Important role for methionine sulfoxide reductase in the oxidative stress response of Xanthomonas campestris pv. phaseoli

A methionine sulfoxide reductase gene (msrA) from Xanthomonas campestris pv. phaseoli has unique expression patterns and physiological function. msrA expression is growth dependent and is highly induced by exposure to oxidants and N-ethylmaleimide in an OxyR- and OhrR-independent manner. An msrA mutant showed increased sensitivity to oxidants but only during stationary phase.     

Exposure of phytopathogenic Xanthomonas spp. to lethal concentrations of multiple oxidants affects bacterial survival in a complex manner

During plant-microbe interactions and in the environment, Xanthomonas campestris pv. phaseoli is likely to be exposed to high concentrations of multiple oxidants. Here, we show that simultaneous exposures of the bacteria to multiple oxidants affects cell survival in a complex manner. A superoxide generator (menadione) enhanced the lethal effect of an organic peroxide (tert-butyl hydroperoxide) by 1, 000-fold; conversely, treatment of cells with menadione plus H(2)O(2) resulted in 100-fold protection compared to that for cells treated with the individual oxidants. Treatment of X. campestris with a combination of H(2)O(2) and tert-butyl hydroperoxide elicited no additive or protective effect. High levels of catalase alone are sufficient to protect cells against the lethal effect of menadione plus H(2)O(2) and tert-butyl hydroperoxide plus H(2)O(2). These data suggest that H(2)O(2) is the lethal agent responsible for killing the bacteria as a result of these treatments. However, increased expression of individual genes for peroxide (alkyl hydroperoxide reductase, catalase)- and superoxide (superoxide dismutase)-scavenging enzymes or concerted induction of oxidative stress-protective genes by menadione gave no protection against killing by a combination of menadione plus tert-butyl hydroperoxide. However, X. campestris cells in the stationary phase and a spontaneous H(2)O(2)-resistant mutant (X. campestris pv. phaseoli HR) were more resistant to killing by menadione plus tert-butyl hydroperoxide. These findings give new insight into oxidant killing of Xanthomonas spp. that could be generally applied to other bacteria.     

A suppressor of the menadione-hypersensitive phenotype of a Xanthomonas campestris pv. phaseoli oxyR mutant reveals a novel mechanism of toxicity and the protective role of alkyl hydroperoxide reductase

We isolated menadione-resistant mutants of Xanthomonas campestris pv. phaseoli oxyR (oxyR(Xp)). The oxyRR2(Xp) mutant was hyperresistant to the superoxide generators menadione and plumbagin and was moderately resistant to H(2)O(2) and tert-butyl hydroperoxide. Analysis of enzymes involved in oxidative-stress protection in the oxyRR2(Xp) mutant revealed a >10-fold increase in AhpC and AhpF levels, while the levels of superoxide dismutase (SOD), catalase, and the organic hydroperoxide resistance protein (Ohr) were not significantly altered. Inactivation of ahpC in the oxyRR2(Xp) mutant resulted in increased sensitivity to menadione killing. Moreover, high levels of expression of cloned ahpC and ahpF in the oxyR(Xp) mutant complemented the menadione hypersensitivity phenotype. High levels of other oxidant-scavenging enzymes such as catalase and SOD did not protect the cells from menadione toxicity. These data strongly suggest that the toxicity of superoxide generators could be mediated via organic peroxide production and that alkyl hydroperoxide reductase has an important novel function in the protection against the toxicity of these compounds in X. campestris.     

