Cloning and characterization of tek, the gene encoding the major extracellular protein of Pseudomonas solanacearum.

Susceptible plants infected by Pseudomonas solanacearum usually will, largely due to extracellular proteins (EXPs) and the high-molecular-mass extracellular polysaccharide (EPS I) this pathogen produces. Circumstantial evidence suggested that a 28-kDa protein, the single most abundant EXP made by P. solanacearum in culture, is associated with production of EPS I, and thus might have a role in pathogenesis. The 28-kDa EXP was purified and, based on its N-terminal amino acid sequence, an oligonucleotide mixture was made and used as a hybridization probe to clone the gene encoding it. DNA sequence analysis suggested that the coding sequence for the 28-kDa EXP is within a gene, designated tek, that encodes a 58-kDa membrane-associated precursor protein that is processed by signal peptidase II during export. Analysis of radiolabeled polypeptides expressed from tek confirmed that it encodes a 58-kDa precursor protein, which is exported out of the cells as a 55-kDa preprotein and processed extracellularly to release the very basic 28-kDa EXP from its C terminus. The position, transcriptional direction, and regulated expression of tek suggest that it is cotranscribed with xpsR, a gene essential for regulating biosynthesis of EPS I, and reinforces the association of the 28-kDa EXP with virulence. However, since P. solanacearum mutants lacking only the 28-kDa EXP produced wild-type amounts of EPS I and were fully virulent, the function of this protein remains unclear.

Nucleotide sequence of the P1 attachment-protein gene of Mycoplasma pneumoniae.

The specific attachment of Mycoplasma pneumoniae to the respiratory ciliated epithelium is mediated by a surface protein designated P1. The nucleotide (nt) sequence of the P1 attachment-protein gene has been determined and the amino acid (aa) sequence deduced. mRNA and cDNA sequencing confirm that this gene is transcribed in M. pneumoniae. The predicted amino acid sequence matches the N-terminal 12 aa residues of P1 protein from M. pneumoniae [Jacobs et al., J. Gen. Microbiol. 133 (1987) 2233-2236] beginning with Asn at aa position 60, where aa 1 represents the first codon of the open reading frame (ORF). Notably, the Trp at aa position 69 aligns with a UGA codon deduced from the nucleotide sequence, providing supporting evidence that UGA is read as Trp rather than stop in M. pneumoniae. Analysis of the first 59 aa suggests that it is probably a leader sequence that is processed to yield the mature protein. The codons of the mature P1 protein sequence represent 1568 aa with a calculated Mr of 169,758. A unique feature of this protein sequence is the lack of cysteine, and this was confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of M. pneumoniae proteins metabolically labeled with radioactive cysteine or methionine. This study has revealed that the 4881 nt of the P1 structural gene are flanked by ORFs, and there are no obvious ribosome-binding sites or transcription termination sequences in the immediately adjacent regions. This suggests that the P1 gene is transcribed as part of a larger polycistronic message. In addition, a number of untranscribed and therefore nonfunctional P1 epitope sequences were found in the M. pneumoniae genome; their purpose remains unknown.

Role of Extracellular Polysaccharide and Endoglucanase in Root Invasion and Colonization of Tomato Plants by Ralstonia solanacearum.

ABSTRACT Ralstonia solanacearum is a soilborne plant pathogen that normally invades hosts through their roots and then systemically colonizes aerial tissues. Previous research using wounded stem infection found that the major factor in causing wilt symptoms was the high-molecular-mass acidic extracellular polysaccharide (EPS I), but the beta-1,4-endoglucanase (EG) also contributes to virulence. We investigated the importance of EPS I and EG for invasion and colonization of tomato by infesting soil of 4-week-old potted plants with either a wild-type derivative or genetically well-defined mutants lacking EPS I, EG, or EPS I and EG. Bacteria of all strains were recovered from surface-disinfested roots and hypocotyls as soon as 4 h after inoculation; that bacteria were present internally was confirmed using immunofluorescence microscopy. However, the EPS-minus mutants did not colonize stems as rapidly as the wild type and the EG-minus mutant. Inoculations of wounded petioles also showed that, even though the mutants multiplied as well as the wild type in planta, EPS-minus strains did not spread as well throughout the plant stem. We conclude that poor colonization of stems by EPS-minus strains after petiole inoculation or soil infestation is due to reduced bacterial movement within plant stem tissues.

