Dynamic networks of protein-protein interactions regulate numerous cellular processes and determine the ability to respond appropriately to environmental stimuli. However, the investigation of protein complex formation in living plant cells by methods such as fluorescence resonance energy transfer has remained experimentally difficult, time consuming and requires sophisticated technical equipment. Here, we report the implementation of a bimolecular fluorescence complementation (BiFC) technique for visualization of protein-protein interactions in plant cells. This approach relies on the formation of a fluorescent complex by two non-fluorescent fragments of the yellow fluorescent protein brought together by association of interacting proteins fused to these fragments (Hu et al., 2002). To enable BiFC analyses in plant cells, we generated different complementary sets of expression vectors, which enable protein interaction studies in transiently or stably transformed cells. These vectors were used to investigate and visualize homodimerization of the basic leucine zipper (bZIP) transcription factor bZIP63 and the zinc finger protein lesion simulating disease 1 (LSD1) from Arabidopsis as well as the dimer formation of the tobacco 14-3-3 protein T14-3c. The interaction analyses of these model proteins established the feasibility of BiFC analyses for efficient visualization of structurally distinct proteins in different cellular compartments. Our investigations revealed a remarkable signal fluorescence intensity of interacting protein complexes as well as a high reproducibility and technical simplicity of the method in different plant systems. Consequently, the BiFC approach should significantly facilitate the visualization of the subcellular sites of protein interactions under conditions that closely reflect the normal physiological environment.
-Ottmann contributed equally to this workThe fungal phytotoxin fusicoccin stabilizes the interaction between the C-terminus of the plant plasma membrane H + -ATPase and 14-3-3 proteins, thus leading to permanent activation of the proton pump. This results in an irreversible opening of the stomatal pore, followed by wilting of plants. Here, we report the crystal structure of the ternary complex between a plant 14-3-3 protein, fusicoccin and a phosphopeptide derived from the C-terminus of the H + -ATPase. Comparison with the corresponding binary 14-3-3 complexes indicates no major conformational change induced by fusicoccin. The compound rather ®lls a cavity in the protein±phosphopeptide interaction surface. Isothermal titration calorimetry indicates that the toxin alone binds only weakly to 14-3-3 and that peptide and toxin mutually increase each others' binding af®nity~90-fold. These results are important for herbicide development but might have general implications for drug development, since rather than inhibiting protein±protein interactions, which is dif®cult to accomplish, it might be easier to reverse the strategy and stabilize protein±protein complexes. As the fusicoccin interaction shows, only low-af®nity interactions would be required for this strategy. Keywords: 14-3-3/crystal structure/drug design/ fusicoccin/plant plasma membrane H + -ATPase Introduction Fusicoccin (FC) (Figure 1), a diterpene glycoside, is a wiltinducing phytotoxin produced by the fungus Fusicoccum amygdali (Ballio et al., 1964). Despite the fact that the fungus is host speci®c, isolated FC exerts its effects in virtually any higher plant (Marre, 1979). The plant plasma membrane H + -ATPase (PMA) has been identi®ed as the molecular target of FC action (Aducci et al., 1995). This P-type ATPase is responsible for building up an electrochemical proton gradient across the plasma membrane that provides the driving force for nutrient uptake and maintenance of cell turgor (Morsomme and Boutry, 2000). Changes of the latter are known to affect the osmotic swelling of the guard cells and consequently the opening of the stomatal pore, that regulates transpiration in plants.The proton pump is composed of 10 transmembrane helices locating both the N-and C-termini at the cytoplasmic face of the plasma membrane (Auer et al., 1998;Ku Èhlbrandt et al., 2002). The enzyme's C-terminus acts as an intrasteric inhibitor, the autoinhibitory activity of which is relieved by phosphorylation of the penultimate threonine residue and subsequent association with 14-3-3 proteins (Fuglsang et al., 1999;Svennelid et al., 1999;Maudoux et al., 2000).Members of the eukaryotic 14-3-3 family are highly conserved proteins that have been implicated in the regulation of diverse physiological processes by protein± protein interactions. 14-3-3 proteins bind to their numerous target proteins in a sequence-speci®c and phosphorylation-dependent manner (Sehnke et al., 2002;Tzivion and Avruch, 2002;Yaffe, 2002).The proposed mechanisms of activity of 14-3-3 proteins on their liga...
