Molecular Plant • Volume 1 • Number 2 • Pages 308-320 • March 2008 RESEARCH ARTICLE Subcellular Localization and In Vivo Interactions of the Arabidopsis thaliana Ethylene Receptor Family Members Christopher Grefena, Katrin Städele3, Kamil Ruzickab, Petr Obrdlikc, Klaus Harter3,1 and Jakub Horaka a Zentrum für Molekularbiologie der Pflanzen, Pflanzenphysiologie, Universität Tübingen, Auf der Morgenstelle 1, 72076 Tübingen, Germany b Zentrum für Molekularbiologie der Pflanzen, Entwicklungsgenetik, Universität Tübingen, Auf der Morgenstelle 3, 72076 Tübingen, Germany c lonGate Biosciences GmbH, Industriepark Höchst D 528, 65926 Frankfurt am Main, Germany ABSTRACT The gaseous phytohormone ethylene regulates many developmental processes and responses to environmental conditions in higher plants. In Arabidopsis thaliana, ethylene perception and initiation of signaling are mediated by a family of five receptors which are related to prokaryotic two-component sensor histidine kinases. The transient expression of fluorescence-tagged receptors in tobacco (Nicotiana benthamiana) epidermal leaf cells demonstrated that all ethylene receptors are targeted to the ER endomembrane network and do not localize to the plasmalemma. In support of in planta overlay studies, the ethylene receptors form homomeric and heteromeric protein complexes at the ER in living plant cells, as shown by membrane recruitment assays. A comparable in vivo interaction pattern was found in the yeast mating-based split-ubiquitin system. The overlapping but distinct expression pattern of the ethylene receptor genes suggests a differential composition of the ethylene receptor complexes in different plant tissues. Our findings may have crucial functional implications on the ethylene receptor-mediated efficiency of hormone perception, induction of signaling, signal attenuation and output. INTRODUCTION In recent years, the molecular action of phytohormones like ethylene has been intensively studied in plants. The gaseous and diffusible molecule ethylene affects many aspects of the plant life, including seed germination, seedling development, abscission, organ senescence, fruit ripening and stomata opening (Abeles et al., 1992; Guo and Ecker, 2004; Desikan et al., 2005, 2006). Moreover, reactions of plants to biotic and abiotic stresses involve ethylene. Recently, several studies point out a complex interplay between signaling by ethylene and other plant hormones such as auxin (Li et al., 2004; Stepanova et al., 2005) , gibberellins (Vriezen et al., 2004), brassinosteroids (De Grauwe et al., 2005) and cytokinin (Smets et al., 2005; Cho and Yoo, 2007), which also depends on the environmental condition and the plant's developmental stage. Insights into the ethylene-response pathway have mainly arisen from molecular studies in the model plant Arabidopsis thaliana {At) using genetic screens based on an altered 'triple response' (summarized in Chen et al., 2005; Etheridge et al., 2006) : in Arabidopsis ethylene is perceived by a family of five receptors (ETR1, ERS1, ETR2, ERS2, EIN4), which are related to prokaryotic, fungal and plant sensor histidine kinases (Hwang et al., 2002; Grefen and Harter, 2004). Based on phylogenetic analysis and the presence of conserved sequences in the histi- dine kinase domain, the receptors are divided into two subfamilies (Hall and Bleecker, 2003). Subfamily I consists of ETR1 and ERS1 which have histidine kinase activity. Subfamily II is formed by ETR2, ERS2 and EIN4. The amino acid sequences of the subfamily II members lack residues considered to be essential for histidine kinase activity. In the absence of ethylene, the receptors maintain the activity of the MAPKKK CTR1, which interacts with the ethylene receptor complex (Gao et al., 2003) and represses downstream ethylene signaling in air. In the presence of ethylene, the receptors become inactivated, which leads to a proposed conformational change in CTR1, causing the suppression of its kinase activity and the de-repression of the ethylene response pathway. The signaling events downstream of CTR1 are mediated by a potential and debated MAP kinase cascade—the Nramp metal ion transporter-like protein EIN2 followed by members of the EIN3/ EIL family of transcription factors. The EIN3/EIL transcription 1 To whom correspondence should be addressed. E-mail klaus.harterOzmbp. uni-tuebingen.de, tel. +49 7071 29 72605, fax 49 7071 29 3287. © The Author 2007. Published by the Molecular Plant Shanghai Editoria Office in association with Oxford University Press on behalf of CSPP and IPPE, SIBS, CAS. doi: 10.1093/mp/ssm015, Advance Access publication 12 November 2007 Grefen eta/. • Subcellular Localization and In Vivo Interactions of Ethylene Receptor in Arabidopsis 309 factors differentially regulate the transcription of primary ethylene response genes which induce a transcriptional cascade responsible for the realization of the plant's reactions to exog-enously applied hormone (Chen et al., 2005). However, there also appearto exist CTR1-independent, two-component system (TCS) element-dependent signaling pathways which are regulated by the histidine kinase activity of the subfamily I members ETR1 and ERS1. The histidine kinase activity of ETR1 was demonstrated to be important in the rate of growth recovery after ethylene removal (Binder et al., 2004a) and in the endogenous ethylene-regulated promotion of Arabidopsis growth (Cho and Yoo, 2007). Furthermore, it was shown that ETR1-dependent phosphorylation of the B-type response regulator ARR2 activates ethylene response transcription (Hass et al., 2004), and that ETR1 is ableto induce two component signaling events in vivo (Cho and Yoo, 2007). Although the