Spatial-Temporal and Quantitative Analysis of Growth and EPS I Production by Ralstonia solanacearum in Resistant and Susceptible Tomato Cultivars.

ABSTRACT One susceptible and two resistant cultivars of tomato were tested for differences in infection by Ralstonia solanacearum and for the subsequent multiplication, colonization, and production of the wilt-inducing virulence factor, exopolysaccharide I (EPS I). Bacterial ingress into the taproot was fastest in the susceptible cv. Marion, followed by the resistant cvs. L285 (fivefold slower) and Hawaii 7996 (15-fold slower). Once inside the taproot, R. solanacearum colonized, to some extent, almost all regions of the resistant and susceptible plants. However, colonization occurred sooner in the susceptible than in the resistant cultivars, as measured by viablecell counts of bacteria in the midstems. Rates of multiplication and maximum bacterial cell densities were also greater in the susceptible than in the resistant cultivars. Growth experiments utilizing xylem fluid from infected and uninfected plants indicated that neither antimicrobial activities nor reduced levels of growth-supporting nutrients in the xylem fluids were responsible for the reduced bacterial multiplication in the resistant cultivars. Quantification of EPS I in the infected plants, using an enzyme-linked immunosorbent assay, revealed that the bacterial populations in the susceptible cultivar produced greater amounts of EPS I per plant than those in the resistant cultivars. Immunofluorescence microscopy using antibodies against either EPS I or R. solanacearum cells revealed that bacteria and EPS I were distributed throughout the vascular bundles and intercellular spaces of the pith in the susceptible cultivar, whereas in the resistant cultivars, bacteria and EPS I were restricted to the vascular tissues.

A cloned avirulence gene from Pseudomonas solanacearum determines incompatibility on Nicotiana tabacum at the host species level.

A locus in Pseudomonas solanacearum AW1 responsible for the hypersensitive response (HR) on tobacco was cloned by complementation in the tobacco-pathogenic strain P. solanacearum NC252. The NC252 HR+ transconjugants lost pathogenicity on tobacco, indicating that the cloned locus could restrict the host range of NC252. Restriction enzyme mapping, transposon mutagenesis, and subcloning showed that, at most, 2.0 kilobases of the cloned DNA was required for NC252 transconjugants to elicit HR on tobacco. Site-directed insertional mutagenesis of the wild-type locus in strain AW1 to create AW1-31 eliminated HR activity on tobacco. However, AW1-31 retained pathogenicity on tomato and eggplant, confirming that this locus contains an avirulence gene, designated avrA. In contrast to the wild type, AW1-31 multiplied to almost the same extent as NC252 after infiltration into tobacco leaves. Nevertheless, AW1-31 did not wilt tobacco when stem inoculated, suggesting that additional factors condition host range. AW1 was HR+ on 27 N. tabacum cultivars, whereas AW1-31 was always HR-, strongly suggesting that avrA is specific at the host species level.

Cloning of wild-type Pseudomonas solanacearum phcA, a gene that when mutated alters expression of multiple traits that contribute to virulence.

