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。     

串联亲和纯化技术及其应用

串联亲和纯化(tandemaffinitypurification,TAP)是一种能快速研究体内蛋白质相互作用的新技术,经过两步特异性亲和纯化,可快速得到生理条件下与靶蛋白质存在真实相互作用的蛋白质。TAP方法最初用于酵母中,因其具通用性、高效性、高纯度及假阳性低等特点得到了快速发展,至今已成功运用于许多其他生物。现主要介绍TAP方法的原理、TAP标签及其在不同物种中的应用。     

亲和标签在重组蛋白表达与纯化中的应用

亲和标签融合技术为重组蛋白的纯化提供了一种简单方便的纯化工具,具有结合特异性高、洗脱条件温和、通用性强、纯化倍数高等显著优点。概述了亲和标签对融合蛋白表达的影响,可以提高重组蛋白的产量,增强重组蛋白的可溶性,促进重组蛋白的正确折叠;回顾了在重组蛋白表达与纯化中广泛使用的几种亲和标签,以及近年来相继出现的几种比较新颖的纯化标签;介绍了亲和标签的组合使用策略,His6-MBP组合标签集合了两个标签的优点,串联亲和纯化可以纯化获得生理条件下的蛋白质复合体;展望了亲和标签未来的发展趋势,认为仍需继续开发性能更加优越、纯化效果更加显著的纯化标签系统。     

蛋白质相互作用研究的新技术与新方法

目前，蛋白质相互作用已成为蛋白质组学研究的热点. 新方法的建立及对已有技术的改进标志着蛋白质相互作用研究的不断发展和完善．在技术改进方面，本文介绍了弥补酵母双杂交的蛋白定位受限等缺陷的细菌双杂交系统；根据目标蛋白特性设计和修饰TAP标签来满足复合体研究要求的串联亲和纯化技术，以及在双分子荧光互补基础上发展的动态检测多个蛋白质间瞬时、弱相互作用的多分子荧光互补技术．还综述了近两年建立的新方法：与免疫共沉淀相比，寡沉淀技术直接研究具有活性的蛋白质复合体；减量式定量免疫沉淀方法排除了蛋白质复合体中非特异性相互作用的干扰；原位操作的多表位－配基绘图法避免了样品间差异的影响，以及利用多点吸附和交联加固研究弱蛋白质相互作用的固相蛋白质组学方法.     

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（TAP）技术在蛋白质组学中的应用

蛋白质是各种生命活动的主要执行者,因此构建蛋白质相互作用的网络图对于准确理解蛋白质功能、揭开各种细胞活动的奥秘十分重要.串联亲和纯化（TAP）,是近年来发展出来的一种能够快速研究在生理条件下蛋白质相互作用,揭示蛋白质复合体相互作用网络的新技术,已成为研究蛋白质组学的一个重要工具.随着该技术的不断完善,TAP技术在认识蛋白质相互作用的过程中必将发挥越来越重要的作用.     

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。     

动粒蛋白CENP-K和CENP-H可形成异源超螺旋复合体

动粒（kinetochore）是位于纺锤体主缢痕处表层的特化结构.它通过与纺锤体微管的结合,在有丝分裂期拉动染色体向两极运动,同时具有机械力产生和与中期检验点有关的功能,是细胞中机械强度最高的结构之一.动粒由一个很大的复杂的蛋白网络组成,目前了解较清楚的核心蛋白网络是KMN网络（K,KNL1;M,Mis12复合物;N,NDC80复合物）和CCAN网络（常驻性着丝粒相关网络,constitutive centromere-associated network）,但对其蛋白组分之间相互作用的分子机制仍然了解很少.本研究采用串联亲和纯化（TAP）技术在稳定表达TAP-CENP-K的HEK293细胞中寻找CENP-K的稳定蛋白复合体,结果表明CENP-K和CENP-H形成强稳定的（耐受750mmol/L盐浓度）、比例接近11的蛋白复合体.经过预测,CENP-K与CENP-H都是超螺旋（coiled-coil）蛋白.CENP-K与CENP-H片段进行的体外Pull-down实验也证明了两者的N端片段之间以及C端片段之间分别存在直接的相互作用,并且C端片段之间的相互作用更明显.综上所述,CENP-H与CENP-K之间的强相互作用可能是通过形成异源超螺旋复合体实现的,可能在介导动粒与微管连接中起到重要的作用。     

