Subcellular localization of the Hpa RxLR effector repertoire identifies a tonoplast-associated protein HaRxL17 that confers enhanced plant susceptibility

Filamentous phytopathogens form sophisticated intracellular feeding structures called haustoria in plant cells. Pathogen effectors are likely to play a role in the establishment and maintenance of haustoria in addition to their better-characterized role in suppressing plant defence. However, the specific mechanisms by which these effectors promote virulence remain unclear. To address this question, we examined changes in subcellular architecture using live-cell imaging during the compatible interaction between the oomycete Hyaloperonospora arabidopsidis (Hpa) and its host Arabidopsis. We monitored host-cell restructuring of subcellular compartments within plant mesophyll cells during haustoria ontogenesis. Live-cell imaging highlighted rearrangements in plant cell membranes upon infection, in particular to the tonoplast, which was located close to the extra-haustorial membrane surrounding the haustorium. We also investigated the subcellular localization patterns of Hpa RxLR effector candidates (HaRxLs) in planta. We identified two major classes of HaRxL effector based on localization: nuclear-localized effectors and membrane-localized effectors. Further, we identified a single effector, HaRxL17, that associated with the tonoplast in uninfected cells and with membranes around haustoria, probably the extra-haustorial membrane, in infected cells. Functional analysis of selected effector candidates in planta revealed that HaRxL17 enhances plant susceptibility. The roles of subcellular changes and effector localization, with specific reference to the potential role of HaRxL17 in plant cell membrane trafficking, are discussed with respect to Hpa virulence.     

The Plasmodesmal Protein PDLP1 Localises to Haustoria-Associated Membranes during Downy Mildew Infection and Regulates Callose Deposition

The downy mildew pathogen Hyaloperonospora arabidopsidis (Hpa) is a filamentous oomycete that invades plant cells via sophisticated but poorly understood structures called haustoria. Haustoria are separated from the host cell cytoplasm and surrounded by an extrahaustorial membrane (EHM) of unknown origin. In some interactions, including Hpa-Arabidopsis, haustoria are progressively encased by host-derived, callose-rich materials but the molecular mechanisms by which callose accumulates around haustoria remain unclear. Here, we report that PLASMODESMATA-LOCATED PROTEIN 1 (PDLP1) is expressed at high levels in Hpa infected cells. Unlike other plasma membrane proteins, which are often excluded from the EHM, PDLP1 is located at the EHM in Hpa-infected cells prior to encasement. The transmembrane domain and cytoplasmic tail of PDLP1 are sufficient to convey this localization. PDLP1 also associates with the developing encasement but this association is lost when encasements are fully mature. We found that the pdlp1,2,3 triple mutant is more susceptible to Hpa while overexpression of PDLP1 enhances plant resistance, suggesting that PDLPs enhance basal immunity against Hpa. Haustorial encasements are depleted in callose in pdlp1,2,3 mutant plants whereas PDLP1 over-expression elevates callose deposition around haustoria and across the cell surface. These data indicate that PDLPs contribute to callose encasement of Hpa haustoria and suggests that the deposition of callose at haustoria may involve similar mechanisms to callose deposition at plasmodesmata.     

Homologous RXLR effectors from Hyaloperonospora arabidopsidis and Phytophthora sojae suppress immunity in distantly related plants

