农杆菌T-复合物的形成与转运研究进展

在简要介绍农杆菌T-DNA转运全过程的基础上,结合作者近年的工作,重点对T-复合物的形成和T-复合物在农杆菌细胞内的转运机理的最新进展进行归纳和评述．农杆菌能够将其Ti质粒上的一段DNA以单链DNA-蛋白质复合物(简称T-复合物)的形式,通过其细胞两端的四型分泌系统(typeⅣ secretion system,T4SS)转运到宿主植物中,并使宿主发生遗传转化,因而农杆菌介导的T-DNA转运技术已成为应用最广泛的植物转基因技术,同时,由于转运T-复合物的T4SS也是某些质粒接合转移和许多病源微生物分泌致病效应蛋白的通道,因此,农杆菌T-DNA转运机理的研究受到了广泛的重视和关注,使得这方面的研究进展非常迅速．     

HrpB7 from Xanthomonas campestris pv. vesicatoria is an essential component of the type III secretion system and shares features of HrpO/FliJ/YscO family members

The Gram‐negative bacterium Xanthomonas campestris pv. vesicatoria translocates effector proteins via a type III secretion system (T3SS) into eukaryotic cells. The T3SS spans both bacterial membranes and consists of more than 20 proteins, 9 of which are conserved in plant and animal pathogens and constitute the core subunits of the secretion apparatus. T3S in X. campestris pv. vesicatoria also depends on nonconserved proteins with yet unknown function including HrpB7, which contains predicted N‐ and C‐terminal coiled‐coil regions. In the present study, we provide experimental evidence that HrpB7 forms stable oligomeric complexes. Interaction and localisation studies suggest that HrpB7 interacts with inner membrane and predicted cytoplasmic (C) ring components of the T3SS but is dispensable for the assembly of the C ring. Additional interaction partners of HrpB7 include the cytoplasmic adenosinetriphosphatase HrcN and the T3S chaperone HpaB. The interaction of HrpB7 with T3SS components as well as complex formation by HrpB7 depends on the presence of leucine heptad motifs, which are part of the predicted N‐ and C‐terminal coiled‐coil structures. Our data suggest that HrpB7 forms multimeric complexes that associate with the T3SS and might serve as a docking site for the general T3S chaperone HpaB.     

Cyclic di‐GMP inactivates T6SS and T4SS activity in Agrobacterium tumefaciens

The Type VI secretion system (T6SS) is a bacterial nanomachine that delivers effector proteins into prokaryotic and eukaryotic preys. This secretion system has emerged as a key player in regulating the microbial diversity in a population. In the plant pathogen Agrobacterium tumefaciens, the signalling cascades regulating the activity of this secretion system are poorly understood. Here, we outline how the universal eubacterial second messenger cyclic di‐GMP impacts the production of T6SS toxins and T6SS structural components. We demonstrate that this has a significant impact on the ability of the phytopathogen to compete with other bacterial species in vitro and in planta. Our results suggest that, as opposed to other bacteria, c‐di‐GMP turns down the T6SS in A. tumefaciens thus impacting its ability to compete with other bacterial species within the rhizosphere. We also demonstrate that elevated levels of c‐di‐GMP within the cell decrease the activity of the Type IV secretion system (T4SS) and subsequently the capacity of A. tumefaciens to transform plant cells. We propose that such peculiar control reflects on c‐di‐GMP being a key second messenger that silences energy‐costing systems during early colonization phase and biofilm formation, while low c‐di‐GMP levels unleash T6SS and T4SS to advance plant colonization.     

