microRNA‐379 couples glucocorticoid hormones to dysfunctional lipid homeostasis

In mammals, glucocorticoids (GCs) and their intracellular receptor, the glucocorticoid receptor (GR), represent critical checkpoints in the endocrine control of energy homeostasis. Indeed, aberrant GC action is linked to severe metabolic stress conditions as seen in Cushing's syndrome, GC therapy and certain components of the Metabolic Syndrome, including obesity and insulin resistance. Here, we identify the hepatic induction of the mammalian conserved microRNA (miR)‐379/410 genomic cluster as a key component of GC/GR‐driven metabolic dysfunction. Particularly, miR‐379 was up‐regulated in mouse models of hyperglucocorticoidemia and obesity as well as human liver in a GC/GR‐dependent manner. Hepatocyte‐specific silencing of miR‐379 substantially reduced circulating very‐low‐density lipoprotein (VLDL)‐associated triglyceride (TG) levels in healthy mice and normalized aberrant lipid profiles in metabolically challenged animals, mediated through miR‐379 effects on key receptors in hepatic TG re‐uptake. As hepatic miR‐379 levels were also correlated with GC and TG levels in human obese patients, the identification of a GC/GR‐controlled miRNA cluster not only defines a novel layer of hormone‐dependent metabolic control but also paves the way to alternative miRNA‐based therapeutic approaches in metabolic dysfunction.     

MicroRNA‐379 suppresses osteosarcoma progression by targeting PDK1

Osteosarcoma is the most common primary bone tumour. Increasing evidence has demonstrated the pathogenic role of microRNA (miRNAs) dysregulation in tumour development. miR‐379 was previously reported to function as an oncogenic or tumour‐suppressing miRNA in a tissue‐dependent manner. However, its function in osteosarcoma remains unknown. In this study, we found that the expression of miR‐379 was downregulated in osteosarcoma tissues and cell lines. Further functional characterization revealed that miR‐379 suppressed osteosarcoma cell proliferation and invasion in vitro and retarded the growth of osteosarcoma xenografts in vivo. Mechanistically, PDK1 was identified as the direct target of miR‐379 in osteosarcoma, in which PDK1 expression was up‐regulated and showed inverse correlation with miR‐379. Enforced expression of PDK1 promoted osteosarcoma cell proliferation and rescued the anti‐proliferative effect of miR‐379. These data suggest that miR‐379 could function as a tumour‐suppressing miRNA via targeting PDK1 in osteosarcoma.     

miR379–410 cluster miRNAs regulate neurogenesis and neuronal migration by fine‐tuning N‐cadherin

N‐cadherin‐mediated adhesion is essential for maintaining the tissue architecture and stem cell niche in the developing neocortex. N‐cadherin expression level is precisely and dynamically controlled throughout development; however, the underlying regulatory mechanisms remain largely unknown. MicroRNAs (miRNAs) play an important role in the regulation of protein expression and subcellular localisation. In this study, we show that three miRNAs belonging to the miR379–410 cluster regulate N‐cadherin expression levels in neural stem cells and migrating neurons. The overexpression of these three miRNAs in radial glial cells repressed N‐cadherin expression and increased neural stem cell differentiation and neuronal migration. This phenotype was rescued when N‐cadherin was expressed from a miRNA‐insensitive construct. Transient abrogation of the miRNAs reduced stem cell differentiation and increased cell proliferation. The overexpression of these miRNAs specifically in newborn neurons delayed migration into the cortical plate, whereas the knockdown increased migration. Collectively, our results indicate a novel role for miRNAs of the miR379–410 cluster in the fine‐tuning of N‐cadherin expression level and in the regulation of neurogenesis and neuronal migration in the developing neocortex.     

Hepatic miR‐29ab1 expression modulates chronic hepatic injury

MicroRNAs (miRNAs) are small, regulatory non‐coding RNAs that have potent effects on gene expression. Several miRNA are deregulated in cellular processes involved in human liver diseases and regulation of cellular processes. Recent studies have identified the involvement of miR‐29 in hepatic fibrosis and carcinogenesis. Although several targets of miR‐29 have been identified, there is limited information regarding the cell‐type specific roles of miR‐29 in the liver, and we sought to evaluate the role of this miRNA in hepatic pathobiology. We report the generation of a tissue–specific knockout mouse to evaluate the role of miR‐29 in hepatic fibrosis and carcinogenesis in response to injury. We hypothesized that miR‐29 contributes to the hepatocyte driven response to chronic cellular injury that results in fibrosis. In support of this hypothesis, fibrosis and mortality were enhanced in miR29 knockout mice in response to carbon tetrachloride. Genome‐wide gene expression analysis identified an over‐representation of genes associated with fibrosis. The oncofetal RNA H19 was modulated in a miR‐29 dependent manner following exposure to carbon tetrachloride in vivo. The impact of a hepatocyte specific miR‐29 knockout on survival following chronic hepatic injury in vivo implicates this miRNA as a potential target for intervention. These results provide evidence of the involvement of miR‐29 in chronic hepatic injury, and suggest a role for deregulated hepatocyte expression of miR‐29 in the response to hepatic injury, fibrosis and carcinogenesis.     

