Phenotypic expression of Pseudomonas syringae avr genes in E. coli is linked to the activities of the hrp-encoded secretion system.

The specific recognition of elicitors produced by plant pathogenic bacteria carrying avirulence (avr) genes is postulated to initiate cellular defense responses in plants expressing corresponding resistance genes. The biochemical functions of most avr genes, however, are not known. A heterologous system was developed to phenotypically express Pseudomonas syringae avr genes in Escherichia coli cells that required the P. syringae hrp cluster. E. coli MC4100 transformants carrying the plasmic-borne P. syringae pv. syringae Pss61 hrp cluster and p. syringae pv. glycinea avrB expressed from a triple lacUV5 promoter gained the ability to elicit the hypersensitive response in soybean cultivars expressing Rpg1 and in an Arabidopsis thaliana accession expressing RPM1. Inactivation of energy transducing or outer membrane components of the hrp-encoded secretion system blocked phenotypic expression expression of avrB in E. coli, but deletions abolishing harpinPSS production had little effect on the production of the AvrB phenotype by the E. coli transformants. Phenotypic expression of avrA, AvrPto, avrRpm1, avrRpt2, and avrPph3 in E. coli was also shown to require the hrp cluster. The results indicate that generation of the Avr phenotype in P. syringae strains is specifically dependent on the secretion activities of the hrp cluster.

Characterization of the hrpJ and hrpU operons of Pseudomonas syringae pv. syringae Pss61: similarity with components of enteric bacteria involved in flagellar biogenesis and demonstration of their role in HarpinPss secretion.

The hrp/hrmA gene cluster of Pseudomonas syringae pv. syringae Pss61 has been shown to form a minimum genetic unit sufficient to enable nonpathogenic bacteria, such as Escherichia coli, to elicit the hypersensitive response associated with disease resistance. The biochemical functions of most of these genes have not been established. The nucleotide sequence of a 4.3-kb SstI-BglII fragment carrying hrp apparent translational units V, VI, and VII revealed one partial open reading frame (ORF) and five complete ORFs producing 35,126-, 48,866-, 17,308-, 20,482-, and 26,364-Da gene products (hrpJ3, J4, J5, U1, U2, respectively). The production of these proteins was confirmed by using T7 RNA polymerase-directed expression. The partial ORF was found to be identical to the C terminus of HrpJ2. The absence of apparent transcriptional terminators and promoters between hrpI (hrpJ2), hrpJ3, hrpJ4, and hrpJ5 together with the observation that the HrpL-dependent hrpJ promoter directs expression of hrpJ3-J5 indicates that these genes form a single operon controlled by the HrpL-dependent hrpJ promoter. A second HrpL-dependent promoter consensus sequence was also identified upstream of hrpU1 and demonstrated to function as a HrpL-dependent promoter, thus indicating that hrpU1, hrpU2, and additional downstream genes may be part of a second operon. The deduced product of hrpJ3 exhibits similarity to FliG of Salmonella typhimurium, a cytoplasmic protein that regulates flagellar rotation and biogenesis. HrpJ4 shares extensive similarity with the FliI family of ATPase-like proteins and retains the known functional domains conserved among this family of proteins. HrpJ5 has properties similar to the S. typhimurium FliJ. Neither HrpU1 nor HrpU2 exhibit significant similarity to known proteins. Secretion of HarpinPss by E. coli MC4100 transformants carrying pHIR11::TnphoA derivatives was blocked in hrpJ4, J5, and U2 mutants. In view of the previously reported similarity of HrpJ2 to the LcrD super-family that includes FlhA, these results predict that the gene products of the hrpJ and hrpU operons form an inner membrane complex for translocation of proteins similar to that used by the flagellar biogenesis system of S. typhimurium.