外泌体源性miRNAs在肺癌发生发展中的作用

外泌体(exosomes)是细胞分泌的纳米级细胞外囊泡.外泌体通过释放其内的生物活性大分子,比如微小RNA(microRNA,miRNA)到受体细胞,从而介导细胞间交流通讯. MiRNAs作为一类主要在转录后水平负向调控靶mRNAs的非编码RNAs,其在外泌体中含量最为丰富.在肺癌中,miRNAs经肿瘤细胞分泌的外泌体转运释放而发挥重要的作用.本文主要讨论了外泌体源性miRNAs在肺癌发生发展的各个阶段,包括血管生成、细胞增殖、侵袭转移、免疫逃逸、耐药等方面的作用,以及其在作为新型肺癌诊断和预后标志物方面的临床价值.     

不同强度运动训练对心肌凋亡途径微小RNA及其靶蛋白的影响

目的：考察不同负荷运动训练对小鼠心肌凋亡相关miR-1,miR-21和靶蛋白的影响,探讨运动干预心肌凋亡的可能机制。方法：选取21只C57BL/6小鼠,随机分为3组（n=7）：安静组（SE组）、训练1组（ET1组）、训练2组（ET2）。SE组不进行训练,ET1组完成8周递增负荷游泳训练,5天/周,1次/天,第1周30 min/count,每周增加10 min,第7、8周时间维持在90 min;ET2组在ET1组方案基础上增加负荷,前5周与ET1相同,后3周每天训练2次。TUNEL检测考察心肌凋亡水平,Western blot和RT-PCR分别测定蛋白和miRs的变化。结果：ET1组游泳训练对小鼠心肌凋亡影响不明显,miR-1表达无显著变化,但其靶蛋白Bcl-2表达显著增高（P<0.01）,miR-21及其靶蛋白PDCD4表达均无显著变化。ET2组游泳训练显著降低心肌凋亡水平及miR-1表达（P<0.01）、提高Bcl-2表达（P<0.05）;同时显著提高miR-21表达（P<0.05）,但对PDCD4表达无明显影响。结论：ET1组训练对心肌凋亡干预不明显,ET2组运动训练可降低心肌凋亡水平,miR-1及靶蛋白Bcl-2变化可能是机制之一,PDCD4对运动训练不敏感,miR-21可能与其它靶蛋白参与运动干预心肌凋亡的分子机制。     

The Role of Epigenetic Regulation and Pluripotency‐Related MicroRNAs in Differentiation of Pancreatic Stem Cells to Beta Cells

In this study, we aimed to research the effects of class‐I HDACs and glucose on differentiation of pancreatic islet derived mesenchymal stem cells (PI‐MSCs) to beta cells. Beta cell differentiation determined by flow cytometric analysis and gene expression levels of PDX1, PAX4, PAX6, NKX6.1, NGN3, INS2, and GLUT2. As a result the valproic acid, is an inhibitor of class‐I HDACs, caused the highest beta cell differentiation in PI‐MSCs. However, the cells in this group were at early stages of differentiation. Glucose co‐administration to this group carried the differentiation to higher levels, but these newly formed beta cells were not functional. Moreover, reduction in the levels of pluripotency factors that Oct3/4, c‐Myc, and Nanog were parallel to beta cell differentiation. Also, the levels of HDAC1 and acetylated H3/H4 were increased and methylated H3 was decreased by VPA treatment. In addition, we have detected over expression in genes of miR‐18a‐5p, miR‐19b‐5p, miR‐30d‐3p, miR‐124, miR‐146a‐5p, miR‐184, miR‐335, and miR‐433‐5p in parallel to beta cell differentiation. As the conclusion, this study is important for understanding the epigenetic mechanism that controls the beta cell differentation and it suggests new molecules that can be used for diagnosis, and treatment of diabetes. J. Cell. Biochem. 119: 455–467, 2018. © 2017 Wiley Periodicals, Inc.     

