Identification of proteins that interact with a protein of interest: Applications of the yeast two-hybrid system

The yeast two-hybrid system is a molecular genetic test for protein interaction. Here we describe a step by step procedure to screen for proteins that interact with a protein of interest using the two-hybrid system. This process includes, construction and testing of the bait plasmid, screening a plasmid library for interacting fusion proteins, elimination of false positives and deletion analysis of true positives. This procedure is designed to allow investigators to identify proteins and their encoding cDNAs that have a biologically significant interaction with your protein of interest.     

A two-hybrid dual bait system to discriminate specificity of protein interactions.

Biological regulatory systems require the specific organization of proteins into multicomponent complexes. Two hybrid systems have been used to identify novel components of signaling networks based on interactions with defined partner proteins. An important issue in the use of two-hybrid systems has been the degree to which interacting proteins distinguish their biological partner from evolutionarily conserved related proteins and the degree to which observed interactions are specific. We adapted the basic two-hybrid strategy to create a novel dual bait system designed to allow single-step screening of libraries for proteins that interact with protein 1 of interest, fused to DNA binding domain A (LexA), but do not interact with protein 2, fused to DNA binding domain B (lambda cI). Using the selective interactions of Ras and Krev-1(Rap1A) with Raf, RalGDS, and Krit1 as a model, we systematically compared LexA- and cI-fused baits and reporters. The LexA and cI baitr reporter systems are well matched for level of bait expression and sensitivity range for interaction detection and allow effective isolation of specifically interacting protein pairs against a nonspecific background. These reagents should prove useful to refine the selectivity of library screens, to reduce the isolation of false positives in such screens, and to perform directed analyses of sequence elements governing the interaction of a single protein with multiple partners.     

Molecular cloning of a novel ubiquitin-like protein, UBIN, that binds to ER targeting signal sequences

To identify proteins that interact with HSP47, an endoplasmic reticulum (ER)-resident molecular chaperone, a yeast two-hybrid screening was performed using mouse full-length HSP47 including an N-terminal signal sequence as a bait. Analysis of several positive clones led to the identification and cloning of a novel gene, ubin, encoding a ubiquitin-like protein. Unlike other ubiquitin-like proteins, UBIN was shown to interact with signal sequences of various secretory and ER-luminal proteins, including HSP47, but not interact with signal sequences of mitochondrial targeting in two-hybrid system. The possible function of UBIN will be discussed with regards to novel characteristics of binding to signal sequences for ER targeting.     

酵母双杂交技术筛选并回转验证在胞内与PML-C结构域相互作用的蛋白

目的 利用酵母双杂交技术在活细胞内筛选并回转验证与PML-C结构域相互作用的蛋白质.方法 通过诱饵质粒pGBKT7-PML-C,利用酵母双杂交系统从白血病细胞cDNA文库中筛选与PML-C结构域相互作用的蛋白质.结果 利用酵母双杂交技术筛选到43个能与PML-C结构域相互作用的克隆;经进一步的归类与酵母回转试验得到9个阳性克隆.结论 在细胞内PML-C结构域能与多种蛋白质有相互作用.中性粒细胞弹性蛋白酶（neutrophil elastase,NE）介导的急性早幼粒细胞白血病的发生可能与这些相互作用所致的生物学功能改变有关.     

Direct association of tristetraprolin with the nucleoporin CAN/Nup214

Tristetraprolin (TTP) is a widely expressed, zinc finger-containing protein that has been implicated in the regulation of TNFalpha production in mice. Stimulus-dependent cytoplasmic translocation of TTP has been demonstrated in several cells. In this report we used the yeast two-hybrid screen to identify proteins able to interact with full length, human TTP. One of the isolated TTP-interacting clones encoded the FG repeat region of the nuclear pore protein Nup214. Full length Nup214 co-precipitated with TTP from resting and LPS-stimulated THP-1 cells, indicating that this interaction occurred in intact cells. The ability of TTP to associate with Nup214 was dependent on two intact zinc fingers within TTP. In contrast to wild type TTP that localized primarily in the cytosol, a mutant unable to associate with Nup214 localized throughout the cell, suggesting that the interaction with Nup214 regulates TTP localization.     

利用酵母双杂交系统筛选与人巨细胞病毒皮层蛋白pUL23相互作用的病毒编码蛋白

人巨细胞病毒(HCMV) UL23基因编码病毒皮层蛋白,该基因缺失时,病毒在人包皮成纤维细胞(HFF)中的繁殖速度加快.为进一步阐述HCMV UL23基因编码产物 pUL23的功能及调控机制,采用鸟枪法构建了融合于GAL4活性区域的HCMV Towne株 基因组随机表达文库.利用酵母双杂交技术,以pGBKT7 -UL23为诱饵质粒,从构建 的HCMV基因组表达文库中筛选到与pUL23相互作用的病毒编码蛋白pUL24. GST-pull down实验和免疫共沉淀实验进一步确认两种病毒蛋白之间的相互作用.结果 表明,构建的HCMV基因组表达文库能够用于GAL4酵母双杂交系统筛选与诱饵蛋白相互作用的病毒自身编码蛋白.病毒蛋白pUL23和pUL24之间具有相互作用,这为进一 步阐述pUL23在HCMV感染过程中的功能提供依据.该研究为揭示HCMV病毒感染机制奠定了基础.     

