BB sitmulated smooth muscle cells. Scratch assay showed that ITGB2 silencing inhibited the migration of PDGF-BB stimulated smooth muscle cells. Transwell assay showed that ITGB2 silencing significantly inhibited the invasion of PDGF-BB stimulated smooth muscle cells. It is indicated that ITGB2 was the key gene in vein graft restenosis,and may be the potential treatment target in restenosis patients.

Project description:Purpose: Intimal hyperplasia is the leading cause of graft failure in aortocoronary bypass grafts performed using human saphenous vein (SV). The long-term consequences of the altered pulsatile stress on the cells that populate the vein wall remain elusive, in particular onto saphenous vein progenitors (SVPs), adult cell phenotype of the human adventitia that upholds differentiation capacity. In the present study, we performed global transcriptomic profiling of SVPs that underwent in vitro uniaxial cyclic strain, a type of mechanical stimulation that we recently found to be involved in the pathology of the SV. Methods: To investigate the effect of mechanical strain on cultured cells, SVPs were subjected to cyclic strain using the FlexCell Tension Plus FX-5000T system. Cells were subjected to uniaxial cyclic deformation protocol (0-10% deformation, 1 Hz frequency), for 24 and 72 hours, while static controls were provided by seeding an equal amount of cells, under the same atmospheric conditions, but without mechanical stimulation. For RNA-Seq analysis, total RNA was extracted from 5 different donors of SVPs using TRIzol, treated with DNase I, and quantified by using NanoDrop-1000 spectrophotometer before integrity assessment with Agilent 2100 Bioanalyzer (RNA Integrity Number values >8). Results: Results showed a consistent stretch-dependent gene regulation in cyclically strained SVPs vs. controls, especially at 72hrs. We also observed a robust mechanically related overexpression of Adhesion Molecule with Ig Like Domain 2 (AMIGO2), a cell surface type I transmembrane protein involved in cell adhesion. The overexpression of AMIGO2 in stretched SVPs was associated with the activation of the transforming growth factor β pathway and modulation of cell signalling, cell-cell, and cell-matrix interactions. Conclusions: These results show that mechanical stress promotes SVPs' molecular phenotypic switching and increases their responsiveness to extracellular environment alterations, thus prompting the targeting of new molecular effectors to improve the outcome of bypass graft procedure.

Project description:Arteriovenous hemodialysis graft (AVG) stenosis results in thrombosis and AVG failure, and develops chiefly as a consequence of neotinimal hyperplasia (NH) formation in the graft-venous anastomosis region. Of note, the juxta-anastomotic vein regions are relatively resistant to NH. AVG stenosis has not been resolved partly due to our limited understanding of the molecular processes involved in the pathophysiology. We hypothesized that the gene expression profiles of the NH prone and NH-resistant regions will be different after graft placement, and analysis of their genomic profiles may yield therapeutic targets to address AVG stenosis. To test this hypothesis we evaluated the global genomic profiles of the graft-venous anastomosis (NH-prone) and juxta-anastomotic (NH-resistant) vein regions in a porcine model of AVG stenosis using a porcine microarray. Gene expression changes in these two distinct vein regions, relative to the gene expression in un-operated veins, were examined at an early (5 days) and later (14 days) time period following graft placement. Global genomic changes were much greater in the NH-prone region than in the NH-resistant region at both time points. In the NH-prone region, genes related to regulation of cell proliferation and osteo/chondrogenic vascular remodeling were most enriched among the significantly up-regulated genes at day 5 and day 14, respectively. At both time points, genes related to muscle phenotype were significantly down-regulated. These results provide insights into the spatial and temporal genomic modulation underlying NH formation in AVG, and suggest potential therapeutic strategies to prevent and/or limit AVG stenosis.

Project description:The pathology of failure in currently used biological treatments (cell therapies and microfracture) for cartilage repair or early osteoarthritis (OA) is poorly understood. We aimed to identify a reliable panel of biological predictors, present in synovial fluid, which can be used in the preoperative setting to optimise patient selection and therapy efficacy. The-long term aim is to reduce the number of patients who progress to end-stage OA and require knee replacement by making earlier, less invasive treatments more effective. In this first stage, we have taken synovial fluid aspirates from patients undergoing autologous chondrocyte implantation (ACI) at our centre in Oswestry, UK. Synovial fluids (SFs) were obtained from 14 ACI responders (mean Lysholm improvement of 33 (17-54)) and 13 non-responders (mean Lysholm decrease of 14 (4-46)) at the two stages of surgery (cartilage harvest and chondrocyte implantation). Dynamic range compression of synovial fluids coupled with label-free quantification mass spectrometry (MS), was used in an unbiased approach to identify predictive markers of ACI success or failure and to investigate the biological pathways involved in the clinical response to ACI.

Project description:Gene expression profiling of vein graft restenosis