How the RNA isolation method can affect microRNA microarray results

The quality of RNA is crucial in gene expression experiments. RNA degradation interferes in the measurement of gene expression, and in this context, microRNA quantification can lead to an incorrect estimation. In the present study, two different RNA isolation methods were used to perform microRNA microarray analysis on porcine brain tissue. One method is a phenol-guanidine isothiocyanate-based procedure that permits isolation of total RNA. The second method, miRVana? microRNA isolation, is column based and recovers the small RNA fraction alone. We found that microarray analyses give different results that depend on the RNA fraction used, in particular because some microRNAs appear very sensitive to the RNA isolation method. We conclude that precautions need to be taken when comparing microarray studies based on RNA isolated with different methods.     

Genetic characterization of the complete genome of a highly divergent simian T-lymphotropic virus (STLV) type 3 from a wild Cercopithecus mona monkey

Background

RNA interference is a gene regulatory mechanism that employs small RNA molecules such as microRNA. Previous work has shown that HIV-1 produces TAR viral microRNA. Here we describe the effects of the HIV-1 TAR derived microRNA on cellular gene expression.

Results

Using a variation of standard techniques we have cloned and sequenced both the 5' and 3' arms of the TAR miRNA. We show that expression of the TAR microRNA protects infected cells from apoptosis and acts by down-regulating cellular genes involved in apoptosis. Specifically, the microRNA down-regulates ERCC1 and IER3, protecting the cell from apoptosis. Comparison to our cloned sequence reveals possible target sites for the TAR miRNA as well.

Conclusion

The TAR microRNA is expressed in all stages of the viral life cycle, can be detected in latently infected cells, and represents a mechanism wherein the virus extends the life of the infected cell for the purpose of increasing viral replication.     

MicroRNA: Biogenesis, Function and Role in Cancer

MicroRNAs are small, highly conserved non-coding RNA molecules involved in the regulation of gene expression. MicroRNAs are transcribed by RNA polymerases II and III, generating precursors that undergo a series of cleavage events to form mature microRNA. The conventional biogenesis pathway consists of two cleavage events, one nuclear and one cytoplasmic. However, alternative biogenesis pathways exist that differ in the number of cleavage events and enzymes responsible. How microRNA precursors are sorted to the different pathways is unclear but appears to be determined by the site of origin of the microRNA, its sequence and thermodynamic stability. The regulatory functions of microRNAs are accomplished through the RNA-induced silencing complex (RISC). MicroRNA assembles into RISC, activating the complex to target messenger RNA (mRNA) specified by the microRNA. Various RISC assembly models have been proposed and research continues to explore the mechanism(s) of RISC loading and activation. The degree and nature of the complementarity between the microRNA and target determine the gene silencing mechanism, slicer-dependent mRNA degradation or slicer-independent translation inhibition. Recent evidence indicates that P-bodies are essential for microRNA-mediated gene silencing and that RISC assembly and silencing occurs primarily within P-bodies. The P-body model outlines microRNA sorting and shuttling between specialized P-body compartments that house enzymes required for slicer -dependent and -independent silencing, addressing the reversibility of these silencing mechanisms. Detailed knowledge of the microRNA pathways is essential for understanding their physiological role and the implications associated with dysfunction and dysregulation.     

MicroRNA-based RNA Interference Vector for Gene Silencing in Plants

RNA interference (RNAi) is a powerful tool for functional gene analysis, which has been successfully used to down-regulate the levels of specific target genes. In this study a microRNA 159a-based binary vector was constructed which can be used for hpRNA expression. Hairpin (hp) RNA expression cassettes carrying the gene sequences are typically constructed on binary plasmid and delivered into plant cells by Agrobacterium-mediated genetic transformation. This system allows simple insertion of 21- nt target gene sequences into microRNA backbone, to facilitate the processing of microRNA hpRNA by the endogenous machinery of host, thereby producing artificial microRNA carrying the sequence of target gene(s). The functionality of new vector system was tested by silencing viral gene in transgenic plants. Strong down regulation of viral gene was observed in virus infected tobacco plants transformed with pAmiR₁₅₉ vector. The processing of amIRNA leading to viral-specific sIRNA was confirmed by northern blotting. This vector system provides an important addition to the plant molecular biologists’ toolbox, which will significantly facilitate the use of RNAi technology for analyses of various gene functions in plant cells.     

Expression and processing of polycistronic artificial microRNAs and trans-acting siRNAs from transiently introduced transgenes in Solanum lycopersicum and Nicotiana benthamiana

Targeted gene silencing using small regulatory RNAs is a widely used technique for genetic studies in plants. Artificial microRNAs are one common approach, as they have the advantage of producing just a single functional small RNA, which can be designed for high target specificity and low off-target effects. Simultaneous silencing of multiple targets with artificial microRNAs can be achieved by producing polycistronic microRNA precursors. Alternatively, specialized trans-acting short interfering RNA (tasiRNA) precursors can be designed to produce several specific tasiRNAs at once. Here we tested several artificial microRNA- and tasiRNA-based methods for multiplexed gene silencing in Solanum lycopersicum (tomato) and Nicotiana benthamiana. All analyses used transiently expressed transgenes delivered by infiltration of leaves with Agrobacterium tumefacians. Small RNA sequencing analyses revealed that many previously described approaches resulted in poor small RNA processing. The 5′-most microRNA precursor hairpins on polycistronic artificial microRNA precursors were generally processed more accurately than precursors at the 3′-end. Polycistronic artificial microRNAs where the hairpin precursors were separated by transfer RNAs had the best processing precision. Strikingly, artificial tasiRNA precursors failed to be processed in the expected phased manner in our system. These results highlight the need for further development of multiplexed artificial microRNA and tasiRNA strategies. The importance of small RNA sequencing, as opposed to single-target assays such as RNA blots or real-time polymerase chain reaction, is also discussed.     

