Global Analysis of the HrpL Regulon in the Plant Pathogen Pseudomonas syringae pv. tomato DC3000 Reveals New Regulon Members with Diverse Functions

The type III secretion system (T3SS) is required for virulence in the gram-negative plant pathogen Pseudomonas syringae pv. tomato DC3000. The alternative sigma factor HrpL directly regulates expression of T3SS genes via a promoter sequence, often designated as the “hrp promoter.” Although the HrpL regulon has been extensively investigated in DC3000, it is not known whether additional regulon members remain to be found. To systematically search for HrpL-regulated genes, we used chromatin immunoprecipitation coupled with high-throughput sequencing (ChIP-Seq) and bulk mRNA sequencing (RNA-Seq) to identify HrpL-binding sites and likely hrp promoters. The analysis recovered 73 sites of interest, including 20 sites that represent new hrp promoters. The new promoters lie upstream of a diverse set of genes encoding potential regulators, enzymes and hypothetical proteins. PSPTO_5633 is the only new HrpL regulon member that is potentially an effector and is now designated HopBM1. Deletions in several other new regulon members, including PSPTO_5633, PSPTO_0371, PSPTO_2130, PSPTO_2691, PSPTO_2696, PSPTO_3331, and PSPTO_5240, in either DC3000 or ΔhopQ1-1 backgrounds, do not affect the hypersensitive response or in planta growth of the resulting strains. Many new HrpL regulon members appear to be unrelated to the T3SS, and orthologs for some of these can be identified in numerous non-pathogenic bacteria. With the identification of 20 new hrp promoters, the list of HrpL regulon members is approaching saturation and most likely includes all DC3000 effectors.     

Cloning of genes required for hypersensitivity and pathogenicity inPseudomonas syringae pv.aptata

A genomic library ofPseudomonas syringae pv.aptata strain NCPPB 2664, which causes bacterial blight of sugar beet, lettuce and other plants, was constructed in the cosmid vector pCPP31. The 13.4 kbEcoRI fragment of the cosmid pHIR11, containing thehrp (hypersensitiveresponse andpathogenicity) gene cluster of the closely related bacteriumPseudomonas syringae pv.syringae strain 61, was used as a probe to identify a homologoushrp gene cluster inP. syringae pv.aptata. Thirty of 2500 cosmid clones, screened by colony hybridization, gave a strong hybridization signal with the probe, but none of these conferred to the non-pathogenic bacterium,Pseudomonas fluorescens, the ability to elicit the hypersensitive response (HR) in tobacco. Southern blot analysis ofEcoRI-digested genomic DNA ofP. syringae pv.aptata showed hybridizing bands of 12 kb and 4.4 kb. Only a 12 kb fragment hybridized in digests of the cosmids. Cosmid clone pCPP1069 was mutagenized with Tn10-minitet and marker-exchanged into the genome ofP. syringae pv.aptata. Three resulting prototrophic mutant strains failed to elicit the HR in tobacco and to cause disease in lettuce. The DNA flanking the Tn10-minitet insertions from mutated derivatives of pCPP1069 hybridized with the 10.6 kbBglII fragment of pHIR11. These results indicate thatP. syringae pv.aptata harbourshrp genes that are similar to, but arranged differently from, homologoushrp genes ofP. syringae pv.syringae.Abbreviations HR hypersensitive response - Hrp mutant unable to induce HR and pathogenicity - Psa Pseudomonas syringae pv.aptata - Pss Pseudomonas syringae pv.syringae - Ea Erwinia amylovora     

Identification of harpins in Pseudomonas syringae pv. tomato DC3000, which are functionally similar to HrpK1 in promoting translocation of type III secretion system effectors

Harpins are a subset of type III secretion system (T3SS) substrates found in all phytopathogenic bacteria that utilize a T3SS. Pseudomonas syringae pv. tomato DC3000 was previously reported to produce two harpins, HrpZ1 and HrpW1. DC3000 was shown here to deploy two additional proteins, HopAK1 and HopP1, which have the harpin-like properties of lacking cysteine, eliciting the hypersensitive response (HR) when partially purified and infiltrated into tobacco leaves, and possessing a two-domain structure similar to that of the HrpW1 class of harpins. Unlike the single-domain harpin HrpZ1, the two-domain harpins have C-terminal enzyme-like domains: pectate lyase for HopAK1 and lytic transglycosylase for HopP1. Genetic techniques to recycle antibiotic markers were applied to DC3000 to generate a quadruple harpin gene polymutant. The polymutant was moderately reduced in the elicitation of the HR and translocation of the T3SS effector AvrPto1 fused to a Cya translocation reporter, but the mutant was unaffected in the secretion of AvrPto1-Cya. The DC3000 hrpK1 gene encodes a putative translocator in the HrpF/NopX family and was deleted in combination with the four harpin genes. The hrpK1 quadruple harpin gene polymutant was strongly reduced in HR elicitation, virulence, and translocation of AvrPto1-Cya into plant cells but not in the secretion of representative T3SS substrates in culture. HrpK1, HrpZ1, HrpW1, and HopAK1, but not HopP1, were independently capable of restoring some HR elicitation to the hrpK1 quadruple harpin gene polymutant, which suggests that a consortium of semiredundant translocators from three protein classes cooperate to form the P. syringae T3SS translocon.     

Effect of Iron Concentration on the Growth Rate of Pseudomonas syringae and the Expression of Virulence Factors in hrp-Inducing Minimal Medium