Induced miR‐99a expression represses Mtor cooperatively with miR‐150 to promote regulatory T‐cell differentiation

Peripheral induction of regulatory T (Treg) cells provides essential protection from inappropriate immune responses. CD4⁺ T cells that lack endogenous miRNAs are impaired to differentiate into Treg cells, but the relevant miRNAs are unknown. We performed an overexpression screen with T‐cell‐expressed miRNAs in naive mouse CD4⁺ T cells undergoing Treg differentiation. Among 130 candidates, the screen identified 29 miRNAs with a negative and 10 miRNAs with a positive effect. Testing reciprocal Th17 differentiation revealed specific functions for miR‐100, miR‐99a and miR‐10b, since all of these promoted the Treg and inhibited the Th17 program without impacting on viability, proliferation and activation. miR‐99a cooperated with miR‐150 to repress the expression of the Th17‐promoting factor mTOR. The comparably low expression of miR‐99a was strongly increased by the Treg cell inducer “retinoic acid”, and the abundantly expressed miR‐150 could only repress Mtor in the presence of miR‐99a. Our data suggest that induction of Treg cell differentiation is regulated by a miRNA network, which involves cooperation of constitutively expressed as well as inducible miRNAs.     

Exosomes derived from miR‐181‐5p‐modified adipose‐derived mesenchymal stem cells prevent liver fibrosis via autophagy activation

Proliferating hepatic stellate cells (HSCs) respond to liver damage by secreting collagens that form fibrous scar tissue, which can lead to cirrhosis if in appropriately regulated. Advancement of microRNA (miRNA) hepatic therapies has been hampered by difficulties in delivering miRNA to damaged tissue. However, exosomes secreted by adipose‐derived mesenchymal stem cells (ADSCs) can be exploited to deliver miRNAs to HSCs. ADSCs were engineered to overexpress miRNA‐181‐5p (miR‐181‐5p‐ADSCs) to selectively home exosomes to mouse hepatic stellate (HST‐T6) cells or a CCl4‐induced liver fibrosis murine model and compared with non‐targeting control Caenorhabditis elegans miR‐67 (cel‐miR‐67)‐ADSCs. In vitro analysis confirmed that the transfer of miR‐181‐5p from miR‐181‐5p‐ADSCs occurred via secreted exosomal uptake. Exosomes were visualized in HST‐T6 cells using cyc3‐labelled pre‐miRNA‐transfected ADSCs with/without the exosomal inhibitor, GW4869. The effects of miRNA‐181‐5p overexpression on the fibrosis associated STAT3/Bcl‐2/Beclin 1 pathway and components of the extracellular matrix were assessed. Exosomes from miR181‐5p‐ADSCs down‐regulated Stat3 and Bcl‐2 and activated autophagy in the HST‐T6 cells. Furthermore, the up‐regulated expression of fibrotic genes in HST‐T6 cells induced by TGF‐β1 was repressed following the addition of isolated miR181‐5p‐ADSC exosomes compared with miR‐67‐ADSCexosomes. Exosome therapy attenuated liver injury and significantly down‐regulated collagen I, vimentin, α‐SMA and fibronectin in liver, compared with controls. Taken together, the effective anti‐fibrotic function of engineered ADSCs is able to selectively transfer miR‐181‐5p to damaged liver cells and will pave the way for the use of exosome‐ADSCs for therapeutic delivery of miRNA targeting liver disease.     