CTR1-independent and TCS-related pathway provides only a minor contribution to the realization of the exogenous ethylene-controlled hypocotyl growth response in etiolated seedlings (Hass et al., 2004; Mason et al., 2005; Cho and Yoo, 2007), it appears to play a crucial role in the ethylene-regulated stomatal closure (Desikan et al., 2006). The functional relevance of the histidine kinase activity and an alternative pathway was recently supported by the observation that the subfamily I receptors ETR1 and ERS1 play a predominant role in mediating ethylene responses (Qu et al., 2007). Genetic studies in Arabidopsis and other plant species have shown that gain-of-function mutations in any of the five receptors confer ethylene insensitivity (Bleecker and Schaller, 1996; Gamble et al., 2002). Furthermore, physiological investigations demonstrated that ethylene effects in plants are observed at extremely low concentrations and over a concentration range of seven orders of magnitude (Chen and Bleecker, 1995; Binder et al., 2004a, 2004b). This suggests that the ethylene perception system has evolved signal-amplification mechanisms that enable the recognition of very subtle changes in the number of hormone-occupied receptors and the transformation of the system into a state that allows the efficient induction of the response pathway. In analogy to the bacterial chemotaxis histidine kinase receptors (Gestwicki and Kiessling, 2002; Thomason et al., 2002), one possible mechanism is that a few ethylene-occupied, active receptors recruit by physical interaction with neighboring receptors to higher-order protein clusters. Through direct contact, the active receptors can influence the signaling state of the neighbors within the cluster. This could result in the coordinated transformation of multiple receptors into active states by a few eth-ylene-binding events. However, such a mechanism implicates that all members of the ethylene receptor family are targeted to the same intracellular compartment and physically interact at this subcellular site. A candidate compartment is the ER network, to which at least ETR1, ETR2 and the Cucumis melo ortholog of the Arabidopsis ERS1, CmERSI, and CTR1 are targeted or recruited to (Chen et al., 2002, 2007; Gao et al., 2003; Ma et al., 2006). Here, we provide for the first time cell biological evidence that all Arabidopsis ethylene receptors are located in the ER endomembrane system in living plant cells. Furthermore, by using a novel in planta membrane recruitment assay (MeRA) and the mating based split-ubiquitin system (mbSUS; Johnsson and Varshavsky, 1994; Obrdlik et al., 2004), we show that the receptors form homo- and heteromeric complexes in any combination in vivo. The analysis of the steady-state transcript level by semi-quantitative RT-PCR and ETR1 and ERS1 gene activity using promoterr.uidA reporter lines indicates an overlapping but distinct expression of the receptors in Arabidopsis. The latter suggests a tissue-specific configuration of ethylene receptor complexes. We discuss the functional implications of our observations in the light of ethylene perception, receptor function and initiation of signaling. RESULTS The Arabidopsis Ethylene Receptors are Localized in the Endoplasmatic Reticulum Membrane (ER) of Plant Cells In order to investigate the subcellular localization of the Arabidopsis ethylene receptors, we fused the fluorescent proteins GFP or RFP to the C-terminus of all five Arabidopsis ethylene receptors and expressed the fusion proteins under the control of the constitutive 355 promoter. The repeated transient trans-fection of these constructs into Arabidopsis protoplast yielded no detectable fluorescence signals, probably due to strong transgene silencing. To overcome this problem, we chose to examine the localization of the receptors in Agrobacterium-infiltrated Nicotiana benthamiana leaf cells. The co-infiltration of the silencing inhibitor gene p19 from the tomato bushy stunt virus (TBSV) enables the efficient expression of many plant proteins in this system (Voinnet et al., 2003). After transformation, the abaxial epidermis of the tobacco leaves was subjected to confocal laser scanning microscopy (CLSM). As shown in Figure 1A, a reticular pattern was observed for all five ethylene receptors. The identity of the stained endomembrane system as ER was verified by the identical localization pattern of an ER marker protein (Figure 1 A). Please note that we focused at the cytoplasmic surfaces of the transformed cells in these images. The ER localization of ERS1 was directly tested by co-expression with the ER marker protein. A clear co-localization of ERS1 and the ER marker was observed, as indicated by the perfect overlay of the RFP and GFP fluorescent signals (Figure 1B). Furthermore, a comprehensive CSLM overlay study revealed a strict co-localization of all five ethylene receptors in the ER (Supplementary Figure 1). The Ethylene Receptors are not Detectable in the Plasmalemma of Plant Cells We next examined whether the ethylene receptors are exclusively localized in the ER or whether a detectable fraction is also found in the plasmalemma. Therefore, the RFP-tagged 310 Crefen eta/. • Subcellular Localization and In Vivo Interactions of Ethylene Receptor in Arabidopsis GFP bright field B O + ^ it 4 .. & ir'' k ' 3 _ ATM-ETR2:GFP ERS1:RFP ER:RFP ERS1:RFP ERS1:RFP + GFP + GFP ATM-ETR2:GFP ATM/GAF-ERS1:GFP ETR1 ERS1 ETR2 ERS2 EIN4 ATM-ETR1 + ATM-ERS1 + + ATM-ETR2 + + + ATM-ERS2 + + + + ATM-EIN4 + + + + + Figure 4. The Ethylene Receptors Interact at the ER Membrane in Transiently Transformed Tobacco Leaf Cells. (A) Principle of the membrane recruitment assay (MeRA) and scheme of the hypothetical