双分子荧光互补技术及其在蛋白质相互作用研究中的应用

双分子荧光互补(bimolecularfluorescencecomplementation,BiFC)分析技术,是由Hu等在2002年最先报道的一种直观、快速地判断目标蛋白在活细胞中的定位和相互作用的新技术.该技术巧妙地将荧光蛋白分子的两个互补片段分别与目标蛋白融合表达,如果荧光蛋白活性恢复则表明两目标蛋白发生了相互作用.其后发展出的多色荧光互补技术(multicolorBiFC),不仅能同时检测到多种蛋白质复合体的形成,还能够对不同蛋白质间产生相互作用的强弱进行比较.目前,该技术已用于转录因子,G蛋白βγ亚基的二聚体形式,不同蛋白质间产生相互作用强弱的比较以及蛋白质泛素化等方面的研究工作上.     

应用双分子荧光互补技术分析米曲霉Fus3与Ste12之间的蛋白互作

【背景】双分子荧光互补(Bimolecularfluorescencecomplementation,BiFC)在水稻恶苗病菌(Fusarium fujikuroi)等微生物蛋白互作中的应用已有报道,但在工业菌株米曲霉(Aspergillus oryzae)中还未见应用。【目的】探究米曲霉中Fus3和Ste12蛋白在生长发育中可能存在的相互作用关系,建立在米曲霉活细胞中检测蛋白互作的方法,即BiFC体系。该系统可用于特异性、可视化米曲霉目标蛋白在活细胞中的定位,并且可以更加直观地探究蛋白之间是否存在相互作用。【方法】利用MultisiteGateway复杂载体构建技术,使用切开的绿色荧光蛋白,将荧光蛋白分子的两个片段N端和C端分别与米曲霉Fus3和Ste12蛋白融合,对获得的转化株进行荧光观察。通过BiFC系统检测蛋白之间的相互作用。【结果】成功转化的米曲霉菌丝中观察到荧光,Fus3和Ste12在米曲霉中存在相互作用。【结论】通过BiFC技术证实蛋白质Fus3和Ste12在无性繁殖菌株米曲霉体内发生互作,暗示它们通过互作可能参与除了有性生殖之外的其他细胞功能,并为米曲霉蛋白互作功能研究提供一种新的检测技术和方法。     

CFP荧光蛋白文库构建及FRET技术筛选钙调素结合蛋白

钙调素（Calmodulin,CaM）是细胞内Ca^2＋信号的主要受体,能够与靶蛋白相互结合调节靶蛋白的活性,在细胞增殖、分化、凋亡、迁移等过程中都起着重要作用。荧光共振能量转移（fluorescence resonance energy transfer,FRET）技术是目前研究蛋白质相互作用比较成熟的方法之一。作者通过Cre-loxP位点特异性重组技术构建了带有CFP荧光蛋白标记的文库,与YFP—CaM共同转染HEK293细胞,应用荧光共振能量转移技术（FRET）进行检测,挑取发生FRET作用的单个细胞,并进行单细胞PcR检测。由此扩增出的片段通过测序和蛋白序列数据库NCBI进行序列比对后,筛选出与CaM产生相互作用的蛋白。目前,已经通过这种方法成功地筛选到了一些与CaM相结合的蛋白,从而为进一步研究CaM蛋白在生理环境下的作用提供有利条件。     

茶树花发育MADS-box转录因子CsGLO1、CsGLO2与CsAG之间的互作关系研究

利用酵母双杂交方法和双分子荧光互补技术（BiFC）研究了茶树（Camellia sinensis（L.）O.Kuntze）花发育MADS-box的B类转录因子CsGLO1、CsGLO2与C类转录因子CsAG间的互作关系及其可能发生互作的亚细胞定位。通过构建5个酵母表达载体,利用酵母单杂交实验检测了3个蛋白的转录激活活性,并通过酵母双杂交实验分析了蛋白间的互作关系。结果显示,3个蛋白均无转录激活活性,且两两之间可发生相互作用。进一步构建6个BiFC表达载体,采用压力注射法瞬时浸染烟草（Nicotiana benthamiana L.）叶表皮细胞,并利用激光共聚焦显微镜观察荧光信号,结果表明茶树B类CsGLO与C类CsAG蛋白可在植物活细胞内形成同源和异源二聚体,并具有在细胞质中发生互作的特定模式。本研究可为利用分子生物学技术抑制茶树“花果同现”现象提供理论依据。     