Although chemically defined media have been developed and widely used to study the expression of virulence factors in the model plant pathogen Pseudomonas syringae, it has been difficult to link specific medium components to the induction response. Using a chemostat system, we found that iron is the limiting nutrient for growth in the standard hrp-inducing minimal medium and plays an important role in inducing several virulence-related genes in Pseudomonas syringae pv. tomato DC3000. With various concentrations of iron oxalate, growth was found to follow Monod-type kinetics for low to moderate iron concentrations. Observable toxicity due to iron began at 400 μM Fe³⁺. The kinetics of virulence factor gene induction can be expressed mathematically in terms of supplemented-iron concentration. We conclude that studies of induction of virulence-related genes in P. syringae should control iron levels carefully to reduce variations in the availability of this essential nutrient.The type III secretion system (T3SS) is used by diverse plant and animal pathogens to invade and colonize their hosts (1). This secretion system translocates bacterial proteins (effectors) from the bacterial cytoplasm directly into the eukaryotic host cell cytosol, where the effectors subvert host cell processes to the advantage of the pathogen. In Pseudomonas syringae pv. tomato DC3000, the T3SS is responsible for the elicitation of hypersensitive reactions of nonhost plants and is essential for disease on host plants (14). Many T3SS genes in plant pathogens are denoted hrp, for hypersensitive response and pathogenicity. We know of several regulatory elements that control T3SS genes in P. syringae pv. tomato DC3000 (7, 27), including HrpL, an alternative sigma factor. However, the exact environmental signals that the bacteria respond to are unknown.The expression of avrB, a T3SS effector, varies depending on the carbon source in Pseudomonas syringae pv. glycinea race 0 (9). Other environmental factors affecting the expression of virulence-related genes have also been studied. Nitrogen and osmolarity are important for the expression of the Pseudomonas syringae pv. syringae 61 hrp genes (28). Osmotic strength, pH, and carbon source differentially affected the expression of T3SS genes in Pseudomonas syringae pv. phaseolicola (18). These results imply that catabolite repression by the tricarboxylic acid cycle intermediates may be involved in the induction process. With other pathogenic bacteria, nutritional conditions are reported to be an important factor for the induction of virulence. For example, the Xanthomonas hrp genes are induced by sucrose and sulfur-containing amino acids (21). The optimal condition for hrp gene expression may simulate leaf apoplast environmental factors, including hypo-osmotic pressure, low pH, and limited nutrient concentration (18).Iron is a micronutrient (required in concentrations less than 10⁻⁴ M) for in vitro cultures (22), and the typical concentration needed for optimal bacterial growth is 0.3 to 1.8 μM (24). Iron is an essential element for bacteria due to its participation in the tricarboxylic acid cycle, electron transport, amino acid and pyrimidine biosynthesis, DNA synthesis, and other critical functions (3). Iron uptake must also be regulated due to its lethal effect through the Fenton reaction (2). The effect of iron limitation on bacterial growth has been documented for Escherichia coli cultures (6, 19, 20). Two studies have shown that production of the phytotoxins, syringomycin, and syringotoxin from P. syringae responds in batch culture to iron supplementation (5, 15). Iron is known to alter the physiology of other pseudomonads in both batch and chemostat cultures (11, 16). Although iron is the fourth most abundant element in the earth''s crust, its availability is very low due to its low solubility in aqueous solution ([Fe³⁺] at pH 7, 10⁻¹⁸ μM) (24). Bacteria have evolved complex mechanisms to ensure that iron requirements are met but not exceeded. Siderophore-mediated transport of iron is one of the mechanisms used by bacteria to uptake iron from their environment (17).In this study, medium components in hrp-inducing minimal medium were evaluated systematically with a chemostat culture. Iron was found to be both a growth-limiting nutrient in hrp-inducing minimal medium and a mediator of virulence gene expression in the model plant pathogen P. syringae pv. tomato DC3000.     

Multiple approaches to a complete inventory of Pseudomonas syringae pv. tomato DC3000 type III secretion system effector proteins

Pseudomonas syringae pv. tomato DC3000 is a pathogen of tomato and Arabidopsis that translocates virulence effector proteins into host cells via a type III secretion system (T3SS). Many effector-encoding hypersensitive response and pathogenicity (Hrp) outer protein (hop) genes have been identified previously in DC3000 using bioinformatic methods based on Hrp promoter sequences and characteristic N-terminal amino acid patterns that are associated with T3SS substrates. To approach completion of the Hop/effector inventory in DC3000, 44 additional candidates were tested by the Bordetella pertussis calmodulin-dependent adenylate cyclase (Cya) translocation reporter assay; 10 of the high-probability candidates were confirmed as T3SS substrates. Several previously predicted hop genes were tested for their ability to be expressed in an HrpL-dependent manner in culture or to be expressed in planta. The data indicate that DC3000 harbors 53 hop/avr genes and pseudogenes (encoding both injected effectors and T3SS substrates that probably are released to the apoplast); 33 of these genes are likely functional in DC3000, 12 are nonfunctional members of valid Hop families, and 8 are less certain regarding their production at functional levels. Growth of DC3000 in tomato and Arabidopsis Col-0 was not impaired by constitutive expression of repaired versions of two hops that were disrupted naturally by transposable elements or of hop genes that are naturally cryptic. In summary, DC3000 carries a complex mixture of active and inactive hop genes, and the hop genes in P. syringae can be identified efficiently by bioinformatic methods; however, a precise inventory of the subset of Hops that are important in pathogenesis awaits more knowledge based on mutant phenotypes and functions within plants.     

Bioinformatics-enabled identification of the HrpL regulon and type III secretion system effector proteins of Pseudomonas syringae pv. phaseolicola 1448A

The ability of Pseudomonas syringae pv. phaseolicola to cause halo blight of bean is dependent on its ability to translocate effector proteins into host cells via the hypersensitive response and pathogenicity (Hrp) type III secretion system (T3SS). To identify genes encoding type III effectors and other potential virulence factors that are regulated by the HrpL alternative sigma factor, we used a hidden Markov model, weight matrix model, and type III targeting-associated patterns to search the genome of P. syringae pv. phaseolicola 1448A, which recently was sequenced to completion. We identified 44 high-probability putative Hrp promoters upstream of genes encoding the core T3SS machinery, 27 candidate effectors and related T3SS substrates, and 10 factors unrelated to the Hrp system. The expression of 13 of these candidate HrpL regulon genes was analyzed by real-time polymerase chain reaction, and all were found to be upregulated by HrpL. Six of the candidate type III effectors were assayed for T3SS-dependent translocation into plant cells using the Bordetella pertussis calmodulin-dependent adenylate cyclase (Cya) translocation reporter, and all were translocated. PSPPH1855 (ApbE-family protein) and PSPPH3759 (alcohol dehydrogenase) have no apparent T3SS-related function; however, they do have homologs in the model strain P. syringae pv. tomato DC3000 (PSPTO2105 and PSPTO0834, respectively) that are similarly upregulated by HrpL. Mutations were constructed in the DC3000 homologs and found to reduce bacterial growth in host Arabidopsis leaves. These results establish the utility of the bioinformatic or candidate gene approach to identifying effectors and other genes relevant to pathogenesis in P. syringae genomes.     