ethylene receptor interaction pattern (hypothesis). Grey, ER membrane; black, transmembrane domain; yellow, GAF domain; blue, histidine kinase (-like) domain; brown, receiver domain; red, RFP-tag; green, GFP-tag. Grefen eta/. • Subcellular Localization and In Vivo Interactions of Ethylene Receptor in Arabidopsis 315 DISCUSSION The Arabidopsis Ethylene Receptors are ER-Localized Proteins In our study, we present for the first time cell biological data which demonstrates that all Arabidopsis ethylene receptors localize to the ER in plant cells and confirm by in vivo experiments earlier biochemical findings for ETR1 and ETR2 (Chen et al., 2002, 2007). This intracellular distribution was observed independently of whether the fluorescence protein was fused to the N-terminus or the C-terminus of the receptors (J. Horak and K. Harter, unpublished results), indicating that the tag does not mislocalize the proteins. Furthermore, our control experiments diminish the possibility of the location of the receptors in other membrane compartments, including the plasmalemma. In conclusion, our results support earlier findings that the ER endomembrane network is the primary intracellular location of ethylene perception in plants. Although we used the identical constructs for the transient transformation assays, the expression of fluorescence-tagged ethylene receptors failed in Arabidopsis cell culture protoplasts and was only detectable in /Agrobacfer/um-infiltrated tobacco leaf cells in the presence of the silencing suppressor protein p19 (Voinnet et al., 2003). The Arabidopsis protoplasts are either capable to generally silence the transgenes or dra- matically attenuate the ethylene-sensing machinery as a reaction to high ethylene levels which are generated in responseto wounding during protoplast preparation (Yanagisawa et al., 2003). Similarly, we were not able to achieve the overexpression of the ethylene receptors in transgenic Arabidopsis plants stably transformed with the identical GFP fusion constructs used for the transient assays. Although the fusion genes were under the control of the strong and constitutive 35S promoter, the transgenic plants managed to repress the expression of the fusion proteins to the transcript level of wild-type plants (Supplementary Figure 2A). Thus, the total RNA level of the ethylene receptors is tightly controlled in transgenic Arabidopsis plants by a post-transcriptional feedback mechanism. At this low expression level, we were not able to detect fluorescence in the transgenic plants. However, although with low penetrance, we regularly observed a premature leaf senescence phenotype in F1 transgenic plants which contained the ethylene receptor transgenes (Supplementary Figure 2B). Whilst more dramatic, a similar premature leaf senescence phenotype was recently described for etrllersl double loss-of-function mutants (etrl-9/ersl-3, etrl-7/ersl-3; Qu etal., 2007). This similarity suggests that the fluorescence protein-tagged ethylene receptors exert a dominant negative effect on the activity of the endogenous family members. Such interference can, however, only ETR1 ETR2 ERS1 ERS2 EIN4 Marker ATM- ATM- ATM- ATM- ATM- ETR1 ETR2 ERS1 ERS2 EIN4 Marker < E full-length Cub-PLV fusions truncated Nub-3HA fusions B ATM-ETR1 ATM-ETR2 ,„ ATM-ERS1 .o § ATM-ERS2 i ■Q 2 ATM-EIN4 NubWt NubG Cub-fusions ETR1 ETR2 ERS1 ERS2 EIN4 ETR1 ETR2 ERS1 ERS2 EIN4 interaction-selective media vector-selective media Figure 5. In-Vivo Interaction of the Ethylene Receptors in the Yeast Mating-Based Split-Ubiquitin System (mbSUS). (A) Western blot analysis of total extracts derived from haploid yeast cells (THY.AP4 and THY.AP5) expressing the indicated ethylene receptor fusion proteins. Immunodetection of the fusion proteins were carried out with an antibody against the VP16-tag (oc-VP16) and HA-tag (oc-HA), respectively. The molecular mass of the markers are 150 and 100 kDa on the left and 100 and 75 kDa on the right. (B) Yeast mbSUS growth assays. Yeast THY.AP4 clones expressing the Cub-PLV-tagged full-length ethylene receptors were mated with THY.AP5 clones expressing the transmembrane-lacking (ATM) l\lub-3HA-tagged receptor derivates. The diploid cells were grown at 28°C either for 7 d on interaction- (left) or 3 d on vector-selective (right) media. NubWT was used as a positive, NubG as a negative control. (B) Confocal images of abaxial epidermal leaf cells (surface focus) expressing the indicated GFP and RFP fusion proteins. The emission channels for the RFP and GFP fluorescence are indicated on the left. The lowest row shows the bright field images of the transformed cells. ATM, lack of the transmembrane domain; ATM/GAF, lack of the transmembrane and the GAF domain. The bars represent 10 |xm. (C) MeRA-based matrix of the ethylene receptor interaction pattern. 316 Crefen et al. • Subcellular Localization and In Vivo Interactions of Ethylene Receptor in Arabidopsis occur when the dominant-negative and wild-type receptor variants function from the identical cellular compartment. According to the most recent model of ethylene receptor signaling (Qu et al., 2007), the fluorescent protein-tagged and dominant-negative-acting ethylene receptors might reduce the activity of the endogenous receptors to act on CTRL This would lead to the inactivation of CTR1 and the activation of ethylene response pathway in air, which is reflected by the premature leaf senescence. It should be noted that the fluorescent tag of the ethylene receptors is attached to their C-terminus which is the interaction site for CTR1 (Clark et al., 1998; Gao et al., 2003). However, we cannot entirely exclude the possible mechanism that the 35S promoter-generated transcript of the