Pseudomonas solanacearum undergoes a spontaneous mutation that pleiotropically reduces extracellular polysaccharide (EPS) production, endoglucanase activity, and virulence and increases motility. We refer to the process that coordinately affects these traits as phenotype conversion (PC) and the resulting mutants as PC types. Previous research with the wild-type strain AW1 suggested that inactivation of a single locus could mimic phenotype conversion (T. P. Denny, F. W. Makini, and S. M. Brumbley, Mol. Plant-Microbe Interact. 1:215-223, 1988). Additional Tn5 mutagenesis of AW1 generated three more mutants (AW1-81, AW1-82, and AW1-84) that were indistinguishable from the PC type and one slightly leaky mutant (AW1-87); all four had single insertions in the same 4.0-kilobase (kb) EcoRI fragment that were responsible for the PC-like phenotype. Another insertion mutant, AW1-83, which lacks an insertion in this 4.0-kb fragment, resembled the PC type except that it was reversibly induced to produce wild-type levels of EPS when cultured adjacent to AW1. The wild-type region containing the gene that controls traits affected by phenotype conversion in AW1, designated phcA, was cloned on a 2.2-kb DNA fragment that restored all the phcA::Tn5 mutants and 11 independent spontaneous PC-type derivatives of AW1 to wild-type status. Homology with the phcA region was found in diverse wild-type strains of P. solanacearum, although restriction fragment length polymorphisms were seen. No major DNA alterations were observed in the phcA homologous region of PC types from strain AW1 or 82N. PC types from 7 of 11 conjugal strains of P. solanacearum were restored to EPS+ by phcA from AW1; however, only some PC types of strain K60 were restored, whereas others were not. We believe that a functional phcA gene is required to maintain the wild-type phenotype in P. solanacearum, and for most strains phenotype conversion results from a loss of phcA gene expression or the function of its gene product.

Genetic diversity and relationships of two pathovars of Pseudomonas syringae.

To determine genetic relationships within and between two pathovars of Pseudomonas syringae, strains typical of P. syringae pv. tomato (P. s. tomato) and selected strains of P. syringae pv. syringae (P. s. syringae) were characterized by three methods. DNA-DNA hybridization experiments showed that strains of P. s. tomato and P. s. syringae were, respectively, 86-100% and 37-47% homologous to DNA from a P. s. tomato reference strain when tested under stringent conditions. An analysis of electrophoretic variation in enzymes encoded by 26 loci placed 17 P. s. tomato strains studied in a group of four electrophoretic types, and these strains had a mean genetic diversity per locus of 0.076. Six P. s. syringae strains formed a second group of six electrophoretic types, which had a higher mean genetic diversity per locus of 0.479. The mean genetic distance separating P. s. tomato from P. s. syringae (D = 0.94) was unexpectedly large for strains of a single species. An analysis of restriction fragment length polymorphisms (RFLPs) with three cloned hybridization probes demonstrated that each of the P. s. tomato and P. s. syringae strains was unique. A method was developed to quantify the RFLP difference between pairs of strains, and cluster analysis revealed relationships among P. s. tomato, but not among P. s. syringae, that were similar to those based on enzyme polymorphisms. Implications of these findings for bacterial systematics and epidemiology are discussed.

Analysis of the Pseudomonas solanacearum polygalacturonase encoded by pglA and its involvement in phytopathogenicity.

A major endopolygalacturonase excreted by Pseudomonas solanacearum was purified to greater than 95% homogeneity and shown to have an isoelectric point of 9.0 and a subunit molecular mass of 52 kilodaltons (kDa). The gene encoding this enzyme (pglA) was isolated from a genomic library of P. solanacearum DNA based on its expression in Escherichia coli and shown to be contained on a 1.8-kilobase DNA fragment. The identity of the pglA gene product and the 52-kDa polygalacturonase was demonstrated by immunoadsorption and isoelectric focusing experiments. The cloned pglA gene was apparently expressed from its own promoter in E. coli and its product was partially secreted into the periplasm. The pglA gene was insertionally inactivated in vitro and used to mutate the chromosomal pglA gene of P. solanacearum by marker exchange mutagenesis. The resulting mutant strain was deficient in production of the 52-kDa polygalacturonase and took twice as long to wilt and kill tomato plants as the wild-type parent in plant bioassay experiments. Complementation in trans with the wild-type cloned pglA gene restored virulence to near wild-type levels. The data indicate that the pglA gene is important, but not absolutely necessary, for pathogenesis.

