Project description:Background: Using proteomics, we strove to reveal novel molecular subtypes of human atherosclerotic lesions, study their associations with histology and imaging and relate them to long-term cardiovascular outcomes. Methods: 219 samples were obtained from 120 patients undergoing carotid endarterectomy. Sequential protein extraction was combined with multiplexed, discovery proteomics. Parallel reaction monitoring for 135 proteins was deployed for targeted validation. A combination of statistical, bioinformatics and machine learning methods was used to perform differential expression, network, pathway enrichment analysis and train and evaluate prognostic models. Results: Our extensive proteomics analysis from the core and periphery of plaques doubled the coverage of the plaque proteome compared to the largest proteomics study on atherosclerosis thus far. Plaque inflammation and calcification signatures were inversely correlated and validated with targeted proteomics. The inflammation signature was enriched with neutrophil-derived proteins, including calprotectin (S100A8/9) and myeloperoxidase. The calcification signature contained fetuin-A, osteopontin, and gamma-carboxylated proteins. Sex differences in the proteome of atherosclerosis were explained by a higher proportion of calcified plaques in women. Single-cell RNA sequencing data attributed the inflammation signature predominantly to neutrophils and macrophages and the calcification signature to smooth muscle cells, except for certain plasma proteins that were not expressed but retained in the plaque, i.e., fetuin-A. Echogenic lesions reflect the collagen content and calcification of plaque but carotid Duplex ultrasound fails to capture the extent of inflammatory protein changes in symptomatic plaques. Applying dimensionality reduction and machine learning on the proteomics data defined 4 distinct plaque phenotypes and revealed key protein signatures linked to smooth muscle cell content, plaque calcification and structural extracellular matrix, which improved the 9-year prognostic AUC by 25% compared to ultrasound and histology. A biosignature of four proteins (CNN1, PROC, SERPH, and CSPG2) independently predicted the progression of atherosclerosis and cardiovascular mortality with an AUC of 75% Conclusion: We combined discovery and targeted proteomics with network reconstruction and clustering techniques to provide molecular insights into protein changes in atherosclerotic plaques. The application of proteomics and machine learning techniques revealed distinct clusters of plaques that inform on disease progression and future adverse cardiovascular events.

Project description:Background: Using proteomics, we strove to reveal novel molecular subtypes of human atherosclerotic lesions, study their associations with histology and imaging and relate them to long-term cardiovascular outcomes. Methods: 219 samples were obtained from 120 patients undergoing carotid endarterectomy. Sequential protein extraction was combined with multiplexed, discovery proteomics. Parallel reaction monitoring for 135 proteins was deployed for targeted validation. A combination of statistical, bioinformatics and machine learning methods was used to perform differential expression, network, pathway enrichment analysis and train and evaluate prognostic models. Results: Our extensive proteomics analysis from the core and periphery of plaques doubled the coverage of the plaque proteome compared to the largest proteomics study on atherosclerosis thus far. Plaque inflammation and calcification signatures were inversely correlated and validated with targeted proteomics. The inflammation signature was enriched with neutrophil-derived proteins, including calprotectin (S100A8/9) and myeloperoxidase. The calcification signature contained fetuin-A, osteopontin, and gamma-carboxylated proteins. Sex differences in the proteome of atherosclerosis were explained by a higher proportion of calcified plaques in women. Single-cell RNA sequencing data attributed the inflammation signature predominantly to neutrophils and macrophages and the calcification signature to smooth muscle cells, except for certain plasma proteins that were not expressed but retained in the plaque, i.e., fetuin-A. Echogenic lesions reflect the collagen content and calcification of plaque but carotid Duplex ultrasound fails to capture the extent of inflammatory protein changes in symptomatic plaques. Applying dimensionality reduction and machine learning on the proteomics data defined 4 distinct plaque phenotypes and revealed key protein signatures linked to smooth muscle cell content, plaque calcification and structural extracellular matrix, which improved the 9-year prognostic AUC by 25% compared to ultrasound and histology. A biosignature of four proteins (CNN1, PROC, SERPH, and CSPG2) independently predicted the progression of atherosclerosis and cardiovascular mortality with an AUC of 75% Conclusion: We combined discovery and targeted proteomics with network reconstruction and clustering techniques to provide molecular insights into protein changes in atherosclerotic plaques. The application of proteomics and machine learning techniques revealed distinct clusters of plaques that inform on disease progression and future adverse cardiovascular events.