ethylene receptor-GFP fusion itself competes with the corresponding mRNA of the endogenous gene which also would lead to a reduced number of functional wild-type receptor proteins in the ER. The observation that all Arabidopsis receptors are targeted to the ER (shown here) and that CTR1—the immediate downstream signaling component of the receptors—is recruited by the receptors to the ER (Gao et al., 2003) strongly suggest that this endomembrane system is the general intracellular site for the initiation of ethylene signaling. Arabidopsis Ethylene Receptor Interactions and the Role of the GAF Domain We demonstrated the interaction of all five Arabidopsis receptor family members in any combination by in-planta MeRAand yeast mbSUS, as hypothesized earlier (O'Malley et al., 2005). Surprisingly, our comprehensive in-planta BiFC and yeast mbSUS analysis failed to demonstrate the association of the full-length receptors, although the corresponding C-terminal split-YFP- and split-ubiquitin-tagged fusion proteins were properly expressed (data not shown). The most likely explanation for this discrepancy is that in the context of the full-length protein, the cytoplasmic domains of the receptors are less flexible or structurally arranged in a way that a close distance of the split-YFP- and split-ubiquitin-tagged monomers is not accomplished, which is necessary for the functional complementation of the YFP fluorophore or ubiquitin. The results of our MeRA interaction analysis in tobacco cells expressing ERS1:RFP, ATM-ERS1 :GFP and ATM/GAF-ERS1 :GFP demonstrated that the interaction capability of at least the cytoplasmic extension of the ethylene receptor depends on the GAF domain in living plant cells. A comparable GAF domain-dependent interaction was recently reported for various soluble ATM fragments of Arabidopsis ETR1 in the yeast two-hybrid system (Xie et al., 2006). As shown for several other organisms, the GAF domain is capable of mediating reversible protein-protein interactions and activation of enzymatic activity (Aravind and Ponting, 1997; Ho et al., 2000; Martinez et al., 2002). Although the formation of covalent, non-reversible disulfide bounds in the N-terminal transmembrane domain was proposed to be relevant for ETR1 homodimerization (Schaller et al., 1995), Xie and colleagues (2006) showed by a functional approach in transgenic Arabidopsis plants that this biochemical modification appears to be dispensable for ETR1 activity. In conclusion, our results and the data of Xie et al. (2006) suggest that the GAF domain is the amino acid stretch which predominantly mediates non-covalent and reversible receptor association in vivo. However, we cannot excludethe possibility that the transmembrane domain also contributes to the interaction of the ethylene receptors. Further cell biological and functional studies are required to determine the function of the transmembrane and GAF domain for the dynamics of ethylene receptor association. Interactions and Differential Expression of Ethylene Receptors: Functional Implications As shown here, the five Arabidopsis ethylene receptors form heteromeric and homomeric protein complexes in vivo. With our cell biological techniques, we are not able to differentiate whether the observed interactions represent receptor homo-and heterodimers and/or homo- and heteromeric higher-order receptor complexes and their appearance in the different/Ara-bidopsis tissues. In any case, the detected interaction capacity could provide the molecular basis for inter-receptor signaling which is responsible for the lack of a simple additive relationship between ligand binding and ethylene receptor outputs (O'Malley et al., 2005). Furthermore, it explains the high sensitivity and broad concentration range of ethylene responses and the observation that gain-of-function mutations in any ethylene receptor lead to the almost complete ethylene insen-sitivity in the otherwise wild-type background (Bleecker and Schaller, 1996; Gamble etal., 2002; Gehretet al., 2006). In analogy to the action of the chemotaxis receptors in bacteria (Gestwicki and Kiessling, 2002; Thomason et al., 2002), a mutant dominant-active ethylene receptor could be able to maintain the signaling state of the other family members, resulting in a constitutively high activity of CTRL This would result in the continued repression of the ethylene response pathway, even in the presence of ethylene. Furthermore, especially at very low hormone concentrations, the activation of few receptor molecules could influence the activity state of the neighbors, enabling the efficient perception of the hormone over the reported seven orders of magnitude (Chen and Bleecker, 1995; Binder et al., 2004a, 2004b). Our expression studies using semi-quantitative RT-PCR and transgenic Arabidopsis plants containing PETR1::GUS and PERS1::GUS show an overlapping but distinctive steady-state mRNA and gene activity pattern. For instance, whereas the activity of PErsi is restricted to the root tip and vascular tissue of 7 d old light-grown and 3 d old etiolated seedlings, Petri activity is found in the lateral root primordia and the elongation zone. The differential expression pattern in combination with the capability for homo- and heteromeric interaction and Grefen eta/. • Subcellular Localization and In Vivo Interactions of Ethylene Receptor in Arabidopsis 317 ethylene-induced degradation (Chen et al., 2007) indicates that different plant tissues contain a distinct set of ethylene receptor complexes, whose composition may change during development and hormone treatment. Depending especially on the relative contribution of the functionally predominant class I receptors ETR1 and ERS1 (Qu et al., 