Introduction

Protein-protein interactions (PPIs) are attracting increased attention in drug discovery studies. PPIs have functions in the regulation of cellular states involved in various diseases1,2. In particular, membrane-mediated PPIs play central roles in vital biological processes and are prime drug targets. For example, tumorigenesis is often the result of gene mutations that lead to alterations in membrane PPIs and aberrant signaling cascades3. Because the molecules that control (inhibit or activate) these membrane PPIs can be used as drug candidates, rapid and unbiased screening of these molecules is essential for drug development.

The major targets of membrane proteins are G-protein-coupled receptors (GPCRs), ion channels, transporters, receptor serine/threonine and tyrosine protein kinases4,5 (e.g. epidermal growth factor receptor (EGFR)6,7, human epidermal growth factor receptor 2 (HER2)8,9 and vascular endothelial growth factor receptor (VEGFR)10,11). The extracellular domains of these transmembrane proteins are commonly targeted to identify agonistic and antagonistic ligands. However, recently developed drug therapies have increasingly targeted the intracellular domains (kinase domains) of these transmembrane proteins to control interactions with the components of downstream signaling cascades12. Similarly, membrane-associated proteins, such as guanine nucleotide-binding protein (G-protein), small GTPases, kinase proteins and other signal transducers, hold enormous potential for use in the development of novel drugs. As a representative example, protein kinases are responsible for the reversible phosphorylation of proteins via PPIs and have a strong relationship with growth, infiltration and apoptosis in cancer cells. A multitude of these membrane-associated proteins are involved in various diseases and are often associated with the inner side of the plasma membrane13. Several kinase and GTPase inhibitors have been developed in the pharmaceutical industry14,15,16. More recently, intracellular antibodies (intrabodies), which can inhibit signal transducers, including membrane-associated proteins, have been studied as valuable tools for controlling PPIs inside cells17,18,19. Thus, molecules that can control the PPIs of transmembrane and membrane-associated proteins on the inner side of the plasma membrane have a potential to become an important group of drug targets.

Various useful screening systems for PPIs exist and have yielded significant findings20,21,22,23. These techniques are required for screening of large numbers of proteins and are preferable in the in vivo cellular context. In particular, yeast two-hybrid systems are the typical tools for such screening of candidate proteins in vivo24,25,26,27. Among them, split-ubiquitin system is a well-established, useful technique to screen the candidate proteins with the PPIs for membrane target proteins28,29. As in other yeast systems, small G-protein-based methods, including the Sos recruitment system and the Ras recruitment system, are occasionally used to study the PPIs of membrane proteins23,30,31. These methods remain useful alternatives to the original two-hybrid system; however, they suffer from technical complexities, such as the different temperatures required for growth and screening (25 °C and 36 °C), slow growth at suboptimal temperatures, obligatory replica-plating steps (glucose to galactose medium) and the total time required for the procedure (~7 days including precultivation)32,33,34. In addition to bioluminescence resonance energy transfer (BRET) and fluorescence resonance energy transfer (FRET)35, protein fragment complementation assays using split-GFP and split-luciferase36,37,38,39,40 are useful tools for detecting the association of two proteins in living cells and have the potential to resolve these limitations. Among the varied systems used, growth reporters are generally applicable to library screening because of their convenience. Our previously developed screening method using yeast heterotrimeric G-proteins, called the Gγ recruitment system41,42,43, also makes it possible to screen PPIs between a target protein and candidate proteins by the mating growth assay without false-positive clones. The details of the mechanism utilized for detecting PPIs are presented below.

The Gγ recruitment system for detecting PPIs is based on the fundamental principle that yeast pheromone (mating) signaling requires the localization of a complex consisting of the β- and γ-subunits of heterotrimeric G-proteins (Gβ/Gγ) to the inner leaflet of the plasma membrane42. In yeast, the G-protein-coupled receptor (GPCR) undergoes a conformational change after binding ligands and then activates heterotrimeric G-proteins. The activated G-proteins trigger the dissociation of the Gβ/Gγ complex from Gα concurrently with the exchange of GDP/GTP on the Gα subunit. The Gβ subunit (complexed with membrane-associated Gγ) then acts upon the effectors, thereby activating the downstream signaling cascade for mating44. Notably, localization of the Gβ/Gγ complex to the inner leaflet of the plasma membrane via the lipidation motif of the Gγ subunit is required for initiating G-protein signaling. Our Gγ recruitment system specifically makes use of a cytosolic truncated variant of Gγ (named Gγcyto) that is fused to a soluble target protein of interest, ‘X’ (Gγcyto-X), as shown in Fig. 1A. For the library, the candidate proteins (Y1) should be attached to the artificial lipidation site to ensure localization to the membrane (Fig. 1A). When an interaction occurs between target ‘X’ and candidate ‘Y1’, the Gγcyto-X fusion protein brings Gβ to the membrane and induces subsequent activation of the pheromone signaling pathway. The promoted signaling can be detected by a fluorescent reporter assay or a mating growth assay after growth in simple glucose media at the optimal temperature (30 °C). Briefly, the expression of GFP under the control of a pheromone-responsive FIG1 promoter or mating with intact haploid cells of the opposite mating type permits the detection of PPIs (Fig. 1A and Fig. S1). Because the localization of Gγcyto in the cytosol completely prevents this signaling activation, the Gγ recruitment system allows for extremely reliable, low-background growth screening that excludes false-positive candidates at the optimal temperature (30 °C)42. The procedures for screening involve simply mixing the different mating-type cells (recombinant a-cells and intact α-cells) and plating on selective media (~4 days including precultivation) (Fig. S1; right). The advanced system (competitor-introduced Gγ recruitment system), which additionally expresses an interaction competitor protein (Y2) in the cytosol (Fig. 2A), can offer highly selective screening for protein variants whose affinities have been intentionally altered to exceed the set threshold41. This approach is applicable to selectively screening affinity-enhanced or affinity-attenuated protein variants by exchanging the positions of the competitor protein and the library proteins (Y1 and Y2)41,45.

Figure 1
figure 1

Schematic diagram of Gγ recruitment systems to detect PPIs of cytosolic or membrane target proteins.

(A) Schematic outline of the previously established Gγ recruitment system for cytosolic target proteins. When target protein ‘X’ fused to Gγcyto interacts with candidate protein ‘Y1’, the Gβ and Gγcyto complex (Gβγcyto) migrates to the inner leaflet of the plasma membrane and restores the signaling function. If protein ‘X’ cannot interact with protein ‘Y1’, Gβγcyto is released into the cytosol and signaling is blocked. (B) Schematic outline of the Gγ recruitment system for membrane protein targets. When membrane target protein ‘X’ interacts with candidate protein ‘Y1’ fused to Gγcyto, the Gβ and Gγcyto complex (Gβγcyto) migrates to the inner leaflet of the plasma membrane and restores the signaling function. If membrane protein ‘X’ cannot interact with protein ‘Y1’, Gβγcyto is released into the cytosol and signaling is blocked.

