Amke den Dulk-Ras

Conjugative Transfer by the Virulence System of Agrobacterium tumefaciens

Agrobacterium tumefaciens transfers part of its Ti plasmid, the transferred DNA (T-DNA), to plant cells during tumor induction. Expression of this T-DNA in plant cells results in their transformation into tumor cells. There are similarities between the process of T-DNA transfer to plants and the process of bacterial conjugation. Here, the T-DNA transfer machinery mediated conjugation between bacteria. Thus, products of the Vir region of the Ti plasmid of Agrobacterium tumefaciens, normally involved in transfer of DNA from bacteria to plants, can direct the conjugative transfer of an IncQ plasmid between agrobacteria.

Anaplasma phagocytophilum AnkA secreted by type IV secretion system is tyrosine phosphorylated by Abl-1 to facilitate infection†

Anaplasma phagocytophilum, the agent of human granulocytic anaplasmosis, is an obligate intracellular bacterium of granulocytes. A. phagocytophilum specifically induces tyrosine phosphorylation of a 160 kDa protein (P160) in host cells. However, identity of P160, kinases involved, and effects of tyrosine phosphorylation on bacterial infection remain largely unknown. Here, we demonstrated through proteomic analysis that P160, an abundant and rapidly tyrosine‐phosphorylated protein throughout infection, was AnkA of bacterial origin. Differential centrifugation and confocal microscopy revealed that AnkA was rarely retained within A. phagocytophilum or its inclusion, but localized mainly in the cytoplasm of infected cells. Using Cre recombinase reporter assay of Agrobacterium tumefaciens, we proved that AnkA could be secreted by VirB/D4‐dependent type IV secretion (T4S) system. Yeast two‐hybrid and coimmunoprecipitation analyses demonstrated that AnkA could bind to Abl‐interactor 1 (Abi‐1), an adaptor protein that interacts with Abl‐1 tyrosine kinase, thus mediating AnkA phosphorylation. AnkA and Abl‐1 were critical for bacterial infection, as infection was inhibited upon host cytoplasmic delivery of anti‐AnkA antibody, Abl‐1 knockdown with targeted siRNA, or treatment with a specific pharmacological inhibitor of Abl‐1. These data establish AnkA as the first proven T4S substrate in members of obligate intracellular α‐proteobacteria; furthermore, it demonstrated that AnkA plays an important role in facilitating intracellular infection by activating Abl‐1 signalling pathway, and suggest a novel approach to treatment of human granulocytic anaplasmosis through inhibition of host cell signalling pathways.

Octopine and nopaline strains of Agrobacterium tumefaciens differ in virulence; molecular characterization of the virF locus

Octopine and nopaline strains of Agrobacterium tumefaciens were found to differ in virulence on Nicotiana glauca. This difference is due to the absence of a functional virF locus, which is necessary for efficient tumorigenesis on N. glauca, from the nopaline Ti plasmids. Genetic studies and DNA sequence analysis of the virF locus revealed that virF embraces one open reading frame coding for a hydrophilic protein with a molecular mass of 22437 Da. Transcription of virF is directed from left to right, towards the T region, and is strongly induced by the phenolic compound acetosyringone. We established that virA and virG, two genes known to be essential for induction of the vir regulon, are necessary for acetosyringoneinduced virF expression, implying that virF is a member of this vir regulon. Agrobacterium virF mutants can be complemented for tumor induction by co-infection with avirulent Agrobacterium ‘helper’ strains. We found that such ‘helper’ strains must express not only the virF gene but also the vir operons virA, virB, virD and virG.

Recognition of the Agrobacterium tumefaciens VirE2 Translocation Signal by the VirB/D4 Transport System Does Not Require VirE1