不同蛋白标签对LMO2融合蛋白沉淀实验的影响

融合蛋白沉淀技术是一种用来研究蛋白质相互作用的新的体外实验技术, 通常利用蛋白亲和标签与探针蛋白融合表达来钓取未知相互作用蛋白或验证已知蛋白间的相互作用, 其中以谷胱甘肽巯基转移酶(GST)标签最为常用。LMO2(由LIM only缩写得名, 也称Ttg-2或Rbtn2)是一种小分子量难溶蛋白。利用原核系统分别表达了含有GST和麦芽糖结合蛋白(MBP)两种标签的LMO2融合蛋白, 发现GST-LMO2融合蛋白以包涵体的形式表达, 而MBP-LMO2融合蛋白则能够以可溶形式表达, 而且MBP-LMO2的表达量明显高于GST-LMO2融合蛋白。将可溶性的MBP-LMO2融合蛋白和复性后的GST-LMO2融合蛋白分别用于钓取K562细胞中LMO2的结合蛋白, 结果显示二者都可以结合K562细胞中内源性的GATA1蛋白, 而MBP-LMO2融合蛋白捕获的GATA1蛋白明显多于复性后的GST-LMO2融合蛋白。这一结果提示, 在研究一些分子量小、疏水性强的蛋白质时改变标签蛋白可能是一种有益的尝试。     

不同蛋白标签对LMO2融合蛋白沉淀实验的影响

融合蛋白沉淀技术是一种用来研究蛋白质相互作用的新的体外实验技术, 通常利用蛋白亲和标签与探针蛋白融合表达来钓取未知相互作用蛋白或验证已知蛋白间的相互作用, 其中以谷胱甘肽巯基转移酶(GST)标签最为常用。LMO2(由LIM only缩写得名, 也称Ttg-2或Rbtn2)是一种小分子量难溶蛋白。利用原核系统分别表达了含有GST和麦芽糖结合蛋白(MBP)两种标签的LMO2融合蛋白, 发现GST-LMO2融合蛋白以包涵体的形式表达, 而MBP-LMO2融合蛋白则能够以可溶形式表达, 而且MBP-LMO2的表达量明显高于GST-LMO2融合蛋白。将可溶性的MBP-LMO2融合蛋白和复性后的GST-LMO2融合蛋白分别用于钓取K562细胞中LMO2的结合蛋白, 结果显示二者都可以结合K562细胞中内源性的GATA1蛋白, 而MBP-LMO2融合蛋白捕获的GATA1蛋白明显多于复性后的GST-LMO2融合蛋白。这一结果提示, 在研究一些分子量小、疏水性强的蛋白质时改变标签蛋白可能是一种有益的尝试。     

Identification of novel protein-protein interactions using a versatile mammalian tandem affinity purification expression system

Identification of protein-protein interactions is essential for elucidating the biochemical mechanism of signal transduction. Purification and identification of individual proteins in mammalian cells have been difficult, however, due to the sheer complexity of protein mixtures obtained from cellular extracts. Recently, a tandem affinity purification (TAP) method has been developed as a tool that allows rapid purification of native protein complexes expressed at their natural level in engineered yeast cells. To adapt this method to mammalian cells, we have created a TAP tag retroviral expression vector to allow stable expression of the TAP-tagged protein at close to physiological levels. To demonstrate the utility of this vector, we have fused a TAP tag, consisting of a protein A tag, a cleavage site for the tobacco etch virus (TEV) protease, and the FLAG epitope, to the N terminus of human SMAD3 and SMAD4. We have stably expressed these proteins in mammalian cells at desirable levels by retroviral gene transfer and purified native SMAD3 protein complexes from cell lysates. The combination of two different affinity tags greatly reduced the number of nonspecific proteins in the mixture. We have identified HSP70 as a specific interacting protein of SMAD3. We demonstrated that SMAD3, but not SMAD1, binds HSP70 in vivo, validating the TAP purification approach. This method is applicable to virtually any protein and provides an efficient way to purify unknown proteins to homogeneity from the complex mixtures found in mammalian cell lysates in preparation for identification by mass spectrometry.     

The tandem affinity purification technology: an overview

Tandem affinity purification (TAP) is a methodology for the isolation of protein complexes from endogenous sources. It involves incorporation of a dual-affinity tag into the protein of interest and introduction of the construct into desired cell lines or organisms. Using the two affinity handles, the protein complex assembled under physiological conditions, which contains the tagged target protein and its interacting partners, can be isolated by a sequential purification scheme. Compared with single-step purification, TAP greatly reduces non-specific background and isolates protein complexes with higher purity. TAP-based protein retrieval plus mass spectrometry-based analysis has become a standard approach for identification and characterization of multi-protein complexes. The present article gives an overview of the TAP method, with a focus on its key feature—the dual-affinity tag. In addition, the application of this technology in various systems is briefly discussed.     