Figure 2
figure 2

Schematic diagram of competitor-introduced Gγ recruitment systems to screen affinity-altered protein variants for cytosolic or membrane target proteins.

(A) Schematic outline of the previously established competitor-introduced Gγ recruitment system for cytosolic target proteins. Target protein ‘X’ should be expressed as a fusion with Gγcyto in the cytosol. Protein ‘Y1’ should be anchored to the plasma membrane, whereas ‘Y2’ should be expressed in the cytosol. By establishing ‘Y1’ and ‘Y2’ as the parental (known) proteins originally bound to target ‘X’ and the candidate variant proteins, respectively, ‘Y1’ and ‘Y2’ compete to bind to target ‘X.’ When ‘X’ has higher affinity for ‘Y2,’ G-protein signaling is prevented due to the inability of Gγcyto to migrate to the plasma membrane. When ‘X’ has higher affinity for ‘Y1,’ G-protein signaling is transmitted into the yeast cells and invokes the mating process. Thus, affinity-enhanced proteins or affinity-attenuated proteins can be screened in a specific manner. (B) Schematic outline of competitor-introduced Gγ recruitment system for membrane protein targets. Target protein ‘X’ is a transmembrane or membrane-associated protein. Protein ‘Y1’ should be fused to Gγcyto, whereas ‘Y2’ should be expressed in the cytosol. By establishing ‘Y1’ and ‘Y2’ as the parental (known) proteins originally bound to the membrane target ‘X’ and the candidate variant proteins, respectively, ‘Y1’ and ‘Y2’ compete to bind to target ‘X.’ When ‘X’ has a higher affinity for ‘Y2,’ G-protein signaling is prevented due to the inability of Gγcyto to migrate to the plasma membrane. When ‘X’ has higher affinity for ‘Y1’ fused to Gγcyto, G-protein signaling is transmitted into the yeast cells and initiates the mating process.

The localization of Gγ is of key importance for the low background of the Gγ recruitment system42. The previous Gγ recruitment system was limited to using only soluble cytosolic proteins as the target (X), as candidate proteins (Y1) should be expressed on the membrane (Fig. 1A). The competitor-introduced system also had a similar problem, restricting the target X to cytosolic proteins (Fig. 2A). Thus, these previous systems could not target membrane proteins. In the current study, we have reevaluated the Gγ recruitment system by changing the localization of target proteins from the cytosol to the membrane; however, the prior protocol did not work well. With the aim of expanding the applicability of the system, we considered new protocols for the Gγ recruitment systems that might be suitable for evaluating membrane proteins as targets. The updated method allows the Gγ recruitment system to be used in the analysis of both cytoplasmic and membrane target proteins.

Results

Selection of candidate proteins interacting with membrane protein targets using a previously established PPI-detecting Gγ recruitment system

First, we tested whether the previous Gγ recruitment system could target membrane proteins. In the previous system, the Fc protein of human immunoglobulin G (IgG) and the Z domain of Staphylococcus aureus protein A (ZWT)46 were used for the PPI models. Several Z variants (ZWT, ZK35A, ZI31A and Z955) with varied affinities for the Fc protein were also used for the PPI models (ZWT, 5.9 × 107 M−1; ZK35A, 4.6 × 106 M−1; ZI31A, 8.0 × 103 M−1; and Z955, none)47,48. In contrast to the previous system, target protein ‘X’ was set to localize to the inner leaflet of the plasma membrane (previously, target ‘X’ was fused to Gγcyto in the cytosol) and candidate protein ‘Y1’ was fused to Gγcyto (previously, candidate protein ‘Y1’ was artificially localized to the inner leaflet of the membrane) (Fig. 1A,B). As the fictive model of target protein ‘X,’ the Fc fragment was fused to the lipidation motifs in this study (Fig. 1B). It was also notable that the lipidation motifs were fused to the Fc fragment at both the N-terminus (Gpa1p motif; Gpa1N) and the C-terminus (Ste18p motif; Ste18C) to test the accessibility between the Fc fragment and the Z variants (the C-terminal Ste18p motif was used to express the Z variants as the candidate ‘Y1’ proteins described in the previous study) (Fig. 1B). As the models of ‘Y1’ proteins for the candidate library, the Z variants were fused to the C-terminus of Gγcyto to express Gγcyto-Y1 fusion proteins in the cytosol (Fig. 1B).

To express the target membrane proteins, the genes encoding the Fc fragment attached to artificial lipidation motifs were stably integrated into the ste18 locus of an a-type haploid yeast chromosome, resulting in MC-FC and MC-FN yeast strains (Table 1). For the candidate proteins, autonomous replication plasmids for the expression of the four different Z variants (ZWT, ZK35A, ZI31A and Z955) fused to Gγcyto (Gγcyto-Y1) (pGK413-Gγ-EZWT, pGK413-Gγ-EZK35A, pGK413-Gγ-EZI31A and pGK413-Gγ-EZ955) (Table 2) were introduced into the MC-FC and MC-FN yeast cells (Fig. 3A and Fig. S2A). Flow cytometric analysis of the transformants was conducted after incubation in medium containing the α-alpha-cell mating pheromone (α-factor) (Fig. S1; left). The engineered yeast strains expressing the Gγcyto-ZWT and Gγcyto-ZK35A fusion proteins as candidates slightly induced the transcription of GFP reporter genes via interaction with the membrane-associated Fc fragment, although the fluorescence levels were extremely low (Fig. 3B and Fig. S2B). In mating selection with intact α-type yeast cells (Fig. S1; right), the strains expressing Gγcyto-ZWT and Gγcyto-ZK35A exhibited specific but negligible cell growth on selective medium (Fig. 3C and Fig. S2C). In both GFP transcription assays and mating growth selection, interactions of Gγcyto-ZI31A (very low affinity for Fc) and Gγcyto-Z955 (negative control) with the membrane-associated Fc fragment were not detected. These results showed that the previous protocol was not sufficient to screen the interactions between membrane-associated target ‘X’ and candidate ‘Y1’-fused Gγcyto proteins.

Table 1 Yeast strains used in this study.
Table 2 List of plasmids used in this study.
Figure 3
figure 3

Selection of Z variants binding to a membrane-associated target Fc protein using previous and new Gγ recruitment systems.

(A) Previous Gγ recruitment system for membrane proteins as targets. (B,C) Flow cytometric analyses and mating growth assay. The fluorescence and growth intensities of the engineered strains expressing C-terminally membrane-associated Fc via stable integration into the yeast chromosome as well as cytosolic Z variants fused to Gγcyto ‘Y1’ via autonomous replication plasmids. The control yeast shows the strain without the expression of ‘Y1’ fused to Gγcyto (transformed with pGK413 mock vector). (D) New Gγ recruitment system for membrane proteins as targets. (E,F) Flow cytometric analyses and mating growth assay. The fluorescence and growth intensities of the engineered strains expressing C-terminally membrane-associated Fc and cytosolic Z variants fused to Gγcyto via stable integration into the yeast chromosome. The control yeast shows the strain without the expression of ‘Y1’ fused to Gγcyto (MC-FC in Table 1).