Cloning of the egl gene of Pseudomonas solanacearum and analysis of its role in phytopathogenicity.

The egl gene of Pseudomonas solanacearum was cloned on a cosmid and expressed in Escherichia coli. Restriction endonuclease mapping, transposon mutagenesis, and subclone analysis showed that the egl gene was located on a 2.7-kilobase XhoI-SalI P. solanacearum DNA fragment. Immunoabsorption experiments and sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis showed that the egl gene encodes the 43-kilodalton endoglucanase that is the major excreted endoglucanase of P. solanacearum. In E. coli, the egl gene appeared to be expressed from its own promoter, but its product was restricted to the cytoplasm. The cloned egl gene was mutagenized with Tn5 and used to specifically mutate the chromosomal egl gene of P. solanacearum by site-directed mutagenesis. The resultant mutant was identical to the wild-type strain in production of extracellular polysaccharide and extracellular polygalacturonase as well as several other excreted proteins but produced at least 200-fold less endoglucanase. This mutant strain was significantly less virulent on tomato than the wild-type strain in plant bioassay experiments. Virulence of the endoglucanase-deficient strain was restored to near wild-type levels by complementation in trans with the cloned egl gene, indicating that the egl gene is important but not absolutely required for pathogenesis.

An RpoS (sigmaS) homologue regulates acylhomoserine lactone-dependent autoinduction in Ralstonia solanacearum.

Many bacteria sense an appropriate growth condition or a critical population density for gene expression by producing acylhomoserine lactones (acyl-HSLs) that act as intercellular autoinduction signals. We recently showed that, in Ralstonia (Pseudomonas) solanacearum, a phytopathogenic bacterium, acyl-HSL production requires soll, which encodes a putative acyl-HSL synthase, and that its expression is positively regulated by the acyl-HSL-responsive SolR transcriptional regulator. This acyl-HSL-dependent autoinduction system is noteworthy because (i) it is regulated by a 'higher level' autoinducer system (responsive to 3-hydroxypalmitic acid methyl ester) via PhcA, a LysR-type transcriptional regulator and (ii) acyl-HSL production requires two additional unlinked loci. As reported here, cloning and sequencing of one of these other loci revealed that it encodes a homologue of RpoS, an alternative sigma factor (sigmaS) that in other bacteria activates gene expression during stationary phase or in response to stress conditions. R. solanacearum RpoS (RpoS(Rso)) was demonstrated to function as a sigma factor because when introduced in trans into an Escherichia coli rpoS mutant it largely restored expression of the RpoS-dependent bolAp1 gene. Mutation of rpoS(Rso) in R. solanacearum reduced survival during starvation and low pH conditions, but did not affect survival during exposure to hydrogen peroxide, high osmolarity or high temperature. This mutant was also altered in its production of several virulence factors and wilted tomato plants several days more slowly than the wild-type parent. Transcription of solR and soll were decreased in an rpoS(Rso) background (thereby reducing acyl-HSL production), but neither mutations in solR, soll or phcA nor addition of acyl-HSLs affected rpoS(Rso) expression. Therefore, in R. solanacearum the acyl-HSL-dependent autoinduction system is controlled both by a second autoinduction system and by the RpoS(Rso) sigma factor.

VsrA, a second two-component sensor regulating virulence genes of Pseudomonas solanacearum.

