A bacterial E3 ubiquitin ligase targets a host protein kinase to disrupt plant immunity

Many bacterial pathogens of plants and animals use a type III secretion system to deliver diverse virulence-associated 'effector' proteins into the host cell. The mechanisms by which these effectors act are mostly unknown; however, they often promote disease by suppressing host immunity. One type III effector, AvrPtoB, expressed by the plant pathogen Pseudomonas syringae pv. tomato, has a carboxy-terminal domain that is an E3 ubiquitin ligase. Deletion of this domain allows an amino-terminal region of AvrPtoB (AvrPtoB(1-387)) to be detected by certain tomato varieties leading to immunity-associated programmed cell death. Here we show that a host kinase, Fen, physically interacts with AvrPtoB(1-387 )and is responsible for activating the plant immune response. The AvrPtoB E3 ligase specifically ubiquitinates Fen and promotes its degradation in a proteasome-dependent manner. This degradation leads to disease susceptibility in Fen-expressing tomato lines. Various wild species of tomato were found to exhibit immunity in response to AvrPtoB(1-387 )and not to full-length AvrPtoB. Thus, by acquiring an E3 ligase domain, AvrPtoB has thwarted a highly conserved host resistance mechanism.     

A Xanthomonas uridine 5'-monophosphate transferase inhibits plant immune kinases

Plant innate immunity is activated on the detection of pathogen-associated molecular patterns (PAMPs) at the cell surface, or of pathogen effector proteins inside the plant cell. Together, PAMP-triggered immunity and effector-triggered immunity constitute powerful defences against various phytopathogens. Pathogenic bacteria inject a variety of effector proteins into the host cell to assist infection or propagation. A number of effector proteins have been shown to inhibit plant immunity, but the biochemical basis remains unknown for the vast majority of these effectors. Here we show that the Xanthomonas campestris pathovar campestris type III effector AvrAC enhances virulence and inhibits plant immunity by specifically targeting Arabidopsis BIK1 and RIPK, two receptor-like cytoplasmic kinases known to mediate immune signalling. AvrAC is a uridylyl transferase that adds uridine 5'-monophosphate to and conceals conserved phosphorylation sites in the activation loop of BIK1 and RIPK, reducing their kinase activity and consequently inhibiting downstream signalling.     

Bacterial virulence proteins as tools to rewire kinase pathways in yeast and immune cells

Bacterial pathogens have evolved specific effector proteins that, by interfacing with host kinase signalling pathways, provide a mechanism to evade immune responses during infection. Although these effectors contribute to pathogen virulence, we realized that they might also serve as valuable synthetic biology reagents for engineering cellular behaviour. Here we exploit two effector proteins, the Shigella flexneri OspF protein and Yersinia pestis YopH protein, to rewire kinase-mediated responses systematically both in yeast and mammalian immune cells. Bacterial effector proteins can be directed to inhibit specific mitogen-activated protein kinase pathways selectively in yeast by artificially targeting them to pathway-specific complexes. Moreover, we show that unique properties of the effectors generate new pathway behaviours: OspF, which irreversibly inactivates mitogen-activated protein kinases, was used to construct a synthetic feedback circuit that shows novel frequency-dependent input filtering. Finally, we show that effectors can be used in T cells, either as feedback modulators to tune the T-cell response amplitude precisely, or as an inducible pause switch that can temporarily disable T-cell activation. These studies demonstrate how pathogens could provide a rich toolkit of parts to engineer cells for therapeutic or biotechnological applications.     

林木与病原菌分子互作机制研究进展

近年来林木与病原菌互作的分子机制研究成果丰硕,尤其是HIGS与CRISPR/Cas9等技术的发展,促进了林木病原菌关键致病基因的功能、病原菌基因组与转录组学、病原菌效应蛋白、林木抗病基因功能、林木抗病与生长平衡、林木抗病分子育种等多个层面研究的快速发展.从植物-病原菌分子互作的基本问题出发,综述了国内外林木-病原菌分子...     

