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.     

Improving yeast two-hybrid screening systems.

Yeast two-hybrid (Y2H) screening methods are an effective means for the detection of protein-protein interactions. Optimisation and automation has increased the throughput of the method to an extent that allows the systematic mapping of protein-protein interactions on a proteome-wide scale. Since two-hybrid screens fail to detect a great number of interactions, parallel high-throughput approaches are needed for proteome-wide interaction screens. In this review, we discuss and compare different approaches for adaptation of Y2H screening to high-throughput, the limits of the method and possible alternative approaches to complement the mapping of organism-wide protein-protein interactions.     

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.     

Yeast "N"-hybrid systems for protein-protein and drug-protein interaction discovery

The majority of small molecule drugs act on protein targets to exert a therapeutic function. It has become apparent in recent years that many small molecule drugs act on more than one particular target and consequently, approaches which profile drugs to uncover their target binding spectrum have become increasingly important. Classical yeast two-hybrid systems have mainly been used to discover and characterize protein-protein interactions, but recent modifications and improvements have opened up new routes towards screening for small molecule-protein interactions. Such yeast "n"-hybrid systems hold great promise for the development of drugs which interfere with protein-protein interactions and for the discovery of drug-target interactions. In this review, we discuss several yeast two-hybrid based approaches with applications in drug discovery and describe a protocol for yeast three-hybrid screening of small molecules to identify their direct targets.     

A versatile bait vector allowing rapid isolation of prey vectors in Gal4-dependent yeast two-hybrid screens.

Two-hybrid screens have been widely used in recent years for identifying and isolating new interaction partners to known proteins. Current Gal4-dependent two-hybrid screens employ mostly bait and library vectors, which both have the ampicillin gene as a selection marker in bacteria. The isolation of the library plasmids takes several days, because library and bait plasmid cannot be separated easily. We have replaced the ampicillin gene by a kanamycin gene in a Gal4 DNA binding domain bait vector. This vector reduces four- to fivefold the time period required for the isolation of library plasmid DNA. In addition we have changed the multicloning site in the modified vector for easy cloning of cDNA inserts. This vector is advantageous not only in standard two-hybrid screens, but also in mass screens that require multiple screening rounds in order to characterize networks of protein-protein interactions.     

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.     

酵母双杂交技术应用进展

酵母双杂交技术是鉴定蛋白互作最有效和最广泛的分子生物学技术。该技术能直接作用于活细胞,检测细胞内蛋白质互作,具有成本低、易操作、可达到全基因组水平、能进行品种间的互作鉴定等诸多优点。较之传统的检测方法有明显优势,已在越来越多的领域得到应用。对酵母双杂交的技术原理以及应用进行了综述,介绍了该技术在发现新蛋白质、探究蛋白质功能、建立基因组蛋白连锁图、研究人类DNA文库和筛选药物作用位点等方面的重要应用,以期为该技术的广泛应用提供参考。     

Methods for the detection and analysis of protein-protein interactions

A large number of methods have been developed over the years to study protein-protein interactions. Many of these techniques are now available to the nonspecialist researcher thanks to new affordable instruments and/or resource centres. A typical protein-protein interaction study usually starts with an initial screen for novel binding partners. We start this review by describing three techniques that can be used for this purpose: (i) affinity-tagged proteins (ii) the two-hybrid system and (iii) some quantitative proteomic techniques that can be used in combination with, e.g., affinity chromatography and coimmunoprecipitation for screening of protein-protein interactions. We then describe some public protein-protein interaction databases that can be searched to identify previously reported interactions for a given bait protein. Four strategies for validation of protein-protein interactions are presented: confocal microscopy for intracellular colocalization of proteins, coimmunoprecipitation, surface plasmon resonance (SPR) and spectroscopic studies. Throughout the review we focus particularly on the advantages and limitations of each method.     

Development of a high-throughput yeast two-hybrid screening system to study protein-protein interactions in plants

We have developed a high-throughput yeast two-hybrid screening system (HTP-YTH) that incorporates yeast gap-repair cloning, multiple positive ( ADE2, HIS3, lacZ) and negative ( URA3-based) selection schemes to reduce the incidence of negative and false positive clones, and automation of laboratory procedures to increase throughput. This HTP-YTH system has been applied to the study of protein-protein interactions that are involved in rice defense signal transduction pathways. More than 100 genes involved in plant defense responses were selected from DuPont's rice expressed sequence tag (EST) databases as baits for HTP-YTH screening. Results from YTH screening of eight of these rice genes are presented in this paper. Not only have we identified known protein-protein interactions, but we have also discovered novel interactions, which may ultimately reveal the regulatory network of host defense signal transduction pathways. We have demonstrated that our HTP-YTH method can be used to map protein-protein interaction networks and signal transduction pathways in any system. In combination with other approaches, such efficient YTH screens can help us systemically to study the functions of known and unknown genes in the genomics era.     

A search for protein-protein interactions of peroxiredoxin 6 with the yeast two-hybrid system

Peroxiredoxins (Prx) are a family of nonselenium peroxidases that are involved in cell defense against oxidative stress and in redox regulation of intracellular signaling. Mammalian peroxiredoxin 6 (Prx6) belongs to the 1-Cys Prx subfamily. The protein-protein interactions of human Prx6 were studied using a yeast two-hybrid system. Hybrid plasmid pHybLex/Zeo/Prx6, which directed synthesis of a chimeric protein consisting of the DNA-binding domain (BD) of LexA and a Prx6 sequence, was used to screen a two-hybrid cDNA library Hybrid Hunter (Invitrogen). The screening identified two potential interaction partners of Prx6: the calcium-activated cysteine endopeptidase calpain and the p50RhoGAP protein of the family of Sec14-like proteins. The possibility for the interactions observed in the two-hybrid system to occur in oxidative stress in vivo is discussed.     

酵母双杂交中诱饵蛋白载体的构建与鉴定方法

酵母双杂交已是研究蛋白质相互作用的经典方法之一。该方法以真核生物酵母为模型,在体内研究活细胞内蛋白质的相互作用,具有高度敏感性,被很多研究者采用。综述了酵母双杂交系统中诱饵蛋白载体的构建,及其在转化酵母中的毒性、自激活性检测研究的最新进展。