Identification of Protein Interacting Partners Using Tandem Affinity Purification

A critical and often limiting step in understanding the function of host and viral proteins is the identification of interacting cellular or viral protein partners. There are many approaches that allow the identification of interacting partners, including the yeast two hybrid system, as well as pull down assays using recombinant proteins and immunoprecipitation of endogenous proteins followed by mass spectrometry identification¹. Recent studies have highlighted the utility of double-affinity tag mediated purification, coupled with two specific elution steps in the identification of interacting proteins. This approach, termed Tandem Affinity Purification (TAP), was initially used in yeast^2,3 but more recently has been adapted to use in mammalian cells^4-8.As proof-of-concept we have established a tandem affinity purification (TAP) method using the well-characterized eukaryotic translation initiation factor eIF4E^9,10.The cellular translation factor eIF4E is a critical component of the cellular eIF4F complex involved in cap-dependent translation initiation¹⁰. The TAP tag used in the current study is composed of two Protein G units and a streptavidin binding peptide separated by a Tobacco Etch Virus (TEV) protease cleavage sequence. The TAP tag used in the current study is composed of two Protein G units and a streptavidin binding peptide separated by a Tobacco Etch Virus (TEV) protease cleavage sequence⁸. To forgo the need for the generation of clonal cell lines, we developed a rapid system that relies on the expression of the TAP-tagged bait protein from an episomally maintained plasmid based on pMEP4 (Invitrogen). Expression of tagged murine eIF4E from this plasmid was controlled using the cadmium chloride inducible metallothionein promoter.Lysis of the expressing cells and subsequent affinity purification via binding to rabbit IgG agarose, TEV protease cleavage, binding to streptavidin linked agarose and subsequent biotin elution identified numerous proteins apparently specific to the eIF4E pull-down (when compared to control cell lines expressing the TAP tag alone). The identities of the proteins were obtained by excision of the bands from 1D SDS-PAGE and subsequent tandem mass spectrometry. The identified components included the known eIF4E binding proteins eIF4G and 4EBP-1. In addition, other components of the eIF4F complex, of which eIF4E is a component were identified, namely eIF4A and Poly-A binding protein. The ability to identify not only known direct binding partners as well as secondary interacting proteins, further highlights the utility of this approach in the characterization of proteins of unknown function.     

A generic protein purification method for protein complex characterization and proteome exploration.

We have developed a generic procedure to purify proteins expressed at their natural level under native conditions using a novel tandem affinity purification (TAP) tag. The TAP tag allows the rapid purification of complexes from a relatively small number of cells without prior knowledge of the complex composition, activity, or function. Combined with mass spectrometry, the TAP strategy allows for the identification of proteins interacting with a given target protein. The TAP method has been tested in yeast but should be applicable to other cells or organisms.     

Highly efficient purification of protein complexes from mammalian cells using a novel streptavidin-binding peptide and hexahistidine tandem tag system: application to Bruton's tyrosine kinase

Tandem affinity purification (TAP) is a generic approach for the purification of protein complexes. The key advantage of TAP is the engineering of dual affinity tags that, when attached to the protein of interest, allow purification of the target protein along with its binding partners through two consecutive purification steps. The tandem tag used in the original method consists of two IgG‐binding units of protein A from Staphylococcus aureus (ProtA) and the calmodulin‐binding peptide (CBP), and it allows for recovery of 20–30% of the bait protein in yeast. When applied to higher eukaryotes, however, this classical TAP tag suffers from low yields. To improve protein recovery in systems other than yeast, we describe herein the development of a three‐tag system comprised of CBP, streptavidin‐binding peptide (SBP) and hexa‐histidine. We illustrate the application of this approach for the purification of human Bruton's tyrosine kinase (Btk), which results in highly efficient binding and elution of bait protein in both purification steps (>50% recovery). Combined with mass spectrometry for protein identification, this TAP strategy facilitated the first nonbiased analysis of Btk interacting proteins. The high efficiency of the SBP‐His₆ purification allows for efficient recovery of protein complexes formed with a target protein of interest from a small amount of starting material, enhancing the ability to detect low abundance and transient interactions in eukaryotic cell systems.     