2007), the complexes may possess differential in-planta affinity to ethylene, CTR1 (Clark et al., 1998; Cancel and Larsen, 2002), TCS signaling elements (Hass et al., 2004; Cho and Yoo, 2007) or putative membrane-intrinsic structural components such as RTE1 (Resnick et al., 2006). Therefore, a differential complex composition could result in differences in the signal-induced formation of higher-order receptor clusters, signaling efficiencies or signal attenuation. Moreover, the receptor complexes could also differ in other molecular features, such as membrane trafficking and internalization, feedback modification, turnover rate or recovery. Thus, one would predict a differential competence and responsiveness of plant tissues to ethylene, which depends on the intracellular level and composition of the receptor complexes. Homo- and heteromeric ternary complex formation-dependent ligand binding and functional activity is well described for animal transmembrane receptor families such as the ErbB receptors (Carraway and Carraway, 2007). From the four members of the Erb family, only ErbB1 and ErbB4 are able to bind the high-affinity ligand and have a functional tyrosine kinase domain. ErbB2 cannot bind the ligand and ErbB3 has no functional kinase domain. However, every ErbB heterodimer is able to initiate signaling as long as it is composed of a signal sensing and phosphorylation-active monomer. The heterodi-merization of ErbB receptors also permits a greater diversity of downstream responses regulating organism development and promoting oncogenesis (Carraway and Carraway, 2007). Our results show that all five Arabidopsis ethylene receptors are targeted to the ER network in plant cells, form homo- and heteromeric protein complexes in vivo, and show an overlapping but distinct expression pattern, adding an additional level of complexity to ethylene perception and signal transduction. To define the specific biochemical features and functional attributes of distinct ethylene receptor complexes in a given tissue is a major scientific challenge for the future. Moreover, by the means of molecular and cell biological approaches using fluorescence-tagged ethylene receptors, it will now be possible to investigate signal-dependent receptor complex formation, movement, internalization, and recovery in living plant cells. This will provide novel insights into the intracellular dynamics and function of this important plant receptor family. METHODS Plant Materials and Growth Conditions Nicotiana benthamiana plants were cultivated in the greenhouse (temperature: day 25°C, night 19°C, humidity 60%, lighting period 7:00-21:00). Arabidopsis thaliana Columbia ecotype (Col-0) was used as wild-type and cultivated in the greenhouse (temperature: day 21°C, night 18°C, humidity 45%, lighting period 7:00-21:00). Arabidopsis seedlings were cultivated at sterile conditions for histochemical staining and selection of transformants. Vapor sterilization of seeds was performed by placing seeds in opened Eppendorf tubes in a desiccator jar. A 250-ml beaker containing 100 ml of 12% sodium hypochlorite was placed inside and 10 ml concentrated HCI was added. The desiccator jar was closed and the seeds were sterilized through the nascent chlorine for 2 h. After sterilization, the Eppendorf tubes were placed under the fume hood for another 2 h to allow evaporation of remaining chlorine. Seedlings were cultivated in a growth chamber at 21°C under long-day conditions on 0.5 Murashige-Skoog medium, 1 % (w/v) sucrose and 0.8% (w/v) phytoagar. Transformed seedlings were selected on media supplemented with 25 |ig ml~1 hygromycin B for 14 d and resistant plants were propagated on soil. Cloning Strategies All clones used in this article were constructed using Gateway™ technology (Invitrogen). The Entry clones were either obtained via BP-reaction in pDONR201 (full-length receptors) or through TOPO-reaction using the pENTR/D-TOPO vector (truncated receptors; both vectors Invitrogen). The template used to clone the ethylene receptors was either cDNA from Arabidopsis roots (ETR1, ERS1), or a corresponding clone kindly provided by G.E. Schaller (ETR2) and E.M. Meyerowitz (ERS2, EIN4; Hua et al. 1998). Entry clones of ETR2, ERS2, and EIN4 seem to be problematic for E. coli, as we observed spontaneous mutations and insertions in the cDNA sequence. The use of the E.coli strain CopyCutter™ (Epicentre) enabled us to amplify and clonethese receptor genes. The reverse primers contained no stop codon to enable C-terminal fusions. Sequences of forward and reverse primers could be sent upon request. Construction of the truncated ethylene receptors was performed using the full-length Entry clones as template, appropriate reverse primer and the following forward primer: ATM-ETR1 (deletion aa1-121) 5'-G4CC-ATGTTGAAAAA-TAAAGCTGCTGAGCTC, ATM-ERS1 (aa1-121) 5'-C/\CC-ATGCT-CAAGAAGAAAGCTGATGAGTTAG, 5-ATM-ETR2 (aa1-150) 5-GACC-ATGCTTAAGAAGAAAGCTCATGAGC, ATM-ERS2 (aa1-153) 5 - GACC-ATGTTGAGTAAGAAGACCAGAGAGCTTG, ATM-EIN4 (aa1-144) 5 - CACC-ATGTTGAAGCAGAATGTGTTGGAGC ATM/GAF-ERS1 (aa1-316) 5-attS7-TAATGCACGCTCGTGACC-AGCTTATG. All clones were carefully verified via restriction analysis and sequencing (GATC Biotech) prior to LR-reaction. For creation of the Destination clones, see below. Agrobacterium Infiltration of Nicotiana benthamiana Leaves The binary vectors for expression of the GFP/RFP fusion proteins under the control of 35S promoter were constructed via LR-reaction using the corresponding Entry clones. The 318 Crefen et al. • Subcellular Localization and In Vivo Interactions of Ethylene Receptor in Arabidopsis full-length ethylene receptors were cloned into the destination vectors pMDC83 (Curtis and