Project description:To explore the transcriptional changes in human aortic endothelial cells (HAECs) caused by miR-30e-5p overexpression, we transfected HAECs with miR-30e-5p mimics or control miRNA and profiled transcriptomes by RNA-seq

Project description:Objective: Adipose tissue plays a key role in obesity related metabolic dysfunction. MicroRNA (miRNA) are gene regulatory molecules involved in inter-cellular and inter-organ communication. We hypothesised that miRNA levels in adipose tissue would change after gastric bypass surgery and that this would provide insights into their role in obesity-induced metabolic dysregulation. Methods: miRNA-profiling (Affymetrix_Gene-Chip_miRNA2.0_Arrays) of omental and subcutaneous adipose (n=15 females) before, and after, gastric bypass surgery. Results: One omental, and thirteen subcutaneous adipose miRNAs were significantly, differentially expressed after gastric bypass, including down-regulation of miR-223-3p and its antisense relative, miR-223-5p, in both adipose tissues. mRNA levels of miR-223-3p targets NLRP3 and GLUT4 were increased and decreased respectively following gastric bypass in both adipose tissues. Significantly more NLRP3 protein was observed in omental adipose after gastric bypass (P=0.02). Significant hypomethlyation of NLRP3 and hypermethylation of miR-223 was observed in both adipose tissues after gastric bypass. In subcutaneous adipose significant correlations were observed between both miR-223-3p and miR-223-5p and glucose, and between NLRP3 mRNA and protein levels and blood lipids. Conclusions: This is the first report detailing genome-wide miRNA-profiling of omental adipose before and after gastric bypass, and further highlights a link between miR-223-3p and the NLRP3 inflammasome in obesity.

Project description:Background: It is well recognized that obesity leads to arterial endothelial dysfunction and cardiovascular disease. However, the progression to endothelial dysfunction is not clear. Endothelial cells (ECs) adapt to the unique needs of their resident tissue and respond to systemic metabolic perturbations. We sought to better understand how obesity affects EC phenotypes in different tissues specifically focusing on mitochondrial gene expression. Methods: We performed bulk RNA sequencing (RNA-seq) and single cell RNA-seq (scRNA-seq) on mesenteric and adipose ECs isolated from normal chow (NC) and high fat diet (HFD) fed mice. Differential gene expression, gene ontology pathway, and transcription factor analyses were performed. We further investigated our hypothesis in humans using published human adipose single nuclei RNA-seq (snRNA-seq) data. Results: Bulk RNA-seq revealed higher mitochondrial gene expression in adipose ECs compared to mesenteric ECs in both NC and HFD mice. We then performed scRNA-seq and categorized EC clusters as arterial, capillary, venous, or lymphatic. HFD decreased the number of differentially expressed genes between mesenteric and adipose ECs in all subtypes, but the largest effect was seen in arterial ECs. Further analysis of arterial ECs revealed genes coding for mitochondrial oxidative phosphorylation proteins were enriched in adipose compared to mesentery under NC conditions. In HFD mice, these genes were decreased in adipose ECs becoming similar to mesenteric ECs. Transcription factor analysis revealed C/EBP and PPAR, both known to regulate lipid handling and metabolism, had high specificity scores in the NC adipose artery ECs. These findings were recapitulated in snRNA-seq data from human adipose. Conclusions: These data suggest mesenteric and adipose arterial ECs metabolize lipids differently and the transcriptional phenotype of these two vascular beds converge in obesity, in part, due to downregulation of PPARand C/EBP in adipose artery ECs. This work lays the foundation for investigating vascular bed specific adaptations to obesity.

Project description:Background: It is well recognized that obesity leads to arterial endothelial dysfunction and cardiovascular disease. However, the progression to endothelial dysfunction is not clear. Endothelial cells (ECs) adapt to the unique needs of their resident tissue and respond to systemic metabolic perturbations. We sought to better understand how obesity affects EC phenotypes in different tissues specifically focusing on mitochondrial gene expression. Methods: We performed bulk RNA sequencing (RNA-seq) and single cell RNA-seq (scRNA-seq) on mesenteric and adipose ECs isolated from normal chow (NC) and high fat diet (HFD) fed mice. Differential gene expression, gene ontology pathway, and transcription factor analyses were performed. We further investigated our hypothesis in humans using published human adipose single nuclei RNA-seq (snRNA-seq) data. Results: Bulk RNA-seq revealed higher mitochondrial gene expression in adipose ECs compared to mesenteric ECs in both NC and HFD mice. We then performed scRNA-seq and categorized EC clusters as arterial, capillary, venous, or lymphatic. HFD decreased the number of differentially expressed genes between mesenteric and adipose ECs in all subtypes, but the largest effect was seen in arterial ECs. Further analysis of arterial ECs revealed genes coding for mitochondrial oxidative phosphorylation proteins were enriched in adipose compared to mesentery under NC conditions. In HFD mice, these genes were decreased in adipose ECs becoming similar to mesenteric ECs. Transcription factor analysis revealed C/EBP and PPAR, both known to regulate lipid handling and metabolism, had high specificity scores in the NC adipose artery ECs. These findings were recapitulated in snRNA-seq data from human adipose. Conclusions: These data suggest mesenteric and adipose arterial ECs metabolize lipids differently and the transcriptional phenotype of these two vascular beds converge in obesity, in part, due to downregulation of PPARand C/EBP in adipose artery ECs. This work lays the foundation for investigating vascular bed specific adaptations to obesity.

