Project description:Given that extracellular vesicles (EVs) secreted from stem cells contain angiogenic microRNAs (miRNAs), these EVs show equivalent angiogenic therapeutic effect to cell transplantation. This study aimed to identify the angiogenic miRNAs from several miRNAs involved in EVs secreted from stem cells. In human dental pulp stem cells (hDPSCs) under hypoxic culture, vascular endothelial growth factor (VEGF) involved in EVs increased. We hypothesized that angiogenic miRNAs increase in EVs that are secreted from hDPSCs under hypoxic culture compared with those under normoxic culture. In the first screening, the expression levels of miRNAs involved in EVs that were secreted from hDPSCs cultured under hypoxic and normoxic conditions were analyzed using miRNA array. In the second screening, 12 miRNAs were individually involved in EVs, and the growth of human aortic endothelial cells was assayed. In the third screening, miRNA-encapsulated EVs were injected in BALB/c mouse hindlimb ischemia model, followed by angiogenesis evaluation by blood flow analysis. Results showed that miR-765 is an angiogenic miRNA, targeting the 3′ untranslated region of dipeptidyl peptidase 4 (DPP4) and upregulating fibroblast growth factor 2 (FGF2) in vitro and in vivo. In conclusion, as an angiogenesis mechanism, miR-765 increased FGF2 expression levels by inhibiting DPP4.

Project description:Peripheral Artery Disease is caused by the restriction or occlusion of arteries supplying the leg. Better understanding of the molecular mechanisms underpinning tissue response to acute and chronic ischemia is urgently needed to improve therapeutic options. The aim of this study is understanding miR-210 regulation and role in a mouse model of hindlimb ischemia. To investigate miR-210 function, mice were injected with a miR-210 complementary LNA-oligonucleotide (anti-miR-210). Then, the left femoral artery was dissected in order to induce unilateral hindlimb ischemia. Mice were sacrified 3 days later and gene expression profiles of gastrocnemius muscles were obatained.

Project description:We analyzed miRNA profiles in normal liver and identified miR-709, a highly abundant miRNA in this tissue. Through microarray analysis, gene targets were identified. Thirty-six genes were significantly down-regulated >2-fold in the miR-709-treated relative to the control group, and at least three of them, including Ras-related protein 11b (Rab11b), phosphatidylcholine transfer protein (Pctp), and carboxylesterase 1g (Ces1g), are direct targets. miR-709 regulates genes implicated in cytoskeleton organization, extracellular matrix attachment, cell proliferation and fatty acid metabolism, suggesting a coordinated response during cell division, when cytoskeleton remodeling requires substantial changes in gene expression.

Project description:Extracellular vesicle(EV) secretion and capture is an important method of communication between cells. Melanocytes and their surrounding keratinocytes form epidermal melanin units in the thin, outermost layer of the skin to protect the skin from ultraviolet radiation damage. It is important to understand the mechanisms by which changes in melanocyte EV signal transduction influence pigmentation. Mouse melanocytes (melan-α cell) overexpressing MITF and CD63-GFP were used to to investigate the effect on vesicle formation by WB and SEM. Coculturing of melanocyte with keratinocyte(PAM212) was used to explore the polarization of vesicles and transfer between cells by immunofluorescence, flow cytometry. EVs from melanocytes were extracted and used to investigate changes in the miRNA profile of EVs, and the effect of exosomal miR-28 on keratinocyte growth and transcriptomics was analyzed by flow cytometry, TEM, particle size analysis, WB, the iCELLigence system and RNA-seq analysis.Our results indicate that melanocytes in the skin affected vesicle synthesis under the condition of enhanced melanin synthesis function: the expression of CD81, VPS37, VPS36B and Rab27b (melanosome and vesicle transport protein during ESCRT machinery) increased. Keratinocytes can cause the polarization of vesicles in melanocytes and capture EVs from melanocytes via plasmalemma fusion. Analysis of the miRNA profile derived from melanocyte EVs showed that the expression levels of miR-125, miR-130, miR-211, miR-127, miR-692 and miR-709 were increased, while the expression levels of miR-28, miR-744, let-7g and miR-6240 were decreased. The content of miR-28 in EVs may be reduced to induce keratinocytes to prevent carcinogenesis, resist infection and prevent premature apoptosis.