Grossniklaus, 2003) and pB7RWG2.0 (Karimi et al., 2002) and the truncated versions into pH7FWG2.0(Karimi et al., 2002). ER marker protein was constructed via in-frame GFP insertion into the Arabidopsis ORF At2g31710 (genomic DNA fragment containing promoter region) in the binary vector pTkan+ (pPZP212 deriváte, Hajdukiewicz et al., 1994). Endoplasmatic reticulum localization of the fusion protein was proved by immunogold labeling and electron microscopy (K. Schumacher and Y.D. Stierhof, personal communication). BRI1 plasmalemma marker (Friedrichsen et al., 2000) was kindly provided by K. Schumacher. The p19 protein from tomato bushy stunt virus cloned in pBIN61 (Voinnet et al., 2000) was used to suppress gene silencing. All vectors were transformed in Agrobacterium tumefaciens strain GV3101 pMP90 and prior infiltration resuspended in AS-medium (10 mM MgCI2, 150|iM acetosyringone and 10 mM MES pH 5.7) to OD600 0.8. Corresponding Agrobacterium strains containing the GFP/RFP constructs and the p19 silencing plasmid were mixed 1:1:1 and co-infiltrated into leaves of 2-4 week old N. benthamiana plants, as desribed in Voinnet et al. (2003) and Witte et al. (2004). Abaxial epidermis of infiltrated tobacco leaves was assayed for fluorescence by confocal laser-scanning microscopy 2-3 d post infiltration. Microscope Image Acquisition Confocal laser-scanning microscopy (CLSM) was performed using a Leica TCS SP2 confocal microscope (Leica Microsystems GmbH). All CLSM images were obtained using Leica Confocal Software and the HCX PL APO 63x/1.2 W CORR water-immersion objective. GFP and RFP channels were acquired by simultaneous scanning using 488-/568-nm laser lines for excitation; signals were detected between 500 and 530 nm for GFP and 590 and 630 nm for RFP. Images were processed using Leica Confocal Software (Leica Microsystems GbmH) and Adobe Photoshop 9.0. Microscopy of histochemically stained primary roots was carried out on a Zeiss AxioPhot microscope (Carl Zeiss AG) equipped with an AxioCam HR CCD camera using a 10/0.3 objective. Images were aquired using AxioVision 3.1 software (Carl Zeiss AG) and processed in Adobe Illustrator 12.0.1. Semi-quantitative RT-PCR Total RNA from corresponding tissues and developmental stages of A. thaliana was isolated using RNAwiz™ (Ambion) and genomic DNA was removed using TURBO DNA-free™ (Ambion). Subsequently, 1.5 |ig of total RNA was reverse transcribed using oligo-dT primer with Superscript™ III Reverse Transcriptase (Invitrogen) and resulting cDNA was used as a template for PCR with HotStart Taq polymerase (Genaxxon). PCR products were separated via agarose gel electrophoresis after a different number of PCR cycles for comparison with ACTIN2 at non-saturating conditions as described in Horák at al. (2003). The sequences of the primers were as follows: ACT2 detF 5'-CTGCTCAATCTCATCTTCTTCC; ACT2 detR 5'-GACCTGCCTCATCATACTCG; ETR1 detF 5'-TGTCACCAAGTCA- GACACACGA; ETR1 detR 5'-TCATGGGACACAACTCGG AG; ERS1 detF 5-CACTAATCAGCGACGTTCTGGA; ERS1 detR 5-GCCCGACAAACCGTTTACAG; ETR2 detF 5'-TCGTACGATCCAT-GAAGCAGC; ETR2 detR 5-ATGGTCTCCGGTGAACCATC; ERS2 detF 5' - G G GTTG CTTCCTTTG ATACTTC A; ERS2 detR 5'-TCGATCGCCGGAGTTGA; EIN4 detF 5' -ACG GTTCCAG CTA-CATTCCTTG; EIN4 detR 5'-ATACTCTGTGTTTGTCCATGCGA. Generation of the ETR1 and ERS1 Promoter:u/dA Fusions and Histochemical Staining Promoter DNA fragments were amplified from A. thaliana genomic DNA using Phusion™ polymerase (Finnzymes) and the primers ETRIpF 5-attB1-TTACTTGTGGACCAGTGTGAGC, ETRIpR 5' -att B 2-GTTG CG GTTCAATACAATTG C, ERSIpF 5'-attB1-CCAACGGTGAAATGCAGCA and ERSIpR 5-attB2-GCA-CATGCGTCTCAAAACAATCG. Promoter DNA fragments were cloned into pDONR201 through BP-reaction and verified by sequencing. The ETR1 promoter fragment comprises the region 2201 bp upstream of the start codon, including the first 30 bp of the ETR1 coding sequence and the ERS1 promoter, and the region 1811 bp upstream of the start codon, including 33 bp of the ERS1 coding sequence. Both promoters were transla-tionally fused to uidA reporter gene via LR-reaction with the destination vector pMDC163 (Curtis and Grossniklaus, 2003). Plasmids were transformed in Agrobacterium tumefaciens strain GV3101 pMP90 and Arabidopsis plants were transformed via the flower-dipping method. Transformed seedlings were selected through hygromycin-resistance (see Plant material). Primary roots of light-grown seedlings, etiolated seedlings, 30 d old leaves and flowers from several independent transgenic lines (T2) were tested for GUS activity using histochemical staining as described previously in Friml et al. (2003). Mating-Based Split-Ubiquitin System (mbSUS) The full-length ethylene receptors were cloned via LR-reaction of the corresponding entry-clones into pMetYC-DEST and the truncated versions into pNX32-DESTand pXN22-DEST (Grefen et al., 2007). The Destination clones were transformed into the haploid yeast strains THY.AP4 (pMetYC-DEST clones) and THY.AP5 (pNX32-DEST, pXN22-DEST), respectively (Obrdlik et al., 2004). After 3 d on vector-selective media, single colonies of each clone were harvested and analyzed by western blot to guarantee correct expression of the fusion proteins (for a detailed protocol, see Grefen et al., 2007). Positive haploid yeast clones were inoculated to an OD600 of 3.0-5.0 in vector-selective media, harvested and resuspended in an appropriate volume of YPD. The mating was performed by mixing the haploid yeast, dropping 4 ml on solid YPD media and incubating for up to 16 h at 28°C. Using a replicator stamp, the mated colonies were transferred on vector-selective media and incubated for 3 d. Colonieswerethen harvested, inoculated in liquid, vector-selective media and incubated