The Pseudomonas syringae pv. tomato HrpW Protein Has Domains Similar to Harpins and Pectate Lyases and Can Elicit the Plant Hypersensitive Response and Bind to Pectate

The host-specific plant pathogen Pseudomonas syringae elicits the hypersensitive response (HR) in nonhost plants and secretes the HrpZ harpin in culture via the Hrp (type III) secretion system. Previous genetic evidence suggested the existence of another harpin gene in the P. syringae genome. hrpW was found in a region adjacent to the hrp cluster in P. syringae pv. tomato DC3000. hrpW encodes a 42.9-kDa protein with domains resembling harpins and pectate lyases (Pels), respectively. HrpW has key properties of harpins. It is heat stable and glycine rich, lacks cysteine, is secreted by the Hrp system, and is able to elicit the HR when infiltrated into tobacco leaf tissue. The harpin domain (amino acids 1 to 186) has six glycine-rich repeats of a repeated sequence found in HrpZ, and a purified HrpW harpin domain fragment possessed HR elicitor activity. In contrast, the HrpW Pel domain (amino acids 187 to 425) is similar to Pels from Nectria haematococca, Erwinia carotovora, Erwinia chrysanthemi, and Bacillus subtilis, and a purified Pel domain fragment did not elicit the HR. Neither this fragment nor the full-length HrpW showed Pel activity in A₂₃₀ assays under a variety of reaction conditions, but the Pel fragment bound to calcium pectate, a major constituent of the plant cell wall. The DNA sequence of the P. syringae pv. syringae B728a hrpW was also determined. The Pel domains of the two predicted HrpW proteins were 85% identical, whereas the harpin domains were only 53% identical. Sequences hybridizing at high stringency with the P. syringae pv. tomato hrpW were found in other P. syringae pathovars, Pseudomonas viridiflava, Ralstonia (Pseudomonas) solanacearum, and Xanthomonas campestris. ΔhrpZ::nptII or hrpW::ΩSp^r P. syringae pv. tomato mutants were little reduced in HR elicitation activity in tobacco, whereas this activity was significantly reduced in a hrpZ hrpW double mutant. These features of hrpW and its product suggest that P. syringae produces multiple harpins and that the target of these proteins is in the plant cell wall.     

Pseudomonas syringae HrpP Is a Type III Secretion Substrate Specificity Switch Domain Protein That Is Translocated into Plant Cells but Functions Atypically for a Substrate-Switching Protein