The wilt-inducing phytopathogen Pseudomonas solanacearum produces several extracellular virulence factors, both polysaccharides (EPS I) and proteins (EXPs), which are independently regulated by a LysR-type transcriptional regulator, PhcA, and a histidine kinase sensor, VsrB. Here we characterize a third locus, vsrA, which is also required for normal production of EPS I, some EXPs and wilt disease. Analysis of eps::lacZ reporters in vsrA mutants showed that, like vsrB and phcA, vsrA is required for maximal expression (transcription) of eps, which contains some of the genes necessary for production of EPS I. Unlike vsrB and phcA mutants, however, eps transcription (and EPS I production) by vsrA mutants varies from 3 to 17% of wild-type levels, depending on growth conditions. Inactivation of vsrA also causes a dramatic reduction in production of three species of EXPs (28 kDa, 48 kDa, and 66 kDa), and an apparent increase in production of a few other EXPs. Unlike most other EPS-deficient P. solanacearum strains, vsrA mutants caused almost no disease symptoms when 10(4) cells were stem-inoculated into tomato plants. This correlated with a greater than 10-fold reduction in their ability to grow in planta. vsrA was cloned from a P. solanacearum genomic library by complementation of the vsrA mutant and was further subcloned on a 2.3 kb DNA fragment. PhoA fusion analysis and subcellular localization of the vsrA gene product in Escherichia coli maxicells suggest that it is a 53 kDa membrane-associated protein. Analysis of the nucleotide sequence of vsrA revealed a 502 residue open reading frame with homology to the histidine kinase domain of sensors in the two-component regulator family. This discovery shows that EPS I production by P. solanacearum is simultaneously controlled by dual two-component sensors.

vsrB, a regulator of virulence genes of Pseudomonas solanacearum, is homologous to sensors of the two-component regulator family.

Pseudomonas solanacearum, an important wilt pathogen of many plants, produces several extracellular proteins (EXPs) and extracellular polysaccharides (EPSs) that contribute to its virulence. Using TnphoA mutagenesis, we discovered a new gene, vsrB, that when inactivated causes a major reduction in the virulence and production of an EPS. Analysis of eps::lacZ reporters showed that vsrB is required for maximal expression (transcription) of eps, whose products are required for production of EPS I, a major virulence determinant. Analysis of EXPs in culture supernatants revealed that inactivation of vsrB also causes reduced production of two major EXPs, with molecular masses of 28 and 97 kDa, and a simultaneous 15-fold increase in levels of another EXP, PglA endopolygalacturonase. The vsrB gene was cloned from a P. solanacearum genomic library by complementation of the nonmucoid phenotype of the vsrB::TnphoA mutant and then subcloned on a 2.4-kb DNA fragment. TnphoA fusion analysis and subcellular localization of the vsrB gene product in Escherichia coli maxicells suggest that it is a ca. 60-kDa transmembrane protein. The nucleotide sequence of the 2.4-kb DNA fragment was determined, and a 638-amino-acid open reading frame was found for VsrB. A search of the GenBank data base found that the central part of VsrB has homology with the histidine kinase domain of sensors in the two-component regulator family, while the C terminus has homology with the phosphate receiver domain of response regulators in the same family. Genetic analysis suggests that the receiver domain is not required for vsrB function.

Phenotype conversion in Pseudomonas solanacearum due to spontaneous inactivation of PhcA, a putative LysR transcriptional regulator.

Phenotype conversion (PC) in Pseudomonas solanacearum is the coordinated change in production of extracellular polysaccharide and a variety of extracellular proteins, some of which contribute to virulence. Although PC is normally spontaneous, it is mimicked by transposon inactivation of the phcA locus (S. M. Brumbley and T. P. Denny, J. Bacteriol. 172:5677-5685, 1990). The DNA sequence of a 1.8-kb region from strain AW1 that contains phcA revealed one open reading frame that should encode a polypeptide of 38.6 kDa. The PhcA protein produced in Escherichia coli by using a T7 RNA polymerase expression system was of the predicted size. The deduced amino acid sequence of PhcA is similar to that of some members of the LysR transcriptional activator gene family, especially in the amino terminus, where a putative helix-turn-helix DNA-binding motif was identified. An analogous allele (phcA1) was cloned from the spontaneous PC mutant strain AW1-PC and found to be nonfunctional in complementation studies. When phcA1 was expressed in E. coli, the PhcA1 protein was 35.5 kDa, 3 kDa smaller than PhcA. Sequence analysis of phcA1 and chimeric constructs of phcA and phcA1 confirmed that PhcA1 is truncated by a 2-bp insertion 147 nucleotides upstream of the carboxyl terminus of PhcA. Southern blot analysis of 10 additional independently isolated PC mutants of strain AW1 revealed that two strains have larger insertions (0.2 and 1.0 kb) within phcA. These results suggest that phcA encodes a DNA-binding protein that regulates the transcription of one or more of the genes involved in P. solanacearum virulence and that spontaneous PC can be attributed to one of several different insertions within this locus.