PPI-detecting Gγ recruitment system for the selection of candidate proteins interacting with membrane protein targets

Next, we tested the new protocol, in which we changed the method used to introduce the Gγcyto-Y1 candidate genes. The DNA cassettes for cytosolic expression of the Gγcyto-fused candidate Z variants (ZWT, ZK35A, ZI31A and Z955) as a library were stably integrated into the MC-FC and MC-FN yeast chromosomes, generating FC(FN)-GW, FC(FN)-GK, FC(FN)-GI and FC(FN)-G9 strains (Table 1) (Fig. 3D and Fig. S2D). The engineered yeast strains chromosomally harboring Gγcyto-ZWT and Gγcyto-ZK35A genes showed apparent fluorescence in the GFP transcription assays (Fig. 3E and Fig. S2E). Similarly, in the mating selection, the same strains grew well on the selective medium (Fig. 3F and Fig. S2F). Compared with the Gpa1p-derived N-terminal lipidation motif, the C-terminally attached Ste18p lipidation motif was likely slightly favorable for PPI detection due to a reduction in accessibility between the membrane-associated Fc fragment and the Gγcyto-fused Z domain (Fig. 3D–F and Fig. S2D–F). These results were clearly different from those following expression of Gγcyto-fused candidate ‘Y1’ using autonomous replicating plasmids (Fig. 3A–C and Fig. S2A–C).

Competitive selection of affinity-enhanced protein variants interacting with membrane protein targets using a previous protocol

Previously, we established the competitor-introduced Gγ recruitment system for selective screening of protein variants that exceed a specified affinity threshold41 (Fig. 2A). In the conventional Gγ recruitment system, additional expression of a cytosolic parental (known) protein (Y2) that binds to Gγcyto-fused target protein ‘X’ competes with artificially membrane-associated protein variants as a candidate library (Y1), thereby permitting the selective screening of affinity-enhanced protein variants (Fig. 2A).

To test whether the previous competitor-introduced Gγ recruitment system allows for the use of membrane proteins as target ‘X’ (Fig. 2B and S3A), we consistently used the membrane-associated Fc fragment and the Gγcyto-fused Z variants as target ‘X’ and candidate ‘Y1’ proteins, respectively (Figs. 4A and S4A). ZI31A (low affinity for Fc; 8.0 × 103 M−1) was utilized as the model of the competitive parental ‘Y2’ protein (Figs. 4B and S4B). Therefore, the ZWT and ZK35A candidate proteins (Y1), with higher affinities, should have outcompeted the interaction between membrane-associated Fc (X) and cytosolic ZI31A (Y2), recovering the signaling in the system (Fig. S3A). In the previous system, the DNA cassette for ZI31A expression as a competitor ‘Y2’ protein in the cytosol was stably integrated into the yeast chromosome of MC-FC, in which the C-terminally membrane-associated Fc fragment (X) (with the Ste18p lipidation motif) was expressed, generating an FC-I strain (Table 1). Autonomous replication plasmids for expression of the Gγcyto-fused Z variants as candidate ‘Y1’ (pGK413-Gγ-EZWT, pGK413-Gγ-EZK35A, pGK413-Gγ-EZI31A and pGK413-Gγ-EZ955) (Table 2) were then introduced into the FC-I strain. However, both flow cytometric analysis and mating selection were barely able to detect the interactions between the membrane-associated Fc fragment (target ‘X’) and the Gγcyto-fused Z variants (candidate ‘Y1’) relative to the interactions between the membrane-associated Fc fragment and cytosolic ZI31A in all transformants (Fig. 4B). Additionally, when using an FN-I strain chromosomally expressing an N-terminally membrane-associated Fc fragment (X) (with a Gpa1p lipidation motif) and competitive ZI31A protein (Y2) (Table 1), the transformants in which the candidate autonomous plasmids were introduced to express the Gγcyto-fused Z variants (Y1) provided similar results to the C-terminally membrane-associated Fc fragment (Fig. S4B). These results showed that the previous system was unable to screen the interactions between membrane-associated target ‘X’ and candidate ‘Y1’-fused Gγcyto proteins relative to the interactions between membrane target ‘X’ and the cytosolic ‘Y2’ competitor.

Figure 4
figure 4

Competitive selection of Z variants with higher affinities for membrane-associated target Fc using previous and new methods for affinity-enhanced systems.

(A) Previous affinity-enhanced system for membrane proteins as targets. (B) Flow cytometric analyses and mating growth assay. The fluorescence and growth intensities of the engineered strains expressing C-terminally membrane-associated Fc and competitor ZI31A as cytosolic ‘Y2’ via stable integration into the yeast chromosome as well as cytosolic Z variants ‘Y1’ fused to Gγcyto via autonomous replication plasmids. Control yeast strains lacked the expression of ‘Y1’ fused to Gγcyto (transformed with pGK413 mock vector). (C) New affinity-enhanced system for membrane proteins as target. (D,E) Flow cytometric analyses and mating growth assay. The fluorescence and growth intensities of the engineered strains expressing C-terminally membrane-associated Fc, competitor cytosolic Z variants ‘Y2’ and cytosolic Z variants ‘Y1’ fused to Gγcyto via stable integration into the yeast chromosome. The control yeast shows the strain without the expression of ‘Y1’ fused to Gγcyto.

Competitor-introduced Gγ recruitment system that specifically selects affinity-enhanced protein variants interacting with membrane protein targets

Similar to what was described in the previous section, we attempted to change the protocol by introducing the expression cassettes for Gγcyto-Y1 candidate genes into the competitor-introduced Gγ recruitment system (Figs. 4C and S4C). As competitive parental ‘Y2’ proteins, the genes for expressing the four different Z variants (ZWT, ZK35A, ZI31A and Z955) in the cytosol were integrated into the MC-FC yeast chromosome (also expressing the C-terminally membrane-associated Fc fragment with the Ste18p lipidation motif as target ‘X’), generating FC-W, FC-K, FC-I and FC-9. The DNA cassettes for expressing the Gγcyto-fused candidate Z variants as model library Y1 proteins were then stably integrated into the chromosome of the four yeast strains, generating 16 engineered yeast strains (FC-GWW through FC-G99; Table 1) (Fig. 4C).

Both flow cytometric analysis and mating selection revealed the interactor combinations between membrane-associated Fc and the Gγcyto-fused Z variants serving as candidate ‘Y1’ proteins, with higher affinities than when the cytosolic Z variants served as competitor ‘Y2’ proteins (e.g., Y1 and Y2: ZWT and ZK35A; ZWT and ZI31A; and ZK35A and ZI31A), although the very weak interactions between Fc and Gγcyto-fused ZI31A (Y1 and Y2: ZI31A and Z955) could not be detected (Fig. 4D,E). These results clearly showed that the strains recovered signal transmission only when interactions between the membrane-associated Fc fragment (target ‘X’) and the Gγcyto-fused Z variants (candidate ‘Y1’) overcame the competitive interactions between Fc (target ‘X’) and the cytosolic Z variants (competitor ‘Y2’). Additionally, when using a strain chromosomally expressing the N-terminally membrane-associated Fc fragment (X) (with the Gpa1p lipidation motif) (FN-GWW through FN-G99; Table 1), similar results were obtained (Fig. S4C–E).