A saponin-detoxifying enzyme mediates suppression of plant defences

Plant disease resistance can be conferred by constitutive features such as structural barriers or preformed antimicrobial secondary metabolites. Additional defence mechanisms are activated in response to pathogen attack and include localized cell death (the hypersensitive response). Pathogens use different strategies to counter constitutive and induced plant defences, including degradation of preformed antimicrobial compounds and the production of molecules that suppress induced plant defences. Here we present evidence for a two-component process in which a fungal pathogen subverts the preformed antimicrobial compounds of its host and uses them to interfere with induced defence responses. Antimicrobial saponins are first hydrolysed by a fungal saponin-detoxifying enzyme. The degradation product of this hydrolysis then suppresses induced defence responses by interfering with fundamental signal transduction processes leading to disease resistance.     

白粉菌效应蛋白研究进展

在病原菌与植物的相互作用过程中,病原菌分泌大量效应蛋白帮助其侵染植物,因此效应蛋白一直是植物病理学研究的热点课题.该文基于大量白粉菌效应蛋白的研究成果,就近年来白粉菌效应蛋白的生物信息学预测分析结果、功能效应蛋白鉴定及其作用机理和无毒效应蛋白研究进展等方面进行综述,同时对未来值得重点关注的研究方向进行探讨,以期为白粉菌致病性的研究提供理论参考.     

Widespread distribution and fitness contribution of Xanthomonas campestris avirulence gene avrBs2

Disease-resistance genes introduced into cultivated plants are often rendered ineffective by the ability of pathogen populations to overcome host resistance. The bacterial pathogen Xanthomonas campestris pathovar vesicatoria causes bacterial spot disease of tomato and pepper, and this pathogen has been shown to overcome disease resistance in pepper (Capsicum annuum) by evading the recognition and defence response of the host plant. Numerous resistance genes to bacterial spot have been identified in pepper and its wild relatives, each providing resistance to specific races of X.c. vesicatoria. The resistance gene Bs1, for example, provides resistance to X.c. vesicatoria strains expressing the avirulence gene avrBs1; Bs2 provides resistance to stains expressing avrBs2 and so on. We now report that avr Bs2 is highly conserved among strains of X.c. vesicatoria, and among many other pathovars of X. campestris. Furthermore, we find that avrBs2 is in fact needed for full virulence of the pathogen on susceptible hosts. This implies that plants carrying Bs2 can recognize an essential gene of the bacterial pathogen, which may explain why Bs2 confers the only effective field resistance to X.c. vesicatoria in pepper.     

R gene expression induced by a type-III effector triggers disease resistance in rice

Disease resistance (R) genes in plants encode products that specifically recognise incompatible pathogens and trigger a cascade of events leading to disease resistance in the host plant. R-gene specificity is dictated by both host R genes and cognate avirulence (avr) genes in pathogens. However, the basis of gene-for-gene specificity is not well understood. Here, we report the cloning of the R gene Xa27 from rice and the cognate avr gene avrXa27 from Xanthomonas oryzae pv. oryzae. Resistant and susceptible alleles of Xa27 encode identical proteins. However, expression of only the resistant allele occurs when a rice plant is challenged by bacteria harbouring avrXa27, whose product is a nuclear localized type-III effector. Induction of Xa27 occurs only in the immediate vicinity of infected tissue, whereas ectopic expression of Xa27 resulted in resistance to otherwise compatible strains of the pathogen. Thus Xa27 specificity towards incompatible pathogens involves the differential expression of the R gene in the presence of the AvrXa27 effector.     

Metabolic priming by a secreted fungal effector

Maize smut caused by the fungus Ustilago maydis is a widespread disease characterized by the development of large plant tumours. U. maydis is a biotrophic pathogen that requires living plant tissue for its development and establishes an intimate interaction zone between fungal hyphae and the plant plasma membrane. U. maydis actively suppresses plant defence responses by secreted protein effectors. Its effector repertoire comprises at least 386 genes mostly encoding proteins of unknown function and expressed exclusively during the biotrophic stage. The U. maydis secretome also contains about 150 proteins with probable roles in fungal nutrition, fungal cell wall modification and host penetration as well as proteins unlikely to act in the fungal-host interface like a chorismate mutase. Chorismate mutases are key enzymes of the shikimate pathway and catalyse the conversion of chorismate to prephenate, the precursor for tyrosine and phenylalanine synthesis. Root-knot nematodes inject a secreted chorismate mutase into plant cells likely to affect development. Here we show that the chorismate mutase Cmu1 secreted by U. maydis is a virulence factor. The enzyme is taken up by plant cells, can spread to neighbouring cells and changes the metabolic status of these cells through metabolic priming. Secreted chorismate mutases are found in many plant-associated microbes and might serve as general tools for host manipulation.     