Novel protein interactors of urokinase-type plasminogen activator receptor

The urokinase-type plasminogen activator receptor (uPAR) has been implicated in tumor growth and metastasis. The crystal structure of uPAR revealed that the external surface is largely free to interact with a number of proteins. Additionally, due to absence of an intracellular cytoplasmic protein domain, many of the biological functions of uPAR necessitate interactions with other proteins. Here, we used yeast two-hybrid screening of breast cancer cDNA library to identify hSpry1 and HAX1 proteins as putative candidate proteins that interact with uPAR bait constructs. Interaction between these two candidates and uPAR was confirmed by GST-pull down, co-immunoprecipitation assays and confocal microscopy. These novel interactions that have been identified may also provide further evidence that uPAR can interact with a number of other proteins which may influence a range of biological functions.     

Genetic analysis of the Escherichia coli FtsZ.ZipA interaction in the yeast two-hybrid system. Characterization of FtsZ residues essential for the interactions with ZipA and with FtsA

The recruitment of ZipA to the septum by FtsZ is an early, essential step in cell division in Escherichia coli. We have used polymerase chain reaction-mediated random mutagenesis in the yeast two-hybrid system to analyze this interaction and have identified residues within a highly conserved sequence at the C terminus of FtsZ as the ZipA binding site. A search for suppressors of a mutation that causes a loss of interaction (ftsZ(D373G)) identified eight different changes at two residues within this sequence. In vitro, wild type FtsZ interacted with ZipA with a high affinity in an enzyme-linked immunosorbent assay, whereas FtsZ(D373G) failed to interact. Two mutant proteins examined restored this interaction significantly. In vivo, the alleles tested are significantly more toxic than the wild type ftsZ and cannot complement a deletion. We have shown that a fusion, which encodes the last 70 residues of FtsZ in the two-hybrid system, is sufficient for the interaction with FtsA and ZipA. However, when the wild type sequence is compared with one that encodes FtsZ(D373G), no interaction was seen with either protein. Mutations surrounding Asp-373 differentially affected the interactions of FtsZ with ZipA and FtsA, indicating that these proteins bind the C terminus of FtsZ differently.     

Evidence that F-plasmid proteins TraV, TraK and TraB assemble into an envelope-spanning structure in Escherichia coli

We have examined the role of the F-plasmid TraV outer membrane lipoprotein in the assembly of F-pili. Yeast two-hybrid analysis with a traV bait repeatedly identified traK, which is predicted to encode a periplasmic protein, among positive prey plasmids. A traK bait in turn identified traV and traB, which is predicted to encode an inner membrane protein. A traB bait exclusively identified traK preys. Several additional observations support the hypothesis that TraV, TraK and TraB form a complex in Escherichia coli that spans the cell envelope from the outer membrane (TraV) through the periplasm (TraK) to the inner membrane (TraB). First, two-hybrid analyses indicated that TraV and TraB bind to different TraK segments, as required if TraK bridges a ternary complex. Secondly, all three proteins fractionated with the E. coli outer membrane in tra+ cells. In contrast, TraB fractionated with the inner membrane in traV or traK mutant cells, and TraK appeared in the osmotic shock fluid from the traV mutant. These results are consistent with a TraV-TraK-TraB complex anchored to the outer membrane via the TraV lipoprotein. Further, in traK mutant cells, TraV failed to accumulate to a detectable level, and the TraB level was significantly reduced, suggesting that TraV and TraB must interact with TraK for either protein to accumulate to its normal level. Both TraK and TraV accumulated in traB2[Am] cells; however, the TraB2 amber fragment could be detected by Western blot, and sequence analysis indicated that the fragment retained the TraK-binding domain suggested by yeast two-hybrid analysis. We propose that TraV is the outer membrane anchor for a trans-envelope, Tra protein structure required for the assembly of F-pili and possibly for other events of conjugal DNA transfer.     