Two new miR‐16 targets: caprin‐1 and HMGA1, proteins implicated in cell proliferation

Background information. miRNAs (microRNAs) are a class of non‐coding RNAs that inhibit gene expression by binding to recognition elements, mainly in the 3′ UTR (untranslated region) of mRNA. A single miRNA can target several hundred mRNAs, leading to a complex metabolic network. miR‐16 (miRNA‐16), located on chromosome 13q14, is involved in cell proliferation and apoptosis regulation; it may interfere with either oncogenic or tumour suppressor pathways, and is implicated in leukaemogenesis. These data prompted us to search for and validate novel targets of miR‐16. Results. In the present study, by using a combined bioinformatics and molecular approach, we identified two novel putative targets of miR‐16, caprin‐1 (cytoplasmic activation/proliferation‐associated protein‐1) and HMGA1 (high‐mobility group A1), and we also studied cyclin E which had been previously recognized as an miR‐16 target by bioinformatics database. Using luciferase activity assays, we demonstrated that miR‐16 interacts with the 3′ UTR of the three target mRNAs. We showed that miR‐16, in MCF‐7 and HeLa cell lines, down‐regulates the expression of caprin‐1, HMGA1a, HMGA1b and cyclin E at the protein level, and of cyclin E, HMGA1a and HMGA1b at the mRNA levels. Conclusions. Taken together, our data demonstrated that miR‐16 can negatively regulate two new targets, HMGA1 and caprin‐1, which are involved in cell proliferation. In addition, we also showed that the inhibition of cyclin E expression was due, at least in part, to a decrease in its mRNA stability.     

A miR‐34a‐SIRT6 axis in the squamous cell differentiation network

Squamous cell carcinomas (SCCs) are highly heterogeneous tumours, resulting from deranged expression of genes involved in squamous cell differentiation. Here we report that microRNA‐34a (miR‐34a) functions as a novel node in the squamous cell differentiation network, with SIRT6 as a critical target. miR‐34a expression increases with keratinocyte differentiation, while it is suppressed in skin and oral SCCs, SCC cell lines, and aberrantly differentiating primary human keratinocytes (HKCs). Expression of this miRNA is restored in SCC cells, in parallel with differentiation, by reversion of genomic DNA methylation or wild‐type p53 expression. In normal HKCs, the pro‐differentiation effects of increased p53 activity or UVB exposure are miR‐34a‐dependent, and increased miR‐34a levels are sufficient to induce differentiation of these cells both in vitro and in vivo. SIRT6, a sirtuin family member not previously connected with miR‐34a function, is a direct target of this miRNA in HKCs, and SIRT6 down‐modulation is sufficient to reproduce the miR‐34a pro‐differentiation effects. The findings are of likely biological significance, as SIRT6 is oppositely expressed to miR‐34a in normal keratinocytes and keratinocyte‐derived tumours.     

Identification of miR‐93 as a suitable miR for normalizing miRNA in plasma of tuberculosis patients

Tuberculosis (TB) remains a major public health issue. New tests to aid diagnoses and monitor the response to therapy are urgently required. There is growing interest in the use of microRNA (miRNA) profiles as diagnostic, prognostic or predictive markers in a range of clinical and infectious diseases, including Mycobacterium tuberculosis infection, however, challenges exist to accurately normalise miRNA levels in cohorts. This study examined the appropriateness of 12 miRs and RNU6B to normalise circulating plasma miRNA levels in individuals with active TB from 2 different geographical and ethnic regions. Twelve miRs (let‐7, miR‐16, miR‐22, miR‐26, miR‐93, miR‐103, miR‐191, miR‐192, miR‐221, miR‐423, miR‐425 and miR‐451) and RNU6B were selected based on their reported production by lung cells, expression in blood and previous use as a reference miRNA. Expression levels were analysed in the plasma of newly diagnosed TB patients from Australia and China compared with individuals with latent TB infection and healthy volunteers. Analysis with both geNorm and NormFinder software identified miR‐93 as the most suitable reference miR in both cohorts, either when analysed separately or collectively. Interestingly, there were large variations in the expression levels of some miRs, in particular miR‐192 and let‐7, between the two cohorts, independent of disease status. These data identify miR‐93 is a suitable reference miR for normalizing miRNA levels in TB patients, and highlight how environmental, and possibly ethnic, factors influence miRNA expression levels, demonstrating the necessity of assessing the suitability of reference miRs within the study population.     

miR‐134 inhibits non‐small cell lung cancer growth by targeting the epidermal growth factor receptor