Pseudomonas syringae delivers virulence effector proteins into plant cells via an Hrp1 type III secretion system (T3SS). P. syringae pv. tomato DC3000 HrpP has a C-terminal, putative T3SS substrate specificity switch domain, like Yersinia YscP. A ΔhrpP DC3000 mutant could not cause disease in tomato or elicit a hypersensitive response (HR) in tobacco, but the HR could be restored by expression of HrpP in trans. Though HrpP is a relatively divergent protein in the T3SS of different P. syringae pathovars, hrpP from P. syringae pv. syringae 61 and P. syringae pv. phaseolicola 1448A restored HR elicitation and pathogenicity to DC3000 ΔhrpP. HrpP was translocated into Nicotiana benthamiana cells via the DC3000 T3SS when expressed from its native promoter, but it was not secreted in culture. N- and C-terminal truncations of HrpP were tested for their ability to be translocated and to restore HR elicitation activity to the ΔhrpP mutant. No N-terminal truncation completely abolished translocation, implying that HrpP has an atypical T3SS translocation signal. Deleting more than 20 amino acids from the C terminus abolished the ability to restore HR elicitation. HrpP fused to green fluorescent protein was no longer translocated but could restore HR elicitation activity to the ΔhrpP mutant, suggesting that translocation is not essential for the function of HrpP. No T3SS substrates were detectably secreted by DC3000 ΔhrpP except the pilin subunit HrpA, which unexpectedly was secreted poorly. HrpP may function somewhat differently than YscP because the P. syringae T3SS pilus likely varies in length due to differing plant cell walls.Many proteobacterial pathogens use a type III secretion system (T3SS) as their primary mechanism to overcome and infect eukaryotic hosts. T3SSs are complex macromolecular machines that span both the bacterial cell envelope and host cell barriers to deliver proteins, commonly termed effectors, from the bacterial cytoplasm into the host cytoplasm (13, 19). After delivery into the host, effector proteins manipulate host cell function and suppress host defenses, allowing bacterial proliferation and disease development (6, 20). Bacteria that rely on T3SS to cause disease include plant pathogens such as Pseudomonas syringae, Ralstonia solanacearum, Erwinia and Xanthomonas species and animal pathogens in the genera Yersinia, Salmonella, Shigella, Escherichia, and Pseudomonas. While the repertoire of effectors delivered by a given T3SS is unique, the T3SS machinery is more universal (13). T3SS includes a core set of eight conserved proteins. These proteins, which are also conserved in bacterial flagellar biogenesis machines, make up the multiringed base structure, or basal body, that spans the bacterial membranes and cell wall. T3SS machines are also comprised of less-conserved and unique proteins that vary between systems. These include regulatory proteins that orchestrate construction of the machine and the extracellular components that function to translocate effectors across host barriers.The extracellular portion of the T3SS is comprised of the pilus or needle appendage (in plant or animal pathogens, respectively), which acts as a conduit for effector delivery, and the translocon complex, which creates the pore in the host cell membrane. These substructures vary between different T3SSs; presumably these external structures have adapted to allow different bacteria to infect different types of host cells. For Yersinia enterocolitica to infect macrophage cells, the T3SS needle must be a particular length (∼58 nm) to bridge the lipopolysaccharides extending from the bacterial outer membrane and reach the host cell membrane (35). Several other animal pathogens have T3SS needles of a defined length (48). Enteropathogenic Escherichia coli also has an additional extension beyond the needle called the EspA filament that functions to span the mucous layer found outside enterocyte cells (13). In plant pathogens, however, the extracellular gap between a bacterium and a plant cell includes a thick plant cell wall that is variable in width between plant species. Consequently, plant pathogenic Pseudomonas syringae has a pilus that can measure over 1 μm in vitro (25).Another major difference between the T3SS machineries of animal and plant pathogens is their translocon complexes. In animal pathogens, these are typically comprised of three essential proteins, but there is growing evidence that plant pathogen translocons employ diverse, functionally redundant components (28). There is growing interest in understanding the regulatory players that orchestrate the construction of diverse machinery. It is hypothesized that the assembly of the T3SS must involve several tightly regulated steps that allow secretion of the required components, followed by that of effectors upon completion. Of particular interest here is the control of pilus/needle subunit secretion, which is necessary when the pilus/needle is being constructed but would presumably compete with translocon and effector secretion after the T3SS is complete.We study the model plant pathogen P. syringae pv. tomato (Pto) DC3000, the causal agent of bacterial speck of tomato and Arabidopsis thaliana (8). DC3000 has a T3SS that delivers ca. 28 effectors and is essential for pathogenesis (11, 12, 30, 43). The P. syringae T3SS is encoded by hrp and hrc genes (hypersensitive response and pathogenicity/conserved), which are located in a pathogenicity island on the chromosome (4). hrc genes encode the conserved core components present in every T3SS. hrp genes encode T3SS components that are divergent or unique to P. syringae and enterobacterial plant pathogens, which also possess Hrp1 class T3SS (13). In contrast, plant pathogenic Ralstonia and Xanthomonas spp. have Hrp2 class T3SS, as indicated by several different Hrp proteins and distinct regulatory systems.To better understand the T3SS machinery, we previously conducted a survey of the hrp genes of P. syringae pv. syringae (Psy) 61 to complete the inventory of all those encoding proteins capable of traveling the T3SS into plant cells when expressed from a constitutive promoter (39). We hypothesized that these proteins might aid in pilus or translocon construction or regulate the construction process. HrpP was one protein found to be a T3SS substrate and important for secretion and translocation of the model effector AvrPto. Importantly, HrpP is related to a well-studied protein from Yersinia enterocolitica, YscP, which is a T3SS-secreted protein and a regulator responsible for switching the T3SS from secreting needle subunits to secreting effector proteins (15, 38, 47). It has also been shown that secretion of YscP into the culture medium is not essential for the switch function and that there may be two type III secretion signals embedded in YscP (2).The phenotype of a yscP mutant is unregulated secretion of the needle subunit, no secretion of effectors, and production of needles of indeterminate length. The switching phenotype requires a domain at the C terminus of YscP called the type III secretion substrate specificity switch (T3S4) domain, which is a conserved feature unifying its homologs (1). YscP has been proposed to act as a molecular ruler because the length of the YscP protein is directly correlated with the length of the Ysc needle (26). According to this model, when the needle has reached its proper length, YscP signals to the T3SS machinery to stop secreting needle subunits and begin secreting effector proteins. However, other functional models have been hypothesized for homologs of YscP. A recent study of the Salmonella enterica serovar Typhimurium YscP homolog InvJ showed that an invJ mutant lacked an inner rod. When the inner rod protein PrgJ was overexpressed, the length of the needle decreased relative to that of the wild type, leading the researchers to conclude that InvJ controls the inner rod, which in turn controls needle length (33). Recent evidence in Yersinia has lent more support to this model. YscP was found to negatively control secretion of YscI, the inner rod protein (51). Also, certain YscI mutations affected needle assembly but not effector secretion, implying that YscI may be a key player in substrate switching. Little is known about HrpB, the inner rod homolog in P. syringae (22), other than that the protein can be translocated into plant cells and is essential for T3SS function (39).Other models for length control/substrate switching have been proposed, such as the “C-ring cup model” in flagella, which was based on the observation that certain mutations in proteins that make up the inner membrane C ring of the basal body lead to shorter hooks (the flagellar equivalent of the needle), thus suggesting that C-ring capacity controls hook length (32). A more recent, flagellar “molecular-clock” model suggests that because overexpression of hook subunits leads to longer hooks and hook polymerization-defective mutants make shorter hooks, hook polymerization initiates a countdown, and the timing, in cooperation with the YscP homolog FliK, determines final hook length (34).HrpP is considered a member of the YscP/FliK family due mostly to the presence of a T3S4 domain at its C terminus. HrpP is also proline rich (10.6%), which is considered a characteristic of the family. The most striking feature of HrpP is its small size; the protein is 189 amino acids, compared with YscP from Y. enterocolitica, which is 453 amino acids and 8.4% proline. We were intrigued by how HrpP functions in P. syringae to regulate a pilus that can measure several hundred nanometers in length. Also, unlike animal pathogen needles and flagellar hooks, the pilus of P. syringae is predicted to be indeterminate in length, based on the fact that plant cell walls vary in width between species (40).We hypothesized that HrpP would be a main player in regulating pilus construction in P. syringae by allowing the system to make the transition between secretion of pilus subunits and secretion of translocon or effector proteins, though perhaps by a novel mechanism. In this study, we more precisely define the role of HrpP in the P. syringae T3SS. We show that HrpP is a T3SS substrate in DC3000, is translocated into plant cells at levels equivalent to those of effectors, and is essential for the function of the T3SS. Though it is highly translocated and variable, we found that HrpP from different P. syringae pathovars could complement the DC3000 hrpP mutant. Analysis of truncations of HrpP and an impassible HrpP-green fluorescent protein (GFP) fusion suggests that it has structural similarities to YscP, but surprisingly, HrpP was found to be required for full secretion of the pilus subunit HrpA as well as for translocation of HrpB.     

Erwinia amylovora Secretes DspE, a Pathogenicity Factor and Functional AvrE Homolog, through the Hrp (Type III Secretion) Pathway

Erwinia amylovora was shown to secrete DspE, a pathogenicity factor of 198 kDa and a functional homolog of AvrE of Pseudomonas syringae pv. tomato. DspE was identified among the supernatant proteins isolated from cultures grown in an hrp gene-inducing minimal medium by immunodetection with a DspE-specific antiserum. Secretion required an intact Hrp pathway.     