Diverse pathogens secrete effector proteins into plant cells to manipulate host cellular processes. Oomycete pathogens contain large complements of predicted effector genes defined by an RXLR host cell entry motif. The genome of Hyaloperonospora arabidopsidis (Hpa, downy mildew of Arabidopsis) contains at least 134 candidate RXLR effector genes. Only a small subset of these genes is conserved in related oomycetes from the Phytophthora genus. Here, we describe a comparative functional characterization of the Hpa RXLR effector gene HaRxL96 and a homologous gene, PsAvh163, from the Glycine max (soybean) pathogen Phytophthora sojae. HaRxL96 and PsAvh163 are induced during the early stages of infection and carry a functional RXLR motif that is sufficient for protein uptake into plant cells. Both effectors can suppress immune responses in soybean. HaRxL96 suppresses immunity in Nicotiana benthamiana, whereas PsAvh163 induces an HR‐like cell death response in Nicotiana that is dependent on RAR1 and Hsp90.1. Transgenic Arabidopsis plants expressing HaRxL96 or PsAvh163 exhibit elevated susceptibility to virulent and avirulent Hpa, as well as decreased callose deposition in response to non‐pathogenic Pseudomonas syringae. Both effectors interfere with defense marker gene induction, but do not affect salicylic acid biosynthesis. Together, these experiments demonstrate that evolutionarily conserved effectors from different oomycete species can suppress immunity in plant species that are divergent from the source pathogen’s host.     

Immunogold localization of THRGP-like epitopes in the haustorial interface of obligate,biotrophic fungi on monocots

Summary Immunoelectron microscopy was used to determine the subcellular distribution of threonine-hydroxyproline-rich glycoprotein (THRGP) epitopes in host-parasite interactions between obligate, biotrophic fungi and cereals. Infection sites of stem rust (Puccinia graminis f. sp.tritici) and leaf rust (Puccinia recondita) on primary leaves of wheat (Triticum aestivum), as well as of powdery mildew (Erysiphe graminis f. sp.hordei) on coleoptiles of barley (Hordeum vulgare), wete probed with a polyclonal antiserum to maize THRGP. A few immunogold particles were found over the cell walls of wheat mesophyll tissue and barley coleoptile epidermis. Unlike previous examples in dicot plants, no enhanced accumulation of THRGP was observed in cereal cell walls adjacent to sites of pathogen ingress. Instead, the most pronounced accumulation of THRGP-like molecules occurred over the extrahaustorial matrix in both incompatible and compatible plant-pathogen interactions. For powdery mildew of barley, immunogold staining was distinctly increased over the center of the penetration sites; however, no labeling was found over papillae that formed during incompatible and compatible interactions. In addition, no cross-reactivity of the anti-THRGP antiserum with intercellularly growing rust pathogens was observed. The highly localized deposition of THRGP-like molecules in the extrahaustorial matrix suggests that the host plant establishes a modified barrier between itself and the pathogen.Abbreviations C chloroplast - EC plant epidermal cell - EM extrahaustorial membrane - EMA extrahaustorial matrix - GO Golgi body - GRP glycine-rich protein - HP high pressure - HRGP hydroxyprolinerich glycoprotein - Hyp hydroxyproline - LT low temperature - PBS phosphate-buffered saline - PBST PBS with Tween-20 - THRGP threonine-hydroxyproline-rich glycoprotein - VA vesicular arbuscular     

Patterns of plant subcellular responses to successful oomycete infections reveal differences in host cell reprogramming and endocytic trafficking

Adapted filamentous pathogens such as the oomycetes Hyaloperonospora arabidopsidis (Hpa) and Phytophthora infestans (Pi) project specialized hyphae, the haustoria, inside living host cells for the suppression of host defence and acquisition of nutrients. Accommodation of haustoria requires reorganization of the host cell and the biogenesis of a novel host cell membrane, the extrahaustorial membrane (EHM), which envelops the haustorium separating the host cell from the pathogen. Here, we applied live-cell imaging of fluorescent-tagged proteins labelling a variety of membrane compartments and investigated the subcellular changes associated with accommodating oomycete haustoria in Arabidopsis and N. benthamiana. Plasma membrane-resident proteins differentially localized to the EHM. Likewise, secretory vesicles and endosomal compartments surrounded Hpa and Pi haustoria revealing differences between these two oomycetes, and suggesting a role for vesicle trafficking pathways for the pathogen-controlled biogenesis of the EHM. The latter is supported by enhanced susceptibility of mutants in endosome-mediated trafficking regulators. These observations point at host subcellular defences and specialization of the EHM in a pathogen-specific manner. Defence-associated haustorial encasements, a double-layered membrane that grows around mature haustoria, were frequently observed in Hpa interactions. Intriguingly, all tested plant proteins accumulated at Hpa haustorial encasements suggesting the general recruitment of default vesicle trafficking pathways to defend pathogen access. Altogether, our results show common requirements of subcellular changes associated with oomycete biotrophy, and highlight differences between two oomycete pathogens in reprogramming host cell vesicle trafficking for haustoria accommodation. This provides a framework for further dissection of the pathogen-triggered reprogramming of host subcellular changes.     