Recombineering and stable integration of the Pseudomonas syringae pv. syringae 61 hrp/hrc cluster into the genome of the soil bacterium Pseudomonas fluorescens Pf0‐1

Many Gram‐negative bacteria use a type III secretion system (T3SS) to establish associations with their hosts. The T3SS is a conduit for direct injection of type‐III effector proteins into host cells, where they manipulate the host for the benefit of the infecting bacterium. For plant‐associated pathogens, the variations in number and amino acid sequences of type‐III effectors, as well as their functional redundancy, make studying type‐III effectors challenging. To mitigate this challenge, we developed a stable delivery system for individual or defined sets of type‐III effectors into plant cells. We used recombineering and Tn5‐mediated transposition to clone and stably integrate, respectively, the complete hrp/hrc region from Pseudomonas syringae pv. syringae 61 into the genome of the soil bacterium Pseudomonas fluorescens Pf0‐1. We describe our development of Effector‐to‐Host Analyzer (EtHAn), and demonstrate its utility for studying effectors for their in planta functions.     

The pathogenicity factor HrpF interacts with HrpA and HrpG to modulate type III secretion system (T3SS) function and t3ss expression in Pseudomonas syringae pv. averrhoi

To ensure the optimal infectivity on contact with host cells, pathogenic Pseudomonas syringae has evolved a complex mechanism to control the expression and construction of the functional type III secretion system (T3SS) that serves as a dominant pathogenicity factor. In this study, we showed that the hrpF gene of P. syringae pv. averrhoi, which is located upstream of hrpG, encodes a T3SS‐dependent secreted/translocated protein. Mutation of hrpF leads to the loss of bacterial ability on elicitation of disease symptoms in the host and a hypersensitive response in non‐host plants, and the secretion or translocation of the tested T3SS substrates into the bacterial milieu or plant cells. Moreover, overexpression of hrpF in the wild‐type results in delayed HR and reduced t3ss expression. The results of protein–protein interactions demonstrate that HrpF interacts directly with HrpG and HrpA in vitro and in vivo, and protein stability assays reveal that HrpF assists HrpA stability in the bacterial cytoplasm, which is reduced by a single amino acid substitution at the 67th lysine residue of HrpF with alanine. Taken together, the data presented here suggest that HrpF has two roles in the assembly of a functional T3SS: one by acting as a negative regulator, possibly involved in the HrpSVG regulation circuit via binding to HrpG, and the other by stabilizing HrpA in the bacterial cytoplasm via HrpF–HrpA interaction prior to the secretion and formation of Hrp pilus on the bacterial surface.     

Type IV secretion in Gram‐negative and Gram‐positive bacteria

Type IV secretion systems (T4SSs) are versatile multiprotein nanomachines spanning the entire cell envelope in Gram‐negative and Gram‐positive bacteria. They play important roles through the contact‐dependent secretion of effector molecules into eukaryotic hosts and conjugative transfer of mobile DNA elements as well as contact‐independent exchange of DNA with the extracellular milieu. In the last few years, many details on the molecular mechanisms of T4SSs have been elucidated. Exciting structures of T4SS complexes from Escherichia coli plasmids R388 and pKM101, Helicobacter pylori and Legionella pneumophila have been solved. The structure of the F‐pilus was also reported and surprisingly revealed a filament composed of pilin subunits in 1:1 stoichiometry with phospholipid molecules. Many new T4SSs have been identified and characterized, underscoring the structural and functional diversity of this secretion superfamily. Complex regulatory circuits also have been shown to control T4SS machine production in response to host cell physiological status or a quorum of bacterial recipient cells in the vicinity. Here, we summarize recent advances in our knowledge of ‘paradigmatic’ and emerging systems, and further explore how new basic insights are aiding in the design of strategies aimed at suppressing T4SS functions in bacterial infections and spread of antimicrobial resistances.     

Fic domain-catalyzed adenylylation: insight provided by the structural analysis of the type IV secretion system effector BepA