Elucidation of the hrp Clusters of Xanthomonas oryzae pv. oryzicola That Control the Hypersensitive Response in Nonhost Tobacco and Pathogenicity in Susceptible Host Rice

Xanthomonas oryzae pv. oryzicola, the cause of bacterial leaf streak in rice, possesses clusters of hrp genes that determine its ability to elicit a hypersensitive response (HR) in nonhost tobacco and pathogenicity in host rice. A 27-kb region of the genome of X. oryzae pv. oryzicola (RS105) was identified and sequenced, revealing 10 hrp, 9 hrc (hrp conserved), and 8 hpa (hrp-associated) genes and 7 regulatory plant-inducible promoter boxes. While the region from hpa2 to hpaB and the hrpF operon resembled the corresponding genes of other xanthomonads, the hpaB-hrpF region incorporated an hrpE3 gene that was not present in X. oryzae pv. oryzae. We found that an hrpF mutant had lost the ability to elicit the HR in tobacco and pathogenicity in adult rice plants but still caused water-soaking symptoms in rice seedlings and that Hpa1 is an HR elicitor in nonhost tobacco whose expression is controlled by an hrp regulator, HrpX. Using an Hrp phenotype complementation test, we identified a small hrp cluster containing the hrpG and hrpX regulatory genes, which is separated from the core hrp cluster. In addition, we identified a gene, prhA (plant-regulated hrp), that played a key role in the Hrp phenotype of X. oryzae pv. oryzicola but was neither in the core hrp cluster nor in the hrp regulatory cluster. A prhA mutant failed to reduce the HR in tobacco and pathogenicity in rice but caused water-soaking symptoms in rice. This is the first report that X. oryzae pv. oryzicola possesses three separate DNA regions for HR induction in nonhost tobacco and pathogenicity in host rice, which will provide a fundamental base to understand pathogenicity determinants of X. oryzae pv. oryzicola compared with those of X. oryzae pv. oryzae.     

Bioinformatics Analysis of the Complete Genome Sequence of the Mango Tree Pathogen Pseudomonas syringae pv. syringae UMAF0158 Reveals Traits Relevant to Virulence and Epiphytic Lifestyle

The genome sequence of more than 100 Pseudomonas syringae strains has been sequenced to date; however only few of them have been fully assembled, including P. syringae pv. syringae B728a. Different strains of pv. syringae cause different diseases and have different host specificities; so, UMAF0158 is a P. syringae pv. syringae strain related to B728a but instead of being a bean pathogen it causes apical necrosis of mango trees, and the two strains belong to different phylotypes of pv.syringae and clades of P. syringae. In this study we report the complete sequence and annotation of P. syringae pv. syringae UMAF0158 chromosome and plasmid pPSS158. A comparative analysis with the available sequenced genomes of other 25 P. syringae strains, both closed (the reference genomes DC3000, 1448A and B728a) and draft genomes was performed. The 5.8 Mb UMAF0158 chromosome has 59.3% GC content and comprises 5017 predicted protein-coding genes. Bioinformatics analysis revealed the presence of genes potentially implicated in the virulence and epiphytic fitness of this strain. We identified several genetic features, which are absent in B728a, that may explain the ability of UMAF0158 to colonize and infect mango trees: the mangotoxin biosynthetic operon mbo, a gene cluster for cellulose production, two different type III and two type VI secretion systems, and a particular T3SS effector repertoire. A mutant strain defective in the rhizobial-like T3SS Rhc showed no differences compared to wild-type during its interaction with host and non-host plants and worms. Here we report the first complete sequence of the chromosome of a pv. syringae strain pathogenic to a woody plant host. Our data also shed light on the genetic factors that possibly determine the pathogenic and epiphytic lifestyle of UMAF0158. This work provides the basis for further analysis on specific mechanisms that enable this strain to infect woody plants and for the functional analysis of host specificity in the P. syringae complex.     

Whole-genome expression profiling defines the HrpL regulon of Pseudomonas syringae pv. tomato DC3000, allows de novo reconstruction of the Hrp cis clement, and identifies novel coregulated genes

Pseudomonas syringae pv. tomato DC3000 is a model pathogen of tomato and Arabidopsis that uses a hypersensitive response and pathogenicity (Hrp) type III secretion system (T3SS) to deliver virulence effector proteins into host cells. Expression of the Hrp system and many effector genes is activated by the HrpL alternative sigma factor. Here, an open reading frame-specific whole-genome microarray was constructed for DC3000 and used to comprehensively identify genes that are differentially expressed in wild-type and deltahrpL strains. Among the genes whose differential regulation was statistically significant, 119 were upregulated and 76 were downregulated in the wild-type compared with the deltahrpL strain. Hierarchical clustering revealed a subset of eight genes that were upregulated particularly rapidly. Gibbs sampling of regions upstream of HrpL-activated operons revealed the Hrp promoter as the only identifiable regulatory motif and supported an iterative refinement involving real-time polymerase chain reaction testing of additional HrpL-activated genes and refinements in a hidden Markov model that can be used to predict Hrp promoters in P. syringae strains. This iterative bioinformatic-experimental approach to a comprehensive analysis of the HrpL regulon revealed a mix of genes controlled by HrpL, including those encoding most type III effectors, twin-arginine transport (TAT) substrates, other regulatory proteins, and proteins involved in the synthesis or metabolism of phytohormones, phytotoxins, and myo-inositol. This analysis provides an extensively verified, robust method for predicting Hrp promoters in P. syringae genomes, and it supports subsequent identification of effectors and other factors that likely are important to the host-specific virulence of P. syringae.     

Differential metabolomic responses of PAMP-triggered immunity and effector-triggered immunity in Arabidopsis suspension cells

Introduction

The rhizobacterial tomato pathogen Pseudomonas syringae pv. tomato str. DC3000 (PstDC3000), like many plant pathogenic bacteria, can elicit hypersensitive response in non-host plant cells. PstDC3000 uses a type III protein secretion system (T3SS) to deliver effector proteins.

Objectives

We compared metabolomic responses of Arabidopsis suspension cells to a wild-type PstDC3000, a T3SS deletion mutant PstDC3000D28E, and a pathogen associated molecular pattern (PAMP) flagellin’s N-terminal domain’s 22-aa peptide (flg22) to obtain metabolomics insights into the plant cell PAMP-triggered immunity (PTI) and effector-triggered immunity (ETI).

Methods

Using targeted HPLC-MRM-MS and untargeted GC-MS approaches, we monitored qualitative and quantitative changes of 312 metabolites in central and specialized metabolic pathways in a time-course study.

Results

The overall metabolomic changes induced by the three treatments included phenylpropanoid, flavonoid, and phytohormone biosynthetic pathways, as well as primary metabolism in amino acid and sugar biosynthesis. In addition to shared metabolites, flg22, PstDC3000D28E and PstDC3000 each caused unique metabolite changes in the course of the development of PTI and ETI.