Probing formation of cargo/importin‐α transport complexes in plant cells using a pathogen effector

Importin‐αs are essential adapter proteins that recruit cytoplasmic proteins destined for active nuclear import to the nuclear transport machinery. Cargo proteins interact with the importin‐α armadillo repeat domain via nuclear localization sequences (NLSs), short amino acids motifs enriched in Lys and Arg residues. Plant genomes typically encode several importin‐α paralogs that can have both specific and partially redundant functions. Although some cargos are preferentially imported by a distinct importin‐α it remains unknown how this specificity is generated and to what extent cargos compete for binding to nuclear transport receptors. Here we report that the effector protein HaRxL106 from the oomycete pathogen Hyaloperonospora arabidopsidis co‐opts the host cell's nuclear import machinery. We use HaRxL106 as a probe to determine redundant and specific functions of importin‐α paralogs from Arabidopsis thaliana. A crystal structure of the importin‐α3/MOS6 armadillo repeat domain suggests that five of the six Arabidopsis importin‐αs expressed in rosette leaves have an almost identical NLS‐binding site. Comparison of the importin‐α binding affinities of HaRxL106 and other cargos in vitro and in plant cells suggests that relatively small affinity differences in vitro affect the rate of transport complex formation in vivo. Our results suggest that cargo affinity for importin‐α, sequence variation at the importin‐α NLS‐binding sites and tissue‐specific expression levels of importin‐αs determine formation of cargo/importin‐α transport complexes in plant cells.     

Observations on the ultrastructure of the uredinial stage ofPuccinia polypogonis onPolypogon monspeliensis

The ultrastructure of the uredinial stage of the rust fungus,Puccinia polypogonis onPolypogon monspeliensis is described, using scanning and transmission electron microscopy. This study examined the urediniospores, intercellular hyphae, and haustoria of the fungus. The formation and structure of urediniospores is similar to those of otherPuccinia species. The ultrastructure of intercellular hyphae and haustoria is similar to those of other rust fungi, but with some differences. No modifications are observed in the wall of the haustorial mother cells during penetration. A collar is found only around old haustoria. In most cases, one nucleus is detected inside the haustorial body and no nucleoli are seen in the nuclei of intercellular hyphae and haustoria. The host-parasite interface, including extrahaustorial matrix and extrahaustorial membrane, is also discussed and compared with those of other rust fungi.     

Ultrastructural comparison of incompatible and compatible interactions in the barley powdery mildew disease

Summary In the powdery mildew disease of barley,Erysiphe graminis f. sp.hordei forms an intimate relationship with compatible hosts, in which haustoria form in epidermal cells with no obvious detrimental effects on the host until late in the infection sequence. In incompatible interactions, by contrast, the deposition of papillae and localized host cell death have been correlated with the cessation of growth byE. g. hordei. With the advent of improved, low temperature methods of sample preparation, we felt that it was useful to reevaluate the structural details of interactions between barley andE. g. hordei by transmission electron microscopy. The haustoria that develop in susceptible barley lines appear highly metabolically active based on the occurrrence of abundant endoplasmic reticulum, Golgi-like cisternae, and vesicles. In comparison, haustoria found in the resistant barley line exhibited varying signs of degradation. A striking clearing of the matrix and loss of cristae were typical early changes in the haustorial mitochondria in incompatible interactions. The absence of distinct endoplasmic reticulum and Golgi-like cisternae, the formation of vacuoles, and the occurrence of a distended sheath were characteristic of intermediate stages of haustorial degeneration. At more advanced stages of degeneration, haustoria were dominated by large vacuoles containing membrane fragments. This process of degeneration was not observed in haustoria ofE. g. hordei developing in the susceptible barley line.Abbreviations b endoplasmic reticulum extension, blebbing - er endoplasmic reticulum - f fibrillar material - g Golgi-like structure - h haustorium - hb haustorial body - hcw haustorial cell wall - hcy haustorial cytoplasm - hf haustorial finger - hocw host cell wall - hocy host cytoplasm - 1 lipid-like droplet - m mitochondrion - mt microtubule - mve multivesicular body - n nucleus - p papilla - ph penetration site of an infection peg - pl plasma membrane - s sheath - sm extrahaustorial membrane - v vacuole - ve vesicle     