Purification and serological characterization of the major envelope glycoprotein from AKR murine leukemia virus and its reactivity with autogenous immune sera from mice.

The major envelope glycoprotein (gp71) from AKR murine leukemia virus (MuLV) was purified and its serological reactivity with heterologous and autogenous immune mouse sera was examined. Homologous and interspecies competition radioimmunoassays using antisera to Rauscher-MulV gp69/71 or Friend-MuLV gp71 or antisera to feline leukemia virus to precipitate 125I-labeled gp71 from various MuLV showed that distinct differences exist between Rauscher- or Friend-MuLV and AKR-MuLV glycoproteins. Characteristically the AKR-MuLV gp71, in contrast to FLV or RLV gp71, does not compete fully in homologous or interspecies radioimmunoassays with iodinated Friend of Rauscher glycoproteins. Purified 125I-labeled AKR-MuLV gp71, in contrast to the Rauscher- or Friend-MuLV glycoproteins, reacts with normal (autogenous immune) mouse sera in direct radioimmune precipitation assays. Competition experiments further demonstrate that this is a predominant immunological reactivity of normal mouse sera which had previously been detected by radioimmune precipitation assay against intact virions.

Identification of 3-hydroxypalmitic acid methyl ester as a novel autoregulator controlling virulence in Ralstonia solanacearum.

Expression of virulence genes in Ralstonia solanacearum, a phytopathogenic bacterium, is controlled by a complex regulatory network that integrates multiple signal inputs. Production of several virulence determinants is coordinately reduced by inactivation of phcB, but is restored by growth in the presence of a volatile extracellular factor (VEF) produced by wild-type strains of R. solanacearum. The VEF was purified from spent culture broth by distillation, solvent extraction, and liquid chromatography. Gas chromatography and mass spectroscopy identified 3-hydroxypalmitic acid methyl ester (3-OH PAME) as the major component in the single peak of VEF activity. Authentic 3-OH PAME and the purified VEF were active at < or =1 nM, and had nearly equivalent specific activities for stimulating the expression of eps (the biosynthetic locus for extracellular polysaccharide) in a phcB mutant. Authentic 3-OH PAME also increased the production of three virulence factors by a phcB mutant over 20-fold to wild-type levels, restored normal cell density-associated expression of eps and increased expression of eps when delivered via the vapour phase. Reanalysis of the PhcB amino acid sequence suggested that it is a small-molecule S-adenosylmethionine-dependent methyltransferase, which might catalyse synthesis of 3-OH PAME from a naturally occurring fatty acid. Biologically active concentrations of extracellular 3-OH PAME were detected before the onset of eps expression, suggesting that it is an intercellular signal that autoregulates virulence gene expression in wild-type R. solanacearum. Other than acyl-homoserine lactones, 3-OH PAME is the only endogenous fatty acid derivative shown to be an autoregulator and may be the first example of a new family of compounds that can mediate long-distance intercellular communication.

Hierarchical autoinduction in Ralstonia solanacearum: control of acyl-homoserine lactone production by a novel autoregulatory system responsive to 3-hydroxypalmitic acid methyl ester.