Thus, Gγcyto-fused ‘Y1’ candidate proteins should be stably integrated into the yeast chromosome to specifically select the affinity-enhanced protein variants against membrane-associated protein ‘X’ in the competitor-introduced Gγ recruitment system. This modification of the method made the competitor-introduced Gγ recruitment system able to screen affinity-enhanced protein variants by using membrane proteins as the target proteins.

Competitive selection of affinity-attenuated protein variants interacting with membrane protein targets using a previous protocol

Previously, we also established a system that permits the selective screening of affinity-attenuated protein variants. In the conventional Gγ recruitment system, by setting the cytosolic protein (Y2) as the candidate library and the artificially membrane-associated protein (Y1) as the parental (known) competitor that binds to Gγcyto-fused target protein ‘X,’ the system permits the selective screening of affinity-attenuated protein variants (Fig. 2A).

To test whether the previous competitor-introduced Gγ recruitment system allows for the use of membrane proteins as target ‘X’ (Fig. 2B and S3B), we consistently used the membrane-associated Fc fragment and the cytosolic Z variants as target ‘X’ and candidate ‘Y2’ proteins, respectively (Fig. 5A and S5A). ZWT was utilized as the model of the competitive parental ‘Y1’ protein. Therefore, Gγcyto-fused ZWT (Y1) should have outcompeted the interactions between membrane-associated Fc (X) and the ZK35A, ZI31A and Z955 candidate proteins (Y2), which have lower affinities, recovering the signaling in the system.

Figure 5
figure 5

Competitive selection of Z variants with lower affinities for membrane-associated target Fc using the previous affinity-attenuated system.

(A) Previous affinity-attenuated system for membrane proteins as targets. (B,C) Flow cytometric analyses and mating growth assay. The fluorescence and growth intensities of the engineered strains expressing C-terminally membrane-associated Fc and competitor ZWT as cytosolic ‘Y1’ fused to Gγcyto via stable integration into the yeast chromosome and cytosolic Z variants ‘Y2’ via autonomous replication plasmids. The control yeast shows the strain without the expression of ‘Y1’ fused to Gγcyto and cytosolic Z variants ‘Y2.’

In the previous system, autonomous replication plasmids for expression of the Z variants in the cytosol as candidate ‘Y2’ proteins (pGK-LsZWTc, pGK-LsZK35Ac, pGK-LsZI31Ac and pGK-LsZ955c) (Table 2) were introduced into the FC-GW strain, which chromosomally expresses Fc-Ste18C as ‘X’ and Gγcyto-ZWT as competitor ‘Y1’ (Table 1). Both flow cytometric analysis and mating selection revealed the interactor combinations between membrane-associated Fc and the cytosolic Z variants serving as candidate ‘Y2’ proteins, whose affinities were lower than that of Gγcyto-fused ZWT as the competitor ‘Y1’ protein (Fig. 5B,C). Additionally, when using the FN-GW strain chromosomally expressing Gpa1N-Fc as ‘X’ and Gγcyto-fused ZWT as competitor ‘Y1’ (Table 1), the transformants in which the candidate autonomous plasmids were introduced to express the Z variants in the cytosol (Y2) provided similar results (Fig. S5B,C). In contrast to the affinity-enhanced system, these results showed that the previous competitor-introduced Gγ recruitment system was able to screen affinity-attenuated protein variants using membrane proteins as the target proteins.

Demonstration of applicability of our system using intracellular domain of EGFR and Grb2

To demonstrate the applicability of our system, we selected the intracellular domain of EGFR (EGFRcyto), which contains a tyrosine kinase domain and tyrosine phosphorylation sites and the adaptor protein Grb2 protein for the PPI pair49. In normal cells, binding of the epidermal growth factor (EGF) to the extracellular domain of EGFR leads to dimerization of the receptor and autophosphorylation of the receptor intracellular domain50,51. Grb2 binds to the phosphotyrosines of EGFR and links to the activation of subsequent intracellular signaling cascades52,53. In yeast, the intracellular domain of EGFR and its mutant derivatives have been often used to test the interaction with Grb2 protein54,55,56. To assay the interaction between EGFR and Grb2 in yeast, we used the intracellular domain of EGFR with L834R mutation (EGFRL834R,cyto; that is constitutively dimerized and activated even in the absence of EGF49,57) as the membrane protein by fusing several types of lipidation motifs at both the N-terminus (Gpa1p motif; Gpa1N) and the C-terminus (Ras1p motif; Ras1C and Ste18p motif; Ste18C). The Grb2 adaptor was fused to Gγcyto at the N-terminus and the C-terminus to test the accessibility between the membrane-associated EGFRL834R,cyto and the cytosolic Gγcyto-fused Grb2.

To express the membrane-associated EGFRL834R,cyto protein, the genes encoding the EGFRL834R,cyto attached to the artificial lipidation motifs (Ras1C, Ste18C and Gpa1N) were stably integrated into the ste18 locus of an a-type haploid yeast chromosome, resulting in MC-ErC, MC-EsC and MC-EgN yeast strains (Table 1). For the candidate proteins, the DNA cassettes for cytosolic expression of the Gγcyto-fused Grb2 at the N-terminus and the C-terminus (Gγcyto-Grb2 and Grb2-Gγcyto) were stably integrated into the MC-ErC, MC-EsC and MC-EgN yeast chromosomes, generating ErC-Ggrb(grbG), EsC-Ggrb(grbG) and EgN-Ggrb(grbG) (Table 1) (Fig. S6A,D). As a consequence of GFP transcription assays and mating selection, the engineered strains co-expressing the EGFRL834R,cyto with C-terminal lipidation motifs (Ras1C and Ste18C) and the C-terminally Gγcyto-fused Grb2 (Grb2-Gγcyto) specifically showed apparent fluorescence and cell growth on the selective medium (Fig. S6A–F). The accessibility between the phosphotyrosines of membrane-associated EGFRL834R,cyto and the SH2 domains of Grb2 or the distance of Gβγcyto complex from the membrane might have influenced the interactions of these proteins or to the subsequent membrane-anchored effector molecule49,52. Compared with the MC-ErC strain introducing the Grb2-Gγcyto-expressing autonomous replicating plasmid (pGK413-Grb2-Gγ) (Table 2), the ErC-grbG strain that chromosomally expressed Grb2-Gγcyto was determinably more suitable for recovering the signaling (Fig. 6A–E).

Figure 6
figure 6

Competitive selection of Grb2 for membrane-associated intracellular domain of EGFR.