Internalization of Flax Rust Avirulence Proteins into Flax and Tobacco Cells Can Occur in the Absence of the Pathogen

Translocation of pathogen effector proteins into the host cell cytoplasm is a key determinant for the pathogenicity of many bacterial and oomycete plant pathogens. A number of secreted fungal avirulence (Avr) proteins are also inferred to be delivered into host cells, based on their intracellular recognition by host resistance proteins, including those of flax rust (Melampsora lini). Here, we show by immunolocalization that the flax rust AvrM protein is secreted from haustoria during infection and accumulates in the haustorial wall. Five days after inoculation, the AvrM protein was also detected within the cytoplasm of a proportion of plant cells containing haustoria, confirming its delivery into host cells during infection. Transient expression of secreted AvrL567 and AvrM proteins fused to cerulean fluorescent protein in tobacco (Nicotiana tabacum) and flax cells resulted in intracellular accumulation of the fusion proteins. The rust Avr protein signal peptides were functional in plants and efficiently directed fused cerulean into the secretory pathway. Thus, these secreted effectors are internalized into the plant cell cytosol in the absence of the pathogen, suggesting that they do not require a pathogen-encoded transport mechanism. Uptake of these proteins is dependent on signals in their N-terminal regions, but the primary sequence features of these uptake regions are not conserved between different rust effectors.     

GAP Activity,but Not Subcellular Targeting,Is Required for Arabidopsis RanGAP Cellular and Developmental Functions

The Ran GTPase activating protein (RanGAP) is important to Ran signaling involved in nucleocytoplasmic transport, spindle organization, and postmitotic nuclear assembly. Unlike vertebrate and yeast RanGAP, plant RanGAP has an N-terminal WPP domain, required for nuclear envelope association and several mitotic locations of Arabidopsis thaliana RanGAP1. A double null mutant of the two Arabidopsis RanGAP homologs is gametophyte lethal. Here, we created a series of mutants with various reductions in RanGAP levels by combining a RanGAP1 null allele with different RanGAP2 alleles. As RanGAP level decreases, the severity of developmental phenotypes increases, but nuclear import is unaffected. To dissect whether the GAP activity and/or the subcellular localization of RanGAP are responsible for the observed phenotypes, this series of rangap mutants were transformed with RanGAP1 variants carrying point mutations abolishing the GAP activity and/or the WPP-dependent subcellular localization. The data show that plant development is differentially affected by RanGAP mutant allele combinations of increasing severity and requires the GAP activity of RanGAP, while the subcellular positioning of RanGAP is dispensable. In addition, our results indicate that nucleocytoplasmic trafficking can tolerate both partial depletion of RanGAP and delocalization of RanGAP from the nuclear envelope.     

