利用串联亲和纯化技术分离大肠杆菌GroEL蛋白复合物

肠出血性大肠杆菌O157∶H7是一种重要的致病菌,加深其致病机理的基础研究将为相关疫苗研究及疾病控制等提供新的思路和依据.串联亲和纯化(TAP)技术是最近发展的分离纯化天然状态蛋白质复合物进而研究蛋白质相互作用的新方法.用我们自己构建的原核表达串联亲和标签载体,在大肠杆菌O157∶H7中表达了标签融合蛋白GroEL-TAP,建立了非变性条件下制备蛋白复合物的方法,并且对串联亲和纯化过程中的相关实验条件进行了探索和优化,最终得到了高纯度的GroEL-TAP与天然GroEL形成的嵌合型多聚体复合物.这表明我们建立的串联亲和纯化技术能高度特异地纯化靶蛋白参与形成的复合物,为后续寻找O157∶H7中毒力蛋白参与形成的复合物奠定了实验基础.     

串联亲和纯化原核表达载体的构建

【目的】构建串联亲和纯化原核表达载体,用于研究细菌中(生理状态或接近生理条件下的)蛋白-蛋白相互作用。【方法】设计并合成两条串联亲和标签序列,分别可以在靶蛋白N端和C端融合Protein G和链亲和素结合肽(Streptavidin binding peptide,SBP)标签;以pUC18载体为骨架,去除原有的阻遏蛋白基因,构建组成型表达载体pNTAP和pCTAP。【结果】成功构建N端和C端标签表达载体pNTAP和pCTAP,它们在大肠杆菌(Escherichia coli)BL21(DE3)、肠出血性大肠杆菌O157:H7和痢疾杆菌福氏5型M90T菌株中都可以实现表达。【结论】本实验构建的两个串联亲和纯化表达载体可以在部分革兰氏阴性细菌中表达,为研究细菌内蛋白-蛋白相互作用及致病菌毒力蛋白的作用机制奠定了基础。     

HeLa细胞端粒酶的分离纯化及其蛋白质组分的研究

根据端粒酶含有蛋白质组分和RNA组分的特点,采用寡核苷酸亲和纯化法从HeLa细胞蛋白粗提物中分离纯化人类端粒酶,纯化产物以TRAP法检测其延伸端粒活性,并采用RNA印迹法进行鉴定,然后从纯化产物中分离蛋白质组分,以SDS-聚丙烯酰胺凝胶电泳检测其蛋白质亚基成分,可见到4种蛋白质亚基成分,与蛋白质分子质量标准比较,有两条位置接近212.2 ku,一条接近116.0 ku,一条接近42.7 ku.结果表明,蛋白质寡核苷酸亲和纯化法一步性分离纯化HeLa细胞端粒酶可得到端粒酶活性片段.     

风疹病毒衣壳蛋白与宿主细胞相互作用蛋白的初步筛选及分析

风疹病毒(Rubella virus,RV)的衣壳蛋白(Capsid protein,CP)不仅是病毒颗粒的重要组成部分,而且还可以通过与宿主蛋白之间的相互作用来调控病毒的转录和复制.为了系统研究衣壳蛋白与宿主蛋白之间的相互作用关系,我们从RV基因组中克隆获得衣壳蛋白基因序列,将该序列导入含有eXact-6His串联亲和纯化标签的慢病毒表达载体中,并构建了稳定表达eXact-6His-Capsid融合蛋白的293T细胞系.通过eXact和6His标签的两次亲和纯化获得衣壳蛋白相互作用蛋白复合物,质谱检测并筛选后发现22个可能与衣壳蛋白相互作用的宿主蛋白.随后构建衣壳蛋白的相互作用网络并进行功能学分析,发现其相互作用蛋白主要参与病毒感染、RNA剪切、细胞凋亡及酶相关通路等过程.     

TAP亲和标签选择及其在植物蛋白互作研究中的应用

串联亲和纯化法(TAP)是一种纯化生理条件下蛋白复合物的技术,已广泛应用于鉴定蛋白相互作用和揭示蛋白复合物互作网络。近年来,随着TAP新型标签的不断出现以及与其他技术的联用,TAP技术正逐渐应用于植物蛋白质互作研究中。综述了TAP亲和标签选择,并介绍其在植物蛋白互作研究中的成功应用。     

RNase A及其链亲和素融合蛋白在pET系统中的表达

在大肠杆菌中用pET28a表达载体表达重组RNaseA。变性条件下,利用His-Resin亲和纯化,得到60mg／L电泳纯的RNaseA。纯化的RNaseA复性后,利用含大量RNA分子的碱法抽提质粒为底物,测定重组RNaseA活性,与商品化的RNaseA活性相当。同时在RNaseA活性测定体系中加入4mol／L尿素会使RNA分子切割效率提高10倍左右。在此基础上,成功表达RNaseA与链亲和素(streptavidjn)的融合蛋白,经纯化复性后,该融合蛋白同时具有核酸酶、biotin结合活性,在分子生物学中具有重要的应用价值。     

