Project description:Pseudomonas syringae uses HrpRSL to regulate the expression of type III secretion system (T3SS) genes and bacterial virulence. However, the molecular mechanism and the regulons of HrpRSL have yet to be fully elucidated. Here, we performed chromatin immunoprecipitation followed by high-throughput DNA sequencing (ChIP-seq) on HrpRSL and Lon. The direct regulation of these genes by corresponding regulator has been confirmed by Electrophoretic mobility shift assays (EMSAs) and quantitative real-time polymerase chain reactions (qRT-PCR). Binding motifs are found by using MEME suite and verified by footprint assays in vitro. Collectively, this work provides new cues to better understand the detailed regulatory networks of T3SS systems in P. syringae. ChIP-seq analysis of HrpRSL and Lon in Pseudomonas syringas

Project description:Pseudomonas syringae uses two-component system RhpRS to regulate the expression of type III secretion system (T3SS) genes and bacterial virulence. However, the molecular mechanism and the regulons of RhpRS have yet to be fully elucidated. Here we show that RhpS functions as an autokinase, an RhpR kinase, and a P-RhpR phosphatase. RhpR can also be phosphorylated by small phosphodonor acetyl phosphate. A specific RhpR-binding site containing an inverted repeat (IR) motif GTATC-N6-GATAC, was mapped to its own promoter by DNase I footprint analysis. Electrophoretic mobility shift assay (EMSA) indicated that P-RhpR has higher binding activity than RhpR to the IR motif. To identify additional targets of RhpR in P. syringae, we performed chromatin immunoprecipitation followed by high-throughput DNA sequencing (ChIP-seq), which detected 167 enriched loci including the hrpR promoter, indicating the direct regulation of T3SS cascade genes by RhpR. Genome-wide microarray analysis showed that, besides the T3SS cascade genes, RhpR differentially regulates a large set of genes of various functions in response to different growth conditions. Together, these results suggested that RhpRS is a global regulator that allows P. syringae to sense and respond to environmental changes to coordinate the T3SS and many other biological processes.

Project description:Pseudomonas syringae pv. aptata is a member of the sugar beet pathobiome and the causative agent of leaf spot disease. Like many pathogenic bacteria, P. syringae relies on the secretion of toxins, which manipulate host-pathogen interactions, to establish and maintain an infection. This study analyzes the secretome of six pathogenic P. syringae pv. aptata strains with different defined virulence capacities in order to identify common and strain-specific features, and correlate the secretome with disease outcome. All strains show a high type III secretion system (T3SS) and type VI secretion system (T6SS) activity under apoplast-like conditions mimicking the infection. Surprisingly, we found that low pathogenic strains show a higher secretion of most T3SS substrates (19 of the 23 detected effectors and accessory harpin proteins), whereas a distinct subgroup of four effectors is exclusively secreted in medium and high pathogenic strains. Similarly, we detected two T6SS secretion patterns: while one set of proteins was highly secreted in all strains, another subset consisting of known T6SS substrates and previously uncharacterized proteins with a highly similar secretion pattern was exclusively secreted in medium and high virulence strains. Taken together, our data shows that P. syringae pathogenicity is correlated with the repertoire and fine-tuning of effector secretion and indicates distinct strategies for establishing virulence of P. syringae pv. aptata in plants.