Biogenesis of a specialized plant-fungal interface during host cell internalization of Golovinomyces orontii haustoria

Powdery mildew fungi are biotrophic pathogens that require living plant cells for their growth and reproduction. Elaboration of a specialized cell called a haustorium is essential for their pathogenesis, providing a portal into host cells for nutrient uptake and delivery of virulence effectors. Haustoria are enveloped by a modified plant plasma membrane, the extrahaustorial membrane (EHM), and an extrahaustorial matrix (EHMx), across which molecular exchange must occur, but the origin and composition of this interfacial zone remains obscure. Here we present a method for isolating Golovinomyces orontii haustoria from Arabidopsis leaves and an ultrastructural characterization of the haustorial interface. Haustoria were progressively encased by deposits of plant cell wall polymers, delivered by secretory vesicles and multivesicular bodies (MVBs) that ultimately become entrapped within the encasement. The EHM and EHMx were not labelled by antibodies recognizing eight plant cell wall and plasma membrane antigens. However, plant resistance protein RPW8.2 was specifically recruited to the EHMs of mature haustoria. Fungal cell wall-associated molecular patterns such as chitin and β-1,3-glucans were exposed at the surface of haustoria. Fungal MVBs were abundant in haustoria and putative exosome vesicles were detected in the paramural space and EHMx, suggesting the existence of an exosome-mediated secretion pathway.     

Subcellular Localization and Functional Analysis of the Arabidopsis GTPase RabE

Membrane trafficking plays a fundamental role in eukaryotic cell biology. Of the numerous known or predicted protein components of the plant cell trafficking system, only a relatively small subset have been characterized with respect to their biological roles in plant growth, development, and response to stresses. In this study, we investigated the subcellular localization and function of an Arabidopsis (Arabidopsis thaliana) small GTPase belonging to the RabE family. RabE proteins are phylogenetically related to well-characterized regulators of polarized vesicle transport from the Golgi apparatus to the plasma membrane in animal and yeast cells. The RabE family of GTPases has also been proposed to be a putative host target of AvrPto, an effector protein produced by the plant pathogen Pseudomonas syringae, based on yeast two-hybrid analysis. We generated transgenic Arabidopsis plants that constitutively expressed one of the five RabE proteins (RabE1d) fused to green fluorescent protein (GFP). GFP-RabE1d and endogenous RabE proteins were found to be associated with the Golgi apparatus and the plasma membrane in Arabidopsis leaf cells. RabE down-regulation, due to cosuppression in transgenic plants, resulted in drastically altered leaf morphology and reduced plant size, providing experimental evidence for an important role of RabE GTPases in regulating plant growth. RabE down-regulation did not affect plant susceptibility to pathogenic P. syringae bacteria; conversely, expression of the constitutively active RabE1d-Q74L enhanced plant defenses, conferring resistance to P. syringae infection.     

Sequential deposition of plant glycoproteins and polysaccharides at the host-parasite interface ofUromyces vignae andVigna sinensis

Summary Monokaryotic haustoria (M-haustoria) ofUromyces vignae inVigna sinensis cells are surrounded by an extrahaustorial matrix (ema) and the invaginated host plasmalemma, the extrahaustorial membrane (ehrn). The ema was characterized with antibodies against components of the plant cell wall; the ema contained hydroxyproline-rich glycoproteins and arabinogalactans/arabinogalactan proteins, both at a higher concentration close to the ehm. Haustoria with large vacuoles had the ema encased by additional layers. An electron-translucent inner layer deposited on top of the ema contained arabinogalactans/arabinogalactan proteins, hydroxyproline-rich glycoproteins, and callose. The inner layer was surrounded by an electron-translucent middle layer with numerous dark inclusions, rich in pectin and fucose bound to xyloglucans. Finally, a more electron-dense outer layer containing arabinogalactans/arabinogalactan proteins and hydroxyproline-rich glycoproteins encased the whole structure. These polysaccharides, with the exception of callose and un-esterified pectin, were also found in the plant Golgi apparatus. The polysaccharides were synthesized in the trans Golgi cisternae and secreted into the host-parasite interface. The secretory events seem to be coupled to endocytosis since numerous coated pits were found on the ehm too. The pits were elongated, sometimes formed tubules and the coat reacted with an antibody against plant clathrin. Our results suggest intensive membrane recycling around haustoria, together with the secretion of cell wall material, which in the case of more or less vacuolated haustoria seems to be responsible for encasementAbbreviations AG/AGP arabinogalactans and arabinogalactan proteins - BSA bovine serum albumin - ehm extrahaustorial membrane - ema extrahaustorial matrix - HRGP_2b hydroxyproline rich glycoproteins - M-haustorium monokaryotic haustorium - TBS tris buffered saline     