Interactions between Rho GTPases and Rho GDP dissociation inhibitor (Rho-GDI)

The Rho-GDP dissociation inhibitor (Rho-GDI) was used as bait in a two-hybrid screen of a human leucocyte cDNA library. Most of the isolated cDNAs encoded GTPases of the Rho subfamily: RhoA, B, C, Rac1, 2, CDC42 and RhoG. The newly discovered RhoH interacted very poorly with Rho-GDI. Another protein partner shared a homology with RhoA that points to Asp67(RhoA)-Arg68(RhoA)-Leu69(RhoA) as critical for interaction with Rho-GDI. A second screen with RhoA as bait led to the isolation of GDI only. In order to investigate the relative role of protein-protein and protein-lipid interactions between Rho GTPases and Rho-GDI, CAAX box mutants of RhoA were produced. They were found to interact with Rho-GDI as efficiently as wild type RhoA, indicating that protein-protein interactions alone lead to strong binding of the two proteins. The C-terminal polybasic region of RhoA was also shown to be a site of protein-protein interaction with Rho-GDI.     

A novel approach for the identification of protein-protein interaction with integral membrane proteins

Protein-protein interaction plays a major role in all biological processes. The currently available genetic methods such as the two-hybrid system and the protein recruitment system are relatively limited in their ability to identify interactions with integral membrane proteins. Here we describe the development of a reverse Ras recruitment system (reverse RRS), in which the bait used encodes a membrane protein. The bait is expressed in its natural environment, the membrane, whereas the protein partner (the prey) is fused to a cytoplasmic Ras mutant. Protein-protein interaction between the proteins encoded by the prey and the bait results in Ras membrane translocation and activation of a viability pathway in yeast. We devised the expression of the bait and prey proteins under the control of dual distinct inducible promoters, thus enabling a rapid selection of transformants in which growth is attributed solely to specific protein-protein interaction. The reverse RRS approach greatly extends the usefulness of the protein recruitment systems and the use of integral membrane proteins as baits. The system serves as an attractive approach to explore novel protein-protein interactions with high specificity and selectivity, where other methods fail.     

Noncovalent SUMO-1 binding activity of thymine DNA glycosylase (TDG) is required for its SUMO-1 modification and colocalization with the promyelocytic leukemia protein

SUMO-1 is a member of a family of ubiquitin-like molecules that are post-translationally conjugated to various cellular proteins in a process that is mechanistically similar to ubiquitylation. To identify molecules that bind noncovalently to SUMO-1, we performed yeast two-hybrid screening with a SUMO-1 mutant that cannot be conjugated to target proteins as the bait. This screening resulted in the isolation of cDNAs encoding the b isoform of thymine DNA glycosylase (TDGb). A deletion mutant of TDGb (TDGb(Delta11)) that lacks a region shown to be required for noncovalent binding of SUMO-1 was also found not to be susceptible to SUMO-1 conjugation at an adjacent lysine residue, suggesting that such binding is required for covalent modification. In contrast, another mutant of TDGb (TDGb(KR)) in which the lysine residue targeted for SUMO-1 conjugation is replaced with arginine retained the ability to bind SUMO-1 non-covalently. TDGb was shown to interact with the promyelocytic leukemia protein (PML) in vitro as well as to colocalize with this protein to nuclear bodies in transfected cells. TDGb(KR) also colocalized with PML, whereas TDGb(Delta11) did not, indicating that the noncovalent SUMO-1 binding activity of TDGb is required for colocalization with PML. Furthermore, SUMO-1 modification of TDGb and PML enhanced the interaction between the two proteins. These results suggest that SUMO-1 functions to tether proteins to PML-containing nuclear bodies through post-translational modification and noncovalent protein-protein interaction.     

A novel approach for the identification of protein–protein interaction with integral membrane proteins

Protein–protein interaction plays a major role in all biological processes. The currently available genetic methods such as the two-hybrid system and the protein recruitment system are relatively limited in their ability to identify interactions with integral membrane proteins. Here we describe the development of a reverse Ras recruitment system (reverse RRS), in which the bait used encodes a membrane protein. The bait is expressed in its natural environment, the membrane, whereas the protein partner (the prey) is fused to a cytoplasmic Ras mutant. Protein–protein interaction between the proteins encoded by the prey and the bait results in Ras membrane translocation and activation of a viability pathway in yeast. We devised the expression of the bait and prey proteins under the control of dual distinct inducible promoters, thus enabling a rapid selection of transformants in which growth is attributed solely to specific protein–protein interaction. The reverse RRS approach greatly extends the usefulness of the protein recruitment systems and the use of integral membrane proteins as baits. The system serves as an attractive approach to explore novel protein–protein interactions with high specificity and selectivity, where other methods fail.     