蛋白片段互补分析方法及其应用北大核心CSCD

蛋白片段互补分析技术是近年发展起来的一种分析蛋白质-蛋白质相互作用的新方法。典型的蛋白片段互补分析技术已经成功地利用二氢叶酸还原酶,β-内酰胺酶,绿色荧光蛋白以及荧光素酶片段互补进行胞内蛋白分子相互作用研究。这一技术不仅可以动态、定位分析细胞内蛋白质分子相互作用、绘制细胞内信号传导、蛋白质生物化学网络,还可以应用到蛋白质文库、cDNA文库和高通量药物筛选等。综述了蛋白片段互补分析技术的原理、方法及其应用。     

双杂交扩展技术——报告蛋白片段互补及功能重建技术的应用与展望

报告蛋白片段互补及功能重建技术是对传统的酵母双杂交技术的改进。其原理是将报告蛋白分割成两个没有功能的片段,分别与两个待检测的蛋白质融合,如果待检测的两个蛋白质能够发生相互作用,就可以使报告蛋白的两个片段发生互补,从而使其功能得以重建。这一技术在检测方法和适用的细胞类型上都对酵母双杂交系统进行了扩展。     

双分子荧光互补技术在动物病毒中的研究进展

病毒侵染宿主的过程存在着一系列相互作用,了解病毒与宿主之间的蛋白质相互作用对于深入研究病毒具有重要意义。在众多研究蛋白质相互作用的方法中,双分子荧光互补技术（bimolecular fluorescence complementation,BiFC）因其能在活细胞中可视化相互作用而被广泛应用。介绍了双分子荧光技术的原理、发展和优势,总结了双分子荧光技术在动物病毒以及抗病毒药物研究中的应用,并进一步阐述了新型双分子荧光系统的原理,以期为研究动物病毒致病机制和抗病毒药物研发提供新的思路。     

拟南芥AtMSI1蛋白与组蛋白去乙酰化酶AtHDA6的相互作用分析

表观遗传修饰是真核生物基因转录调控的重要方式,在拟南芥生长发育过程中起着重要的作用。其中,PRC2(Poly-comb Repressive Complex 2)蛋白复合体和组蛋白脱乙酰化酶HDAC均为重要的表观遗传调控蛋白。本研究利用酵母双杂交系统证明了拟南芥PRC2蛋白复合体成员中的AtMSI1(Multi-Copy Suppressor of IRA1)蛋白和组蛋白脱乙酰化酶AtHDA6(Histone Deacetylase 6)蛋白间的相互作用,且确定其作用位点为AtMSI1蛋白的N端(1~114 aa)和C端(404~424 aa)的非特异性位点与AtHDA6蛋白的HD保守结构域(27~332 aa)和N端非保守的结构域(1~26 aa)。本研究构建AtMSI1-YC和AtHDA6-YN融合蛋白表达载体,共同转化拟南芥原生质体,用双分子荧光互补(BiFC)技术验证了AtMSI1-YC和AtHDA6-YN蛋白间的相互作用,并明确该相互作用的位点为细胞核。另外,pull-down试验再次证明了该相互作用的存在,原核表达并纯化的AtMSI1-GST融合蛋白可以与AtHDA6-His重组蛋白发生体外结合。综上所述,拟南芥AtMSI1与AtHDA6蛋白间存在相互作用,且每个蛋白中均有2个特异性结合位点参与该相互作用。     