Daphnia magna microRNAs respond to nutritional stress and ageing but are not transgenerational

Maternal effects, where the performance of offspring is determined by the condition of their mother, are widespread and may in some cases be adaptive. The crustacean Daphnia magna shows strong maternal effects: offspring size at birth and other proxies for fitness are altered when their mothers are older or when mothers have experienced dietary restriction. The mechanisms for this transgenerational transmission of maternal experience are unknown, but could include changes in epigenetic patterning. MicroRNAs (miRNAs) are regulators of gene expression that have been shown to play roles in intergenerational information transfer, and here, we test whether miRNAs are involved in D. magna maternal effects. We found that miRNAs were differentially expressed in mothers of different ages or nutritional state. We then examined miRNA expression in their eggs, their adult daughters and great granddaughters, which did not experience any treatments. The maternal (treatment) generation exhibited differential expression of miRNAs, as did their eggs, but this was reduced in adult daughters and lost by great granddaughters. Thus, miRNAs are a component of maternal provisioning, but do not appear to be the cause of transgenerational responses under these experimental conditions. MicroRNAs may act in tandem with egg provisioning (e.g., with carbohydrates or fats), and possibly other small RNAs or epigenetic modifications.     

Molecular Paths Linking Metabolic Diseases,Gut Microbiota Dysbiosis and Enterobacteria Infections

Alterations of both ecology and functions of gut microbiota are conspicuous traits of several inflammatory pathologies, notably metabolic diseases such as obesity and type 2 diabetes. Moreover, the proliferation of enterobacteria, subdominant members of the intestinal microbial ecosystem, has been shown to be favored by Western diet, the strongest inducer of both metabolic diseases and gut microbiota dysbiosis. The inner interdependence between the host and the gut microbiota is based on a plethora of molecular mechanisms by which host and intestinal microbes modify each other. Among these mechanisms are as follows: (i) the well-known metabolic impact of short chain fatty acids, produced by microbial fermentation of complex carbohydrates from plants; (ii) a mutual modulation of miRNAs expression, both on the eukaryotic (host) and prokaryotic (gut microbes) side; (iii) the production by enterobacteria of virulence factors such as the genotoxin colibactin, shown to alter the integrity of host genome and induce a senescence-like phenotype in vitro; (iv) the microbial excretion of outer-membrane vesicles, which, in addition to other functions, may act as a carrier for multiple molecules such as toxins to be delivered to target cells. In this review, I describe the major molecular mechanisms by which gut microbes exert their metabolic impact at a multi-organ level (the gut barrier being in the front line) and support the emerging triad of metabolic diseases, gut microbiota dysbiosis and enterobacteria infections.     

Pluripotency-associated miR-290/302 family of microRNAs promote the dismantling of naive pluripotency

The molecular mechanism controlling the dismantling of naive pluripotency is poorly understood. Here we show that microRNAs (miRNAs) have important roles during naive to primed pluripotency transition. Dgcr8^−/− embryonic stem cells (ESCs) failed to completely silence the naive pluripotency program, as well as to establish the primed pluripotency program during differentiation. miRNA profiling revealed that expression levels of a large number of miRNAs changed dynamically and rapidly during naive to primed pluripotency transition. Furthermore, a miRNA screen identified numerous miRNAs promoting naive to primed pluripotency transition. Unexpectedly, multiple miRNAs from miR-290 and miR-302 clusters, previously shown as pluripotency-promoting miRNAs, demonstrated the strongest effects in silencing naive pluripotency. Knockout of both miR-290 and miR-302 clusters but not either alone blocked the silencing of naive pluripotency program. Mechanistically, the miR-290/302 family of miRNAs may facilitate the exit of naive pluripotency in part by promoting the activity of MEK pathway and through directly repressing Akt1. Our study reveals miRNAs as an important class of regulators potentiating ESCs to transition from naive to primed pluripotency, and uncovers context-dependent functions of the miR-290/302 family of miRNAs at different developmental stages.