Bacteria employ autoinduction systems to sense the onset of appropriate cell density for expression of developmental genes. In many gram-negative bacteria, autoinduction involves the production of and response to diffusible acylated-homoserine lactones (acyl-HSLs) and is mediated by members of the LuxR and LuxI families. Ralstonia (Pseudomonas) solanacearum, a phytopathogenic bacterium that appears to autoregulate its virulence genes, produces compounds that promote expression of several heterologous acyl-HSL-responsive reporter gene constructs. High-pressure liquid chromatography of highly concentrated ethyl acetate extracts revealed that culture supernatants of strain AW1 contained two compounds with retention times similar to N-hexanoyl- and N-octanoyl-HSL. To investigate the role of these acyl-HSLs in R. solanacearum virulence gene expression, transposon mutants that were deficient for inducing an acyl-HSL-responsive reporter in Agrobacterium tumefaciens were generated. Three loci involved in normal acyl-HSL production were identified, one of which was shown to contain the divergently transcribed solR and solI genes, the luxR and luxI homologs, respectively. A 4.1-kb fragment containing solR and solI enabled all of the mutants (regardless of the locus inactivated) and a naturally acyl-HSL-defective strain of R. solanacearum to produce acyl-HSLs. Inactivation of solI abolished production of all detectable acyl-HSLs but affected neither the expression of virulence genes in culture nor the ability to wilt tomato plants. AW1 has a functional autoinduction system, because (i) expression of solI required SolR and acyl-HSL and (ii) expression of a gene linked to solR and solI, designated aidA, was acyl-HSL dependent. Because AidA has no homologs in the protein databases, its discovery provided no clues as to the role of acyl-HSLs in R. solanacearum gene regulation. However, expression of solR and solI required the global LysR-type virulence regulator PhcA, and both solR and solI exhibited a cell density-associated pattern of expression similar to other PhcA-regulated genes. The acyl-HSL-dependent autoinduction system in R. solanacearum is part of a more complex autoregulatory hierarchy, since the transcriptional activity of PhcA is itself controlled by a novel autoregulatory system that responds to 3-hydroxypalmitic acid methyl ester.

A two-component system in Ralstonia (Pseudomonas) solanacearum modulates production of PhcA-regulated virulence factors in response to 3-hydroxypalmitic acid methyl ester.

Expression of virulence factors in Ralstonia solanacearum is controlled by a complex regulatory network, at the center of which is PhcA, a LysR family transcriptional regulator. We report here that expression of phcA and production of PhcA-regulated virulence factors are affected by products of the putative operon phcBSR(Q). phcB is required for production of an extracellular factor (EF), tentatively identified as the fatty acid derivative 3-hydroxypalmitic acid methyl ester (3-OH PAME), but a biochemical function for PhcB could not be deduced from DNA sequence analysis. The other genes in the putative operon are predicted to encode proteins homologous to members of two-component signal transduction systems: PhcS has amino acid similarity to histidine kinase sensors, whereas PhcR and OrfQ are similar to response regulators. PhcR is quite unusual because its putative output domain strongly resembles the histidine kinase domain of a sensor protein. Production of the PhcA-regulated factors exopolysaccharide I, endoglucanase, and pectin methyl esterase was reduced 10- to 100-fold only in mutants with a nonpolar insertion in phcB [which express phcSR(Q) in the absence of the EF]; simultaneously, expression of phcA was reduced fivefold. Both a wild-type phenotype and phcA expression were restored by addition of 3-OH PAME to growing cultures. Mutants with polar insertions in phcB or lacking the entire phcBSR(Q) region produced wild-type levels of PhcA-regulated virulence factors. The genetic data suggest that PhcS and PhcR function together to regulate expression of phcA, but the biochemical mechanism for this is unclear. At low levels of the EF, it is likely that PhcS phosphorylates PhcR, and then PhcR interacts either with PhcA (which is required for full expression of phcA) or an unknown component of the signal cascade to inhibit expression of phcA. When the EF reaches a threshold concentration, we suggest that it reduces the ability of PhcS to phosphorylate PhcR, resulting in increased expression of phcA and production of PhcA-regulated factors.