Project description:Disease resistance in plants depends on a molecular dialogue with microbes that involves many known chemical effectors, but the time course of the interaction and the influence of the environment are largely unknown. The outcome of host–pathogen interactions is thought to reflect the offensive and defensive capabilities of both players. When plants interact with Pseudomonas syringae, several well-characterized virulence factors contribute to early bacterial pathogenicity, including the type III secretion system (T3SS), which must be activated by signals from the plant and environment to allow the secretion of virulence effectors. The manner in which these signals regulate T3SS activity is still unclear. Here, we strengthen the paradigm of the plant–pathogen molecular dialogue by addressing overlooked details concerning the timing of interactions, specifically the role of plant signals and temperature on the regulation of bacterial virulence during the first few hours of the interaction. Whole-genome expression profiling after 1 h revealed that the perception of plant signals from kiwifruit or tomato extracts anticipates T3SS expression in P. syringae pv. actinidiae compared to apoplast-like conditions, facilitating more efficient effector transport in planta, as revealed by the induction of a temperature-dependent hypersensitive response in the non-host plant Arabidopsis thaliana Col-0. Our results show that, in the arms race between plants and bacteria, the temperature-dependent timing of bacterial virulence versus the induction of plant defenses is probably one of the fundamental parameters governing the outcome of the interaction.

Project description:The type III secretion system (T3SS) is the main machinery for Pseudomonas syringae and other Gram-negative bacteria to invade plant cells. HrpR/HrpS heterodimer are key factors to activate HrpL which induces all T3SS genes by binding to a ‘hrp box’ in promoters. However, the molecular mechanisms of HrpRS on T3SS or non-T3SS genes have not been fully understood. Following by chromatin immunoprecipitation coupled to high-throughput DNA sequencing (ChIP-seq), we found that HrpRSL had 8, 38, and 36 targets on the genome, respectively. HrpS directly bound to the promoter regions of T3SS genes (hrpK1, hrpA2 and hopAJ1) as well as a group of non-T3SS genes (PSPPH_1496, PSPPH_1525, PSPPH_3494 and PSPPH_3495). Subsequent biochemical and genetic assays showed that HrpS independently regulated these genes in a hrpL deletion strain. In addition, a HrpS-binding motif (GTGCCAAA) in the hrpL promoter was identified by truncation, which was verified by EMSA in vitro and lux-reporter assay in vivo. On the contrary, HrpR alone couldn’t activate hrpL. Overall, our results demonstrated that HrpS directly regulated a group of T3SS and non-T3SS genes, which is independent on HrpL. HrpS functions as the center of the regulatory cascade in T3SS. This work deciphered the key HrpRSL-T3SS regulatory network, which provides insights to develop new strategies to control P. syringae infection in the future.

Project description:Pseudomonas syringae pv. phaseolicola is the causal agent of halo blight disease of beans (Phaseolus vulgaris L.), which is characterized by water-soaked lesions surrounded by a chlorotic halo resulting from the action of a non-host-specific toxin known as phaseolotoxin, that inhibits the enzyme ornithine carbamoyltransferase involved in the arginine biosynthesis pathway. It was previously reported that genes within the Pht cluster were involved in the regulation and synthesis of phaseolotoxin. The GacS/GacA two component signal transduction system controls important pathogenicity and virulence mechanisms in several Gram-negative bacteria. In the present study we hybridized a genomic microarray of P. syringae pv. phaseolicola NPS3121 to compare transcriptional profiles from wild type strain and a gacA- null mutant with a Tox- 11 phenotype. Results show that GacA controls expression of genes within the Pht cluster as well as another group of clustered genes located in a 13 different region in the bacterial chromosome that contains at least one gene unambiguously shown to be directly involved in phaseolotoxin biosynthesis. Results suggest that this cluster is a new pathogenicity island containing genes whose regulation is also under GacA regulatory cascade and it will require further investigation to determine gene functions and their relationship to virulence mechanisms Transcriptional profiles of a P. syringae pv. phaseolicola NPS3121 null gacA mutant were compared to those of the wild-type strain. Cultures were grown in minimal medium at 18°C (which is the temperature at which phaseolotoxin is produced and the bacteria achieves full virulence) and harvested during the late log phase of the exponential growth. RNA from three biological replicates and each with two technical replicates were hybridize to control variation that might affect data interpretation.

