In Pseudomonas syringae strains, the hrp-hrc pathogenicity island consists of an HrpL-dependent regulon that encodes a type III protein translocation complex and translocated effector proteins required for pathogenesis. HrpR and HrpS function as positive regulatory factors for the hrpL promoter, but their mechanism of action has not been established. Both HrpR and HrpS are structurally related to enhancer-binding proteins, but they lack receiver domains and do not appear to require a cognate protein kinase for activity. hrpR and hrpS were shown to be expressed as an operon: a promoter was identified 5 to hrpR, and reverse transcriptase PCR detected the presence of an hrpRS transcript. The hrpR promoter and coding sequence were conserved among P. syringae strains. The coding sequences for hrpR and hrpS were cloned into compatible expression vectors, and their activities were monitored in Escherichia coli transformants carrying an hrpL-lacZ fusion. HrpS could function as a weak activator of the hrpL promoter, but the activity was only 2.5% of the activity detected when both HrpR and HrpS were expressed in the reporter strain. This finding is consistent with a requirement for both HrpR and HrpS in the activation of the hrpL promoter. By using a yeast two-hybrid assay, an interaction between HrpR and HrpS was detected, suggestive of the formation of a heteromeric complex.
Physical interaction of HrpR and HrpS was confirmed by column-binding experiments. The results show that HrpR andHrpS physically interact to regulate the 54 -dependent hrpL promoter in P. syringae strains.Pseudomonas syringae is a causal agent of leaf blights and related diseases in many plant species (19). When introduced into tissue of a susceptible plant, the bacterium colonizes the intercellular spaces of parenchymatous tissue, remaining external to plant cell walls. Colonizing bacteria produce extracellular polysaccharides, derivatized peptide toxins, and plant hormones that lead to altered ion fluxes across cellular membranes and slowly developing tissue necroses typical of leaf blights. Although P. syringae is capable of causing disease in most economically important plant species, a single strain usually causes disease only in a specific subset of plant species or in some cases specific genetic lines of a single plant species. When introduced into plants other than the susceptible host, a P. syringae strain elicits an active defense response that culminates in a rapid programmed cell death. This programmed cell death, also known as the hypersensitive response, and the associated defense responses prevent further colonization of the tissue and are thought to be major factors in the determination of a strain's host range (8, 23).The colonization of plant tissue and elicitation of active defense responses by P. syringae strains have both been linked to a pathogenicity island (PAI) called the hrp gene cluster (for a recent review, see reference 8). The P. syringae hrp gene cluster encodes a type III protein export complex (PEC) similar to those...
A 1116 bp open reading frame (ORF), designated jlpA, encoding a novel species-specific lipoprotein of Campylobacter jejuni TGH9011, was identified from recombinant plasmid pHIP-O. The jlpA gene encodes a polypeptide (JlpA) of 372 amino acid residues with a molecular mass of 42.3 kDa. JlpA contains a typical signal peptide and lipoprotein processing site at the N-terminus. The presence of a lipid moiety on the JlpA molecule was confirmed by the incorporation of [3H]-palmitic acid. Immunoblotting analysis of cell surface extracts prepared using glycine-acid buffer (pH 2.2) and proteinase K digestion of whole cells indicated that JlpA is a surface-exposed lipoprotein in C. jejuni. JlpA is loosely associated with the cell surface, as it is easily extracted from the C. jejuni outer membrane by detergents, such as sarcosyl and Triton X-100. JlpA is released to the culture medium, and its concentration increases in a time-dependent fashion. The adherence of both insertion and deletion mutants of jlpA to HEp-2 epithelial cells was reduced compared with that of parental C. jejuni TGH9011. Adherence of C. jejuni to HEp-2 cells was inhibited in a dose-dependent manner when the bacterium was preincubated with anti-GST-JlpA antibodies or when HEp-2 cells were preincubated with JlpA protein. A ligand-binding immunoblotting assay showed that JlpA binds to HEp-2 cells, which suggests that JlpA is C. jejuni adhesin.
SummaryCampylobacter jejuni is a leading cause of acute bacterial gastroenteritis in humans. The mechanism by which C. jejuni interacts with host cells, however, is still poorly understood. Our previous study has shown that the C. jejuni surface lipoprotein JlpA mediates adherence of the bacterium to epithelial cells. In this report, we demonstrated that JlpA interacts with HEp-2 cell surface heat shock protein (Hsp) 90 a a a a and initiates signalling pathways leading to activation of NF-k k k k B and p38 MAP kinase. Gel overlay and GST pull down assays showed that JlpA interacts with Hsp90 a a a a . Geldanamycin, a specific inhibitor of Hsp90, and anti-human Hsp90 a a a a antibody significantly blocked the interaction between JlpA and Hsp90 a a a a , suggesting a direct interaction between JlpA and HEp-2 cell surface-exposed Hsp90 a a a a . The treatment of
Two actin genes, actA from the hemibiotrophic anthracnose fungus, Colletotrichum gloeosporioides (Penz.) Penz. & Sacc. f. sp. malvae, and act1 from its host, Malva pusilla (Sm.) were cloned from a cDNA library developed from infected host tissue. The actin gene, actA, of C. gloeosporioides f. sp. malvae, which is similar to that of other euascomycetes, appears to be expressed constitutively. The actin gene of M. pusilla is most similar to one of the actin genes of Arabidopsis thaliana that is unique in being responsive to environmental stimuli such as wounding. Expression of actA was used to follow the growth of the fungus in the plant tissue. Low actA expression occurred until 72-96 h after inoculation and then increased rapidly, corresponding with the timing of the shift from slower biotrophic fungal growth to much more rapid necrotrophic growth. In contrast, expression of act1 approximately doubled during the biotrophic phase and then rapidly declined during the necrotrophic phase. Increased host actin expression could be due to host cytoskeleton rearrangement in response to biotrophic infection, and the subsequent decrease in host actin expression could be due to host cell disruption resulting from tissue maceration during necrosis. This is the first report of a host actin gene that can increase in expression during a compatible plant-pathogen interaction.
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