Numerous bacterial pathogens subvert cellular functions of eukaryotic host cells by the injection of effector proteins via dedicated secretion systems. The type IV secretion system (T4SS) effector protein BepA from Bartonella henselae is composed of an N‐terminal Fic domain and a C‐terminal Bartonella intracellular delivery domain, the latter being responsible for T4SS‐mediated translocation into host cells. A proteolysis resistant fragment (residues 10–302) that includes the Fic domain shows autoadenylylation activity and adenylyl transfer onto Hela cell extract proteins as demonstrated by autoradiography on incubation with α‐[³²P]‐ATP. Its crystal structure, determined to 2.9‐Å resolution by the SeMet‐SAD method, exhibits the canonical Fic fold including the HPFxxGNGRxxR signature motif with several elaborations in loop regions and an additional β‐rich domain at the C‐terminus. On crystal soaking with ATP/Mg²⁺, additional electron density indicated the presence of a PP_i/Mg²⁺ moiety, the side product of the adenylylation reaction, in the anion binding nest of the signature motif. On the basis of this information and that of the recent structure of IbpA(Fic2) in complex with the eukaryotic target protein Cdc42, we present a detailed model for the ternary complex of Fic with the two substrates, ATP/Mg²⁺ and target tyrosine. The model is consistent with an in‐line nucleophilic attack of the deprotonated side‐chain hydroxyl group onto the α‐phosphorus of the nucleotide to accomplish AMP transfer. Furthermore, a general, sequence‐independent mechanism of target positioning through antiparallel β‐strand interactions between enzyme and target is suggested.     

Quantitative Image Analysis and Modeling Indicate the Agrobacterium tumefaciens Type IV Secretion System Is Organized in a Periodic Pattern of Foci

The Gram negative plant pathogen Agrobacterium tumefaciens is uniquely capable of genetically transforming eukaryotic host cells during the infection process. DNA and protein substrates are transferred into plant cells via a type IV secretion system (T4SS), which forms large cell-envelope spanning complexes at multiple sites around the bacterial circumference. To gain a detailed understanding of T4SS positioning, the spatial distribution of fluorescently labeled T4SS components was quantitatively assessed to distinguish between random and structured localization processes. Through deconvolution microscopy followed by Fourier analysis and modeling, T4SS foci were found to localize in a non-random periodic pattern. These results indicate that T4SS complexes are dependent on an underlying scaffold or assembly process to obtain an organized distribution suitable for effective delivery of substrates into host cells.     

The type IV secretion system of Sinorhizobium meliloti strain 1021 is required for conjugation but not for intracellular symbiosis

The type IV secretion system (T4SS) of the plant intracellular symbiont Sinorhizobium meliloti 1021 is required for conjugal transfer of DNA. However, it is not required for host invasion and persistence, unlike the T4SSs of closely related mammalian intracellular pathogens. A comparison of the requirement for a bacterial T4SS in plant versus animal host invasion suggests an important difference in the intracellular niches occupied by these bacteria.     

T-DNA转移研究进展

植物遗传转化技术近年在农作物性状改良、植物生物反应器利用以及基因功能鉴定等方面得到了广泛的应用.T-DNA转移是植物细胞农杆菌介导遗传转化整合和表达外源基因的基础.农杆菌Ti质粒vir基因编码蛋白、农杆菌一些染色体基因编码蛋白及植物细胞一些基因编码蛋白或因子均参与T-DNA转移.转移过程包括农杆菌对植物细胞的识别、附着,细菌对植物信号物质的感受,细菌vir基因的诱导表达,T复合体的形成,跨膜运输,进核运输和整合等一序列过程.植物细胞因子与农杆菌T-DNA转移相关蛋白的相互作用最近被认为在T-DNA转移过程中起重要作用.     

Bacterial Type IV secretion systems: versatile virulence machines

Many bacterial pathogens employ multicomponent protein complexes to deliver macromolecules directly into their eukaryotic host cell to promote infection. Some Gram-negative pathogens use a versatile Type IV secretion system (T4SS) that can translocate DNA or proteins into host cells. T4SSs represent major bacterial virulence determinants and have recently been the focus of intense research efforts designed to better understand and combat infectious diseases. Interestingly, although the two major classes of T4SSs function in a similar manner to secrete proteins, the translocated 'effectors' vary substantially from one organism to another. In fact, differing effector repertoires likely contribute to organism-specific host cell interactions and disease outcomes. In this review, we discuss the current state of T4SS research, with an emphasis on intracellular bacterial pathogens of humans and the diverse array of translocated effectors used to manipulate host cells.     

