RNA结合蛋白与RNA互作鉴定技术

RNA结合蛋白（RNA binding proteins,RBPs）通过与RNA相互作用,广泛参与到RNA的剪切、转运、编辑、胞内定位及翻译调控等过程中。RNA领域尤其是非编码RNA（non-coding RNA,ncRNA）研究的快速发展,催生了多种RBPs RNAs相互作用鉴定技术。这些技术反之又推动了 RNA领域的研究进程。本文对紫外交联免疫沉淀（ultraviolet crosslinking and immunoprecipitation,CLIP）,CLIP cDNA文库高通量测序 (high-throughput sequencing of CLIP cDNA library,HITS-CLIP),光活化核苷增强的CLIP(photoactivatable-ribonucleoside-enhanced crosslinking and immunoprecipitation,PAR-CLIP),单核苷酸分离CLIP (individual nucleotide resolution CLIP,iCLIP),TRIBE (targets of RNA-binding protein identified by editing),RNA 标记,相互作用组捕获(interactome capture,IC) 和SerIC (serial RNA interactome capture)等RBPs-RNAs相互作用鉴定技术的基本原理和优缺点以及应用进行综述。     

RNA结合蛋白与非编码RNA调节关系的研究进展

近年来,越来越多的研究表明,RNA结合蛋白(RNA binding protein,RBP)与多种类型的非编码RNAs(noncoding RNA,ncRNAs)具有互相调节的关系,且调节机制形式多样。一方面,RBP可以调节ncRNA的生物合成、稳定性和功能;另一方面,ncRNA也可以影响RBP的功能和结构。同时,RBP和ncRNA的相互作用还在其他靶基因的调节上起着重要的作用,从而参与众多的生物过程,如组织发育、代谢性疾病、神经退行性疾病、抗病毒免疫和各种癌症等。该文就RBP与常见类型的ncRNAs,包括miRNA、lncRNA、circRNA的相互作用方式和调节机制的研究进展作一综述。     

紫外交联免疫沉淀技术原理及其应用

紫外交联免疫沉淀（UV cross-linking immunoprecipitation,CLIP）技术最初建立于2003年。通过紫外交联、免疫沉淀、逆转录及后续的高通量测序等步骤,可在全转录组范围鉴定特定RNA结合蛋白（RNA-binding proteins,RBP）的靶标RNA序列和结合位点。在近20年的应用过程中,该技术被不断改进和完善,可操作性、实验结果的准确性都有所提升,技术的应用范围也有所拓展。本文对CLIP技术的基本原理、实验方法、实际应用进行介绍,着重比较几种主流CLIP技术的异同,并对如何选择具体的技术路线提出建议。     

RNA结合蛋白与RNA相互作用鉴定技术

RNA结合蛋白(RNA binding proteins,RBPs)通过与RNA相互作用,广泛参与到RNA的剪切、转运、编辑、胞内定位及翻译调控等过程中。RNA领域尤其是非编码RNA(non-coding RNA,ncRNA)研究的快速发展,催生了多种RBPs-RNAs相互作用鉴定技术。这些技术反之又推动了RNA领域的研究进程。本文对紫外交联免疫沉淀(ultraviolet crosslinking and immunoprecipitation,CLIP),CLIP cDNA文库高通量测序(high-throughput sequencing of CLIP cDNA library,HITS-CLIP),光活化核苷增强的CLIP(photoactivatable-ribonucleoside-enhanced crosslinking and immunoprecipitation,PAR-CLIP),单核苷酸分离CLIP(individual nucleotide resolution CLIP,i CLIP),TRIBE(targets of RNA-binding protein identified by editing),RNA标记,相互作用组捕获(interactome capture,IC)和Ser IC(serial RNA interactome capture)等RBPs-RNAs相互作用鉴定技术的基本原理和优缺点以及应用进行综述。     

