GENETIC APPROACHES TO THE IDENTIFICATION OF INTERACTIONS BETWEEN MEMBRANE PROTEINS IN YEAST

ABSTRACT

The recent sequencing of entire eukaryotic genomes has renewed the interest in identifying and characterizing all gene products that are expressed in a given organism. The characterization of unknown gene products is facilitated by the knowledge of its binding partners. Thus, a novel protein may be classified by identifying previously characterized proteins that interact with it. If such an approach is carried out on a large scale, it may allow the rapid characterization of the thousands of predicted open reading frames identified by recent sequencing projects. Currently, the yeast two-hybrid system is the most widely used genetic assay for the detection of protein–protein interactions. The yeast two-hybrid system has become popular because it requires little individual optimization and because, as compared to conventional biochemical methods, the identification and characterization of protein–protein interactions can be completed in a relatively short time span. In this review, we briefly discuss the yeast two-hybrid system and its application to large scale screening studies that aim at deciphering all protein–protein interactions taking place in a given cell type or organism. We then focus on a class of proteins that is unsuitable for conventional yeast two-hybrid systems, namely integral membrane proteins and membrane-associated proteins, and describe several novel genetic systems that combine the advantages of the yeast two-hybrid system with the potential to identify interaction partners of membrane-associated proteins in their natural setting.     

Genetic approaches to the identification of interactions between membrane proteins in yeast

The recent sequencing of entire eukaryotic genomes has renewed the interest in identifying and characterizing all gene products that are expressed in a given organism. The characterization of unknown gene products is facilitated by the knowledge of its binding partners. Thus, a novel protein may be classified by identifying previously characterized proteins that interact with it. If such an approach is carried out on a large scale, it may allow the rapid characterization of the thousands of predicted open reading frames identified by recent sequencing projects. Currently, the yeast two-hybrid system is the most widely used genetic assay for the detection of protein-protein interactions. The yeast two-hybrid system has become popular because it requires little individual optimization and because, as compared to conventional biochemical methods, the identification and characterization of protein-protein interactions can be completed in a relatively short time span. In this review, we briefly discuss the yeast two-hybrid system and its application to large scale screening studies that aim at deciphering all protein-protein interactions taking place in a given cell type or organism. We then focus on a class of proteins that is unsuitable for conventional yeast two-hybrid systems, namely integral membrane proteins and membrane-associated proteins, and describe several novel genetic systems that combine the advantages of the yeast two-hybrid system with the potential to identify interaction partners of membrane-associated proteins in their natural setting.     

Foreword: The structural biology of membrane proteins

Membrane protein-protein interactions are important for regulation, targeting, and activity of proteins in membranes but are difficult to detect and analyse. This review covers current approaches to studying membrane protein interactions. In addition to standard biochemical and genetic techniques, the classic yeast nuclear two-hybrid system has been highly successful in identification and characterization of soluble protein-protein interactions. However, classic yeast two-hybrid assays do not work for membrane proteins because such yeast-based interactions must occur in the nucleus. Here, we highlight recent advances in yeast systems for the detection and characterization of eukaryote membrane protein-protein interactions. We discuss these implications for drug screening and discovery.     

酵母双杂交筛选类固醇激素合成急性调节蛋白的相互作用蛋白质

目的:利用酵母双杂交技术筛选人肝cDNA文库中与类固醇激素合成急性调节蛋白(STAR)相互作用的蛋白质。方法:将全长STAR基因克隆到酵母表达载体pDBLeu中,形成诱饵;将构建好的诱饵质粒转化至AH109酵母感受态中,利用酵母双杂交技术筛选人肝cDNA文库中与其相互作用的蛋白质,并进行相互作用的回转验证。结果:构建了酵母诱饵蛋白表达质粒pDBLeu-STAR,并筛选到6个猎物,其中有5对相互作用回转验证阳性。结论:为进一步研究STAR的功能和作用机制提供了新的线索。     