The Plant Membrane-Associated REMORIN1.3 Accumulates in Discrete Perihaustorial Domains and Enhances Susceptibility to Phytophthora infestans

Filamentous pathogens such as the oomycete Phytophthora infestans infect plants by developing specialized structures termed haustoria inside the host cells. Haustoria are thought to enable the secretion of effector proteins into the plant cells. Haustorium biogenesis, therefore, is critical for pathogen accommodation in the host tissue. Haustoria are enveloped by a specialized host-derived membrane, the extrahaustorial membrane (EHM), which is distinct from the plant plasma membrane. The mechanisms underlying the biogenesis of the EHM are unknown. Remarkably, several plasma membrane-localized proteins are excluded from the EHM, but the remorin REM1.3 accumulates around P. infestans haustoria. Here, we used overexpression, colocalization with reporter proteins, and superresolution microscopy in cells infected by P. infestans to reveal discrete EHM domains labeled by REM1.3 and the P. infestans effector AVRblb2. Moreover, SYNAPTOTAGMIN1, another previously identified perihaustorial protein, localized to subdomains that are mainly not labeled by REM1.3 and AVRblb2. Functional characterization of REM1.3 revealed that it is a susceptibility factor that promotes infection by P. infestans. This activity, and REM1.3 recruitment to the EHM, require the REM1.3 membrane-binding domain. Our results implicate REM1.3 membrane microdomains in plant susceptibility to an oomycete pathogen.Filamentous plant pathogens, including oomycetes of the genus Phytophthora, downy mildews and white rusts, as well as powdery mildews and rust fungi, are among the most devastating plant pathogens. These biotrophic parasites associate closely with plant cells through specialized infection structures called haustoria. Haustoria are specialized pathogen hyphal structures formed within host cells and enveloped by a perimicrobial membrane called the extrahaustorial membrane (EHM), a key interface between plant pathogens and the host cell. Haustoria are critical for successful parasitic infection by many filamentous plant pathogens and are a signature of the biotrophic lifestyle. In fungi, haustoria function as feeding structures (Voegele et al., 2001). In addition, haustoria are thought to enable the delivery of host-translocated virulence proteins, known as effectors, by both fungal and oomycete pathogens (Catanzariti et al., 2006; Whisson et al., 2007). However, little is known about the molecular mechanisms underlying the biogenesis and function of haustoria and EHM (Kemen and Jones, 2012; Lu et al., 2012).The EHM is thought to be continuous with the host plasma membrane (PM), yet it is a highly specialized membrane compartment that develops only in plant cells that accommodate haustoria (haustoriated cells; Coffey and Wilson, 1983). On the plant side, all eight PM proteins tested by Koh et al. (2005) were excluded from the EHM in Arabidopsis (Arabidopsis thaliana) cells infected with the powdery mildew fungus Golovinomyces cichoracearum. Conversely, the atypical Arabidopsis resistance protein Resistance to Powdery Mildew8.2 (RPW8.2) exclusively localizes to the EHM in this interaction (Wang et al., 2009). Ultrastructure analyses of the Golovinomyces orontii powdery mildew pathosystem revealed that the EHM is asymmetric, thicker and more electron opaque than the PM, and can be highly convoluted around mature haustoria (Micali et al., 2011). More recently, a survey of Arabidopsis and Nicotiana benthamiana plants infected by the oomycete pathogens Hyaloperonospora arabidopsidis and Phytophthora infestans, respectively, revealed that several integral host PM proteins are excluded from the EHM (Lu et al., 2012). Nevertheless, the remorin REM1.3 and the SYNAPTOTAGMIN1 (SYT1) peripheral membrane proteins localized to undetermined subcellular compartments around haustoria in P. infestans-plant interactions (Lu et al., 2012). Whether the differential accumulation of membrane proteins at the EHM is due to interference with the lateral diffusion of proteins from the PM or targeted secretion of specialized vesicles remains unclear (Lu et al., 2012).The subcellular distribution of effectors inside plant cells provides valuable clues about the host cell compartments they modify to promote disease, and effectors have emerged as useful molecular probes for plant cell biology (Whisson et al., 2007; Bozkurt et al., 2012). Heterologous expression of fluorescently tagged effectors in plant cells has been used to determine their subcellular localization in uninfected and infected tissue. This approach has been successful with the RXLR and CRINKLER (CRN) effectors, the