RNA干扰技术的原理与应用

RNA干扰(RNA interference,RNAi)是由双链RNA(double-stranded RNA,dsRNA)所引起的序列特异性基因沉默,是真核生物中一种非常保守的机制,它与协同抑制(cosuppression)、转座子沉默(transposon silencing)以及发育等许多重要的生物学过程密切相关。RNA干扰依赖于小干扰RNA(Small interference RNA,siRNA)与靶序列之间严格的碱基配对,具有很强的特异性,涉及众多基因和蛋白复合物,构成了一个以小RNA为核心的真核基因表达调控系统,它可以在染色质水平、转录水平、转录后水平和翻译水平参与基因表达的调节。RNA干扰技术为人们迅速、准确的剖析基因的功能,分析基因之间错综复杂的联系和相互作用提供了极为有用的工具,同时也为人们预防和治疗癌症和病毒疾病提供了新的思路。     

活细胞内RNA标记和成像技术

RNA根据其定位、结构、修饰以及与其他生物分子的动态相互作用,复杂而精确地执行丰富多彩的功能。RNA-蛋白质相互作用和RNA在细胞内定位的异常与多种疾病的发生发展密切相关。活细胞RNA标记和成像技术已成为研究RNA定位和运动、基因转录调控及RNA-蛋白质相互作用等生物学过程的有力工具。活细胞RNA标记和成像技术的开发已成为国际科学研究领域的热点。将目前存在的活细胞内RNA标记和成像技术方面的研究进展进行概述。     

黑腹果蝇头部中RNA结合蛋白RBP9的互作蛋白筛选

【目的】筛选RNA结合蛋白RBP9在黑腹果蝇Drosophila melanogaster头部中的互作蛋白。【方法】利用CRISPR/Cas9基因组编辑技术,分别将3×Flag和V5标签编码序列插入到黑腹果蝇成虫头中RBP9和FNE基因起始密码子ATG的后面,构建黑腹果蝇转基因品系3×Flag-RBP 9/3×Flag-RBP9(3FRBP9)和V5-FNE/V5-FNE(VFNE);利用免疫沉淀和质谱法鉴定黑腹果蝇3FRBP9和野生型品系成虫头部中RBP9的互作蛋白并进行生物信息学分析。利用免疫共沉淀方法检测RBP9与FNE蛋白之间的相互作用。【结果】质谱法从黑腹果蝇成虫头部共鉴定了190个与RBP9相互作用的蛋白,其中包括ELAV和FNE。KEGG富集分析显示这些蛋白的基因主要参与核糖体、碳代谢、三羧酸循环、氨基酸生物合成等通路。免疫共沉淀实验结果验证了RBP9与FNE蛋白之间存在相互作用。【结论】RNA结合蛋白ELAV家族成员在黑腹果蝇成虫头部中具有相互作用。本研究为RBP9在果蝇神经系统发育中的功能研究提供了重要实验依据。     

长链非编码RNA的作用机制及其研究方法

长链非编码RNA(Long non-coding RNA, lncRNA)通过多种机制发挥其生物学功能, 这些机制包括基因印记、染色质重塑、细胞周期调控、剪接调控、mRNA降解和翻译调控等。lncRNA通过这些作用机制在不同水平进行基因表达调控。在研究lncRNA功能的过程中, 研究方法的建立和应用起着非常重要的作用。目前用于lncRNA研究的主要方法有：微阵列、转录组测序、Northern印迹、实时荧光定量逆转录-聚合酶链反应、荧光原位杂交、RNA干扰和RNA结合蛋白免疫沉淀等。文章着重介绍了3种前沿方法, 即：在线快速预测RNA与蛋白质相互作用的catRAPID、RNA纯化的染色质分离(Chromatin isolation by RNA purification, ChIRP)以及非编码RNA沉默与定位分析技术(Combined knockdown and localization analysis of non-coding RNAs, c-KLAN)。     

非编码RNA在流感病毒与宿主互作过程中的作用北大核心CSCD

非编码RNA(non-coding RNA,ncRNA)是一类不具备蛋白质编码能力的RNA。随着转录组研究和新一代测序技术的发展,ncRNAs被证明能够调控包含病毒与宿主相互作用在内的诸多生命活动过程。流感病毒是严重威胁人类健康和畜牧业生产的重要病毒,其与宿主互作机制及互作过程中产生的病毒变异情况十分复杂。近年来研究表明,许多ncRNAs在流感病毒与宿主的相互作用过程中发挥重要作用。揭示这些ncRNAs在流感病毒感染、复制等过程中的功能,对于阐明流感病毒的致病机理具有重要意义,也为防控流感提供参考。因此,本文对在流感病毒感染中发挥重要调控作用的ncRNAs进行综述。     

