Genetic architecture modulates diet-induced hepatic mRNA and miRNA expression profiles in Diversity Outbred mice

Genetic approaches in model organisms have consistently demonstrated that molecular traits such as gene expression are under genetic regulation, similar to clinical traits. The resulting expression quantitative trait loci (eQTL) have revolutionized our understanding of genetic regulation and identified numerous candidate genes for clinically relevant traits. More recently, these analyses have been extended to other molecular traits such as protein abundance, metabolite levels, and miRNA expression. Here, we performed global hepatic eQTL and microRNA expression quantitative trait loci (mirQTL) analysis in a population of Diversity Outbred mice fed two different diets. We identified several key features of eQTL and mirQTL, namely differences in the mode of genetic regulation (cis or trans) between mRNA and miRNA. Approximately 50% of mirQTL are regulated by a trans-acting factor, compared to ∼25% of eQTL. We note differences in the heritability of mRNA and miRNA expression and variance explained by each eQTL or mirQTL. In general, cis-acting variants affecting mRNA or miRNA expression explain more phenotypic variance than trans-acting variants. Finally, we investigated the effect of diet on the genetic architecture of eQTL and mirQTL, highlighting the critical effects of environment on both eQTL and mirQTL. Overall, these data underscore the complex genetic regulation of two well-characterized RNA classes (mRNA and miRNA) that have critical roles in the regulation of clinical traits and disease susceptibility     

Neuronal activity regulates hippocampal miRNA expression

Neuronal activity regulates a broad range of processes in the hippocampus, including the precise regulation of translation. Disruptions in proper translational control in the nervous system are associated with a variety of disorders that fall in the autistic spectrum. MicroRNA (miRNA) represent a relatively recently discovered player in the regulation of translation in the nervous system. We have conducted an in depth analysis of how neuronal activity regulates miRNA expression in the hippocampus. Using deep sequencing we exhaustively identify all miRNAs, including 15 novel miRNAs, expressed in hippocampus of the adult mouse. We identified 119 miRNAs documented in miRBase but less than half of these miRNA were expressed at a level greater than 0.1% of total miRNA. Expression profiling following induction of neuronal activity by electroconvulsive shock demonstrates that most miRNA show a biphasic pattern of expression: rapid induction of specific mature miRNA expression followed by a decline in expression. These results have important implications into how miRNAs influence activity-dependent translational control.     

Strategies for profiling microRNA expression

MicroRNAs (miRNAs) are a class of small RNAs ( approximately 22-nt) that play an important role in the control of different cell processes by negative regulation of protein-coding genes. In the last several years, a number of miRNA profiling strategies have been used to document the miRNA expression changes during physiological and pathological processes. Aberrant expression of miRNAs has been linked to developmental defects, cancer, neurological disorders, and heart diseases. Over 540 human miRNAs have been validated to date; however, computer models suggest there may be thousands more. As bench work continue to verify in silico predictions, miRNA profiling will remain a prominent tool for identification of differential expression miRNAs in normal cellular courses and human disorders. This review focuses on current strategies for miRNA expression profiling and discusses their sensitivity and specificity, as well as advantage and disadvantage.     

Identification of putative miRNAs from the deep-branching unicellular flagellates

MicroRNAs (miRNAs) are a class of extensively studied RNAi-associated small RNAs that play a critical role in eukaryotic gene regulation. However, knowledge on the miRNA and its regulation in unicellular eukaryotes is very limited. In order to obtain a better understanding on the origin of miRNA regulation system, we used deep-sequencing technology to investigate the miRNA expression pattern in four deep-branching unicellular flagellates: Giardia lamblia, Trichomonas vaginalis, Tritrichomonas foetus, and Pentatrichomonas hominis. In addition to the known miRNAs that have been described in G. lamblia and T. vaginalis, we identified 14 ancient animal miRNA families and 13 plant-specific families. Bioinformatics analysis also identified four novel miRNA candidates with reliable precursor structures derived from mature tRNAs. Our results indicated that miRNAs are likely to be a general feature for gene regulation throughout unicellular and multicellular eukaryotes and some of them may derive from unconventional ncRNAs such as snoRNA and tRNA.     

microRNA在脆性X综合征发病机制中的研究进展

脆性X综合征(fragile X syndrome,FXS)是最常见的遗传性认知障碍疾病,也是一种与自闭症谱系障碍(autism spectrum disorder,ASD)相关的严重的基因疾病.它主要是由于脆性X智力低下基因1(fragile X mental retardation 1,FMR1)的异常扩增及其上游Cp G岛的异常甲基化,导致其编码的脆性X智力低下蛋白(fragile X mental retardation protein,FMRP)表达减少或缺失引起的.FMRP与miRNA(micro RNA)均具有翻译抑制活性,而且FMRP在生物化学和遗传学上均与miRNA调控通路有相互作用.此外,越来越多的研究发现miRNA调控通路在FXS的发病和治疗中发挥作用.因此,本文对miRNA的功能及其与脆性X蛋白家族成员间的相互作用进行阐述,为在miRNA水平了解FXS的发病机制奠定基础.     