植物天然免疫系统研究进展

很多植物病原菌严重地损害植物的生长和繁殖。植物与病原体协同进化过程中,也逐渐形成了一系列复杂高效的保护机制来抵御病原物的侵染。植物中抵抗外界微生物刺激所形成的系统被称为植物天然免疫系统,可分为两个层次。第1个层次是植物模式识别受体(PRRs)识别病原相关分子模式(PAMPs),触发病原相关分子模式触发的免疫反应（PTI）,激活植物体中促丝裂原活化蛋白激酶(MAPK)信号通路使植物产生早期应答反应。PTI适应性较广,可识别和响应包括非致病菌的许多类微生物。第2个层次是病原菌产生效应因子抑制基础免疫响应PTI,而植物产生针对性更强的抗性蛋白(R蛋白)识别效应因子,并通过效应因子触发型免疫(ETI)来重建植物的抗性。笔者综述了近年来植物天然免疫系统的研究进展,认为随着对植物天然免疫系统研究的深入,应重视PTI和ETI的结合利用,有效扩大植物抗菌谱,改良植物ETI抗性。     

核黄素诱导番茄抗病性与Pti蛋白激酶基因表达

研究了核黄素诱导番茄对丁香假单胞菌番茄致病变种（Pseudom onas syringaepv.tomato）的抗性及相关防卫反应.核黄素诱导处理后,番茄对P.syringaepv.tomato的抗性增强,蛋白激酶基因Pti4,Pti5,Pti6和抗病防卫基因PR-1a,GluA,GluB,ChtA,ChtB表达量提高,水杨酸含量明显升高.蛋白激酶抑制剂K252 a可以部分抑制这些基因的表达,取消核黄素对水杨酸的诱导作用,可减弱诱导抗病性的程度.这些结果表明,核黄素诱导的抗病性受植物细胞内多种信号传导因子控制.     

两个稻瘟病菌假想蛋白的纯化和特性分析

稻瘟病菌(Magnaporthe Grisea)引起的水稻稻瘟病是世界水稻生产最具毁灭性的病害之一,也是研究植物与病原物相互作用分子机理的模式系统之一.真菌分泌蛋白由于其本身所具有的分泌特性极有可能成为被宿主植物识别的作用病菌分泌蛋白,该研究到目前为止还比较有限. 文章证明了稻瘟病菌分泌蛋白的存在并且检验了其中几个蛋白在其宿主植物水稻中的诱导因子作用. 通过同源基因的时空表达技术,表明分泌蛋白在稻瘟病菌中大量表达.其中两个在稻瘟病菌中的未知蛋白被测试出具有诱导因子作用.     

A P-type ATPase required for rice blast disease and induction of host resistance

To cause diseases in plants, pathogenic microorganisms have evolved mechanisms to deliver proteins directly into plant cells, where they suppress plant defences and facilitate tissue invasion. How plant pathogenic fungi, which cause many of the world's most serious plant diseases, deliver proteins during plant infection is currently unknown. Here we report the characterization of a P-type ATPase-encoding gene, MgAPT2, in the economically important rice blast pathogen Magnaporthe grisea, which is required for exocytosis during plant infection. Targeted gene replacement showed that MgAPT2 is required for both foliar and root infection by the fungus, and for the rapid induction of host defence responses in an incompatible reaction. DeltaMgapt2 mutants are impaired in the secretion of a range of extracellular enzymes and accumulate abnormal Golgi-like cisternae. However, the loss of MgAPT2 does not significantly affect hyphal growth or sporulation, indicating that the establishment of rice blast disease involves the use of MgApt2-dependent exocytotic processes that operate during plant infection.     