Agrobacterium tumefaciens uses a type IV secretion system to deliver a nucleoprotein complex and effector proteins directly into plant cells. The single-stranded DNA-binding protein VirE2, the F-box protein VirF and VirE3 are delivered into host cells via this VirB/D4 encoded translocation system. VirE1 functions as a chaperone of VirE2 by regulating its efficient translation and preventing VirE2-VirE2 aggregation in the bacterial cell. We analyzed whether the VirE1 chaperone is also essential for transport recognition of VirE2 by the VirB/D4 encoded type IV secretion system. In addition, we assayed whether translocation of VirF and VirE3, which also forms part of the virE operon, is affected by the absence of VirE1. We employed the earlier developed CRAFT (Cre recombinase Reporter Assay For Translocation) assay to detect transfer of Cre::Vir fusion proteins from A. tumefaciens into plants, monitored by stable reconstitution of a kanamycin resistance marker, and into yeast, screened by loss of the URA3 gene. We show that the C-terminal 50 amino acids of VirE2 and VirE3 are sufficient to mediate Cre translocation into host cells, confirming earlier indications of a C-terminal transport signal. This transfer was independent of the presence or absence of VirE1. Besides, the translocation efficiency of VirF is not altered in a virE1 mutant. The results unambiguously show that the VirE1 chaperone is not essential for the recognition of the VirE2 transport signal by the transport system and the subsequent translocation across the bacterial envelope into host cells.

Electroporation of Agrobacterium tumefaciens

1. Incubate A. tumefaciens in 30 ml of YEB overnight at 28C with shaking. 2. Chill the bacteria on ice and centrifuge at 3000 rpm for 10 min. at 4C 3. Xxx 4. Take the bacteria up in 1 ml ddH 2 0 at 0C. 5. Place an electroporation cuvette on ice to chill. Pipette in 100 ul bacteria. Add 200 to 500 ng of plasmid in water or TE. Used 1 ul of a 1:10 dilution of plasmid and gently mixed with the pipette tip. 6. Electroporate at 200 ohms, 25 uF, 2.5 kV at room temperature (takes only a few seconds). For 0.2 cm cuvettes, use 2.5 kV. For 0.1 cm cuvettes, use 1.8 kV. These specifications are for the BioRad electroporator for E. coli, cat. no. 165-2098. 7. Add immediately 400 ul of YEB + 1% mannitol. 8. Incubate bacteria in a eppendorf tube or the cuvette for 3 hours at 28C. 9. Plate bacteria on YEB (+1% mannitol?) with selective antibiotic and incubate for two to three days at 28C.

Deviating T-DNA transfer fromAgrobacterium tumefaciens to plants

We analyzed 29 T-DNA inserts in transgenicArabidopsis thaliana plants for the junction of the right border sequences and the flanking plant DNA. DNA sequencing showed that in most lines the right border sequences transferred had been preserved during integration, corroborating literature data. Surprisingly, in four independent transgenic lines a complete right border repeat was present followed by binary vector sequences. Cloning of two of these T-DNA inserts by plasmid rescue showed that in these lines the transferred DNA consisted of the complete binary vector sequences in addition to the T-region. On the basis of the structure of the transferred DNA we propose that in these lines T-DNA transfer started at the left-border repeat, continued through the vector part, passed the right border repeat, and ended only after reaching again this left-border repeat.

Insertional mutagenesis in yeasts using T-DNA from Agrobacterium tumefaciens.

Insertional mutagenesis is a powerful tool for the isolation of novel mutations. The gene delivery system of the bacterium Agrobacterium tumefaciens, which mediates transfer not only to plants but also to yeasts and fungi, could be exploited to generate collections of yeasts containing insertional mutations if there were no bias towards particular integration sites, as is the case in plants. To test this, we have analysed a small collection of Saccharomyces cerevisiae strains with T‐DNA copies integrated in the S. cerevisiae genome. The position of 54 of these T‐DNAs was determined. The T‐DNA showed no clear preference for certain DNA sequences or genomic regions. We have isolated insertions in the coding regions of the genes YGR125w, YDR250c, YGR141w, YGR045c, YPL017c, YGR040w, YDL052c, YJL148w, YCL033c, YFL061w, YJR033c, YDR175c and YLR309c confirming that these genes are non‐essential for S. cerevisiae haploid growth on minimal medium. Given the advantages of T‐DNA, we propose its use as an ideal mobile DNA element for insertional mutagenesis in yeasts. Copyright

Poly(ADP-ribose)polymerases are involved in microhomology mediated back-up non-homologous end joining in Arabidopsis thaliana