亲和层析法分离鉴定人类端粒酶复合体及其蛋白质组分分析

为分离纯化人类端粒酶复合体并对其蛋白质组分进行分析 ,自行设计一套特异的以端粒重复序列为配体 ,以亲和磁珠为介质 ,以竞争性碱基序列为洗脱原则的寡核苷酸亲和纯化法 ,对He La细胞端粒酶复合体进行分离纯化 .并采用近年发展起来的主要用于检测序列特异性 DNA结合蛋白的凝胶迁移阻滞分析法对纯化产物进行鉴定分析 .应用 SDS- PAGE对纯化蛋白质亚基组分进行分析与鉴定 ,并采用电泳迁移率和已知蛋白质分子质量标准的对数作图分析测得所得蛋白质亚基成分的相对分子质量 .结果表明 ,纯化产物以 TRAP法检测酶活性可见典型的梯形条带 ;比活性为每 mg蛋白质的 cpm值为 1 80× 1 0 9,纯化倍数 1 80 0 ,得率 90 % .凝胶迁移阻滞法分析显示特异的凝胶迁移阻滞性电泳条带 ;以 SDS- PAGE检测得到 4种蛋白质亚基成分 ,其蛋白质相对分子质量分别为 2 2 0 ku、2 1 2 ku、1 1 6ku和 43ku.由上述可见 ,采用自行设计的寡核苷酸亲和纯化法获得了人端粒酶复合体及 4种蛋白质亚基组分 .     

G蛋白亲和色谱法纯化动物血清、抗体效果比较

比较 Hitrap G蛋白 Sepharose亲和色谱系统对不同动物血清或腹水的纯化效果 ,为抗体纯化提供依据。结果显示 ,G蛋白对不同动物血清 Ig G吸附能力不同 ,体现在单位体积抗体回收量明显不同 ,这一特点与 A蛋白亲和色谱系统相似。该方法简便快速 ,纯化抗体纯度高 ,免疫活性好 ,色谱柱可反复使用多次     

建立基于RNA免疫共沉淀技术的鼠疫耶尔森菌Hfq蛋白相关sRNA的体内验证方法

目的：建立RNA免疫共沉淀方法,为鼠疫耶尔森菌Hfq蛋白相关非编码小RNA（sRNA）提供体内验证方法。方法：首先在RNA结合蛋白Hfq下游加入Flag标签,用Flag标签抗体进行免疫共沉淀,获得蛋白-RNA复合物,然后从沉淀的蛋白-RNA复合物中分离得到纯化的RNA;通过Western印迹检测各步骤Hfq蛋白的表达,再利用Northern印迹检测目的sRNA--RyhB1和RyhB2。结果：构建了带有Flag标签的RNA结合蛋白Hfq的载体,此载体转导入hfq缺失株后与鼠疫菌野生株的生长曲线无明显差异;通过RNA-蛋白免疫共沉淀技术鉴定出已知与鼠疫菌Hfq蛋白结合的2个sRNA--RyhB1和RyhB2。结论：建立了利用RNA-蛋白免疫共沉淀鉴定与鼠疫菌Hfq蛋白结合的sRNA的技术,为细菌sRNA的验证、功能研究和体内蛋白质与RNA相互作用研究提供了有利工具。     

人γ－精浆蛋白的亲和纯化及其糖基化分析

目的:从人精液中提纯γ-精浆蛋白并对其生物学特性进行鉴定。 方法:应用饱和硫酸铵法从小鼠腹水中纯化出抗γ-精浆蛋白的单克隆抗体E4B7,将其共价交联到CNBr-Sepharose4B上,制备成免疫亲和层析柱,用该层析柱亲和纯化经饱和硫酸铵粗提的精液标本。纯化产物分别用SDS-PAGE、Western-blot及ELISA进行生物学特性鉴定,最后经PNGase F、Endo-H酶消化后进行糖基化分析。结果:SDS-PAGE电泳表明纯化蛋白的相对分子量约为44KD,Western-blot及ELISA鉴定显示该蛋白可与抗γ-精浆蛋白的单抗E4B7特异性结合。对纯化蛋白无论是单用Endo-H酶消化,还是同时用Endo-H酶和PNGase F酶共同消化,消化产物电泳后相对分子量均降低到34KD左右,而单独用PNGase F酶消化后相对分子量没有改变。Western-blot及ELISA鉴定显示糖苷酶处理后的纯化蛋白仍可与单抗E4B7特异性结合。结论:成功纯化出N-糖基化形式的γ-精浆蛋白,这为下一步筛选人源化抗体奠定了纯的抗原基础。     

Genome-wide identification of protein binding sites on RNAs in mammalian cells

RNA-binding proteins (RBPs) are proteins that bind to the RNA and participate in forming ribonucleoprotein complexes. They have crucial roles in various biological processes such as RNA splicing, editing, transport, maintenance, degradation, intracellular localization and translation. The RBPs bind RNA with different RNA-sequence specificities and affinities, thus, identification of protein binding sites on RNAs (R-PBSs) will deeper our understanding of RNA-protein interactions. Currently, high-throughput sequencing of RNA isolated by crosslinking immunoprecipitation (HITS-CLIP, also known as CLIP-Seq) is one of the most powerful methods to map RNA-protein binding sites or RNA modification sites. However, this method is only used for identification of single known RBPs and antibodies for RBPs are required. Here we developed a novel method, called capture of protein binding sites on RNAs (RPBS-Cap) to identify genome-wide protein binding sites on RNAs without using antibodies. Double click strategy is used for the RPBS-Cap assay. Proteins and RNAs are UV-crosslinked in vivo first, then the proteins are crosslinked to the magnetic beads. The RNA elements associated with proteins are captured, reverse transcribed and sequenced. Our approach has potential applications for studying genome-wide RNA-protein interactions.     