A combined yeast/bacteria two-hybrid system: development and evaluation

Two-hybrid screening is a standard method used to identify and characterize protein-protein interactions and has become an integral component of many proteomic investigations. The two-hybrid system was initially developed using yeast as a host organism. However, bacterial two-hybrid systems have also become common laboratory tools and are preferred in some circumstances, although yeast and bacterial two-hybrid systems have never been directly compared. We describe here the development of a unified yeast and bacterial two-hybrid system in which a single bait expression plasmid is used in both organismal milieus. We use a series of leucine zipper fusion proteins of known affinities to compare interaction detection using both systems. Although both two-hybrid systems detected interactions within a comparable range of interaction affinities, each demonstrated unique advantages. The yeast system produced quantitative readout over a greater dynamic range than that observed with bacteria. However, the phenomenon of "autoactivation" by baits was less of a problem in the bacterial system than in the yeast. Both systems identified physiological interactors for a library screen with a cI-Ras test bait; however, non-identical interactors were obtained in yeast and bacterial screens. The ability to rapidly shift between yeast and bacterial systems provided by these new reagents should provide a marked advantage for two-hybrid investigations. In addition, the modified expression vectors we describe in this report should be useful for any application requiring facile expression of a protein of interest in both yeast and bacteria.     

Barcode fusion genetics-protein-fragment complementation assay (BFG-PCA): tools and resources that expand the potential for binary protein interaction discovery

Barcode fusion genetics (BFG) utilizes deep sequencing to improve the throughput of protein–protein interaction (PPI) screening in pools. BFG has been implemented in Yeast two-hybrid (Y2H) screens (BFG-Y2H). While Y2H requires test protein pairs to localize in the nucleus for reporter reconstruction, dihydrofolate reductase protein-fragment complementation assay (DHFR-PCA) allows proteins to localize in broader subcellular contexts and proves to be largely orthogonal to Y2H. Here, we implemented BFG to DHFR-PCA (BFG-PCA). This plasmid-based system can leverage ORF collections across model organisms to perform comparative analysis, unlike the original DHFR-PCA that requires yeast genomic integration. The scalability and quality of BFG-PCA were demonstrated by screening human and yeast interactions for >11 000 bait-prey pairs. BFG-PCA showed high-sensitivity and high-specificity for capturing known interactions for both species. BFG-Y2H and BFG-PCA capture distinct sets of PPIs, which can partially be explained based on the domain orientation of the reporter tags. BFG-PCA is a high-throughput protein interaction technology to interrogate binary PPIs that exploits clone collections from any species of interest, expanding the scope of PPI assays.     

酵母双杂交系统筛选GATA-1相互作用蛋白质及功能验证

目的 利用酵母双杂交技术从人脑cDNA文库中筛选与人GATA-1相互作用的蛋白质.方法 从人K562细胞中扩增出全长GATA1基因,设计引物将其3段截断体亚克隆入酵母表达载体pDBLeu中,转化至AH109感受态酵母中,利用酵母双杂交技术筛选人脑cDNA文库中与其相互作用的蛋白质,阳性克隆通过回转及免疫共沉淀试验进行验证,利用3xGATA荧光素酶报告基因对相互作用蛋白质进行功能验证.结果 成功构建出酵母诱饵蛋白表达质粒pDBLeu-GATA1（1）,pDBLeu-GATA1（2）,pDBLeu-GATA1（3）,筛到34个阳性克隆,用生物信息学分析及回转验证得到5个与GATA-1相互作用的候选蛋白,通过免疫共沉淀试验进一步验证,获得3个蛋白质能与GATA-1相互作用,分别是ECSIT,EFEMP1和GPS2.荧光素酶试验表明这3个蛋白质均能对GATA1的转录活性产生影响,证实它们之间的相互作用具有影响GATA1转录的功能.结论 应用酵母双杂交技术及免疫共沉淀试验,从人脑cDNA文库中成功获得3个与GATA-1相互作用并对其转录活性具有调节作用的蛋白质,为研究GATA1蛋白质的功能提供了新的线索.     

