Long‐distance movement of phosphate starvation‐responsive microRNAs in Arabidopsis

• Plant microRNAs are small RNAs that are important for genetic regulation of processes such as plant development or environmental responses. Specific microRNAs accumulate in the phloem during phosphate starvation, and may act as long‐distance signalling molecules.
• We performed quantitative PCR on Arabidopsis hypocotyl micrograft tissues of wild‐type and hen1‐6 mutants to assess the mobility of several phosphate starvation‐responsive microRNA species.
• In addition to the previously confirmed mobile species miR399d, the corresponding microRNA* (miR399d*) was identified for the first time as mobile between shoots and roots. Translocation by phosphate‐responsive microRNAs miR827 and miR2111a between shoots and roots during phosphate starvation was evident, while their respective microRNA*s were not mobile.
• The results suggest that long‐distance mobility of microRNA species is selective and can occur without the corresponding duplex strand. Movement of miR399d* and root‐localised accumulation of miR2111a* opens the potential for persisting microRNA*s to be mobile and functional in novel pathways during phosphate starvation responses.

     

MiR‐106b regulates the apoptosis and tumorigenesis of hepatocellular carcinoma via targeting Zinc finger and BTB domain‐containing protein 7A (Zbtb7a)

MicroRNAs play vital regulatory roles in various type of tumorigenesis. We aimed to explore the functional microRNAs that might play as therapeutic targets in hepatocellular carcinoma (HCC). In this study, our results revealed that microRNA‐106b was significantly increased in HCC tumor tissues. However, miR‐106b knockdown remarkably suppressed the growth and increased the apoptosis of Hub‐7 HCC cells. Biological analysis indicated that miR‐106b directly targeted toZinc finger and BTB domain‐containing protein 7A (Zbtb7a) to regulate the apoptosis of Hub‐7 cells. Extensively, Zbtb7a overexpression reversed Huh‐7 cell apoptosis and growth in vitro. Furthermore, in vivo studies confirmed that miR‐106b inhibition or Zbtb7a overexpression retarded the growth of Hub‐7 xenograft tumor in nude mice. In conclusion, we provide the evidence for the regulatory role of miR‐106b in HCC, which is causally linked to targeting of Zbtb7a. This study may provide miR‐106b as a potential therapeutic strategy for HCC.     

MicroRNA‐155‐3p promotes glioma progression and temozolomide resistance by targeting Six1

The prognosis of glioma is generally poor and is the cause of primary malignancy in the brain. The role of microRNAs has been implicated in tumour inhibition or activation. In several cancers, the Six1 signalling pathway has been found to be aberrant and also relates to the formation of tumours. We analysed the database for expression profiles and clinical specimens of various grades of glioma to assess microRNA‐155‐3p (miR‐155‐3p) expression. The role of miR‐155‐3p in glioblastoma, cell cycle, proliferation, apoptosis and resistance to temozolomide was assessed in vitro through flow cytometry and cell proliferation assays. Bioinformatics analyses, and assays using luciferase reporter, and immunoblotting revealed that miR‐155‐3p targets Six1 and that the relationship between glioma and healthy brain tissues was significantly inverse. In rescue experiments, overexpressed Six1 revoked the changes in cell cycle distribution, proliferation and resistance to temozolomide estimated by apoptosis induced by overexpressed miR‐155‐3p. MiR‐155‐3p inhibition reduced glioma cell growth and proliferation in the brain of a mouse model and increased the survival of mice with gliomas. Thus, miR‐155‐3p modulates Six1 expression and facilitates the progression of glioblastoma and resistance to temozolomide and may act as a novel diagnostic biomarker and a target for glioma treatment.     

MicroRNA‐183‐5p is stress‐inducible and protects neurons against cell death in amyotrophic lateral sclerosis

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease characterized by the death of motor neurons. A fundamental pathogenesis of ALS is the prolonged cell stress in neurons, which is caused by either accumulation of protein aggregates or reactive oxygen species. However, the mechanistic link between stress sensing and cell death is unsettled. Here, we identify that miR‐183‐5p, a neuron‐enriched miRNA, couples stress sensing and cell death programming in ALS. miR‐183‐5p is immediately induced by hydrogen peroxide, tunicamycin or TNF‐α in neurons. The overexpression of miR‐183‐5p increases neuron survival under stress conditions, whereas its knockdown causes neuron death. miR‐183‐5p coordinates apoptosis and necroptosis pathways by directly targeting PDCD4 and RIPK3, and thus protects neurons against cell death under stress conditions. The consistent reduction of miR‐183‐5p in ALS patients and mouse models enhances the notion that miR‐183‐5p is a central regulator of motor neuron survival under stress conditions. Our study supplements current understanding of the mechanistic link between cell stress and death/survival, and provides novel targets for clinical interventions of ALS.     