Candida albicans Cdc37 interacts with the Crk1 kinase and is required for Crk1 production

Crk1, a Cdc2-related protein kinase from the human pathogenic fungus Candida albicans, plays an important role in hyphal development and virulence. To address its regulatory mechanisms, we searched for Crk1 interacting proteins by two-hybrid screening. A CDC37 ortholog (CaCDC37) was cloned from the screening with the Crk1 kinase domain as the bait. The CaCdc37 interacted preferentially with the kinase domain of Crk1 (Crk1N) as shown by two-hybrid and immunoprecipitation experiments. CaCDC37 could complement a cdc37 thermosensitive mutant (cdc37-34) of Saccharomyces cerevisiae. Importantly, Crk1 protein was hardly detectable in the cdc37-34 mutant at restrictive temperature. However, upon expression of CaCdc37 in the cdc37 mutant, Crk1 protein was detected even at restrictive temperature. Our data suggested that CaCdc37 was required for the production of Crk1 kinase. Like Cdc37 proteins of S. cerevisiae and higher eukaryotes, CaCdc37 might function as a molecular chaperone that stabilized Crk1 and other protein kinases in C. albicans. In support of this, CaSTI1 was identified from a two-hybrid screen with the full-length Crk1 as the bait. CaSti1 showed two-hybrid interactions with both Crk1 and the CaCdc37.     

A proposed role for the Polycomb group protein dRING in meiotic sister-chromatid cohesion

ORD protein is required for accurate chromosome segregation during male and female meiosis in Drosophila melanogaster. Null ord mutations result in random segregation of sister chromatids during both meiotic divisions because cohesion is completely abolished prior to kinetochore capture of microtubules during meiosis I. Previous analyses of mutant ord alleles have led us to propose that the C-terminal half of the ORD protein mediates protein-protein interactions that are essential for sister-chromatid cohesion. To identify proteins that interact with ORD, we conducted a yeast two-hybrid screen using an ORD bait and isolated dRING, a core subunit of the Drosophila Polycomb repressive complex 1. We show that a missense mutation in ORD completely ablates the two-hybrid interaction with dRING and prevents nuclear retention of the mutant ORD protein in male meiotic cells. Using affinity-purified antibodies generated against full-length recombinant dRING, we demonstrate that dRING protein is expressed in the male and female gonads and colocalizes extensively with ORD on the chromatin of primary spermatocytes during G2 of meiosis. Our results suggest a novel role for the Polycomb group protein dRING and are consistent with the model that interaction of dRING and ORD is required to promote the proper segregation of meiotic chromosomes.Communicated by R. Paro     

Antifreeze proteins of the beetle Dendroides canadensis enhance one another's activities

Larvae of the beetle Dendroides canadensis produce a family of 13 antifreeze proteins (DAFPs), four of which are in the hemolymph. Antifreeze proteins lower the noncolligative freezing point of water (in the presence of ice) below the melting point, producing a difference between the freezing and melting points termed thermal hysteresis. This activity (THA) is dependent upon DAFP specific activity, concentration, and the presence of enhancers. Enhancers may be low molecular mass enhancers, such as glycerol, or other proteins. The protein enhancers complex with the DAFPs, thereby blocking a larger surface area of the potential seed ice crystal and consequently lowering the freezing point. A yeast two-hybrid screen was performed using certain hemolymph DAFPs as "bait" in an effort to identify endogenous protein enhancers. Among the positive proteins identified as interacting with the bait DAFPs, and confirmed by co-immunoprecipitation, were other DAFPs. When pure DAFPs were added to one another, those identified by the yeast two-hybrid screen as interacting with one another exhibited a synergistic enhancement of thermal hysteresis activity. In contrast, those DAFPs which the screen indicated did not interact failed to enhance one anothers' activities. DAFPs-1 and -2 interact and enhance one another. Point mutations of one of the interacting DAFPs (DAFP-2) indicated that both of the two amino acid residues that differ between DAFPs-1 and -2 were required for interaction. Glycerol enhanced the THA of the DAFPs only when DAFPs known to interact were present in the test solution. Addition of glycerol to a test solution containing only one DAFP did not produce enhancement. Therefore, glycerol enhances activity by stimulating interactions between DAFPs.     

Identification of cytokeratins as accessory mediators of Salmonella entry into eukaryotic cells

Pathogenic Salmonella species initiate infection of a mammalian host by inducing their own uptake into intestinal M-cells. During the uptake process, the bacteria utilize an intrinsic secretion system to release proteins that enter host cells. The secreted invasion-mediating proteins subsequently interact with host cell components that induce alterations in the actin cytoskeleton. To identify potential cellular determinants of invasion, we employed a yeast two-hybrid system using the secreted Salmonella invasion protein (SipC) as the bait protein. This system identified cytokeratins, supportive components of the cytoskeletal matrix, as proteins that may physically interact with SipC. Transfection-based studies revealed an inhibition of Salmonella invasion when a dominant negative cytokeratin-18 was expressed. Immunofluorescent confocal microscopy studies revealed that Salmonella did not enter HEp-2 cells expressing the dominant negative cytokeratin-18. These results suggest that an interaction between SipC and cytokeratin-18 may occur as part of Salmonella invasion.