overnight at 28°C. All clones were diluted to yield the same starting OD600 and hence dropped on vector- and interaction-selective media. Starting on day 3, the growth was monitored. Grefen et al. • Subcellular Localization and In Vivo Interactions of Ethylene Receptor in Arabidopsis 319 SUPPLEMENTARY DATA Supplementary Data are available at www.mplant. oxfordjournals.org ACKNOWLEDGMENTS We thank E.M. Meyerowitz, G.E. Schaller, and K. Schumacher for kindly providing constructs and plasmids. Additionally, we would like to thank Tanja Sikler and her team for their excellent support in the cultivation of tobacco plants. This work was supported by DFG grants to K.H. (AFGN-Ha2146/5, SFB446H"P A23). No conflict of interest declared. REFERENCES Abeles, F.B., Morgan, P.W., and Saltveit, M.E. (1992). Ethylene in plant biology (London: Academic Press). Aravind, L., and Ponting, CP. (1997). The GAF domain: an evolutionary link between diverse phototransducing proteins. Trends Bio-chem. Sci. 22, 458-459. Binder, B.M., Mortimore, L.A., Stepanova, A.N., Ecker, J.R., and Bleecker, A.B. (2004a). Short-term growth responses to ethylene in Arabidopsisseedlingsare EIN3/EIL1 independent. Plant Physiol 136, 2921-2927. Binder, B.M., O'Malley, R.C., Wang, W., Moore, J.M., Parks, B.M., Spalding, E.P., and Bleecker, A.B. (2004b). Arabidopsis seedling growth response and recovery to ethylene: a kinetic analysis. Plant Physiol. 136, 2913-2920. Bleecker, A.B., and Schaller, G.E. (1996). The mechanism of ethylene perception. Plant Physiol 111, 653-660. Cancel, J.D., and Larsen, P.B. (2002). Loss-of-function mutations in the ethylene receptor ETR1 cause enhanced sensitivity and exaggerated response to ethylene in Arabidopsis. Plant Physiol. 129, 1557-1567. Carraway, C.A., and Carraway, K.L. (2007). Sequestration and segregation of receptor kinases in epithelial eel Is: im pi icationsf or ErbB2 oncogenesis. Sci. STKE. 2007, doi: 10.1126/stke.3812007re3. Chen, Q.G., and Bleecker, A.B. (1995). Analysis of ethylene signal-transduction kinetics associated with seedling-growth response and chitinase induction in wild-type and mutant arabidopsis. Plant Physiol. 108, 597-607. Chen, Y.F., Etheridge, N., and Schaller, G.E. (2005). Ethylene signal transduction. Ann. Bot. (Lond). 95, 901-915. Chen, Y.F., Randlett, M.D., Findell, J.L., and Schaller, G.E. (2002). Localization of the ethylene receptor ETR1 to the endoplasmic reticulum of Arabidopsis. J. Biol. Chem. 277, 19861-19866. Chen, Y.F., Shakeel, S.N., Bowers, J., Zhao, X.C., Etheridge, N., and Schaller, G.E. (2007). Ligand-induced degradation of the ethylene receptor etr2 through a proteasome-dependent pathway in Arabidopsis. J. Biol. Chem. 282, 24752-24758. Cho, Y.H., and Yoo, S.D. (2007). ETHYLENE RESPONSE 1 histidine kinase activity of Arabidopsis promotes plant growth. Plant Physiol. 143, 612-616. Clark, K.L, Larsen, P.B., Wang, X., and Chang, C. (1998). Association of the Arabidopsis CTR1 Raf-like kinase with the ETR1 and ERS ethylene receptors. Proc. Natl Acad. Sci. U S A 95, 5401-5406. Curtis, M.D., and Grossnikiaus, U. (2003). A gateway cloning vector set for high-throughput functional analysis of genes in planta. Plant Physiol. 133, 462-469. De Grauwe, L., Vandenbussche, F., Tietz, O., Palme, K., and Van Der Straeten, D. (2005). Auxin, ethylene and brassinosteroids: tripartite control of growth in the Arabidopsis hypocotyl. Plant Cell Physiol. 46, 827-836. Desikan, R., Hancock, J.T., Bright, J., Harrison, J., Weir, I., Hooley, R., and Neill, S.J. (2005). A role for ETR1 in hydrogen peroxide signaling in stomatal guard cells. Plant Physiol. 137, 831-834. Desikan, R., Last, K., Harrett-Williams, R., Tagliavia, C, Harter, K., Hooley, R., Hancock, J.T., and Neill, S.J. (2006). Ethylene-induced stomatal closure in Arabidopsis occurs via AtrbohF-mediated hydrogen peroxide synthesis. Plant J. 47, 907-916. Etheridge, N., Hall, B.P., and Schaller, G.E. (2006). Progress report: ethylene signaling and responses. Planta 223, 387-391. Friedrichsen, D.M., Joazeiro, CA., Li, J., Hunter, T, and Chory, J. (2000). Brassinosteroid-insensitive-1 is a ubiquitously expressed leucine-rich repeat receptor serine/threonine kinase. Plant Physiol. 123, 1247-1256. Friml, J., Benkova, E., Mayer, U., Palme, K., and Muster, G. (2003). Automated whole mount localisation techniques for plant seedlings. Plant J. 34, 115-124. Gamble, R.L., Qu, X., and Schaller, G.E. (2002). Mutational analysis of the ethylene receptor ETR1: role of the histidine kinase domain in dominant ethylene insensitivity. Plant Physiol. 128, 1428-1438. Gao, Z., Chen, Y.F., Randlett, M.D., Zhao, X.C., Findell, J.L, Kieber, J.J., and Schaller, G.E. (2003). Localization of the Raf-like kinase CTR1 to the endoplasmic reticulum of Arabidopsis through participation in ethylene receptor signaling complexes. J. Biol. Chem. 278, 34725-34732. Gehret, A.U., Bajaj, A., Naider, F., and Dumont, M.E. (2006). Oligo-merization of the yeast alpha-factor receptor: implications for dominant negative effects of mutant receptors. J. Biol. Chem. 281, 20698-20714. Gestwicki, J.E., and Kiessling, L.L. (2002). Inter-receptor communication through arrays of bacterial chemoreceptors. Nature 415, 81-84. Grefen, C,and Harter, K. (2004). Plant two-component systems: principles, functions, complexity and cross talk. Planta 219, 733-742. Grefen, C, Lalonde, S., and Obrdlik, P. (2007). Split-ubiquitin system for identifying protein-protein interactions in membrane and full-length proteins. Current Protocols in Neuroscience 5.27.1-5.27.40, doi: 10.1002/0471142301 .ns0527s41. Guo, H., and Ecker, J.R. (2004). The ethylene signaling pathway: new insights. Curr. Opin. Plant Biol. 7, 40-49. Hajdukiewicz, P., Svab, Z., and