(A) Previous Gγ recruitment system for intracellular domain of EGFR as the membrane target. (B) Flow cytometric analyses and mating growth assay. The fluorescence and growth intensities of the engineered strains expressing C-terminally membrane-associated intracellular domain of EGFR L834R mutant (EGFRL834R,cyto) via stable integration into the yeast chromosome as well as cytosolic Grb2 fused to Gγcyto ‘Y1’ (Grb2-Gγcyto) via autonomous replication plasmids. The control yeast shows the strain without the expression of Grb2-Gγcyto (transformed with pGK413 mock vector). (C) New Gγ recruitment system for intracellular domain of EGFR as the membrane target. (D,E) Flow cytometric analyses and mating growth assay. The fluorescence and growth intensities of the engineered strains expressing C-terminally membrane-associated EGFRL834R,cyto and cytosolic Grb2-Gγcyto via stable integration into the yeast chromosome. The control yeast shows the strain without the expression of Grb2-Gγcyto (MC-ErC in Table 1). (F) New affinity-enhanced system for intracellular domain of EGFR as the membrane target. (G,H) Flow cytometric analyses and mating growth assay. The fluorescence and growth intensities of the engineered strains expressing C-terminally membrane-associated EGFRL834R,cyto, competitor cytosolic Grb2 variants ‘Y2’ (Grb2, Grb2E89K and Grb2R86G) and cytosolic Grb2 ‘Y1’ fused to Gγcyto (Grb2-Gγcyto) via stable integration into the yeast chromosome. The control yeast shows the strain without the expression of any competitive ‘Y2’ proteins (ErC-grbG-LEU in Table 1). The negative control yeast shows the strain without the expression of ‘Y1’ fused to Gγcyto.

To further test whether the competitor-introduced Gγ recruitment system that has designed to select the affinity-enhanced protein variants interacting with membrane target proteins is applicable to the intracellular domain of EGFR, we consistently used the membrane-associated EGFRL834R,cyto and the Gγcyto-fused Grb2 as membrane target ‘X’ and candidate ‘Y1’ proteins, respectively (Fig. 6F). Several Grb2 variants (Grb2, Grb2E89K and Grb2R86G) with different affinities for the phosphotyrosines of EGFR were utilized for the competitive parental ‘Y2’ proteins (Ka; Grb2 > Grb2E89K > Grb2R86G)58.

Similar to what was described in the previous section, we tested the new protocol by chromosomally integrating the expression cassettes for Y1-Gγcyto candidate genes (Fig. 6F). As competitive parental ‘Y2’ proteins, the genes for expressing the three different Grb2 variants (Grb2, Grb2E89K and Grb2R86G) in the cytosol were integrated into the ErC-grbG yeast chromosome (also co-expressing the membrane-associated EGFRL834R,cyto with the Ras1p lipidation motif as target ‘X’ and the Grb2-Gγcyto fusion protein as candidate ‘Y1-Gγcyto’), generating ErC-grbG-grb, ErC-grbG-E89K and ErC-grbG-R86G (Table 1). ErC-grbG-LEU yeast strain never expressing any competitor proteins was also generated as positive control (Table 1).

Both flow cytometric analysis and mating selection displayed the consistent results with the Z variants as expected (Fig. 6G,H). When using the strains respectively expressing Grb2E89K and Grb2R86G as the competitive parental ‘Y2’ proteins (ErC-grbG-E89K and ErC-grbG-R86G), the Gγcyto-fused Grb2 expressed as candidate ‘Y1’ (Grb2-Gγcyto) predictably recovered the signaling in accordance with the order of difference in the affinity strengths between the competitive proteins and the candidate proteins. Similarly, the strain co-expressing the same Grb2 protein as the candidate ‘Y1’ and the parental ‘Y2’ proteins (ErC-grbG-grb) barely showed GFP fluorescence and cell growth on the selective medium. Thus, we demonstrated that our systems were applicable to the membrane protein, which linked to the cellular states involved in various diseases.

Discussion

In this study, we found that the previously established Gγ recruitment systems41,42 were basically unable to utilize membrane proteins as target protein ‘X.’ The new systems described here successfully enable the use of membrane proteins as target ‘X,’ both in the conventional (for screening of PPI candidate ‘Y1’ proteins) and competitor-introduced (for screening of affinity-enhanced candidate ‘Y1’ protein variants) Gγ recruitment systems. In the new systems, only the protocol for expression of Gγcyto-fused candidate ‘Y1’ proteins was changed: instead of autonomous replicating plasmids, chromosomal integration was employed. These new systems are therefore very simple but highly useful. The results of the intracellular domain of EGFR and Grb2 interaction showed that our Gγ recruitment systems could be exploited as a convenient heterologous system to discern the strong binders to the phosphotyrosines in the intracellular domain of EGFR and therefore would provide the basis for studying other receptor tyrosine kinases as well. In this manner, the screening of binding partners and affinity-enhanced variants targeted to the inner domains of these membrane proteins has great potential for applications in the treatment of human diseases.

Previously, we demonstrated that Gγ recruitment systems enabled extremely reliable screening that could completely exclude false-positive candidates41,42. Generally, membrane yeast two-hybrid systems30,31,33,34 and protein fragment complementation assays23,38 sometimes exhibit background readouts23,59 due to the use of directly fused artificial transcription factors and automatic self-associations of the split proteins. These background readouts are a critical problem, even when they are negligible, especially in the case of growth screening using a large-scale library23. The exclusive selection in Gγ recruitment systems is made possible by using the signal transduction machinery, which requires the localization of Gβ/Gγ in GFP transcription assays and mating selection (Figs. 3, 4, 5). This extremely disciplined selection machinery makes Gγ recruitment systems worth using.

In the Gγ recruitment system that has designed for membrane proteins as the target, ZI31A with extremely low affinity could not be detected in both cases of the flow cytometric analysis and the mating selection (Fig. 3). Due to the very low affinity between ZI31A and the Fc region (8.0 × 103 M−1), the migration of Gγcyto to the membrane was likely insufficient for the recovering of the signal transduction. This affinity (8.0 × 103 M−1) seems to be less than a lower limit of our present system, although it is unlikely that a protein mutant exhibiting such extremely low affinity would be required.

From the perspective of screening for a target membrane protein ‘X’, the new methods that chromosomally integrate the DNA cassettes expressing Gγcyto-fused candidate ‘Y1’ proteins might have a handicap in constructing a library. Specifically, the transformation efficiencies of homologous integrations into the yeast chromosome are commonly 101–102 fold lower than those of autonomous replicating plasmids (approximately 105–106 cfu/μg)60,61,62. Therefore, constructing a large-scale library might require a little ingenuity to increase the transformation efficiencies, such as via the use of large amounts of DNA, the electroporation method61,63, the spheroplasting method64 and use of I-SceI meganuclease65. Even allowing for this additional effort, however, the conventional Gγ recruitment system is a powerful tool because of its extremely reliable selection of binding partners. In addition, the competitor-introduced Gγ recruitment system, which allows for the specific screening of affinity-enhanced protein variants (specifically excluding protein variants showing equal or lower affinities41), is valuable as a unique and irreplaceable growth selection technique.