Conclusion

PstDC3000D28E triggered PTI responses were different from those of flg22. This study has not only revealed the discernible metabolomics features associated with the flg22, PstDC3000D28E and PstDC3000 treatments, but also laid a foundation toward further understanding of metabolic regulation and responses underlying plant PTI and ETI.

     

In silico analysis reveals multiple putative type VI secretion systems and effector proteins in Pseudomonas syringae pathovars

Type VI secretion systems (T6SS) of Gram-negative bacteria form injectisomes that have the potential to translocate effector proteins into eukaryotic host cells. In silico analysis of the genomes in six Pseudomonas syringae pathovars revealed that P. syringae pv. tomato DC3000, pv. tabaci ATCC 11528, pv. tomato T1 and pv. oryzae 1-6 each carry two putative T6SS gene clusters (HSI-I and HSI-II; HSI: Hcp secretion island), whereas pv. phaseolicola 1448A and pv. syringae B728 each carry one. The pv. tomato DC3000 HSI-I and pv. tomato T1 HSI-II possess a highly similar organization and nucleotide sequence, whereas the pv. tomato DC3000, pv. oryzae 1-6 and pv. tabaci 11528 HSI-II are more divergent. Putative effector orthologues vary in number among the strains examined. The Clp-ATPases and IcmF orthologues form distinct phylogenetic groups: the proteins from pv. tomato DC3000, pv. tomato T1, pv. oryzae and pv. tabaci 11528 from HSI-II group together with most orthologues from other fluorescent pseudomonads, whereas those from pv. phaseolicola, pv. syringae, pv. tabaci, pv. tomato T1 and pv. oryzae from HSI-I group closer to the Ralstonia solanacearum and Xanthomonas orthologues. Our analysis suggests multiple independent acquisitions and possible gene attrition/loss of putative T6SS genes by members of P. syringae.     

Analysis of the Role of the Type III Effector Inventory of Pseudomonas syringae pv. phaseolicola 1448a in Interaction with the Plant

In Pseudomonas syringae, the type III secretion system (T3SS) is essential for disease in compatible hosts and for eliciting the hypersensitive response in incompatible hosts. P. syringae pathovars secrete a variable number of type III effectors that form their secretomes. The secretome of Pseudomonas syringae pv. phaseolicola 1448a (Pph1448a) currently includes 22 experimentally validated effectors, one HrpL-regulated candidate for which translocation results have been inconsistent, two translocated candidates for which in planta expression has not been established, one bioinformatically identified candidate, and six candidates that have been experimentally discarded. We analyzed the translocation and/or expression of these and other candidates to complete the Pph1448a effector inventory, bringing this inventory to 27 bona fide effectors, including a new one that does not belong to any of the previously described effector families. We developed a simple process for rapidly making single and double knockout mutants and apply it to the generation of an effector mutant collection that includes single knockouts for the majority of the Pph1448a effector inventory. We also generated two double mutant strains containing effectors with potentially redundant functions and analyzed the virulence of the single and double mutant strains as well as strains expressing each of the effectors from a plasmid. We demonstrate that AvrB4-1 and AvrB4-2, as well as HopW1-1 and HopW1-2, are fully redundant and contribute to virulence in bean plants, thus validating this approach for dissecting the contribution of the Pph1448a type III effector inventory to virulence. We also analyzed the effect that the expression of these four effectors from Pseudomonas syringae pv. tomato DC3000 (PtoDC3000) has during its interaction with Arabidopsis thaliana, establishing that AvrB4-1, but not the others, determines a restriction of bacterial growth that takes place mostly independently of the salicylic acid (SA)-signaling pathway.Type III secretion systems (T3SS) are complex and specialized machineries that inject effector proteins directly into the host cell cytosol (2). In Pseudomonas syringae, T3SS-mediated secretion is essential for disease in compatible hosts and for eliciting the hypersensitive response (HR) in incompatible hosts (1). P. syringae pathovars secrete a variable number of type III effectors that form their so-called secretomes and are expressed within the plant under the control of the alternative sigma factor HrpL (47). Understanding how the T3SS determines pathogenicity requires the functional characterization of the complete type III effector inventory. However, this characterization has been partially hindered by the fact that mutation of individual effectors, usually the most straightforward approach, rarely causes virulence attenuation (14). Thus, reports showing the contribution of the type III effector to virulence in P. syringae pathovars have resorted to ectopic expression in homolog-lacking related strains (40), plasmid-cured derivatives (21), double mutants (6, 28), or polymutants (3, 26). In relation to this, we have previously established the use of the competitive index (CI) in mixed infections (13, 42) as a more sensitive virulence assay for P. syringae pathovars than traditional assays (31). Using CIs, we demonstrated for the first time the individual contribution of AvrPto, an otherwise thoroughly characterized type III effector from Pseudomonas syringae pv. tomato (9, 17, 18, 27, 36, 39, 40, 46), to pathogen growth within its natural host (31). Therefore, analysis of effector mutants by use of the CI may provide the means to establish the quantitative contribution of the members of P. syringae T3SS secretomes to virulence. In addition, genetic analysis of the effects of combinations of effector mutations on virulence has already proven a useful approach to establishing the contribution of the members of the P. syringae pv. tomato DC3000 secretome to virulence by revealing a functional overlap (6, 26, 28). Thus, generation of knockouts in all individual effector genes of a given secretome, achieved in such a manner as to allow for easy combination of these strains into double or multiple mutant strains, is a desirable task, albeit a cumbersome one, considering the size of most secretomes.The secretome of the fully sequenced wild-type (wt) representative of the Pseudomonas syringae pv. phaseolicola 1448a strain (Pph1448a) has previously been analyzed, using a differential fluorescence induction screen (7) and bioinformatics (44), to identify effector genes. Our laboratory contributed to establishing this secretome through the development and application of a very sensitive assay for T3SS-mediated translocation based on CI assays (30). This assay represents an improvement over the sensitivity of the commonly used AvrRpt2 reporter assay. When fused to a T3SS-secreted protein, AvrRpt2^81-255 is translocated inside the host cell, eliciting a hypersensitive response (HR), dependent on the resistance protein RPS2 (32). By using CIs to measure the bacterial growth reduction associated with the AvrRpt2-RPS-mediated defense response, we detected translocation for two out of four Pph1448a effector candidates previously discarded by other assays, HopAJ1 and HopAK1 (30), and demonstrated translocation for two out of five previously untested candidates, HopAH2 and A0129. However, although in planta expression has been shown to take place in an HrpL-dependent manner for HopAJ1 and HopAK1 (7), it has not been established for HopAH2 and A0129. Effector nomenclature guidelines recommend that the abbreviation for the pathovars as well as the name of the strain should be included within the effector name (29). For simplicity, we include this indication only when effectors from other pathovars are mentioned. In summary, to date, 22 effectors in Pph1448a have been experimentally validated (7, 30, 44), one HrpL-regulated candidate has given inconsistent translocation results (AvrE1) (7), two translocated candidates have not been analyzed for expression in planta (HopAH2 and A0129) (30), one bioinformatically identified candidate has not been experimentally tested (AvrB4-2) (23), and six additional candidates have been proposed but experimentally ruled out (PSPPH3757, HopAN1, HopAJ2, HopW1-2, HopV1, and HopJ1) (7, 30).In this work, we analyzed the translocation and/or expression of these and other candidate effectors to close the type III effector inventory of Pph1448a. Our results indicate that the Pph1448a complete type III secretome is formed by 27 validated effectors, including a new one, HopAY1, which does not belong to any of the previously described effector families. The work includes the development of a simplified process for quick generation of single and double knockout mutants and its application to constructing a collection of single mutants for almost all members of the Pph1448a type III secretome. Additionally, we generated two double mutant strains containing effectors with potentially redundant functions and analyzed the virulence of the four single and two double mutant strains as well as the double mutants expressing each of the effectors from a plasmid. We demonstrate that AvrB4-1 and AvrB4-2, as well as HopW1-1 and HopW1-2, are fully redundant and contribute to the virulence of Pph1448a. The tools and approach used in this work set the groundwork for dissecting the contribution of the entire Pph1448a type III secretome to virulence.     