A Novel Genetic System Based on Zinc Finger Nucleases for the Identification of Interactions between Proteins In Vivo

Yeast two-hybrid (Y2H) methods are powerful tools for detecting protein–protein interactions. The traditional Y2H method has been widely applied to screen novel protein interactions since it was established two decades ago. The high false-positive rate of the traditional method drove the development of modified Y2H systems. Here, we describe a novel Y2H system using zinc-finger nucleases (ZFNs). ZFNs contain two functional domains, a zinc-finger DNA-binding domain (ZFP) and a non-specific nuclease domain (FokI). In this system, the bait is expressed as a fusion protein with a specific ZFP, and the prey is fused to the FokI. A reporter vector is designed such that the ZFN target site disrupts the Gal4 open reading frame. By transforming the three plasmids into a yeast strain (AH109), the interaction between the bait and prey proteins reconstitutes ZFN function and generates the double-strand break (DSB) on its target site. The DNA DSB repair restores Gal4 function, which activates the expression of the four reporter genes. We used p53-SV40LT interacting proteins to prove the concept. In addition, 80% positive rate was observed in a cDNA screening test against WDSV orfA protein. Our results strongly suggested that this Y2H system could increase screening reliability and reproducibility, and provide a novel approach for interactomics research.     

酵母三杂交系统的原理和应用

酵母双杂交系统自出现以来,广泛用于研究蛋白质之间的相互作用,它是一种具有高灵敏度的研究蛋白质之间关系的技术.在酵母双杂交系统基础上发展的酵母三杂交系统将应用范围扩展到蛋白质-蛋白质、蛋白质-RNA、蛋白质-小分子化合物等更广阔的研究领域.本文着重介绍酵母三杂交系统的原理、应用及局限性.     

Development and application of a DNA microarray-based yeast two-hybrid system

The yeast two-hybrid (Y2H) system is the most widely applied methodology for systematic protein–protein interaction (PPI) screening and the generation of comprehensive interaction networks. We developed a novel Y2H interaction screening procedure using DNA microarrays for high-throughput quantitative PPI detection. Applying a global pooling and selection scheme to a large collection of human open reading frames, proof-of-principle Y2H interaction screens were performed for the human neurodegenerative disease proteins huntingtin and ataxin-1. Using systematic controls for unspecific Y2H results and quantitative benchmarking, we identified and scored a large number of known and novel partner proteins for both huntingtin and ataxin-1. Moreover, we show that this parallelized screening procedure and the global inspection of Y2H interaction data are uniquely suited to define specific PPI patterns and their alteration by disease-causing mutations in huntingtin and ataxin-1. This approach takes advantage of the specificity and flexibility of DNA microarrays and of the existence of solid-related statistical methods for the analysis of DNA microarray data, and allows a quantitative approach toward interaction screens in human and in model organisms.     

用于蛋白质间相互作用研究的新型双杂交系统

近年来,一些不依赖于转录因子活性的新型双杂交系统相继建立,如分离的泛素系统、蛋白质片段互补分析、阻遏物重构分析和SOS恢复系统等。同利用转录因子活性的酵母双杂交系统相似,这些方法也利用了一些活性蛋白的结构与功能特点来研究蛋白质间相互作用,这些活性蛋白不是转录因子,但也可在结构上进行分离可通过重构使其生物活性得以恢复。由于这些新型双杂交系统的各自特点,使得它们成为酵母双杂交系统的有益补充和研究蛋白质间相互作用的有力工具。     

应用酵母双杂交系统筛选橡胶延长因子REF的互作蛋白

利用酵母双杂交系统,以橡胶树(Hevea brasiliensis)橡胶延长因子基因REF的开放阅读框(ORF)构建无自激活性的诱饵表达载体pBD-GAL4-REF,并筛选以pAD-GAL4-2.1载体构建的橡胶树胶乳cDNA文库,对阳性克隆的cDNA插入片段进行测序及生物学功能分析。通过酵母双杂交筛选,共获得5种可能与REF互作的候选蛋白质,它们分别为与诱饵蛋白REF高度同源的REF家族成员、小橡胶粒子蛋白(SRPP)、翻译控制肿瘤蛋白(TCTP)、激发子响应蛋白和泛素耦联酶E2,这表明橡胶延长因子REF除了与自身高度同源蛋白质可能存在相互作用之外,还可能与TCTP和激发子响应蛋白等其它蛋白质发生相互作用。这些结果有助于揭示橡胶粒子的生物学功能。