Project description:The adipose tissue is an endocrine regulator and a risk factor for atherosclerosis and cardiovascular disease when by excessive accumulation induces obesity. Although the adipose tissue is also a reservoir for stem cells (ASC) their function and “stemcellness” has been questioned. Our aim was to investigate the mechanisms by which obesity affects subcutaneous white adipose tissue (WAT) stem cells. We used microarrays to analyze differences in transcriptomic profiles between the adipose stem cells from morbidly obese and non-obese individuals.

Project description:The adipose tissue is an endocrine regulator and a risk factor for atherosclerosis and cardiovascular disease when by excessive accumulation induces obesity. Although the adipose tissue is also a reservoir for stem cells (ASC) their function and “stemcellness” has been questioned. Our aim was to investigate the mechanisms by which obesity affects subcutaneous white adipose tissue (WAT) stem cells. We used microarrays to analyze differences in transcriptomic profiles between the adipose stem cells from morbidly obese and non-obese individuals. Subcutaneous white adipose tissues that were obtained during bariatric surgery (Obese) or liposuction (Lean) were donated by patients after obtaining informed consent. Three cases with BMI>40 kg/m2 (ASCmo) and three controls with BMI<25 kg/m2 (ASCn) were selected and processed extracting total RNA, processing and hybridizating on microarrays.

Project description:This study investigates the role of endothelial cell (EC) gene expression in the focal origin of atherosclerosis. The EC transcriptome was profiled in multiple arterial regions of normal swine. Specifically, small amounts of EC RNA were isolated from 7 athero-susceptible and 6 athero-protected regions. The number of replicates for each site varied between 4 and 8. A total of 98 samples from 76 animals were used. For each sample, linearly amplified RNA (labeled with Cy5) was co-hybridized with pooled arterial reference RNA (labeled with Cy3) onto a custom-printed porcine oligo microarray (70-mers).

Project description:RvD1 improves Treg/Th17 through miR-30e-5p

Project description:Little is known about the molecular profiling associated with the effect of cladribine in patients with multiple sclerosis (MS). Here, we aimed first to characterize the transcriptomic and proteomic profiles induced by cladribine in blood cells, and second to identify potential treatment response biomarkers to cladribine in patients with MS. PBMCs treated in vitro with cladribine were characterized by a major downregulation of gene, protein, and miRNA expression compared with the untreated cells. An intermediate pattern between the cladribine-treated and untreated conditions was observed in PBMCs treated with cladribine in its inactive form. The differential expression analysis of each dataset led to the identification of four genes and their encoded proteins, and twenty-two miRNAs regulating their expression, that were associated with cladribine treatment. Two of these genes (PPIF and NHLRC2), and three miRNAs (miR-21-5p, miR-30b-5p, and miR-30e-5p) were validated ex vivo in MS patients treated with cladribine. Conclusions: By using a combination of omics data and bioinformatics approaches we were able to identify a multiomics molecular profile induced by cladribine in vitro in PBMCs. We also identified a number of biomarkers that were validated ex vivo in PBMCs from MS patients treated with cladribine that have the potential to become treatment response biomarkers to this drug.

Project description:Triple-negative breast cancer (TNBC) is an aggressive, heterogeneous subtype of breast cancer. miRNAs play an essential role in TNBC pathogenesis and prognosis. Obesity is linked with an increased risk for several cancers, including breast cancer. Obesity is also related to the dysregulation of miRNA expression in adipose tissues. However, there is limited knowledge about race- and obesity-specific differential miRNA expression in TNBC. We performed miRNA sequencing of 48 samples (24 tumor and 24 adjacent non-tumor tissues) and RNA sequencing of 24 tumors samples from Black (AA) and White (EA) TNBC patients with or without obesity. We identified 55 miRNAs exclusively associated with tumors in obese EA patients and 33 miRNAs in obese AA patients, each capable of distinguishing tumor tissues from obese from lean individuals within their respective racial groups. In EA, we detected 41 significant miRNA–mRNA correlations. Notably, miR-181b-5p and miR-877-5p acted as negative regulators of tumor-suppressor genes (e.g., HEY2, MCL2, HAND2), while miR-204-5p and miR-143-3p appeared to indirectly target oncogenes (e.g., RAB10, DR1, PTBP3, NCBP1). Among AA patients, we found 28 significant miRNA–mRNA interactions. miR-195-5p, miR-130a-3p, miR-130a-5p, miR-424-5p, miR-148a-3p, miR-374-5p, and miR-30a-5p each potentially downregulated two or more genes (e.g., CLCN4, PLCB1, CDC25B, AEBP2, ERBB4). Pathway enrichment analysis highlighted KRAS, ESR1, ESR2, RAB10, TNRC6C, and NCAN as the most commonly differentially expressed in EA, whereas ERBB4, PLCB1, and SERPINE1 were most frequently in AA. These findings highlight the importance of considering race-specific miRNA–mRNA signatures in understanding TNBC in the context of obesity, offering insights into biomarker-driven patient stratification for targeted therapeutic strategies.