A Pseudomonas syringae pv. tomato avrE1/hopM1 mutant is severely reduced in growth and lesion formation in tomato

The model plant pathogen Pseudomonas syringae pv. tomato DC3000 grows and produces necrotic lesions in the leaves of its host, tomato. Both abilities are dependent upon the hypersensitive response and pathogenicity (Hrp) type III secretion system (TTSS), which translocates multiple effector proteins into plant cells. A previously constructed DC3000 mutant with a 9.3-kb deletion in the Hrp pathogenicity island conserved effector locus (CEL) was strongly reduced in growth and lesion formation in tomato leaves. The ACEL mutation affects three putative or known effector genes: avrE1, hopM1, and hopAA1-1. Comparison of genomic sequences of DC3000, P. syringae pv. phaseolicola 1448A, and P. syringae pv. syringae B728a revealed that these are the only effector genes present in the CEL of all three strains. AvrEl was shown to carry functional TTSS translocation signals based on the performance of a fusion of the first 315 amino acids of AvrE1 to the Cya translocation reporter. A DC3000 delta avrE1 mutant was reduced in its ability to produce lesions but not in its ability to grow in host tomato leaves. AvrE1 expressed from the 35S promoter elicited cell death in nonhost Nicotiana tabacum leaves and host tomato leaves in Agrobacterium-mediated transient expression experiments. Mutations involving combinations of avrE1, hopM1, and hopAA1-1 revealed that deletion of both avrE1 and hopM1 reproduced the strongly reduced growth and lesion phenotype of the delta CEL mutant. Furthermore, quantitative assays involving different levels of inoculum and electrolyte leakage revealed that the avrE1/hopM1 and deltaCEL mutants both were partially impaired in their ability to elicit the hypersensitive response in nonhost N. benthamiana leaves. However, the avrE1/hopM1 mutant was not impaired in its ability to deliver AvrPto1(1-100)-Cya to nonhost N. benthamiana or host tomato leaves during the first 9 h after inoculation. These data suggest that AvrE1 acts within plant cells and promotes lesion formation and that the combined action of AvrE1 and HopM1 is particularly important in promoting bacterial growth in planta.     

Plant Immunity Directly or Indirectly Restricts the Injection of Type III Effectors by the Pseudomonas syringae Type III Secretion System