Maliga, P. (1994). The small, versatile pPZP family of Agrobacterium binary vectors for plant transformation. Plant Mol. Biol. 25, 989-994. Hall, A.E., and Bleecker, A.B. (2003). Analysis of combinatorial loss-of-function mutants in the Arabidopsis ethylene receptors revealsthatthe ers1 etrl double mutant has severe developmental defects that are EIN2 dependent. Plant Cell. 15, 2032-2041. Hass, C, Lohrmann, J., Albrecht, V., Sweere, U., Hummel, F., Yoo, S.D., Hwang, I., Zhu, T, Schafer, E., Kudla, J., and Harter, K. (2004). The response regulator 2 mediates ethylene 320 Grefen et al. • Subcellular Localization and In Vivo Interactions of Ethylene Receptor in Arabidopsis signalling and hormone signal integration in Arabidopsis. Embo J. 23, 3290-3302. Ho, Y.S., Burden, L.M., and Hurley, J.H. (2000). Structure of the GAF domain, a ubiquitous signaling motif and a new class of cyclic GMP receptor. Embo J. 19, 5288-5299. Horák, J., Brzobohatý, B., and Lexa, M. (2003). Molecular and physiological characterisation of an insertion mutant in the ARR21 putative response regulator gene from Arabidopsis thaliana. Plant Biol. 5, 245-254. Hua, J., Sakai, H., Nourizadeh, S., Chen, Q.G., Bleecker, A.B., Ecker, J.R., and Meyerowitz, E.M. (1998). ElN4 and ERS2 are members of the putative ethylene receptor gene family in Arabidopsis. Plant Cell 10, 1321-1332. Hwang, I., Chen, H.C., and Sheen, J. (2002). Two-component signal transduction pathways in Arabidopsis. Plant Physiol. 129,500-515. Johnsson, N., and Varshavsky, A. (1994). Split ubiquitin as a sensor of protein interactions in vivo. Proc. Natl Acad. Sci. U S A 91, 10340-10344. Karimi, M., Inze, D., and Depicker, A. (2002). GATEWAY vectors for Agrobacterium-mediated plant transformation. Trends Plant Sci. 7, 193-195. Li, H., Johnson, P., Štěpánova, A., Alonso, J.M., and Ecker, J.R. (2004). Convergence of signaling pathways in the control of differential cell growth in Arabidopsis. Dev. Cell 7, 193-204. Ma, B., Cui, M.L., Sun, H.J., Takada, K., Mori, H., Kamada, H., and Ezura, H. (2006). Subcellular localization and membrane topology of the melon ethylene receptor CmERSI. Plant Physiol 141, 587-597. Martinez, S.E., Wu, A.Y., Glavas, N.A., Tang, X.B., Turley, S., Hol, W.G., and Beavo, J.A. (2002). The two GAF domains in phosphodiesterase 2A have distinct roles in dimerization and in cGMP binding. Proc. Natl Acad. Sci. U S A 99, 13260-13265. Mason, M.G., Mathews, D.E., Argyros, D.A., Maxwell, B.B., Kieber, J.J., Alonso, J.M., Ecker, J.R., and Schaller, G.E. (2005). Multiple type-B response regulators mediate cytokinin signal transduction in Arabidopsis. Plant Cell 17, 3007-3018. O'Malley, R.C., Rodriguez, F.I., Esch, J.J., Binder, B.M., O'Donnell, P., Klee, H.J., and Bleecker, A.B. (2005). Ethylene-binding activity, gene expression levels, and receptor system output for ethylene receptor family members from Arabidopsis and tomato. Plant J. 41, 651-659. Obrdlik, P., et al. (2004). K+ channel interactions detected by a genetic system optimized for systematic studies of membrane protein interactions. Proc. Natl Acad. Sci. USA 101, 12242-12247. Qu, X., Hall, B.P., Gao, Z., and Schaller, G.E. (2007). A strong constitutive ethylene-response phenotype conferred on Arabi- dopsis plants containing null mutations in the ethylene receptors ETR1 and ERS1. BMC. Plant Biol 7, doi: 10.1186/ 1471-2229-7-3. Resnick, J.S., Wen, C.K., Shockey, J.A., and Chang, C. (2006). REVERSION-TO-ETHYLENE SENSITIVITY1, a conserved gene that regulates ethylene receptor function in Arabidopsis. Proc. Natl Acad. Sci. USA 103, 7917-7922. Schaller, G.E., Ladd, A.N., Lanahan, M.B., Spanbauer, J.M., and Bleecker, A.B. (1995). The ethylene response mediator ETR1 from Arabidopsis forms a disulfide-linked dimer. J. Biol. Chem. 270, 12526-12530. Smets, R., Le, J., Prinsen, E., Verbelen, J.P., and Van Onckelen, H.A. (2005). Cytokinin-induced hypocotyl elongation in light-grown Arabidopsis plants with inhibited ethylene action or indole-3-acetic acid transport. Planta 221, 39-47. Stepanova, A.N., Hoyt, J.M., Hamilton, A.A., and Alonso, J.M. (2005). A link between ethylene and auxin uncovered by the characterization of two root-specific ethylene-insensitive mutants in Arabidopsis. Plant Cell 17, 2230-2242. Thomason, P.A., Wolanin, P.M., and Stock, J.B. (2002). Signal transduction: receptor clusters as information processing arrays. Curr. Biol. 12, R399-R401. Voinnet, O., Lederer, C, and Baulcombe, D.C. (2000). A viral movement protein prevents spread of the gene silencing signal in Ni-cotiana benthamiana. Cell 103, 157-167. Voinnet, O., Rivas, S., Mestre, P., and Baulcombe, D. (2003). An enhanced transient expression system in plants based on suppression of gene silencing by the p19 protein of tomato bushy stunt virus. Plant J. 33, 949-956. Vriezen, W.H., Achard, P., Harberd, N.P., and Van Der Straeten, D. (2004). Ethylene-mediated enhancement of apical hook formation in etiolated Arabidopsis thaliana seedlings is gibberellin dependent. Plant J. 37, 505-516. Walter, M., et al. (2004). Visualization of protein interactions in living plant cells using bimolecular fluorescence complementation. Plant J. 40, 428-438. Witte, CP, Noel, L.D., Gielbert, J., Parker, J.E., and Romeis.T. (2004). Rapid one-step protein purification from plant material using the eight-amino acid Strepll epitope. Plant Mol. Biol. 55, 135-147. Xie, F., Liu, Q., and Wen, C.K. (2006). Receptor signal output mediated by the ETR1 N terminus is primarily subfamily I receptor dependent. Plant Physiol. 142, 492-508. Yanagisawa, S., Yoo, S.D., and Sheen, J. (2003). Differential regulation of EIN3 stability by glucose and ethylene signalling in plants. Nature 425, 521-525.