A single-molecule method for the quantitation of microRNA gene expression

MicroRNAs (miRNA) are short endogenous noncoding RNA molecules that regulate fundamental cellular processes such as cell differentiation, cell proliferation and apoptosis through modulation of gene expression. Critical to understanding the role of miRNAs in this regulation is a method to rapidly and accurately quantitate miRNA gene expression. Existing methods lack sensitivity, specificity and typically require upfront enrichment, ligation and/or amplification steps. The Direct miRNA assay hybridizes two spectrally distinguishable fluorescent locked nucleic acid (LNA)-DNA oligonucleotide probes to the miRNA of interest, and then tagged molecules are directly counted on a single-molecule detection instrument. In this study, we show the assay is sensitive to femtomolar concentrations of miRNA (500 fM), has a three-log linear dynamic range and is capable of distinguishing among miRNA family members. Using this technology, we quantified expression of 45 human miRNAs within 16 different tissues, yielding a quantitative differential expression profile that correlates and expands upon published results.     

microRNA参与植物次生代谢与非生物胁迫的调控

微RNA(microRNA,miRNA)为广泛存在于真核生物中的约16 ～ 29个核苷酸长度的内源非编码单链RNA分子,在植物中参与细胞增殖、分化、代谢、器官形成以及抵御盐、温度、干旱、重金属胁迫等方面的调节.植物miRNA主要通过对靶基因降解或抑制靶基因的表达,影响植物的生长发育.目前对miRNA的产生与调控方式的研...     

Mechanisms of microRNA-mediated gene regulation

microRNAs (miRNAs) are identified as a class of non-protein regulators and a new source for broad control of gene expression in eukaryotes. The past years have witnessed substantial progress in understanding miRNA functions and mechanisms, although a few controversies remain. Various hypotheses and models have been suggested for the mechanisms of miRNA repression, including translational inhibition at the level of initiation or elongation, rapid degradation of the nascent peptide, mRNA degradation, and mRNA sequestration into P bodies (processing bodies) and SGs (stress granules) for degradation or/and storage. Recently, some noncanonical miRNA regulation, such as miRNA activation and de-repression of miRNA inhibition, have been uncovered. This review discusses some recent advances about how miRNAs regulate their targets and various modes of miRNA function.     

Environmental chemicals and microRNAs

MicroRNAs (miRNAs) are short single-stranded non-coding molecules that function as negative regulators to silence or suppress gene expression. Aberrant miRNA expression has been implicated in a several cellular processes and pathogenic pathways of a number of diseases. Evidence is rapidly growing that miRNA regulation of gene expression may be affected by environmental chemicals. These environmental exposures include those that have frequently been associated with chronic diseases, such as heavy metals, air pollution, bisphenol A, and cigarette smoking. In this article, we review the published data on miRNAs in relation to the exposure to several environmental chemicals, and discuss the potential mechanisms that may link environmental chemicals to miRNA alterations. We further discuss the challenges in environmental-miRNA research and possible future directions. The accumulating evidence linking miRNAs to environmental chemicals, coupled with the unique regulatory role of miRNAs in gene expression, makes miRNAs potential biomarkers for better understanding the mechanisms of environmental diseases.     

siRNA与miRNA在生物基因调控中的沉默机制比较

siRNA和miRNA的沉默机制是生物基因调控的重要手段之一. 小干扰RNA（small interfering RNA,siRNA）是RNA干扰的引发物,激发与之互补的目标mRNA沉默. 非编码RNA中的微小RNA（microRNA,miRNA）,能够识别特定的目标mRNA,通过与mRNAs的3′ 非翻译区结合,影响该目标蛋白的翻译水平. siRNA和miRNA的基因调控机制对生物学研究及疾病的病因和治疗等有直接影响. 本文主要对siRNAs和miRNAs的生物起源及沉默机制进行比较性论述：提出Dicers酶蛋白、Ago蛋白以及20 nt~25 nt的双链RNAs的 3类大分子是RNA沉默的特征结构,并进行了说明性论述|总结性叙述了siRNA和miRNA的2类小分子经典沉默机制,并提出其异同点. 最后,本文根据近期研究进展,对siRNA和miRNA的生物起源及沉默机制提出了新的疑问.     

MicroRNA定量检测方法的研究进展

MicroRNA是一类内源性的非编码小分子RNA, 通过下调蛋白编码基因的表达而对不同的细胞发育过程起到重要的调控作用。分析组织或细胞样本中microRNA的表达可为研究这类分子的生物学功能提供重要的信息。近年来, 研究者发展了许多方法检测不同的生理和病理学过程中microRNA的表达差异, 并发现microRNA的异常表达与癌症、神经紊乱和心脏疾病等的发生相关。文章系统地介绍了最新发展的microRNA定量检测方法, 详细阐述了基于探针杂交技术的Northern blotting法、微阵列芯片法、纳米金标记法、桥连同位素标记法, 以及基于扩增技术的定量PCR检测法、滚环扩增法、引物入侵法和新一代大规模高通量测序法等, 并对这些方法的优缺点进行了分析比较。     

Altered Gene Expression Associated with microRNA Binding Site Polymorphisms

Allele-specific gene expression associated with genetic variation in regulatory regions can play an important role in the development of complex traits. We hypothesized that polymorphisms in microRNA (miRNA) response elements (MRE-SNPs) that either disrupt a miRNA binding site or create a new miRNA binding site can affect the allele-specific expression of target genes. By integrating public expression quantitative trait locus (eQTL) data, miRNA binding site predictions, small RNA sequencing, and Argonaute crosslinking immunoprecipitation (AGO-CLIP) datasets, we identified genetic variants that can affect gene expression by modulating miRNA binding efficiency. We also identified MRE-SNPs located in regions associated with complex traits, indicating possible causative mechanisms associated with these loci. The results of this study expand the current understanding of gene expression regulation and help to interpret the mechanisms underlying eQTL effects.