A similar approach for screening for affinity-attenuated protein variants among membrane proteins serving as target ‘X’ made it possible to apply the previous method using autonomous replicating plasmids to express the candidate ‘Y2’ in the cytosol (Fig. 5). We believe that the unstable expression of ‘Y1’-fused Gγcyto using autonomous replicating plasmids rendered the Gγ recruitment system useless. Because it has been reported that plasmid retentions become unstable during signal-promoted states66, ‘Y1’-fused Gγcyto might be more affected by this unstable plasmid retention than cytosolic ‘Y2’ is. In any event, the chromosomal expression of ‘Y1’-fused Gγcyto is favorable in our Gγ recruitment systems.

In summary, new Gγ recruitment systems make it possible for membrane proteins to be target protein ‘X.’ These systems permit reliable and specific screens for binding partners and affinity-enhanced protein variants. We envision that our selection method will provide a powerful, broadly applicable tool for studying biological processes, creating new opportunities to develop new drugs targeting a wide range of membrane-associated proteins and inner domains of transmembrane proteins.

Methods

Strains and media

The genotypes of Saccharomyces cerevisiae BY474167, MC-F143 and BY474267 and the other recombinant strains used in this study are provided in Table 1. The yeast strains were grown in YPD medium containing 1% (w/v) yeast extract, 2% peptone and 2% glucose or in SD medium containing 0.67% yeast nitrogen base without amino acids (BD Diagnostic Systems, Sparks, MD, USA) and 2% glucose. The SD medium was supplemented with amino acids and nucleotides (20 mg/L histidine, 60 mg/L leucine, 20 mg/L methionine, or 20 mg/L uracil), as required by the auxotrophic strains. Agar (2%; w/v) was added to the medium to produce YPD and SD solid media.

Construction of plasmids

All plasmids and primers used in this study are listed in Table 2 and Table S1. Plasmids inserting lipidation motifs were constructed as follows. The fragments of the PGK1 promoter (PPGK1) fused to the lipidation motif of Gpa1p (9 a.a. of N-terminus) and the multi-cloning site were amplified from pGK42568 using primer 1, primer 2 and primer 3 and inserted into the XhoI-BglII sites of the autonomous replication plasmid pGK42568, yielding plasmid pGK425-Gpa1N. The fragments of the PGK1 promoter fused to the lipidation motif of Ste18p (9 a.a. of C-terminus) and the multi-cloning site were amplified from pGK42568 using primer 1, primer 4 and primer 5 and inserted into the XhoI-BglII sites of the autonomous replication plasmid pGK42568, yielding plasmid pGK425-Ste18C. The fragments of the PGK1 promoter fused to the lipidation motif of Ras1p (10 a.a. of C-terminus) and the multi-cloning site were amplified from pGK42568 using primer 1, primer 6 and primer 7 and inserted into the XhoI-BglII sites of the autonomous replication plasmid pGK42568, yielding plasmid pGK425-Ras1C.

The plasmids used for the expression of the Fc fragment on the membrane were constructed as follows. The fragments encoding the Fc protein were amplified from pUMGP-GγMFcH42 using primers 8 and 9 or primers 10 and 11 and inserted into the SalI-BamHI sites of the autonomous replication plasmid pGK425-Gpa1N or pGK425-Ste18C, yielding pGK425-Gpa1N-Fc and pGK425-Fc-Ste18C, respectively. The cassettes for expression of the membrane-associated Fc protein for integration at the ste18 locus on the yeast chromosome were then amplified from pGK425-Gpa1N-Fc or pGK425-Fc-Ste18C using primer 12 and primer 13 and inserted into the XhoI sites of pGK426-GPTK42 using an In-Fusion HD Cloning Kit (Clontech Laboratories – Takara Bio, Shiga, Japan), yielding pUMGPTK-Gpa1N-Fc and pUMGPTK-Fc-Ste18C, respectively.

The plasmids used for the expression of the Gγcyto-Z domain variants in the cytosol were constructed as follows. The fragment encoding Gγ lacking the lipidation sites (Gγcyto) was amplified from pUMGP-GγMFcH42 using primer 14 and primer 15. The fragments encoding the Z variants (ZWT, ZK35A, ZI31A and Z955) were amplified from pGK-LsZWTc, pGK-LsZK35Ac, pGK-LsZI31Ac and pGK-LsZ955c41 using primer 16 and primer 17. The fusion fragments encoding the Gγcyto-Z domain were then amplified from these two fragments by overlap PCR using primer 14 and primer 17 and inserted into the SalI-EcoRI sites of the autonomous replication plasmid pGK41368, yielding plasmids pGK413-Gγ-EZWT, pGK413-Gγ-EZK35A, pGK413-Gγ-EZI31A and pGK413-Gγ-EZ955, respectively. Subsequently, the cassettes for expression of the Gγcyto-Z variants for integration at the his3 locus on the yeast chromosome were constructed as follows. The fragment containing the STE18 promoter (PSTE18) and the gene encoding Gγcyto were amplified from pUMGP-GγMFcH42 using primer 18 and primer 19 and inserted into the XhoI-NheI sites of pGK42668, yielding plasmid pUSTE18p-Gγcyto. The fragment encoding HIS3 terminator (THIS3) was amplified from the BY4741 genome using primer 20 and primer 21 and inserted into the NotI-SacI sites of pUSTE18p-Gγcyto, yielding plasmid pUSTE18p-Gγcyto-HIS3t. Finally, the fragments encoding the Z variants were amplified from pGK-LsZWTc, pGK-LsZK35Ac, pGK-LsZI31Ac and pGK-LsZ955c41 using primer 22 and primer 23 and inserted into the SalI-BamHI sites of pUSTE18p-Gγcyto-HIS3t, yielding plasmids pUSTE18p-Gγcyto-ZWT-HIS3t, pUSTE18p-Gγcyto-ZK35A-HIS3t, pUSTE18p-Gγcyto-ZI31A-HIS3t and pUSTE18p-Gγcyto-Z955-HIS3t, respectively.

The cassettes for expression of the cytosolic Z variants as competitors for integration upstream of the HOP2 gene locus (PHOP2: HOP2 promoter region) on the yeast chromosome were constructed as follows. The fragments encoding PHOP2 were amplified using primer 24 and primer 25 and inserted into the NotI-SacI sites of pGK-LsZWTc, pGK-LsZK35Ac, pGK-LsZI31Ac and pGK-LsZ955c41, yielding plasmids pGK-LsZWTc-HOP, pGK-LsZK35Ac-HOP, pGK-LsZI31Ac-HOP and pGK-LsZ955c-HOP, respectively.