two major classes of cytoplasmic (host-translocated) oomycete effectors (Bozkurt et al., 2012). The 49 H. arabidopsidis RXLR effectors studied by Caillaud et al. (2012) localized to the nucleus, the cytoplasm, or various plant membrane compartments. In contrast, CRN effectors from several oomycete species exclusively accumulate in the plant cell nucleus (Schornack et al., 2010; Stam et al., 2013). The P. infestans effectors AVRblb2 and AVR2 accumulate around haustoria when expressed in infected N. benthamiana cells, highlighting the PM and the EHM as important sites for effector activity (Bozkurt et al., 2011; Saunders et al., 2012). These effectors, therefore, can serve as useful probes for plant cell biology to dissect vesicular trafficking and focal immunity, processes that have proved difficult to study using standard genetic approaches (Bozkurt et al., 2011; Win et al., 2012).REM1.3 is one of two plant membrane-associated proteins detected around haustoria during the interaction between P. infestans and the model plant N. benthamiana (Lu et al., 2012). Therefore, we hypothesized that studying REM1.3 should prove useful for understanding the mechanisms governing the function and formation of perihaustorial membranes. REM1.3 belongs to a diverse family of plant-specific proteins containing a Remorin_C domain (PF03763) and has known orthologs in potato (Solanum tuberosum; StREM1.3), tomato (Solanum lycopersicum; SlREM1.2), tobacco (Nicotiana tabacum; NtREM1.2), and Arabidopsis (AtREM1.1–AtREM1.4; Raffaele et al., 2007). Several proteins from the remorin family, including REM1.3, are preferentially associated with membrane rafts, nanometric sterol- and sphingolipid-rich domains in PMs (Pike, 2006; Simons and Gerl, 2010). Indeed, StREM1.3 and NtREM1.2 are highly enriched in detergent-insoluble membranes (DIMs) and form sterol-dependent domains of approximately 75 nm in purified PMs (Mongrand et al., 2004; Shahollari et al., 2004; Raffaele et al., 2009). StREM1.3 directly binds to the cytoplasmic leaflet of the PM through a C-terminal anchor domain (RemCA) that folds into a hairpin of aliphatic α-helices in polar environments (Raffaele et al., 2009; Perraki et al., 2012). StREM1.3 is differentially phosphorylated upon the perception of polygalacturonic acid (Reymond et al., 1996). AtREM1.3 is differentially recruited to DIMs and differentially phosphorylated upon flg22 (for flagellin) peptide perception (Benschop et al., 2007; Keinath et al., 2010; Marín et al., 2012), suggesting a role in plant defense signaling. StREM1.3 and SlREM1.2 prevent Potato virus X spreading by interacting with the Triple Gene Block protein1 (TGBp1) viral movement protein, presumably in plasmodesmata or at the PM (Raffaele et al., 2009; Perraki et al., 2012). AtREM1.2 belongs to protein complexes formed by a negative regulator of immune responses, Resistance to Pseudomonas syringae pv maculicola1 (RPM1)-INTERACTING PROTEIN4, at the PM (Liu et al., 2009). Furthermore, Medicago truncatula MtSYMREM1 is enriched in root cell DIMs (Lefebvre et al., 2007) and localizes to patches at the peribacteroid membrane during symbiosis with Sinorhizobium meliloti (Lefebvre et al., 2010). MtSYMREM1 is important for nodule formation and interacts with the Lysin motif domain–containing receptor-like kinase3 (LYK3) symbiotic receptor (Lefebvre et al., 2010). Multiple lines of evidence, therefore, implicate several remorins in cell surface signaling and the accommodation of microbes during plant-microbe interactions (Raffaele et al., 2007; Jarsch and Ott, 2011; Urbanus and Ott, 2012). Nevertheless, little is known about REM1.3’s molecular function, and its role in immunity against filamentous plant pathogens has not been reported to date.In this study, we analyzed in detail the localization and function of REM1.3 during host colonization by P. infestans. We found that REM1.3 localizes exclusively to the vicinity of the PM and the EHM around noncallosic haustoria. Furthermore, our results suggest that the EHM is likely formed by multiple microdomains. REM1.3 silencing and overexpression experiments demonstrated that it promotes susceptibility to P. infestans in N. benthamiana and tomato. We also show that the REM1.3 membrane anchor domain is required for its localization at the EHM and for the promotion of susceptibility to P. infestans. This work demonstrates the importance of the dynamic reorganization of the PM in response to haustoria-forming pathogens. Our study also revealed that the effector AVRblb2 localizes to remorin-containing host membrane domains at the host-pathogen interface, possibly as a pathogen strategy to facilitate the accommodation of infection structures inside plant cells.     