Besides the KU-dependent classical non-homologous end-joining (C-NHEJ) pathway, an alternative NHEJ pathway first identified in mammalian systems, which is often called the back-up NHEJ (B-NHEJ) pathway, was also found in plants. In mammalian systems PARP was found to be one of the essential components in B-NHEJ. Here we investigated whether PARP1 and PARP2 were also involved in B-NHEJ in Arabidopsis. To this end Arabidopsis parp1, parp2 and parp1parp2 (p1p2) mutants were isolated and functionally characterized. The p1p2 double mutant was crossed with the C-NHEJ ku80 mutant resulting in the parp1parp2ku80 (p1p2k80) triple mutant. As expected, because of their role in single strand break repair (SSBR) and base excision repair (BER), the p1p2 and p1p2k80 mutants were shown to be sensitive to treatment with the DNA damaging agent MMS. End-joining assays in cell-free leaf protein extracts of the different mutants using linear DNA substrates with different ends reflecting a variety of double strand breaks were performed. The results showed that compatible 5′-overhangs were accurately joined in all mutants, that KU80 protected the ends preventing the formation of large deletions and that PARP proteins were involved in microhomology mediated end joining (MMEJ), one of the characteristics of B-NHEJ.

Ehrlichia chaffeensis Tandem Repeat Proteins and Ank200 are Type 1 Secretion System Substrates Related to the Repeats-in-Toxin Exoprotein Family

Ehrlichia chaffeensis has type 1 and 4 secretion systems (T1SS and T4SS), but the substrates have not been identified. Potential substrates include secreted tandem repeat protein (TRP) 47, TRP120, and TRP32, and the ankyrin repeat protein, Ank200, that are involved in molecular host–pathogen interactions including DNA binding and a network of protein–protein interactions with host targets associated with signaling, transcriptional regulation, vesicle trafficking, and apoptosis. In this study we report that E. chaffeensis TRP47, TRP32, TRP120, and Ank200 were not secreted in the Agrobacterium tumefaciens Cre recombinase reporter assay routinely used to identify T4SS substrates. In contrast, all TRPs and the Ank200 proteins were secreted by the Escherichia coli complemented with the hemolysin secretion system (T1SS), and secretion was reduced in a T1SS mutant (ΔTolC), demonstrating that these proteins are T1SS substrates. Moreover, T1SS secretion signals were identified in the C-terminal domains of the TRPs and Ank200, and a detailed bioinformatic analysis of E. chaffeensis TRPs and Ank200 revealed features consistent with those described in the repeats-in-toxins (RTX) family of exoproteins, including glycine- and aspartate-rich tandem repeats, homology with ATP-transporters, a non-cleavable C-terminal T1SS signal, acidic pIs, and functions consistent with other T1SS substrates. Using a heterologous E. coli T1SS, this investigation has identified the first Ehrlichia T1SS substrates supporting the conclusion that the T1SS and corresponding substrates are involved in molecular host–pathogen interactions that contribute to Ehrlichia pathobiology. Further investigation of the relationship between Ehrlichia TRPs, Ank200, and the RTX exoprotein family may lead to a greater understanding of the importance of T1SS substrates and specific functions of T1SS in the pathobiology of obligately intracellular bacteria.

Agrobacterium tumefaciens VirC2 enhances T-DNA transfer and virulence through its C-terminal ribbon-helix-helix DNA-binding fold.

Agrobacterium tumefaciens VirC2 stimulates processing of single-stranded T-DNA that is translocated into plants to induce tumor formation, but how VirC2 functions is unclear. Here, we report the 1.7-Å X-ray crystal structure of its trypsin-resistant C-terminal domain, VirC282–202, which reveals a form of the ribbon-helix-helix (RHH) DNA-binding fold contained within a single polypeptide chain. DNA-binding assays and mutagenesis indicate that VirC2 uses this RHH fold to bind double-stranded DNA but not single-stranded DNA. Mutations that severely affect VirC2 DNA binding are highly deleterious for both T-DNA transfer into yeast and the virulence of A. tumefaciens in different plants including Nicotiana glauca and Kalanchoe daigremontiana. These data suggest that VirC2 enhances T-DNA transfer and virulence through DNA binding with its RHH fold. The RHH fold of VirC2 is the first crystal structure representing a group of predicted RHH proteins that facilitate endonucleolytic processing of DNA for horizontal gene transfer.