Project description:Pseudomonas syringae, a Gram-negative plant pathogen, infects more than 50 crops with its type III secretion system (T3SS) and causes severe economic losses around the world. Although the mechanisms of virulence-associated regulators of P. syringae T3SS have been studied for decades, the crosstalk and network underlying these regulators are still elusive. Previously, we have individually studied a group of T3SS regulators, including AefR, HrpS, and RhpRS. In the present study, we found 4 new T3SS regulator genes (envZ, ompR, tsiS and phoQ) via transposon-mediated mutagenesis. Two-component systems EnvZ and TsiS natively regulate T3SS. In order to uncover the crosstalk between 16 virulence-associated regulators, (including AefR, AlgU, CvsR, GacA, HrpL, HrpR, HrpS, MgrA, OmpR, PhoP, PilR, PsrA, RhpR, RpoN, TsiR and Vfr) in P. syringae, we mapped an intricate network named PSVnet (Pseudomonas syringae Virulence Regulatory Network) by combining differentially expression genes in RNA-seq and binding loci in ChIP-seq of all regulators.

Project description:In response to osmolarity, Salmonella enterica serotype Typhi (S. Typhi) regulates genes required for Vi capsular antigen expression oppositely to those required for motility and invasion. Previous studies suggest that osmoregulation of motility, invasion and capsule expression is mediated through the RcsC/RcsD/RcsB phosphorelay system. Here we performed gene expression profiling and functional studies to determine the role of TviA, an auxiliary protein of the RcsB response regulator, in controlling virulence gene expression in S. Typhi. TviA repressed expression of genes encoding flagella and the invasion associated type III secretion system (T3SS-1) through repression of the flagellar regulators flhDC and fliZ, resulting in reduced invasion and reduced expression of FliC. Both RcsB and TviA reduced expression of flhDC, but only TviA altered flhDC expression in response to osmolarity. These data suggest that the auxiliary TviA protein integrates a new regulatory input into the RcsB regulon of S. Typhi, thereby altering expression of genes encoding flagella, the Vi antigen and T3SS-1 in response to osmolarity. Gene expression profiles of the S. Typhi wild-type strain, a rcsB mutant, a (delta)tviB-vexE (tviBCDEvexABCDE) mutant, and a (delta)viaB (tviABCDEvexABCDE) mutant (lacking tviA expression) was compared. Strains were cultured in SOB broth (low salt), a condition known to induce expression of TviA and the RcsCB system. Total RNA was extracted from two independent cultures (biological replicates) of each strain. cDNA was differentially labeled with Alexa Fluor 555 and 648, respectively and competitively hybridized on S.Typhimurium arrays (PFGRC, version 4). The submitted samples are biological replicates of a competitive hybridization of cDNA from the wild-type strain (Ty2) and the rcsB mutant (SW237) (GSM395580, GSM395581) or the viaB mutant (STY2) and the tviB-vexE mutant (SW74) (GSM395582, GSM395583), respectively.

Project description:Purpose: The outcome of host–pathogen interactions is thought to reflect the offensive and defensive capabilities of both players. When plants interact with Pseudomonas syringae, several well-characterized virulence factors contribute to early bacterial pathogenicity, including the type III secretion system (T3SS), which must be activated by signals from the plant and environment to allow the secretion of virulence effectors. The manner in which these signals regulate T3SS activity is still unclear. Conlusion: the analysis revealed that the perception of plant signals from kiwifruit or tomato extracts anticipates T3SS expression in P. syringae pv. actinidiae compared to apoplast-like conditions

Project description:Transcriptionnal profile changes in ovary during the reproductive cycle of Solea senegalensis: from previtellogenic stage to vitellogenic stage obtained at different times during the annual reproductive cycle. An oligo microarray based on ESTs sequenced from S. senegalensis previously designed (Cerdà et al., 2008, BMC genomics) was used. The two stages of ovary development were directly compared using three individuals for each stage (IR-Pv-1, IR-Pv-2, IR-Pv-3 for previtellogenic individuals and IR-Vt-1, IR-Vt-2, IR-Vt-3 for vitellogenic individuals). For the experiment, the vitellogenic stage was used as the control.