The epidermal growth factor receptor (EGFR) is frequently activated in a wide range of solid tumours and represents an important therapeutic target. MicroRNAs (miRNAs) have recently been recognized as a rational and potential modality for anti‐EGFR therapies. However, more EGFR‐targeting miRNAs need to be explored. In this study, we identified a novel EGFR‐targeting miRNA, miRNA‐134 (miR‐134), in non‐small‐cell lung cancer (NSCLC) cell lines. Luciferase assays confirmed that EGFR is a direct target of miR‐134. In addition, the overexpression of miR‐134 inhibited EGFR‐related signaling and suppressed NSCLC cells proliferation by inducing cell cycle arrest and/or apoptosis, suggesting that miR‐134 functions as a tumour suppressor in NSCLC. Further mechanistic investigation including RNAi and rescue experiments suggested that the down‐regulation of EGFR by miR‐134 partially contributes to the antiproliferative role of miR‐134. Last, in vivo experiments demonstrated that miR‐134 suppressed tumour growth of A549 xenograft in nude mice. Taken together, our findings suggest that miR‐134 inhibits non‐small cell lung cancer growth by targeting the EGFR.     

Modified level of miR‐376a is associated with Parkinson's disease

Parkinson's disease (PD) is a frequent progressive neurodegenerative disorder. Impaired mitochondrial function is a major feature of sporadic PD. Some susceptibility or causative genes detected in PD are strongly associated with mitochondrial dysfunction including PGC1α, TFAM and GSK3β. microRNAs (miRNAs) are non‐coding RNAs whose altered levels are proven in disparate PD models and human brains. Therefore, the aim of this study was to detect modulations of miRs upstream of PGC1α, TFAM and GSK3β in association with PD onset and progress. In this study, a total of 33 PD subjects and 25 healthy volunteers were recruited. Candidate miRNA (miR‐376a) was selected through target prediction tools and literature survey. Chronic and acute in vitro PD models were created by MPP⁺‐intoxicated SHSY5Y cells. The levels of miR‐376a and aforementioned genes were assessed by RT‐qPCR. The expression of target genes was decreased in chronic model while there were dramatically up‐regulated levels of those genes in acute model of PD. miR‐376a was strongly altered in both acute and chronic PD models as well as PBMCs of PD patients. Our results also showed overexpression of PGC1α, and TFAM in PBMCs is inversely correlated with down‐regulation of miR‐376a, suggesting that miR‐376a possibly has an impact on PD pathogenesis through regulation of these genes which are involved in mitochondrial function. miR‐376a expression in PD‐derived PBMCs was also correlated with disease severity and may serve as a potential biomarker for PD diagnosis. This is the first study showing altered levels of miR‐376a in PD models and PBMCs, suggesting the probable role of this miRNA in PD pathogenesis. The present study also proposed TFAM and PGC1α as target genes of miR‐376a for the first time, through which it possibly can exert its impact on PD pathogenesis.     

Cardiomyocyte‐specific role of miR‐24 in promoting cell survival

Cardiomyocyte cell death is a major contributing factor to various cardiovascular diseases and is therefore an important target for the design of therapeutic strategies. More recently, stem cell therapies, such as transplantation of embryonic or induced pluripotent stem (iPS) cell‐derived cardiomyocytes, have emerged as a promising alternative therapeutic avenue to treating cardiovascular diseases. Nevertheless, survival of these introduced cells is a serious issue that must be solved before clinical application. We and others have identified a small non‐coding RNA, microRNA‐24 (miR‐24), as a pro‐survival molecule that inhibits the apoptosis of cardiomyocytes. However, these earlier studies delivered mimics or inhibitors of miR‐24 via viral transduction or chemical transfection, where the observed protective role of miR‐24 in cardiomyocytes might have partially resulted from its effect on non‐cardiomyocyte cells. To elucidate the cardiomyocyte‐specific effects of miR‐24 when overexpressed, we developed a genetic model by generating a transgenic mouse line, where miR‐24 expression is driven by the cardiac‐specific Myh6 promoter. The Myh6‐miR‐24 transgenic mice did not exhibit apparent difference from their wild‐type littermates under normal physiological conditions. However, when the mice were subject to myocardial infarction (MI), the transgenic mice exhibited decreased cardiomyocyte apoptosis, improved cardiac function and reduced scar size post‐MI compared to their wild‐type littermates. Interestingly, the protective effects observed in our transgenic mice were smaller than those from earlier reported approaches as well as our parallelly performed non‐genetic approach, raising the possibility that non‐genetic approaches of introducing miR‐24 might have been mediated via other cell types than cardiomyocytes, leading to a more dramatic phenotype. In conclusion, our study for the first time directly tests the cardiomyocyte‐specific role of miR‐24 in the adult heart, and may provide insight to strategy design when considering miRNA‐based therapies for cardiovascular diseases.