Agrobacterium rhizogenes GALLS protein contains domains for ATP binding, nuclear localization, and type IV secretion

Agrobacterium tumefaciens and Agrobacterium rhizogenes are closely related plant pathogens that cause different diseases, crown gall and hairy root. Both diseases result from transfer, integration, and expression of plasmid-encoded bacterial genes located on the transferred DNA (T-DNA) in the plant genome. Bacterial virulence (Vir) proteins necessary for infection are also translocated into plant cells. Transfer of single-stranded DNA (ssDNA) and Vir proteins requires a type IV secretion system, a protein complex spanning the bacterial envelope. A. tumefaciens translocates the ssDNA-binding protein VirE2 into plant cells, where it binds single-stranded T-DNA and helps target it to the nucleus. Although some strains of A. rhizogenes lack VirE2, they are pathogenic and transfer T-DNA efficiently. Instead, these bacteria express the GALLS protein, which is essential for their virulence. The GALLS protein can complement an A. tumefaciens virE2 mutant for tumor formation, indicating that GALLS can substitute for VirE2. Unlike VirE2, GALLS contains ATP-binding and helicase motifs similar to those in TraA, a strand transferase involved in conjugation. Both GALLS and VirE2 contain nuclear localization sequences and a C-terminal type IV secretion signal. Here we show that mutations in any of these domains abolished the ability of GALLS to substitute for VirE2.     

丁香假单胞菌中的III型分泌系统及其调控机制研究进展

丁香假单胞菌(Pseudomonas syringae)是引起许多作物病害的一种革兰氏阴性病原细菌。该细菌入侵寄主植物细胞主要通过其III型分泌系统(type III secretion system,T3SS)将效应蛋白转入到寄主真核细胞内,抑制寄主免疫功能,以达到成功侵染和定殖的目的。III型分泌系统的主调控因子RhpR/S通过感受环境信号的变化直接调控hrpR/S及其他毒力相关通路。同时III型分泌系统基因的表达也受到其他调控因子的影响,包括σ因子HrpL、双组分系统GacA/S、Lon蛋白酶、第二信使分子和环境信号等。本文在简要介绍丁香假单胞菌III型分泌系统组成和功能的基础上,综述丁香假单胞菌III型分泌系统调控机制的最新研究进展,以期为深入探究病原菌的致病机制提供参考和思路。     

Involvement of Rad52 in T‐DNA circle formation during Agrobacterium tumefaciens‐mediated transformation of Saccharomyces cerevisiae

Agrobacterium tumefaciens cells carrying a tumour inducing plasmid (Ti‐plasmid) can transfer a defined region of transfer DNA (T‐DNA) to plant cells as well as to yeast. This process of Agrobacterium‐mediated transformation (AMT) eventually results in the incorporation of the T‐DNA in the genomic DNA of the recipient cells. All available evidence indicates that T‐strand transfer closely resembles conjugal DNA transfer as found between Gram‐negative bacteria. However, where conjugal plasmid DNA transfer starts via relaxase‐mediated processing of a single origin of transfer (oriT), the T‐DNA is flanked by two imperfect direct border repeats which are both substrates for the Ti‐plasmid encoded relaxase VirD2. Yeast was used as a model system to investigate the requirements of the recipient cell for the formation of T‐DNA circles after AMT. It was found that, despite the absence of self‐homology on the T‐DNA, the homologous repair proteins Rad52 and Rad51 are involved in T‐DNA circle formation. A model is presented involving the formation of T‐DNA concatemers derived from T‐strands by a process of strand‐transfer catalysed by VirD2. These concatemers are then resolved into T‐DNA circles by homologous recombination in the recipient cell.     