The plasmids used for the expression of the intracellular domain of EGFR L834R mutant (EGFRL834R,cyto) on the membrane were constructed as follows. The fragments encoding the intracellular domain of EGFRL834R,cyto mutant were amplified from the B1U-GL49 genome using primers 26 and 27 or primers 28 and 29 and inserted into the SalI-MluI sites of pGK425-Gpa1N, pGK425-Ste18C and pGK425-Ras1C, yielding pGK425-Gpa1N-EGFR(LR), pGK425-EGFR(LR)-Ste18C and pGK425-EGFR(LR)-Ras1C, respectively. The cassettes for expression of the membrane-associated EGFRL834R,cyto for integration at the ste18 locus on the yeast chromosome were then amplified from pGK425-Gpa1N-EGFR(LR), pGK425-EGFR(LR)-Ste18C and pGK425-EGFR(LR)-Ras1C using primer 12 and primer 13 and inserted into the XhoI sites of pGK426-GPTK42 using an In-Fusion HD Cloning Kit, yielding pUMGPTK-Gpa1N-EGFR(LR), pUMGPTK-EGFR(LR)-Ste18C and pUMGPTK-EGFR(LR)-Ras1C, respectively.

The plasmids used for the expression of the Grb2-Gγcyto in the cytosol were constructed as follows. The fragment encoding the Grb2-Gγcyto was amplified from B1U-GL49 using primer 30 and primer 31 and inserted into the SalI-EcoRI sites of the autonomous replication plasmid pGK41368 using an In-Fusion HD Cloning Kit, yielding plasmid pGK413-Grb2-Gγ. Subsequently, the cassettes for expression of the Grb2-Gγcyto for integration at the his3 locus on the yeast chromosome were constructed as follows. The fragment containing the STE18 promoter (PSTE18) was amplified from pUMGP-GγMFcH42 using primer 32 and primer 33 and inserted into the XhoI-NheI sites of pGK41668, yielding plasmid Ste18p-416. The fragment containing the gene encoding Gγcyto were amplified from pUMGP-GγMFcH42 using primer 34 and primer 35 and inserted into the XbaI-EcoRI sites of Ste18p-416, yielding plasmid pUSTE18p-c-Gγcyto. The fragment encoding HIS3 terminator (THIS3) was amplified from the BY4741 genome using primer 20 and primer 21 and inserted into the NotI-SacI sites of pUSTE18p-c-Gγcyto, yielding plasmid pUSTE18p-c-Gγcyto-HIS3t. Finally, the fragment encoding Grb2 was amplified from pGK413-Grb2-Gγ using primer 36 and primer 37 and inserted into the NheI-XmaI sites of pUSTE18p-c-Gγcyto-HIS3t, yielding plasmid pUSTE18p-Grb2-Gγcyto-HIS3t.

The plasmids used for the expression cassettes of the Gγcyto-Grb2 for integration at the his3 locus on the yeast chromosome were constructed as follows. The fragment encoding Grb2 was amplified from pGK413-Grb2-Gγ using primer 38 and primer 39 and inserted into the NheI-XmaI sites of pUSTE18p-Gγcyto-HIS3t, yielding plasmid pUSTE18p-Gγcyto-Grb2-HIS3t.

The cassettes for expression of the cytosolic Grb2 variants as competitors for integration at the upstream of the HOP2 gene locus (PHOP2: HOP2 promoter region) on the yeast chromosome were constructed as follows. The fragments encoding PHOP2 were amplified using primer 24 and primer 25 and inserted into the NotI-SacI sites of pGK41568, yielding plasmid pGK415-HOP2p. The fragment encoding Grb2 was amplified from pGK413-Grb2-Gγ using primers 38 and 39 and inserted into the SalI-XmaI sites of pGK415-HOP2p using an In-Fusion HD Cloning Kit, yielding plasmid pGK415-Grb2-HOP2p. The fragment encoding Grb2R86G mutant was amplified from pGK413-Grb2-Gγ using primers 40 and 42, primers 41 and 43 and the fragments encoding the Grb2R86G mutant was amplified from these two fragments by overlap PCR using primer 40 and primer 41 and inserted into the SalI-XmaI sites of pGK415-HOP2p using an In-Fusion HD Cloning Kit, yielding plasmid pGK415-Grb2R86G-HOP2p. The fragment encoding Grb2E89K mutant was amplified from pGK413-Grb2-Gγ using primers 40 and 44, primers 41 and 45 and the fragments encoding the Grb2E89K mutant was amplified from these two fragments by overlap PCR using primer 40 and primer 41 and inserted into the SalI-XmaI sites of pGK415-HOP2p using an In-Fusion HD Cloning Kit, yielding plasmid pGK415-Grb2E89K-HOP2p.

Construction of yeast strains

All strains used in this study are listed in Table 1. Integration of the DNA cassettes for expressing the membrane-associated Fc protein was achieved as follows. The DNA fragments containing PSTE18-PPGK1-Fc-Ste18C-TPGK1-kanMX4-TSTE18 and PSTE18-PPGK1-Gpa1N-Fc-TPGK1-kanMX4-TSTE18 were amplified from pUMGPTK-Fc-Ste18C and pUMGPTK-Gpa1N-Fc using primer 46 and primer 47. The amplified DNA fragments were then used to transform MC-F143 using the lithium acetate method69. The transformants were selected on a YPD + G418 plate to yield MC-FC and MC-FN (Table 1).

Integration of the DNA cassettes for the Gγcyto-Z domain variants (ZWT, ZK35A, ZI31A and Z955) in the cytosol was achieved as follows. The DNA fragments containing URA3-PPGK1-Gγcyto-ZWT(-ZK35A, -ZI31A and -Z955)-TPGK1-THIS3 were amplified from pUSTE18p-Gγcyto-ZWT(-ZK35A, -ZI31A and -Z955)-HIS3t using primer 48 (containing the homologous regions of the HIS3 promoter) and primer 49. The amplified DNA fragments were used to transform MC-FC and MC-FN using the lithium acetate method69. The transformants were then selected on an SD-Ura plate (containing leucine, histidine and methionine) to yield FC-GW, FC-GK, FC-GI and FC-G9 and FN-GW, FN-GK, FN-GI and FN-G9 (Table 1).

Integration of the DNA cassettes for expressing the Z variants (ZWT, ZK35A, ZI31A and Z955) as competitors in the cytosol was achieved as follows. The DNA fragments containing LEU2-PPGK1-ZWT(-ZK35A, -ZI31A and -Z955)-TPGK1-PHOP2 were amplified from pGK-LsZWTc(-LsZK35Ac, -LsZI31Ac and -LsZ955c)-HOP using primer 50 (containing the homologous regions of PHOP2 upstream) and primer 51. The amplified DNA fragments were used to transform FC-GW, FC-GK, FC-GI and FC-G9 and FN-GW, FN-GK, FN-GI and FN-G9. The transformants were then selected on an SD-Leu/-Ura plate (containing histidine and methionine) to yield FC-GWW, FC-GWK, FC-GWI and FC-GW9; FC-GKW, FC-GKK, FC-GKI and FC-GK9; FC-GIW, FC-GIK, FC-GII and FC-GI9; and FC-G9W, FC-G9K, FC-G9I and FC-G99 as well as FN-GWW, FN-GWK, FN-GWI and FN-GW9; FN-GKW, FN-GKK, FN-GKI and FN-GK9; FN-GIW, FN-GIK, FN-GII and FN-GI9; and FN-G9W, FN-G9K, FN-G9I and FN-G99 (Table 1).