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.     

miR‐19b controls cardiac fibroblast proliferation and migration

Cardiac fibrosis is a fundamental constituent of a variety of cardiac dysfunction, making it a leading cause of death worldwide. However, no effective treatment for cardiac fibrosis is available. Therefore, novel therapeutics for cardiac fibrosis are highly needed. Recently, miR‐19b has been found to be able to protect hydrogen peroxide (H₂O₂)‐induced apoptosis and improve cell survival in H9C2 cardiomyocytes, while down‐regulation of miR‐19b had opposite effects, indicating that increasing miR‐19b may be a new therapeutic strategy for attenuating cellular apoptosis during myocardial ischaemia–reperfusion injury. However, considering the fact that microRNAs might exert a cell‐specific role, it is highly interesting to determine the role of miR‐19b in cardiac fibroblasts. Here, we found that miR‐19b was able to promote cardiac fibroblast proliferation and migration. However, miR‐19b mimics and inhibitors did not modulate the expression level of collagen I. Pten was identified as a target gene of miR‐19b, which was responsible for the effect of miR‐19b in controlling cardiac fibroblast proliferation and migration. Our data suggest that the role of miR‐19b is cell specific, and systemic miR‐19b targeting in cardiac remodelling might be problematic. Therefore, it is highly needed and also urgent to investigate the role of miR‐19b in cardiac remodelling in vivo.     

Epigallocatechin‐3‐O‐gallate up‐regulates microRNA‐199a‐3p expression by down‐regulating the expression of cyclooxygenase‐2 in stimulated human osteoarthritis chondrocytes

Osteoarthritis (OA) is a most common form of arthritis worldwide leading to significant disability. MicroRNAs (miRNAs) are non‐coding RNAs involved in various aspects of cartilage development, homoeostasis and pathology. Several miRNAs have been identified which have shown to regulate expression of target genes relevant to OA pathogenesis such as matrix metalloproteinase (MMP)‐13, cyclooxygenase (COX)‐2, etc. Epigallocatechin‐3‐O‐gallate (EGCG), the most abundant and active polyphenol in green tea, has been reported to have anti‐arthritic effects, however, the role of EGCG in the regulation of miRNAs has not been investigated in OA. Here, we showed that EGCG inhibits COX‐2 mRNA/protein expression or prostaglandin E₂ (PGE₂) production via up‐regulating microRNA hsa‐miR‐199a‐3p expression in interleukin (IL)‐1β‐stimulated human OA chondrocytes. This negative co‐regulation of hsa‐miR‐199a‐3p and COX‐2 by EGCG was confirmed by transfection of OA chondrocytes with anti‐miR‐199a‐3p. Transfection of OA chondrocytes with anti‐miR‐199a‐3p significantly enhanced COX‐2 expression and PGE₂ production (P < 0.001), while EGCG treatment significantly inhibited anti‐miR‐199a‐3p transfection‐induced COX‐2 expression or PGE₂ production in a dose‐dependent manner. These results were further re‐validated by co‐treatment of these transfection OA chondrocytes with IL‐1β and EGCG. EGCG treatment consistently up‐regulated the IL‐1β‐decreased hsa‐miR‐199a‐3p expression (P < 0.05) and significantly inhibited the IL‐1β‐induced COX‐2 expression/PGE₂ production (P < 0.05) in OA chondrocytes transfected with anti‐hsa‐miR‐199a‐3p. Taken together, these results clearly indicate that EGCG inhibits COX‐2 expression/PGE₂ production via up‐regulation of hsa‐miR‐199a‐3p expression. These novel pharmacological actions of EGCG on IL‐1β‐stimulated human OA chondrocytes provide new suggestions that EGCG or EGCG‐derived compounds inhibit cartilage breakdown or pain by up‐regulating the expression of microRNAs in human chondrocytes.     

MiR‐451 is decreased in hypertrophic cardiomyopathy and regulates autophagy by targeting TSC1

The molecular mechanisms that drive the development of cardiac hypertrophy in hypertrophic cardiomyopathy (HCM) remain elusive. Accumulated evidence suggests that microRNAs are essential regulators of cardiac remodelling. We have been suggested that microRNAs could play a role in the process of HCM. To uncover which microRNAs were changed in their expression, microRNA microarrays were performed on heart tissue from HCM patients (n = 7) and from healthy donors (n = 5). Among the 13 microRNAs that were differentially expressed in HCM, miR‐451 was the most down‐regulated. Ectopic overexpression of miR‐451 in neonatal rat cardiomyocytes (NRCM) decreased the cell size, whereas knockdown of endogenous miR‐451 increased the cell surface area. Luciferase reporter assay analyses demonstrated that tuberous sclerosis complex 1 (TSC1) was a direct target of miR‐451. Overexpression of miR‐451 in both HeLa cells and NRCM suppressed the expression of TSC1. Furthermore, TSC1 was significantly up‐regulated in HCM myocardia, which correlated with the decreased levels of miR‐451. As TSC1 is a known positive regulator of autophagy, we examined the role of miR‐451 in the regulation of autophagy. Overexpression of miR‐451 in vitro inhibited the formation of the autophagosome. Conversely, miR‐451 knockdown accelerated autophagosome formation. Consistently, an increased number of autophagosomes was observed in HCM myocardia, accompanied by up‐regulated autophagy markers, and the lipidated form of LC3 and Beclin‐1. Taken together, our findings indicate that miR‐451 regulates cardiac hypertrophy and cardiac autophagy by targeting TSC1. The down‐regulation of miR‐451 may contribute to the development of HCM and may be a potential therapeutic target for this disease.     