一种利用荧光蛋白mNeonGreen2鉴定EI24蛋白拓扑结构的方法（英文）

方便且精准地检测跨膜蛋白拓扑结构,尤其是跨膜片段的氨基(N-)和羧基(C-)端的朝向,有利于发现新的蛋白质与蛋白质之间的相互作用,并进一步揭示蛋白质重要的生物学功能.自组装荧光蛋白已被广泛用于观察蛋白质与蛋白质之间的相互作用、标记细胞内源蛋白质并实现mRNA定位的可视化.本文扩展了自组装荧光蛋白的应用,将自组装荧光蛋白mNeonGreen2与定点标记技术相结合,以确定跨膜蛋白的拓扑结构.通过该方法,第一次清楚地证明了EI24的N端和C端均朝向细胞质方向.此外,该方法可用于确定定位于其他细胞器且结构尚未解析的跨膜蛋白的拓扑结构.     

cDNA克隆p14－6肿瘤抑制功能的分子机制

本文探讨了具有肿瘤抑制功能的ｃＤＮＡ克隆Ｐ１４－６（即人白细胞介素６核转录因子ＮＦ－ＩＬ６的３’非翻译区）的ＲＮＡ转录物与回复相关蛋白ＢＮＦ的相互作用,发现该ＲＮＡ与ＢＮＦ的相互作用位点为其３’侧的富Ｕ序列内的１个２４核苷酸片段;并发现ＢＮＦ系一群蛋白质,它们可能先相互结合成１个蛋白质复合物,然后再与ＲＮＡ位点作用．其中可能只有１个蛋白质（Ｒ６２）直接与该ＲＮＡ结合。     

Multicolor bimolecular fluorescence complementation reveals simultaneous formation of alternative CBL/CIPK complexes in planta

The specificity of intracellular signaling and developmental patterning in biological systems relies on selective interactions between different proteins in specific cellular compartments. The identification of such protein-protein interactions is essential for unraveling complex signaling and regulatory networks. Recently, bimolecular fluorescence complementation (BiFC) has emerged as a powerful technique for the efficient detection of protein interactions in their native subcellular localization. Here we report significant technical advances in the methodology of plant BiFC. We describe a series of versatile BiFC vector sets that are fully compatible with previously generated vectors. The new vectors enable the generation of both C-terminal and N-terminal fusion proteins and carry optimized fluorescent protein genes that considerably improve the sensitivity of BiFC. Using these vectors, we describe a multicolor BiFC (mcBiFC) approach for the simultaneous visualization of multiple protein interactions in the same cell. Application to a protein interaction network acting in calcium-mediated signal transduction revealed the concurrent interaction of the protein kinase CIPK24 with the calcium sensors CBL1 and CBL10 at the plasma membrane and tonoplast, respectively. We have also visualized by mcBiFC the simultaneous formation of CBL1/CIPK1 and CBL9/CIPK1 protein complexes at the plasma membrane. Thus, mcBiFC provides a useful new tool for exploring complex regulatory networks in plants.     

A novel far-red bimolecular fluorescence complementation system that allows for efficient visualization of protein interactions under physiological conditions

Fluorescent protein (FP) has enabled the analysis of biomolecular interactions in living cells, and bimolecular fluorescence complementation (BiFC) represents one of the newly developed imaging technologies to directly visualize protein–protein interactions in living cells. Although 10 different FPs that cover a broad range of spectra have been demonstrated to support BiFC, only Cerulean (cyan FP variant), Citrine and Venus (yellow FP variants)-based BiFC systems can be used under 37 °C physiological temperature. The sensitivity of two mRFP-based red BiFC systems to higher temperatures (i.e., 37 °C) limits their applications in most mammalian cell-based studies. Here we report that mLumin, a newly isolated far-red fluorescent protein variant of mKate with an emission maximum of 621 nm, enables BiFC analysis of protein–protein interactions at 37 °C in living mammalian cells. Furthermore, the combination of mLumin with Cerulean- and Venus-based BiFC systems allows for simultaneous visualization of three pairs of protein–protein interactions in the same cell. The mLumin-based BiFC system will facilitate simultaneous visualization of multiple protein–protein interactions in living cells and offer the potential to visualize protein–protein interactions in living animals.     