Many plant pathogens secrete toxins that enhance microbial virulence by killing host cells. Usually, these toxins are produced by particular microbial taxa, such as bacteria or fungi. In contrast, many bacterial, fungal and oomycete species produce necrosis and ethylene-inducing peptide 1 (Nep1)-like proteins (NLPs) that trigger leaf necrosis and immunity-associated responses in various plants. We have determined the crystal structure of an NLP from the phytopathogenic oomycete Pythium aphanidermatum to 1.35Å resolution. The protein fold exhibits structural similarities to cytolytic toxins produced by marine organisms (actinoporins). Computational modeling of the 3-dimensional structure of NLPs from another oomycete, Phytophthora parasitica, and from the phytopathogenic bacterium, Pectobacterium carotovorum, revealed a high extent of fold conservation. Expression of the 2 oomycete NLPs in an nlp-deficient P. carotovorum strain restored bacterial virulence, suggesting that NLPs of prokaryotic and eukaryotic origins are orthologous proteins. NLP mutant protein analyses revealed that identical structural properties were required to cause plasma membrane permeabilization and cytolysis in plant cells, as well as to restore bacterial virulence. In sum, NLPs are conserved virulence factors whose taxonomic distribution is exceptional for microbial phytotoxins, and that contribute to host infection by plasma membrane destruction and cytolysis. We further show that NLP-mediated phytotoxicity and plant defense gene expression share identical fold requirements, suggesting that toxin-mediated interference with host integrity triggers plant immunity-associated responses. Phytotoxin-induced cellular damage-associated activation of plant defenses is reminiscent of microbial toxin-induced inflammasome activation in vertebrates and may thus constitute another conserved element in animal and plant innate immunity.crystal structure ͉ immunity ͉ pathogen ͉ plant immunity ͉ phytotoxin
Plants deploy cell-surface and intracellular leucine rich-repeat domain (LRR) immune receptors to detect pathogens 1 . LRR receptor kinases and LRR receptor proteins at the plasma membrane recognize microorganism-derived molecules to elicit pattern-triggered immunity (PTI), whereas nucleotide-binding LRR proteins detect microbial effectors inside cells to confer effector-triggered immunity (ETI). Although PTI and ETI are initiated in different host cell compartments, they rely on the transcriptional activation of similar sets of genes 2 , suggesting pathway convergence upstream of nuclear events. Here we report that PTI triggered by the Arabidopsis LRR receptor protein RLP23 requires signalling-competent dimers of the lipase-like proteins EDS1 and PAD4, and of ADR1 family helper nucleotide-binding LRRs, which are all components of ETI. The cell-surface LRR receptor kinase SOBIR1 links RLP23 with EDS1, PAD4 and ADR1 proteins, suggesting the formation of supramolecular complexes containing PTI receptors and transducers at the inner side of the plasma membrane. We detected similar evolutionary patterns in LRR receptor protein and nucleotide-binding LRR genes across Arabidopsis accessions; overall higher levels of variation in LRR receptor proteins than in LRR receptor kinases are consistent with distinct roles of these two receptor families in plant immunity. We propose that the EDS1-PAD4-ADR1 node is a convergence point for defence signalling cascades, activated by both surface-resident and intracellular LRR receptors, in conferring pathogen immunity.Arabidopsis thaliana (hereafter Arabidopsis) cell-surface LRR receptor kinases (LRR-RKs) and LRR receptor protein (LRR-RP)-SOBIR1 complexes recruit the co-receptor BAK1 and signal through receptor-like cytoplasmic kinases (RLCKs) to elicit PTI 3 . Intracellular coiled-coil (CC)-nucleotide-binding LRR (NLR) or TOLL-INTERLEUKIN 1 RECEP-TOR (TIR)-NLR receptors 4 require ADR1-type and NRG1-type helper NLRs (hNLRs) and the lipase-like EDS1 family proteins EDS1, PAD4 and SAG101 to confer ETI 5,6 . While the defence outputs for PTI and ETI are qualitatively similar 2 , where and how pathways activated in different cell compartments converge remain unclear. Effective plant defence relies on mutual potentiation of PTI and ETI pathways 7,8 , suggesting mechanistic links between these two tiers of the plant immune system. RLCKs PBL30 and PBL31 mediate PTIThe Arabidopsis class VII RLCK (RLCK-VII) BIK1 promotes LRR-RK-mediated PTI but is a negative regulator of LRR-RP-mediated PTI 9 . To identify RLCK-VII members with positive roles in LRR-RP-dependent PTI, we screened an Arabidopsis RLCK-VII transfer DNA mutant library 10 for ethylene production elicited by fungal pg13(At) 11 , oomycete nlp20 and bacterial eMax (which are recognized by RLP42, RLP23 and RLP1, respectively) 3 (Extended Data Fig. 1a). A pbl31 mutant was defective in response to these elicitors compared with wild-type plants (Columbia-0 (Col-0)) (Extended Data Fig. 1a). PBL31 belongs to RLCK-VII subfamily 7, together ...
Regulatory 14-3-3 proteins activate the plant plasma membrane H(+)-ATPase by binding to its C-terminal autoinhibitory domain. This interaction requires phosphorylation of a C-terminal, mode III, recognition motif as well as an adjacent span of approximately 50 amino acids. Here we report the X-ray crystal structure of 14-3-3 in complex with the entire binding motif, revealing a previously unidentified mode of interaction. A 14-3-3 dimer simultaneously binds two H(+)-ATPase peptides, each of which forms a loop within the typical 14-3-3 binding groove and therefore exits from the center of the dimer. Several H(+)-ATPase mutants support this structure determination. Accordingly, 14-3-3 binding could result in H(+)-ATPase oligomerization. Indeed, by using single-particle electron cryomicroscopy, the 3D reconstruction of the purified H(+)-ATPase/14-3-3 complex demonstrates a hexameric arrangement. Fitting of 14-3-3 and H(+)-ATPase atomic structures into the 3D reconstruction map suggests the spatial arrangement of the holocomplex.
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