Position-dependent function for a tandem microRNA miR-122-binding site located in the hepatitis C virus RNA genome

MicroRNAs usually interact with 3' noncoding regions (3'NCRs) of target mRNAs leading to downregulation of mRNA expression. In contrast, liver-specific microRNA miR-122 interacts with the 5' end of the hepatitis C virus RNA genome, resulting in increased viral RNA abundance. We find that inserting the viral miR-122 binding site into the 3' noncoding region of a reporter mRNA leads to downregulation of mRNA expression, indicating that the location of the miR-122 binding site dictates its effect on gene regulation. Furthermore, we discovered an adjacent, second miR-122 binding site, separated from the first by a highly conserved 14-nucleotide sequence. Mutational analysis demonstrates that both miR-122 binding sites in a single viral genome are occupied by the microRNA and function cooperatively to regulate target gene expression. These findings set a paradigm for dual, position-dependent functions of tandem microRNA-binding sites. Targeting an oligomeric microRNA complex offers potential as an antiviral-intervention strategy.     

RNA扩增的研究进展

RNA扩增是伴随着基因芯片技术的应用而发展起来的一项技术,但不仅仅应用于芯片杂交。本文对RNA扩增的技术方法进行了综述,重点介绍了mRNA的线性扩增、指数扩增以及两者相结合的扩增方法以及优缺点,对microRNA的扩增方法也作了介绍,并对将来的发展作了展望。     

MicroRNA functions in animal development and human disease

Five years into the 'small RNA revolution' it is hard not to share in the excitement about the rapidly unravelling biology of microRNAs. Since the discovery of the first microRNA gene, lin-4, in the nematode Caenorhabditis elegans, many more of these short regulatory RNA genes have been identified in flowering plants, worms, flies, fish, frogs and mammals. Currently, about 2% of the known human genes encode microRNAs. MicroRNAs are essential for development and this review will summarise our current knowledge of animal microRNA function. We will also discuss the emerging links of microRNA biology to stem cell research and human disease, in particular cancer.     

Direct microRNA detection with universal tagged probe and time-resolved fluorescence technology

microRNAs have emerged as the central player in gene expression regulation and have been considered as potent cancer biomarkers for early disease diagnosis. Direct microRNA detection without amplification and labeling is highly desired. Here we present a rapid, sensitive and selective microRNA detection method based on the base stacking hybridization coupling with time-resolved fluorescence technology. Other than planar microarrays, magnetic beads are used as reaction platforms. In this method, one universal tag is used to report all microRNA targets. Its specificity allows for discrimination between microRNAs differing by a single nucleotide, and between precursor and mature microRNAs. This method also provides a high sensitivity down to 20 fM. Moreover, the full protocol can be completed in about 3 h starting from total RNA.     

microRNA的实验和生物信息学开发方法

mircroRNA是一类约22nt的内源小分子RNA,普遍存在于真核生物体内,它通过与靶基因互补结合来调控基因表达,从而对生物体的生长、发育等起到重要的调节作用。随着生物学技术的不断发展,mircroRNA研究的越发深入,越来越多的mircroRNA被开发出来。本文结合了mircroRNA的生理特点,从RNA、DNA和生物信息学预测这3个方面归纳总结有关开发microRNA的方法,以及由此衍生出来的相关的研究方法。通过对这些研究方法的分类总结,不但为mircroRNA以后的研究工作奠定良好的基础,而且有利于新技术的研发。     

小鼠肝脏MicroRNA的提取与分离

本文对小鼠肝脏microRNA进行分离制备及相关性功能研究.采用poly(A)加尾方法,分离提取小鼠肝脏中的microRNA;利用T4 RNA连接酶,在microRNA两端加上连接引物,通过RT PCR制备microRNA的cDNA文库;经过对cDNA文库的质粒连接,克隆测序获得microRNA. 结果显示：获得4条有效序列,其中包括2条已知序列miR 122和2条未知小分子RNA序列.经查证, 2条microRNA片段在miRBase库中未有记录,在二级结构分析中可形成茎环结构,符合microRNA的特征. BLAST比对显示： 2个序列位于小鼠载脂蛋白B基因和小鼠28S核糖体RNA上,可能与基因调控有关,其功能有待进一步研究.     

Big things from a little RNA

In a recent study, Brennecke and colleagues show that bantam, a previously elusive Drosophila gene that promotes tissue growth, encodes a microRNA. The bantam microRNA regulates cell number in vivo and inhibits cell death by binding to the mRNA of the pro-apoptotic gene hid. These findings demonstrate that a single, tiny Drosophila RNA can regulate organ and organism size and link the nascent field of microRNA function to the study of pathways that coordinate cell death, cell growth and cell proliferation during the development of metazoan organisms.