A modified mammalian tandem affinity purification procedure to prepare functional polycystin-2 channel

The tandem affinity purification (TAP) procedure was initially developed as a tool for rapid purification of native protein complexes expressed at their natural levels in yeast cells. This purification procedure was also applied to study interactions between soluble proteins in mammalian cells. In order to apply this procedure to mammalian membrane proteins, we created a modified TAP tag expression vector and fused with the PKD2 gene, encoding a membrane cation channel protein, polycystin-2, mutated in 15% of autosomal dominant polycystic kidney disease. We generated epithelial Madin-Darby canine kidney cell line stably expressing TAP-tagged polycystin-2, improved the subsequent steps for membrane protein release and stability, and succeeded in purifying this protein. Using patch clamp electrophysiology, we detected specific polycystin-2 channel activities when the purified protein was reconstituted into a lipid bilayer system. Thus, this modified TAP procedure provides a powerful alternative to functionally characterize membrane proteins, such as ion channels, transporters and receptors, using cell-free system derived from mammalian cells.     

An alternative tandem affinity purification strategy applied to Arabidopsis protein complex isolation

Tandem affinity purification (TAP) strategies constitute an efficient approach for protein complex purification from many different organisms. However, the application of such strategies for purifying endogenous Arabidopsis multi-protein complexes has not yet been reported. Here, we describe an alternative TAP (TAPa) system that successfully allows protein complex purification from Arabidopsis. In our newly generated TAPa tag we have replaced the tobacco etch virus (TEV) protease cleavage site with the more specific and low-temperature active rhinovirus 3C protease site. In addition, the second purification step can now be performed through two different affinity tags: a six His repeat or nine copies of a myc repeat. To examine our purification procedure we generated a C-terminal fusion between the TAPa tag and CSN3, a component of the multi-protein COP9 signalosome (CSN) complex. Subsequent analysis showed that CSN3-TAPa could rescue a csn3 mutant, and that the components of the CSN complex could be co-purified with CSN3-TAPa. As part of our long running interest in light signaling in Arabidopsis we have generated Arabidopsis transgenic lines harboring, both N-terminal and C-terminal TAPa fusions of many different light signaling pathway regulators. Molecular characterization of these transgenic lines showed fusion expression in 88% of the genes analyzed and that this expression is largely independent of the fusion orientation. Mutant complementation analysis showed that most of the TAPa fusions analyzed retained function of the wild-type proteins. Taken together, the data demonstrate the suitability of the TAPa system to allow efficient multi-protein complex isolation from stably transformed Arabidopsis.     

Tandem affinity purification in Drosophila: the advantages of the GS-TAP system

Tandem affinity purification (TAP) has been widely used for the analysis of protein complexes. We investigated the parameters of the recently developed TAP method (GS-TAP) and its application in Drosophila. This new tag combination includes two Protein G modules and a streptavidin binding peptide (SBP), separated by one or two TEV protease cleavage sites. We made pMK33-based GS-TAP vectors to allow for generation of stable cell lines using hygromycin selection and inducible expression from a metallothionein promoter, as well as pUAST-based vectors that can be used for inducible expression in flies. Rescue experiments in flies demonstrated that the GS-TAP tag preserves the function of the tagged protein. We have done parallel purifications of proteins tagged with the new GS-TAP tag or with the conventional TAP tag (containing the Protein A and calmodulin binding peptide domains) at the amino terminus, using both cultured cells and embryos. A major difference between the two tags was in the levels of contaminating proteins, which were significantly lower in the GS-TAP purifications. The GS-TAP procedure also resulted in higher yield of the bait protein. Overall, GS-TAP is an improved method of protein complex purification because it provides a superior signal-to-noise ratio of the bait protein relative to contaminants in purified material.     

A novel tandem affinity purification strategy for the efficient isolation and characterisation of native protein complexes

Isolation and dissection of native multiprotein complexes is a central theme in functional genomics. The development of the tandem affinity purification (TAP) tag has enabled an efficient and large-scale purification of native protein complexes. However, the TAP tag features a size of 21 kDa and requires time consuming cleavage. By combining a tandem Strep-tag II with a FLAG-tag we were able to reduce the size of the TAP (SF-TAP) tag to 4.6 kDa. Both moieties have a medium affinity and avidity to their immobilised binding partners. This allows the elution of SF-tagged proteins under native conditions using desthiobiotin in the first step and the FLAG octapeptide in the second step. The SF-TAP protocol represents an efficient, fast and straightforward purification of protein complexes from mammalian cells within 2.5 h. The power of this novel method is demonstrated by the purification of Raf associated protein complexes from HEK293 cells and subsequent analysis of their protein interaction network by dissection of interaction patterns from the Raf binding partners MEK1 and 14-3-3.