RNase-mediated protein footprint sequencing reveals protein-binding sites throughout the human transcriptome

Background

Sequence specific RNA binding proteins are important regulators of gene expression. Several related crosslinking-based, high-throughput sequencing methods, including PAR-CLIP, have recently been developed to determine direct binding sites of global protein-RNA interactions. However, no studies have quantitatively addressed the contribution of background binding to datasets produced by these methods.

Results

We measured non-specific RNA background in PAR-CLIP data, demonstrating that covalently crosslinked background binding is common, reproducible and apparently universal among laboratories. We show that quantitative determination of background is essential for identifying targets of most RNA-binding proteins and can substantially improve motif analysis. We also demonstrate that by applying background correction to an RNA binding protein of unknown binding specificity, Caprin1, we can identify a previously unrecognized RNA recognition element not otherwise apparent in a PAR-CLIP study.

Conclusions

Empirical background measurements of global RNA-protein crosslinking are a necessary addendum to other experimental controls, such as performing replicates, because covalently crosslinked background signals are reproducible and otherwise unavoidable. Recognizing and quantifying the contribution of background extends the utility of PAR-CLIP and can improve mechanistic understanding of protein-RNA specificity, protein-RNA affinity and protein-RNA association dynamics.     

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。     

Identification of mRNAs bound and regulated by human LIN28 proteins and molecular requirements for RNA recognition

Human LIN28A and LIN28B are RNA-binding proteins (RBPs) conserved in animals with important roles during development and stem cell reprogramming. We used Photoactivatable-Ribonucleoside-Enhanced Crosslinking and Immunoprecipitation (PAR-CLIP) in HEK293 cells and identified a largely overlapping set of ∼3000 mRNAs at ∼9500 sites located in the 3′ UTR and CDS. In vitro and in vivo, LIN28 preferentially bound single-stranded RNA containing a uridine-rich element and one or more flanking guanosines and appeared to be able to disrupt base-pairing to access these elements when embedded in predicted secondary structure. In HEK293 cells, LIN28 protein binding mildly stabilized target mRNAs and increased protein abundance. The top targets were its own mRNAs and those of other RBPs and cell cycle regulators. Alteration of LIN28 protein levels also negatively regulated the abundance of some but not all let-7 miRNA family members, indicating sequence-specific binding of let-7 precursors to LIN28 proteins and competition with cytoplasmic miRNA biogenesis factors.     

dCLIP: a computational approach for comparative CLIP-seq analyses

Although comparison of RNA-protein interaction profiles across different conditions has become increasingly important to understanding the function of RNA-binding proteins (RBPs), few computational approaches have been developed for quantitative comparison of CLIP-seq datasets. Here, we present an easy-to-use command line tool, dCLIP, for quantitative CLIP-seq comparative analysis. The two-stage method implemented in dCLIP, including a modified MA normalization method and a hidden Markov model, is shown to be able to effectively identify differential binding regions of RBPs in four CLIP-seq datasets, generated by HITS-CLIP, iCLIP and PAR-CLIP protocols. dCLIP is freely available at http://qbrc.swmed.edu/software/.     

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.     

Identification and characterization of proteins binding A + U-rich elements

A + U-Rich elements (AREs) have been extensively investigated as cis-acting determinants of rapid mRNA turnover. Recently, a number of RNA-binding proteins interacting with AREs have been described. This article presents strategies and techniques used by our laboratory to identify and characterize a family of ARE-binding proteins collectively termed AUF1. However, these techniques may be applied to the study of any protein displaying sequence-specific RNA binding activity. The techniques described here include the purification of native AUF1 from cultured cells as well as the preparation of recombinant AUF1 proteins using a bacterial expression system. Analyses of RNA-protein interactions are also described, including the use of gel mobility shift assays with synthetic RNA probes to monitor specific RNA binding activity in cell extracts or with recombinant proteins. Variations of this technique are also described to evaluate the RNA binding affinity of recombinant proteins and the use of specific RNA competitors to assess RNA determinants of protein binding specificity. Other techniques presented include the identification of specific proteins in RNA:protein complexes using antibody supershifts and the estimation of molecular weights of RNA-binding proteins by UV crosslinking. Results of individual experiments are presented as examples of some techniques. Throughout the article, suggestions are included to avoid commonly encountered problems and to assist in the optimization of these techniques for the study of other RNA-binding proteins.