Integration of the DNA cassettes for expressing the membrane-associated intracellular domain of EGFR L834R mutant (EGFRL834R,cyto) was achieved as follows. The DNA fragments containing PSTE18-PPGK1-EGFRL834R,cyto-Ras1C-TPGK1-kanMX4-TSTE18, PSTE18-PPGK1-EGFRL834R,cyto-Ste18C-TPGK1-kanMX4-TSTE18 and PSTE18-PPGK1-Gpa1N-EGFRL834R,cyto-TPGK1-kanMX4-TSTE18 were amplified from pGK425-EGFR(LR)-Ras1C, pGK425-EGFR(LR)-Ste18C and pGK425-Gpa1N-EGFR(LR) using primer 46 and primer 47. The amplified DNA fragments were then used to transform MC-F143 using the lithium acetate method69. The transformants were selected on a YPD + G418 plate to yield MC-ErC, MC-EsC and MC-EgN (Table 1).

Integration of the DNA cassettes for the Grb2-Gγcyto in the cytosol was achieved as follows. The DNA fragments containing URA3-PPGK1-Grb2-Gγcyto-TPGK1-THIS3 was amplified from pUSTE18p-Grb2-Gγcyto-HIS3t using primer 48 (containing the homologous regions of the HIS3 promoter) and primer 49. The amplified DNA fragments were used to transform MC-ErC, MC-EsC and MC-EgN using the lithium acetate method69. The transformants were the selected on an SD-Ura plate to yield ErC-grbG, EsC-grbG and EgC-grbG (Table 1). Integration of the DNA cassettes for the Gγcyto-Grb2 in the cytosol was achieved as follows. The DNA fragments containing URA3-PPGK1-Gγcyto-Grb2-TPGK1-THIS3 was amplified from pUSTE18p-Gγcyto-Grb2-HIS3t using primer 48 (containing the homologous regions of the HIS3 promoter) and primer 49. The amplified DNA fragments were used to transform MC-ErC, MC-EsC and MC-EgN using the lithium acetate method69. The transformants were then selected on an SD-Ura plate to yield ErC-Ggrb, EsC-Ggrb and EgC-Ggrb (Table 1).

Integration of the DNA cassettes for expressing Grb2 variants (Grb2, Grb2E89K and Grb2R86G) and positive control (no competitor expression) as the competitor in the cytosol was achieved as follows. The DNA fragments containing LEU2-PPGK1-Grb2(-Grb2E89K and -Grb2R86G)-TPGK1-PHOP2 and LEU2-PPGK1-TPGK1-PHOP2 were amplified from pGK-LsGrb2(-LsGrb2(R89K) and -LsGrb2(R86G))-HOP and pGK415-HOP2p using primer 50 (containing the homologous regions of PHOP2 upstream) and primer 51. The amplified DNA fragments were used to transform ErC-grbG. The transformants were then selected on an SD-Leu/-Ura plate to yield ErC-grbG-grb, ErC-grbG-E89K, ErC-grbG-R86G and ErC-grbG-LEU (Table 1).

All transformants were obtained by introducing the autonomous replicating plasmids (Table 2) into these yeast strains using the lithium acetate method69.

GFP reporter expression analysis

GFP reporter expression analysis basically followed previous methods41, with certain modifications. In the case of the previous method, the engineered yeast a-cells were grown in 5 mL of SD-His medium (for the PPI detection system), SD-His/-Leu medium (for the affinity-enhanced system) or SD-Leu/-Ura medium (for the affinity-attenuated system) at 30 °C overnight. The cultured cells were then inoculated in 2 mL of fresh SD-His, SD-His/-Leu or SD-Leu/-Ura medium containing 5 μM α-factor (Zymo Research, Orange, CA, USA) to obtain an initial OD600 of 0.1 (OD600 = 0.1). In the case of the new method, the engineered yeast a-cells were grown in 5 mL of YPD medium (for the PPI detection system and affinity-enhanced system) at 30 °C overnight. The cultured cells were then inoculated in 2 mL of fresh YPD medium containing 5 μM α-factor (Zymo Research, Orange, CA, USA) to obtain an initial OD600 of 0.1 (OD600 = 0.1). The expression of the FIG1-EGFP fusion reporter gene was then stimulated by growth at 30 °C for 6 hours.

The fluorescence intensities of the cultured cells were measured using a BD FACSCanto II flow cytometer equipped with a 488-nm blue laser (BD Biosciences, San Jose, CA, USA)70. The GFP fluorescence signal was specifically collected through a 530/30-nm band-pass filter. The mean fluorescence intensity was defined as the GFP-A mean of 10,000 cells. The data were analyzed using BD FACSDiva software (version 5.0, BD Biosciences).

Mating growth spotting assay

The mating growth spotting assay basically followed a previous method41, with certain modifications. For the previous method, each engineered yeast a-cell was grown in 5 mL of SD-His media (for PPI detection system), SD-His/-Leu medium (for the affinity-enhanced system) or SD-Leu/-Ura medium (for the affinity-attenuated system) at 30 °C overnight and then cultivated in 5 mL of YPD medium with the mating partner, or the BY4742 α-cell67, at 30 °C for 3 hours. The initial OD600 of each haploid cell was set at 0.1 (OD600 = 0.1). For the new method, each engineered yeast a-cell was grown in 5 mL of YPD medium (for the PPI detection system and the affinity-enhanced system) at 30 °C overnight and then cultivated in 5 mL of YPD medium with the mating partner, or the BY4742 α-cell67, at 30 °C for 3 hours. The initial OD600 of each haploid cell was again set at 0.1 (OD600 = 0.1). After cultivation, the yeast cells were harvested, washed and resuspended in distilled water. To quantify the mating ability of each strain, a dilution series of each yeast cell suspension was prepared (OD600 = 1.0, 0.1, 0.01, 0.001 and 0.0001) and 40 μL of each dilution was then spotted on a selective SD-Ura/Leu plate (lacking methionine, lysine and histidine; for the PPI detection system generated by the previous method), SD-Ura plate (lacking methionine, lysine, histidine and leucine; for the affinity-enhanced system generated by the previous method), SD-His plate (lacking methionine, lysine, leucine and uracil; for the affinity-attenuated system generated by the previous method), SD-His/Leu plate (lacking methionine, lysine and uracil; for the PPI detection system generated by the new method) or SD-His plate (lacking methionine, lysine, uracil and leucine; for the affinity-enhanced system generated by the new method).

Additional Information

How to cite this article: Kaishima, M. et al. Gγ recruitment systems specifically select PPI and affinity-enhanced candidate proteins that interact with membrane protein targets. Sci. Rep. 5, 16723; doi: 10.1038/srep16723 (2015).