Project description:Malignant germ-cell-tumours (GCTs) are characterised by microRNA (miRNA/miR-) dysregulation, with universal over-expression of miR-371~373 and miR-302/367 clusters regardless of patient age, tumour site, or subtype (seminoma/yolk-sac-tumour/embryonal carcinoma). These miRNAs are released into the bloodstream, presumed within extracellular-vesicles (EVs) and represent promising biomarkers. Here, we comprehensively examined the role of EVs, and their miRNA cargo, on (fibroblast/endothelial/macrophage) cells representative of the testicular GCT (TGCT) tumour microenvironment (TME). Small RNA next-generation-sequencing was performed on 34 samples, comprising representative malignant GCT cell lines/EVs and controls (testis fibroblast [Hs1.Tes] cell-line/EVs and testis/ovary samples). TME cells received TGCT co-culture, TGCT-derived EVs, and a miRNA overexpression system (miR-371a-OE) to assess functional relevance. TGCT cells secreted EVs into culture media. MiR-371~373 and miR-302/367 cluster miRNAs were overexpressed in all TGCT cells/subtypes compared with control cells and were highly abundant in TGCT-derived EVs, with miR-371a-3p/miR-371a-5p the most abundant. TGCT co-culture resulted in increased levels of miRNAs from the miR-371~373 and miR-302/367 clusters in TME (fibroblast) cells. Next, fluorescent labelling demonstrated TGCT-derived EVs were internalised by all TME (fibroblast/endothelial/macrophage) cells. TME (fibroblast/endothelial) cell treatment with EVs derived from different TGCT subtypes resulted in increased miR-371~373 and miR-302/367 miRNA levels, and other generic (eg, miR-205-5p/miR-148-3p) and subtype-specific (seminoma, eg, miR-203a-3p; yolk-sac-tumour, eg, miR-375-3p) miRNAs. MiR-371a-OE in TME cells resulted in increased collagen contraction (fibroblasts) and angiogenesis (endothelial cells), via direct mRNA downregulation and alteration of relevant pathways. TGCT cells communicate with nontumour stromal TME cells through release of EVs enriched in oncogenic miRNAs, potentially contributing to tumour progression.

Project description:We report transcriptomic changes in bone marrow cells of systemic miR-181a2b2 KO mice in response after chow diet feeding and hindlimb ischemia

Project description:We report transcriptomic changes in bone marrow cells of systemic miR-181a2b2 KO mice in response after HFSC diet feeding and hindlimb ischemia

Project description:We report transcriptomic changes in skeletal muscle of systemic miR-181a2b2 KO mice in response to chow and HFSC diet feeding and hindlimb ischemia

Project description:Using NGS, we report the impact of cardiovascular risk factors (CRF) including hypercholesteolemia, aging and smoking compare to healthy control mice, on the differential-expression profile of miRNAs in proangiogenic cells (PACs) isolated during ischemia-induced neovascularization in a mouse model of hindlimb ischemia. Data of total miRNA expression are presented as normalized copy number: read per millions of read (RPM). Hindlimb ischemia was surgicaly induced by feromal artery ablation and the animal was sacrified 2 day after ischemic surgery for PACs isolation. After 4 days of culture, PACs RNAs were extracted to perform NGS.

Project description:Regulation of microRNA (miR) biogenesis is complex and stringently controlled. Here we identify the kinase GSK3B as an important modulator of global miR biogenesis at microprocessor level. Repression of GSK3B activity reduces Drosha activity towards pri-miRs, leading to accumulation of unprocessed pri-miRs and reduction of pre-miRs and mature miRs without altering levels or cellular localisationof miR biogenesisproteins. Conversly, GSK3B activation increases Drosha activityand mature miR accumulation. GSK3B achieves this through promoting Drosha:cofactor and Drosha:pri-miR interactions: it binds to DGCR8 and p72 in the Microprocessor, an effect dependent of RNA. Indeed GSK3B itself can immunoprecipitate pri-miRs, suggesting possible RNA binding capacity. Kinase assays identify the mechanism for GSK3B-enhansed Drosha activity, which requires GSK3B nuclear localisation, as phosphorylation of Drosha at s300 and/or s302 confirmed by enhanced Drosha activity and association with cofactors, and increased abundance of mature microRNAs in the presence of phospho-mimetic Drosha. Functional implicatons of GSK3B-enhanced miR biogenesis are illustrated by increased levels of GSK3B-upregulatd miR targets following GSK3B inhibition. These data, the first link GSK3B with the miR cascade in humans, hilight a novel pro-biogenesis role for GSK3B in increasing miR biogenesis as a component of the Microprocessor complex with wide ranging consiquences.