Bimolecular Fluorescence Complementation Analysis of Inducible Protein Interactions: Effects of Factors Affecting Protein Folding on Fluorescent Protein Fragment Association

Bimolecular fluorescence complementation (BiFC) analysis enables visualization of the subcellular locations of protein interactions in living cells. Using fragments of different fluorescent proteins, we investigated the temporal resolution and the quantitative accuracy of BiFC analysis. We determined the kinetics of BiFC complex formation in response to the rapamycin-inducible interaction between the FK506 binding protein (FKBP) and the FKBP-rapamycin binding domain (FRB). Fragments of yellow fluorescent protein fused to FKBP and FRB produced detectable BiFC complex fluorescence 10 min after the addition of rapamycin and a 10-fold increase in the mean fluorescence intensity in 8 h. The N-terminal fragment of the Venus fluorescent protein fused to FKBP produced constitutive BiFC complexes with several C-terminal fragments fused to FRB. A chimeric N-terminal fragment containing residues from Venus and yellow fluorescent protein produced either constitutive or inducible BiFC complexes depending on the temperature at which the cells were cultured. The concentrations of inducers required for half-maximal induction of BiFC complex formation by all fluorescent protein fragments tested were consistent with the affinities of the inducers for unmodified FKBP and FRB. Treatment with the FK506 inhibitor of FKBP-FRB interaction prevented the formation of BiFC complexes by FKBP and FRB fusions, but did not disrupt existing BiFC complexes. Proteins synthesized before the addition of rapamycin formed BiFC complexes with the same efficiency as did newly synthesized proteins. Inhibitors of protein synthesis attenuated BiFC complex formation independent of their effects on fusion protein synthesis. The kinetics at which they inhibited BiFC complex formation suggests that they prevented association of the fluorescent protein fragments, but not the slow maturation of BiFC complex fluorescence. Agents that induce the unfolded protein response also reduced formation of BiFC complexes. The effects of these agents were suppressed by cellular adaptation to protein folding stress. In summary, BiFC analysis enables detection of protein interactions within minutes after complex formation in living cells, but does not allow detection of complex dissociation. Conditional BiFC complex formation depends on the folding efficiencies of fluorescent protein fragments and can be affected by the cellular protein folding environment.     

Identification of interacting proteins for calcium-dependent protein kinase 8 by a novel screening system based on bimolecular fluorescence complementation

Protein kinases are key regulators of cell function that constitute one of the largest and most functionally diverse gene families. We developed a novel assay system, based on the bimolecular fluorescence complementation (BiFC) technique in Escherichia coli, for detecting transient interactions such as those between kinases and their substrates. This system detected the interaction between OsMEK1 and its direct target OsMAP1. By contrast, BiFC fluorescence was not observed when OsMAP2 or OsMAP3, which are not substrates of OsMEK1, were used as prey proteins. We also screened for interacting proteins of calcium-dependent protein kinase 8 (OsCPK8), a regulator of plant immune responses, and identified three proteins as interacting molecules of OsCPK8. The interaction between OsCPK8 and two of these proteins (ARF-GEF and peptidyl prolyl isomerase) was confirmed in rice cells by means of BiFC technology. These results indicate that our new assay system has the potential to screen for protein kinase target molecules.     

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.     

LEC–BiFC: a new method for rapid assay of protein interaction

Abstract

Protein–protein interactions play fundamental roles in most biological processes. Bimolecular fluorescence complementation (BiFC) is a promising method for its simplicity and direct visualization of protein–protein interactions in cells. This method, however, is limited by background fluorescence that appears without specific interaction between the proteins. We report here a point mutation (V150L) in one Venus BiFC fragment that efficiently decreases background fluorescence of BiFC assay. Furthermore, by combining this modified BiFC and linear expression cassette (LEC), we develop a simple and rapid method (LEC–BiFC) for protein interaction analysis that is demonstrated by a case study of the interaction between Bcl–X_L and Bak BH3 peptide. The total analysis procedure can be completed in two days for screening tens of mutants. LEC–BiFC can be applied easily in any lab equipped with a fluorescence microscope.     