Project description:We performed two different pools for the 10 AAA patients (n=5 AAA patients in pool A and n=5 AAA patients in pool B) and two different pools for the 10 healthy subjects (n=5 controls in pool C and n=5 controls in pool D). Two replicates of the two microarray experiments were made. Experiment 1: AAA pool A Cy3 labeled vs control pool C Cy5 labeled AAA pool A Cy5 labeled vs control pool C Cy3 labeled (dye swap); Experiment 2: AAA pool B Cy3 labeled vs control pool D Cy5 labeled AAA pool B Cy5 labeled vs control pool D Cy3 labeled (dye swap).

Project description:Wild type (C57BL/6J) mice were divided in control (W), leptin-treated (E) and pair-fed (F). Obese (ob/ob) mice were divided in control (O), leptin-treated (L) and pair-fed (P). Control (W and O) and pair-fed animals (F and P) received vehicle (PBS), while E and L groups were intraperitoneally administrated with leptin for 28 days. Control (W and O) and leptin-treated (E and L) groups were provided with water and food ad libitum with, while daily food intake of pair fed (F and P) groups were matched to the amount eaten by the leptin-treated groups (E and L) the day before to discriminate the inhibitory effect of leptin on appetite.

Project description:In this study we aimed to identify the molecular pathways modified by the false positive genotoxins Quercetin, 8-Hydroxyquinoline and 17beta-Estradiol that may explain their in vitro genotoxic and their in vivo non-genotoxic effects, by combining in vitro transcriptomics with phenotypic data. The effects of the false positive genotoxins were compared to the effects of the true genotoxins Benzo[a]pyrene and Aflatoxin B1 and the non-genotoxins 2,3,7,8-Tetrachlorodibenzodioxin, Cyclosporin A and Ampicillin C. <br><br>A custom CDF for use with the processed data file is available on the FTP site for this experiment.

Project description:The purpose of this study was to assess the impact of sex on gene expression in LV of AS patients at the time of AVR. LV samples of men (n = 9; age: 75 M-1 8 y) and women (n = 10; age: 72 M-1 9 y) undergoing AVR were used for RNA isolation. Genome-wide expression profiling was performed using the Affymetrix platform and the data were analyzed with R and Bioconductor. Diseased samples were compared with LV samples of men (n = 10; age: 56 M-1 4 y) and women (n = 8; age: 56 M-1 5 y) with no apparent cardiovascular disorder.

Project description:We have used normal, tumoral and pure stromal whole tissue samples, and cells lines in order to identify new markers of prostate cancer.<br>The normal, tumoral and stromal tissue were obtained from patients diagnosed with prostate adenocarcinoma.<br>

Project description:The integration of different M-^SomicsM-^T technologies has already been shown in several in vivo studies to offer a complementary insight into cellular responses of toxic processes. We therefore hypothesize that the combining of transcriptomics and metabonomics data may improve the understanding of molecular mechanisms underlying non-genotoxic carcinogenicity in vitro. To test this hypothesis, the human hepatocarcinoma cell line HepG2 was exposed to the well known environmental pollutant TCDD. <br><br>A custom CDF file is available on the FTP site for this experiment (in file E-MEXP-2817.additional.zip) for use with the normalized data file for this experiment.

Project description:Study of the role of micro RNAs in IL-18 synthesis regulation in rheumatoid fibroblast-like synoviocytes (FLS)

Project description:Direct comparison of the hepatoma cell lines HepG2 and HepaRG using whole genome gene expression analysis before and after exposure to the GTX carcinogens AFB1 and BaP and the NGTX carcinogens CsA, E2 and TCDD for 12 and 48 h.