Agrobacterium rhizogenes GALLS protein substitutes for Agrobacterium tumefaciens single-stranded DNA-binding protein VirE2

Agrobacterium tumefaciens and Agrobacterium rhizogenes transfer plasmid-encoded genes and virulence (Vir) proteins into plant cells. The transferred DNA (T-DNA) is stably inherited and expressed in plant cells, causing crown gall or hairy root disease. DNA transfer from A. tumefaciens into plant cells resembles plasmid conjugation; single-stranded DNA (ssDNA) is exported from the bacteria via a type IV secretion system comprised of VirB1 through VirB11 and VirD4. Bacteria also secrete certain Vir proteins into plant cells via this pore. One of these, VirE2, is an ssDNA-binding protein crucial for efficient T-DNA transfer and integration. VirE2 binds incoming ssT-DNA and helps target it into the nucleus. Some strains of A. rhizogenes lack VirE2, but they still transfer T-DNA efficiently. We isolated a novel gene from A. rhizogenes that restored pathogenicity to virE2 mutant A. tumefaciens. The GALLS gene was essential for pathogenicity of A. rhizogenes. Unlike VirE2, GALLS contains a nucleoside triphosphate binding motif similar to one in TraA, a strand transferase conjugation protein. Despite their lack of similarity, GALLS substituted for VirE2.     

The Small Heat-shock Protein HspL Is a VirB8 Chaperone Promoting Type IV Secretion-mediated DNA Transfer

Agrobacterium tumefaciens is a plant pathogen that utilizes a type IV secretion system (T4SS) to transfer DNA and effector proteins into host cells. In this study we discovered that an α-crystallin type small heat-shock protein (α-Hsp), HspL, is a molecular chaperone for VirB8, a T4SS assembly factor. HspL is a typical α-Hsp capable of protecting the heat-labile model substrate citrate synthase from thermal aggregation. It forms oligomers in a concentration-dependent manner in vitro. Biochemical fractionation revealed that HspL is mainly localized in the inner membrane and formed large complexes with certain VirB protein subassemblies. Protein-protein interaction studies indicated that HspL interacts with VirB8, a bitopic integral inner membrane protein that is essential for T4SS assembly. Most importantly, HspL is able to prevent the aggregation of VirB8 fused with glutathione S-transferase in vitro, suggesting that it plays a role as VirB8 chaperone. The chaperone activity of two HspL variants with amino acid substitutions (F98A and G118A) for both citrate synthase and glutathione S-transferase-VirB8 was reduced and correlated with HspL functions in T4SS-mediated DNA transfer and virulence. This study directly links in vitro and in vivo functions of an α-Hsp and reveals a novel α-Hsp function in T4SS stability and bacterial virulence.     

VirE2: a unique ssDNA-compacting molecular machine

The translocation of single-stranded DNA (ssDNA) across membranes of two cells is a fundamental biological process occurring in both bacterial conjugation and Agrobacterium pathogenesis. Whereas bacterial conjugation spreads antibiotic resistance, Agrobacterium facilitates efficient interkingdom transfer of ssDNA from its cytoplasm to the host plant cell nucleus. These processes rely on the Type IV secretion system (T4SS), an active multiprotein channel spanning the bacterial inner and outer membranes. T4SSs export specific proteins, among them relaxases, which covalently bind to the 5' end of the translocated ssDNA and mediate ssDNA export. In Agrobacterium tumefaciens, another exported protein—VirE2—enhances ssDNA transfer efficiency 2000-fold. VirE2 binds cooperatively to the transferred ssDNA (T-DNA) and forms a compact helical structure, mediating T-DNA import into the host cell nucleus. We demonstrated—using single-molecule techniques—that by cooperatively binding to ssDNA, VirE2 proteins act as a powerful molecular machine. VirE2 actively pulls ssDNA and is capable of working against 50-pN loads without the need for external energy sources. Combining biochemical and cell biology data, we suggest that, in vivo, VirE2 binding to ssDNA allows an efficient import and pulling of ssDNA into the host. These findings provide a new insight into the ssDNA translocation mechanism from the recipient cell perspective. Efficient translocation only relies on the presence of ssDNA binding proteins in the recipient cell that compacts ssDNA upon binding. This facilitated transfer could hence be a more general ssDNA import mechanism also occurring in bacterial conjugation and DNA uptake processes.