A novel Arabidopsis–oomycete pathosystem: differential interactions with Phytophthora capsici reveal a role for camalexin,indole glucosinolates and salicylic acid in defence

Phytophthora capsici causes devastating diseases on a broad range of plant species. To better understand the interaction with its host plants, knowledge obtained from a model pathosystem can be instrumental. Here, we describe the interaction between P. capsici and Arabidopsis and the exploitation of this novel pathosystem to assign metabolic pathways involved in defence against P. capsici. Inoculation assays on Arabidopsis accessions with different P. capsici isolates revealed interaction specificity among accession‐isolate combinations. In a compatible interaction, appressorium‐mediated penetration was followed by the formation of invasive hyphae, haustoria and sporangia in leaves and roots. In contrast, in an incompatible interaction, P. capsici infection elicited callose deposition, accumulation of active oxygen species and cell death, resulting in early pathogen encasement in leaves. Moreover, Arabidopsis mutants with defects in salicylic acid signalling, camalexin or indole glucosinolates biosynthesis pathways displayed severely compromised resistance to P. capsici. It is anticipated that this model pathosystem will facilitate the genetic dissection of complex traits responsible for resistance against P. capsici.     

Activity profiling of vacuolar processing enzymes reveals a role for VPE during oomycete infection

Vacuolar processing enzymes (VPEs) are important cysteine proteases that are implicated in the maturation of seed storage proteins, and programmed cell death during plant–microbe interactions and development. Here, we introduce a specific, cell‐permeable, activity‐based probe for VPEs. This probe is highly specific for all four Arabidopsis VPEs, and labeling is activity‐dependent, as illustrated by sensitivity for inhibitors, pH and reducing agents. We show that the probe can be used for in vivo imaging and displays multiple active isoforms of VPEs in various tissues and in both monocot and dicot plant species. Thus, VPE activity profiling is a robust, simple and powerful tool for plant research for a wide range of applications. Using VPE activity profiling, we discovered that VPE activity is increased during infection with the oomycete pathogen Hyaloperonospora arabidopsidis (Hpa). The enhanced VPE activity is host‐derived and EDS1‐independent. Sporulation of Hpa is reduced on vpe mutant plants, demonstrating a role for VPE during compatible interactions that is presumably independent of programmed cell death. Our data indicate that, as an obligate biotroph, Hpa takes advantage of increased VPE activity in the host, e.g. to mediate protein turnover and nutrient release.