Association of single nucleotide polymorphisms in the microRNA miR‐1596 locus with residual feed intake in chickens

MicroRNAs are an abundant class of small non‐coding RNAs that regulate gene expression. Genetic variations in microRNA sequences may be associated with phenotype differences by influencing the expression of microRNAs and/or their targets. This study identified two single nucleotide polymorphisms (SNPs) in the genomic region of the microRNA miR‐1596 locus of chicken. Of the two SNPs, one was 95 bp upstream of miR‐1596 (g.5678784A>T) and the other was in the middle of the sequence producing the mature microRNA gga‐miR‐1596‐3p (g.5678944A>G). Genotypic distribution of the two SNPs had large differences among 12 chicken breeds (lines), especially between the fast‐growing commercial lines and the slow‐growing Chinese indigenous breeds for the g.5678784A>T SNP. Only the g.5678784A>T SNP was significantly associated with residual feed intake (RFI) in the F₂ population derived from a fast‐growing and a slow‐growing broiler as well as in the pure Huiyang bearded chicken. The birds with the AA genotype of the g.5678784A>T SNP had lower RFI and higher expression of the mature gga‐miR‐1596‐3p microRNA of miR‐1596 than did those with the other genotypes of the same SNP. We also found that the expression of the mature gga‐miR‐1596‐3p microRNA of miR‐1596 was significantly associated with RFI. These findings suggest that miR‐1596 can become a candidate gene related to RFI, and its genetic variation may contribute to changes in RFI by altering expression levels of the mature gga‐miR‐1596‐3p microRNA in chicken.     

Cytotoxic effects of β‐asarone on Sf9 insect cells

β‐Asarone is the predominant component of the essential oil of rhizomes of Acorus calamus Linn ( Sweet flag). Although rhizome extracts from this plant have long been used for insect pest control, their cytotoxic effects on insect cells are not well understood. In this study, we evaluated the potency of β‐asarone as a natural insecticide by using a Spodoptera frugiperda cell line (Sf9). To assess the cytotoxic effects of β‐asarone on Sf9 cells, we observed morphologic changes in treated cells and performed a cell proliferation assay and a DNA fragmentation assay. After 24 and 48 h of treatment with β‐asarone, the proliferation of the Sf9 cells was inhibited in a dose‐dependent manner, with IC₅₀ values of 0.558 mg/ml at 24 h and 0.253 mg/ml at 48 h. Morphologic changes in β‐asarone‐treated cells were typical of apoptosis and included loss of adhesion, cell shrinkage, and small apoptotic bodies. The DNA laddering present in β‐asarone‐treated SF9 cells and annexin V assay confirmed that this compound can induce apoptosis in insect cells. Together, these findings suggest that apoptosis induction may be one mechanism through which β‐asarone inhibits the proliferation of insect cells and thus exerts insecticidal effects.     

MicroRNA‐155 prevents necrotic cell death in human cardiomyocyte progenitor cells via targeting RIP1

To improve regeneration of the injured myocardium, cardiomyocyte progenitor cells (CMPCs) have been put forward as a potential cell source for transplantation therapy. Although cell transplantation therapy displayed promising results, many issues need to be addressed before fully appreciating their impact. One of the hurdles is poor graft‐cell survival upon injection, thereby limiting potential beneficial effects. Here, we attempt to improve CMPCs survival by increasing microRNA‐155 (miR‐155) levels, potentially to improve engraftment upon transplantation. Using quantitative PCR, we observed a 4‐fold increase of miR‐155 when CMPCs were exposed to hydrogen‐peroxide stimulation. Flow cytometric analysis of cell viability, apoptosis and necrosis showed that necrosis is the main cause of cell death. Overexpressing miR‐155 in CMPCs revealed that miR‐155 attenuated necrotic cell death by 40 ± 2.3%via targeting receptor interacting protein 1 (RIP1). In addition, inhibiting RIP1, either by pre‐incubating the cells with a RIP1 specific inhibitor, Necrostatin‐1 or siRNA mediated knockdown, reduced necrosis by 38 ± 2.5% and 33 ± 1.9%, respectively. Interestingly, analysing gene expression using a PCR‐array showed that increased miR‐155 levels did not change cell survival and apoptotic related gene expression. By targeting RIP1, miR‐155 repressed necrotic cell death of CMPCs, independent of activation of Akt pro‐survival pathway. MiR‐155 provides the opportunity to block necrosis, a conventionally thought non‐regulated process, and might be a potential novel approach to improve cell engraftment for cell therapy.