非编码RNA在流感病毒与宿主互作过程中的作用

非编码RNA(non-coding RNA,ncRNA)是一类不具备蛋白质编码能力的RNA。随着转录组研究和新一代测序技术的发展,ncRNAs被证明能够调控包含病毒与宿主相互作用在内的诸多生命活动过程。流感病毒是严重威胁人类健康和畜牧业生产的重要病毒,其与宿主互作机制及互作过程中产生的病毒变异情况十分复杂。近年来研究表明,许多ncRNAs在流感病毒与宿主的相互作用过程中发挥重要作用。揭示这些ncRNAs在流感病毒感染、复制等过程中的功能,对于阐明流感病毒的致病机理具有重要意义,也为防控流感提供参考。因此,本文对在流感病毒感染中发挥重要调控作用的ncRNAs进行综述。     

High throughput platform to explore RNA–protein interactomes

RNA binding proteins (RBPs) and RNA interaction is an emerging topic in molecular biology. Many reports showed that such interactions contribute to many cellular processes as well as disease development. Several standard in vitro and in vivo methods were developed to fulfill the needs of this RBP–RNA interaction study to explore their biological functions. However, these methods have their limitations in terms of throughput. In this review, we emphasize two important high throughput methods to studying RBP–RNA interactions, affinity purification and protein microarray. These methods have recently become robust techniques regarding their efficiency in systematically analyzing RBP–RNA interactions. Here, we provide technique overviews, strategies and applications of these methods during biological research. Although these technologies are just beginning to be explored, they will be most important methods in this study.     

Genome-wide Mapping of Cellular Protein–RNA Interactions Enabled by Chemical Crosslinking

RNA–protein interactions influence many biological processes. Identifying the binding sites of RNA-binding proteins（RBPs） remains one of the most fundamental and important challenges to the studies of such interactions. Capturing RNA and RBPs via chemical crosslinking allows stringent purification procedures that significantly remove the non-specific RNA and protein interactions. Two major types of chemical crosslinking strategies have been developed to date, i.e., UV-enabled crosslinking and enzymatic mechanism-based covalent capture. In this review, we compare such strategies and their current applications, with an emphasis on the technologies themselves rather than the biology that has been revealed. We hope such methods could benefit broader audience and also urge for the development of new methods to study RNA RBP interactions.     

Trypanosoma brucei: functions of RBP16 cold shock and RGG domains in macromolecular interactions

The RNA binding protein RBP16 regulates mitochondrial RNA editing and stability in Trypanosoma brucei. To aid in understanding the biochemical mechanisms of RBP16 function, we analyzed the RNA and protein binding capacity of RBP16 and its individual cold shock (CSD) and RGG domains. Both recombinantly expressed domains possess RNA binding activity. However, the specificity and affinity of RBP16 for gRNA is mediated predominantly through the interaction of the CSD with poly(U). The RGG domain contributes to the association between full length RBP16 and gRNA, as it was required for maximal binding. We further demonstrate that both domains contribute to maximal binding of RBP16 to the mitochondrial p22 protein. However, p22 can interact with the CSD alone and stimulate its gRNA binding activity. Thus, the CSD is primary in RBP16 interactions, while the RGG domain enhances the capacity of the CSD to bind both RNA and protein. These results suggest a model for RBP16 molecular interactions.     

GoldCLIP: Gel-omitted Ligation-dependent CLIP

Protein–RNA interaction networks are essential to understand gene regulation control.Identifying binding sites of RNA-binding proteins(RBPs) by the UV-crosslinking and immunoprecipitation(CLIP) represents one of the most powerful methods to map protein–RNA interactions in vivo. However, the traditional CLIP protocol is technically challenging, which requires radioactive labeling and suffers from material loss during PAGE-membrane transfer procedures. Here we introduce a super-efficient CLIP method(Gold CLIP) that omits all gel purification steps. This nonisotopic method allows us to perform highly reproducible CLIP experiments with polypyrimidine tract-binding protein(PTB), a classical RBP in human cell lines. In principle, our method guarantees sequencing library constructions, providing the protein of interest can be successfully crosslinked to RNAs in living cells. Gold CLIP is readily applicable to diverse proteins to uncover their endogenous RNA targets.