Detection of protein-protein interactions in plants using bimolecular fluorescence complementation

Protein function is often mediated via formation of stable or transient complexes. Here we report the determination of protein-protein interactions in plants using bimolecular fluorescence complementation (BiFC). The yellow fluorescent protein (YFP) was split into two non-overlapping N-terminal (YN) and C-terminal (YC) fragments. Each fragment was cloned in-frame to a gene of interest, enabling expression of fusion proteins. To demonstrate the feasibility of BiFC in plants, two pairs of interacting proteins were utilized: (i) the alpha and beta subunits of the Arabidopsis protein farnesyltransferase (PFT), and (ii) the polycomb proteins, FERTILIZATION-INDEPENDENT ENDOSPERM (FIE) and MEDEA (MEA). Members of each protein pair were transiently co-expressed in leaf epidermal cells of Nicotiana benthamiana or Arabidopsis. Reconstitution of a fluorescing YFP chromophore occurred only when the inquest proteins interacted. No fluorescence was detected following co-expression of free non-fused YN and YC or non-interacting protein pairs. Yellow fluorescence was detected in the cytoplasm of cells that expressed PFT alpha and beta subunits, or in nuclei and cytoplasm of cells that expressed FIE and MEA. In vivo measurements of fluorescence spectra emitted from reconstituted YFPs were identical to that of a non-split YFP, confirming reconstitution of the chromophore. Expression of the inquest proteins was verified by immunoblot analysis using monoclonal antibodies directed against tags within the hybrid proteins. In addition, protein interactions were confirmed by immunoprecipitations. These results demonstrate that plant BiFC is a simple, reliable and relatively fast method for determining protein-protein interactions in plants.     

Applying bimolecular fluorescence complementation to screen and purify aquaporin protein:protein complexes

Protein:protein interactions play key functional roles in the molecular machinery of the cell. A major challenge for structural biology is to gain high‐resolution structural insight into how membrane protein function is regulated by protein:protein interactions. To this end we present a method to express, detect, and purify stable membrane protein complexes that are suitable for further structural characterization. Our approach utilizes bimolecular fluorescence complementation (BiFC), whereby each protein of an interaction pair is fused to nonfluorescent fragments of yellow fluorescent protein (YFP) that combine and mature as the complex is formed. YFP thus facilitates the visualization of protein:protein interactions in vivo, stabilizes the assembled complex, and provides a fluorescent marker during purification. This technique is validated by observing the formation of stable homotetramers of human aquaporin 0 (AQP0). The method's broader applicability is demonstrated by visualizing the interactions of AQP0 and human aquaporin 1 (AQP1) with the cytoplasmic regulatory protein calmodulin (CaM). The dependence of the AQP0‐CaM complex on the AQP0 C‐terminus is also demonstrated since the C‐terminal truncated construct provides a negative control. This screening approach may therefore facilitate the production and purification of membrane protein:protein complexes for later structural studies by X‐ray crystallography or single particle electron microscopy.     

Interactions between the budding yeast IQGAP homologue Iqg1p and its targets revealed by a split-EGFP bimolecular fluorescence complementation assay

A split-EGFP based bimolecular fluorescence complementation (BiFC) assay has been used to detect interactions between the Saccharomyces cerevisiae cytoskeletal scaffolding protein Iqg1p and three targets: myosin essential light chain (Mlc1p), calmodulin (Cmd1p) and the small GTPase Cdc42p. The format of the BiFC assay used ensures that the proteins are expressed at wild type levels thereby avoiding artefacts due to overexpression. This is the first direct in vivo detection of these interactions; in each case, the complex is localised to discrete regions of the yeast cytoplasm. The labelling with EGFP fragments results in changes in growth kinetics, cell size and budding frequency. This is partly due to the reassembled EGFP locking the complexes into essentially permanent interactions. The consequences of this for Iqg1p interactions and BiFC assays in general are discussed.