禾谷炭疽菌效应分子motif序列研究

禾谷炭疽菌侵染玉米、小麦等粮食作物而引起的炭疽病,给各国农业生产造成了巨大经济损失。植物病原菌可以利用效应分子来操控寄主植物的防卫反应,从而实现其对植物的侵染、定殖和扩展等过程。研究基于前人对禾谷炭疽菌中已报道的177个候选效应分子(CE)的氨基酸数据,利用MEME对全部CE和不同氨基酸类别的CE进行在线motif分析,未获得较满意结果。随后,结合已报道效应分子(E)所具有保守motif的氨基酸位置范围,对82个具有典型特征E的信号肽序列后30~60 aa进行获取,并将信号肽位置大于28、氨基酸数量较小的E进行剔除,最终明确64个E存在着保守的PAAX motif。该研究丰富了真菌保守motif的类型,为进一步开展禾谷炭疽菌效应分子的motif功能研究提供重要的理论指导。     

Co-option of a default secretory pathway for plant immune responses

Cell-autonomous immunity is widespread in plant-fungus interactions and terminates fungal pathogenesis either at the cell surface or after pathogen entry. Although post-invasive resistance responses typically coincide with a self-contained cell death of plant cells undergoing attack by parasites, these cells survive pre-invasive defence. Mutational analysis in Arabidopsis identified PEN1 syntaxin as one component of two pre-invasive resistance pathways against ascomycete powdery mildew fungi. Here we show that plasma-membrane-resident PEN1 promiscuously forms SDS-resistant soluble N-ethylmaleimide sensitive factor attachment protein receptor (SNARE) complexes together with the SNAP33 adaptor and a subset of vesicle-associated membrane proteins (VAMPs). PEN1-dependent disease resistance acts in vivo mainly through two functionally redundant VAMP72 subfamily members, VAMP721 and VAMP722. Unexpectedly, the same two VAMP proteins also operate redundantly in a default secretory pathway, suggesting dual functions in separate biological processes owing to evolutionary co-option of the default pathway for plant immunity. The disease resistance function of the secretory PEN1-SNAP33-VAMP721/722 complex and the pathogen-induced subcellular dynamics of its components are mechanistically reminiscent of immunological synapse formation in vertebrates, enabling execution of immune responses through focal secretion.     

Structure of the small G protein Cdc42 bound to the GTPase-binding domain of ACK.

The proteins Cdc42 and Rac are members of the Rho family of small GTPases (G proteins), which control signal-transduction pathways that lead to rearrangements of the cell cytoskeleton, cell differentiation and cell proliferation. They do so by binding to downstream effector proteins. Some of these, known as CRIB (for Cdc42/Rac interactive-binding) proteins, bind to both Cdc42 and Rac, such as the PAK1-3 serine/threonine kinases, whereas others are specific for Cdc42, such as the ACK tyrosine kinases and the Wiscott-Aldrich-syndrome proteins (WASPs). The effector loop of Cdc42 and Rac (comprising residues 30-40, also called switch I), is one of two regions which change conformation on exchange of GDP for GTP. This region is almost identical in Cdc42 and Racs, indicating that it does not determine the specificity of these G proteins. Here we report the solution structure of the complex of Cdc42 with the GTPase-binding domain ofACK. Both proteins undergo significant conformational changes on binding, to form a new type of G-protein/effector complex. The interaction extends the beta-sheet in Cdc42 by binding an extended strand from ACK, as seen in Ras/effector interactions, but it also involves other regions of the G protein that are important for determining the specificity of effector binding.     

A salmonella protein antagonizes Rac-1 and Cdc42 to mediate host-cell recovery after bacterial invasion.

An essential feature of the bacterial pathogen Salmonella spp. is its ability to enter cells that are normally non-phagocytic, such as those of the intestinal epithelium. The bacterium achieves entry by delivering effector proteins into the host-cell cytosol by means of a specialized protein-secretion system (termed type III), which causes reorganization of the cell's actin cytoskeleton and ruffling of its membrane. One of the bacterial effectors that stimulates these cellular responses is SopE, which acts as a guanyl-nucleotide-exchange factor on Rho GTPase proteins such as Cdc42 and Rac. As the actin-cytoskeleton reorganization induced by Salmonella is reversible and short-lived, infected cells regain their normal architecture after bacterial internalization. We show here that the S. Typhimurium effector protein SptP, which is delivered to the host-cell cytosol by the type-III secretion system, is directly responsible for the reversal of the actin cytoskeletal changes induced by the bacterium. SptP exerts this function by acting as a GTPase-activating protein (GAP) for Rac-1 and Cdc42.