Plants perceive microorganisms by recognizing microbial molecules known as pathogen-associated molecular patterns (PAMPs) inducing PAMP-triggered immunity (PTI) or by recognizing pathogen effectors inducing effector-triggered immunity (ETI). The hypersensitive response (HR), a programmed cell death response associated with ETI, is known to be inhibited by PTI. Here, we show that PTI-induced HR inhibition is due to direct or indirect restriction of the type III protein secretion system''s (T3SS) ability to inject type III effectors (T3Es). We found that the Pseudomonas syringae T3SS was restricted in its ability to inject a T3E-adenylate cyclase (CyaA) injection reporter into PTI-induced tobacco (Nicotiana tabacum) cells. We confirmed this restriction with a direct injection assay that monitored the in planta processing of the AvrRpt2 T3E. Virulent P. syringae strains were able to overcome a PAMP pretreatment in tobacco or Arabidopsis (Arabidopsis thaliana) and continue to inject a T3E-CyaA reporter into host cells. In contrast, ETI-inducing P. syringae strains were unable to overcome PTI-induced injection restriction. A P. syringae pv tomato DC3000 mutant lacking about one-third of its T3E inventory was less capable of injecting into PTI-induced Arabidopsis plant cells, grew poorly in planta, and did not cause disease symptoms. PTI-induced transgenic Arabidopsis expressing the T3E HopAO1 or HopF2 allowed higher amounts of the T3E-CyaA reporter to be injected into plant cells compared to wild-type plants. Our results show that PTI-induced HR inhibition is due to direct or indirect restriction of T3E injection and that T3Es can relieve this restriction by suppressing PTI.Plants come into contact with a myriad of microorganisms and rely on their innate immune systems to perceive potential microbial infections and induce immune responses. Plant innate immunity can be broadly portrayed as consisting of two major branches, distinguished primarily by their mode of microbe detection. The first branch is activated by extracellular pattern recognition receptors (Boller and Felix, 2009; Nicaise et al., 2009) that perceive broadly conserved molecules called pathogen (microbe)-associated molecular patterns (PAMPs; Medzhitov and Janeway, 1997; Ausubel, 2005). The response induced by this recognition is termed PAMP-triggered immunity (PTI; Jones and Dangl, 2006). A well-characterized example of PTI in plants is the recognition of and subsequent immune response to a small N-terminal region of bacterial flagellin by the FLS2 receptor kinase of Arabidopsis (Arabidopsis thaliana; Felix et al., 1999; Zipfel et al., 2004). Plant resistance (R) proteins activate the second branch of the plant innate immune system by recognizing specific pathogen effector proteins. The response induced by this recognition is termed effector-triggered immunity (ETI; Jones and Dangl, 2006). ETI and PTI induce similar innate immune responses, including ion fluxes, reactive oxygen species (ROS), and callose (β-1,3-glucan) deposition in the cell wall (Tsuda et al., 2008; Boller and Felix, 2009); however, ETI generally also includes the induction of a programmed cell death called the hypersensitive response (HR; Heath, 2000).The induction of ETI in response to a bacterial plant pathogen is generally due to the recognition of bacterial type III effector (T3E) proteins injected into the plant cell by the pathogen''s type III protein secretion system (T3SS; Alfano and Collmer, 1997; Buttner and He, 2009). These recognized T3Es were classically known as avirulence (Avr) proteins because they induced ETI responses sufficient to prevent a normally virulent pathogen from causing disease, thereby rendering it avirulent (Leach and White, 1996). However, it has become increasingly apparent that many T3Es benefit their bacteria by suppressing PTI and ETI (Block et al., 2008; Cui et al., 2009; Guo et al., 2009). Under the current model, plants first developed PTI to reduce microbial colonization of the apoplast. Successful bacterial pathogens countered this by acquiring a T3SS and PTI-suppressing T3Es (Espinosa and Alfano, 2004; Chisholm et al., 2006; Jones and Dangl, 2006).The bacterial pathogen Pseudomonas syringae infects the aerial parts of many plant species. It displays host specificity, and its strains have been separated into more than 50 pathovars based on the host plants that they infect. For example, P. syringae pv tabaci is virulent in tobacco (Nicotiana tabacum), but it triggers nonhost resistance in Arabidopsis, a plant-microbe interaction referred to as a nonhost interaction. Nonhost resistance describes the resistance observed when all members of a plant species are resistant to a specific pathogen (Thordal-Christensen, 2003; Mysore and Ryu, 2004). While not well understood, both PTI (Li et al., 2005) and ETI (Nissan et al., 2006; Wei et al., 2007) have been shown to play a role in nonhost resistance to bacterial pathogens. In some cases, P. syringae strains display race cultivar resistance. This is generally due to the resistant cultivar possessing an R protein that can recognize a T3E from the pathogen inducing ETI (Bent and Mackey, 2007). One well-studied P. syringae strain is P. syringae pv tomato DC3000, which causes bacterial speck disease on specific tomato (Solanum lycopersicum) cultivars and disease on all ecotypes of Arabidopsis tested. These interactions have been classically referred to as compatible interactions. However, DC3000 triggers nonhost resistance in tobacco and many other plants.DC3000 contains more than 30 T3Es (Lindeberg et al., 2006; Cui et al., 2009; Cunnac et al., 2009). These are encoded by genes contained within the Hrp pathogenicity island, which also encodes the T3SS apparatus (Alfano et al., 2000), other pathogenicity islands, or as individual genes throughout the genome of DC3000 (Buell et al., 2003; Wei et al., 2007). One molecular tool that has been useful in studying the effect individual T3Es have on plants is the cosmid pHIR11 (Huang et al., 1988). This cosmid encodes a functional T3SS from P. syringae pv syringae 61 and the T3E HopA1. It confers upon nonpathogenic bacteria, such as Pseudomonas fluorescens, the ability to inject HopA1 into plant cells. In tobacco and other plants, injected HopA1 induces ETI, including an HR (Huang et al., 1988; Alfano et al., 1997). The expression of other T3Es in P. fluorescens(pHIR11) enabled them to be screened for the ability to suppress HopA1-induced ETI (Jamir et al., 2004; Guo et al., 2009). Bacterial strains carrying the pHIR11 derivatives pLN18 or pLN1965, both of which lack hopA1 and so no longer induce ETI, were used to determine which T3Es could suppress PTI (Oh and Collmer, 2005; Guo et al., 2009). Collectively, these experiments demonstrated that many P. syringae T3Es possessed the ability to suppress both ETI and PTI.One PTI suppression assay using P. fluorescens(pLN18) employed by Oh and Collmer (2005) took advantage of earlier observations indicating that PTI could inhibit the ability of the plant to mount an HR in response to an ETI-inducing bacterial strain (Newman et al., 2000; Klement et al., 2003). In this assay, the PTI inducers P. fluorescens(pLN18) or a 22-amino-acid peptide from flagellin (flg22) are infiltrated into Nicotiana benthamiana. Six hours later, the ETI inducer DC3000 is infiltrated in a region of the leaf that overlaps with the earlier infiltration. The HR is typically inhibited in the overlapping region that was pretreated with a PTI inducer. Several T3Es suppressed this inhibition when they were separately delivered at time of pretreatment (Oh and Collmer, 2005). It has been speculated that the probable mechanisms for inhibition of the HR caused by PTI include impairment of delivery of T3Es that induce the HR, modification of the events downstream of T3E recognition, or a shutdown of programmed cell death (Newman et al., 2000).Here, we show that PTI inhibits the HR on tobacco because it directly or indirectly restricts the ability of P. fluorescens(pLN1965) or DC3000 to inject T3Es based on injection (translocation) assays using T3E-adenylate cyclase (CyaA) fusions. This was confirmed using an independent injection assay that monitored the amount of the cleaved in planta form of the T3E AvrRpt2. Interestingly, this injection restriction was greatly reduced in the compatible interactions between DC3000 and Arabidopsis or between P. syringae pv tabaci 11258 and tobacco. A DC3000 mutant lacking four clusters of T3E genes, which corresponds to 11 T3Es, was less able to inject a T3E-CyaA fusion into PTI-induced Arabidopsis, suggesting that the PTI suppressing activities of the T3E inventory of DC3000 allow it to overcome the injection restriction. Transgenic Arabidopsis plants separately expressing specific T3Es known to be capable of PTI suppression increased the ability of P. fluorescens(pLN1965) to inject a T3E-CyaA fusion into PTI-induced plant cells. Collectively, these data suggest that PTI can directly or indirectly restrict type III injection and PTI suppression by T3Es can relieve this restriction in susceptible plant cells but not plant cells undergoing ETI.