Exposure of Phytopathogenic Xanthomonas spp. to Lethal Concentrations of Multiple Oxidants Affects Bacterial Survival in a Complex Manner

During plant-microbe interactions and in the environment, Xanthomonas campestris pv. phaseoli is likely to be exposed to high concentrations of multiple oxidants. Here, we show that simultaneous exposures of the bacteria to multiple oxidants affects cell survival in a complex manner. A superoxide generator (menadione) enhanced the lethal effect of an organic peroxide (tert-butyl hydroperoxide) by 1,000-fold; conversely, treatment of cells with menadione plus H₂O₂ resulted in 100-fold protection compared to that for cells treated with the individual oxidants. Treatment of X. campestris with a combination of H₂O₂ and tert-butyl hydroperoxide elicited no additive or protective effect. High levels of catalase alone are sufficient to protect cells against the lethal effect of menadione plus H₂O₂ and tert-butyl hydroperoxide plus H₂O₂. These data suggest that H₂O₂ is the lethal agent responsible for killing the bacteria as a result of these treatments. However, increased expression of individual genes for peroxide (alkyl hydroperoxide reductase, catalase)- and superoxide (superoxide dismutase)-scavenging enzymes or concerted induction of oxidative stress-protective genes by menadione gave no protection against killing by a combination of menadione plus tert-butyl hydroperoxide. However, X. campestris cells in the stationary phase and a spontaneous H₂O₂-resistant mutant (X. campestris pv. phaseoli HR) were more resistant to killing by menadione plus tert-butyl hydroperoxide. These findings give new insight into oxidant killing of Xanthomonas spp. that could be generally applied to other bacteria.     

Production of monoclonal antibodies to Pseudomonas syringae pv. phaseolicola and Xanthomonas campestris pv. phaseoli

The production of monoclonal antibodies (MAbs) to ethylenediamine tetraacetic acid (sodium salt) soluble antigens of Pseudomonas syringae pv. phaseolicola and Xanthomonas campestris pv. phaseoli (fuscans strain) is described. MAbs A6-1 and A6-2 produced to Ps. syringae pv. phaseolicola are pathovar specific. Although MAb XP2 produced to X. campestris pv. phaseoli recognized surface antigens of all strains of this pathovar (including fuscans strains) it cross-reacted specifically with X. campestris pv. malvacearum; it did not react with any other known bacteria or unidentified epiphytes from navy bean seed or leaves. The isotype of both MAbs XP2 and A6-1 is IgG3 whereas that of MAb A6-2 is IgG2a. The reactive antigens are thermostable, but their chemical nature has not been determined.     

Mutations in oxyR resulting in peroxide resistance in Xanthomonas campestris

A spontaneous Xanthomonas campestris pv. phaseoli H(2)O(2)-resistant mutant emerged upon selection with 1 mM H(2)O(2). In this report, we show that growth of this mutant under noninducing conditions gave high levels of catalase, alkyl hydroperoxide reductase (AhpC and AhpF), and OxyR. The H(2)O(2) resistance phenotype was abolished in oxyR-minus derivatives of the mutant, suggesting that elevated levels and mutations in oxyR were responsible for the phenotype. Nucleotide sequence analysis of the oxyR mutant showed three nucleotide changes. These changes resulted in one silent mutation and two amino acid changes, one at a highly conserved location (G197 to D197) and the other at a nonconserved location (L301 to R301) in OxyR. Furthermore, these mutations in oxyR affected expression of genes in the oxyR regulon. Expression of an oxyR-regulated gene, ahpC, was used to monitor the redox state of OxyR. In the parental strain, a high level of wild-type OxyR repressed ahpC expression. By contrast, expression of oxyR5 from the X. campestris pv. phaseoli H(2)O(2)-resistant mutant and its derivative oxyR5G197D with a single-amino-acid change on expression vectors activated ahpC expression in the absence of inducer. The other single-amino-acid mutant derivative of oxyR5L301R had effects on ahpC expression similar to those of the wild-type oxyR. However, when the two single mutations were combined, as in oxyR5, these mutations had an additive effect on activation of ahpC expression.     

Structures of the O-polysaccharide chains of the lipopolysaccharides of Xanthomonas campestris pv phaseoli var fuscans GSPB 271 and X campestris pv malvacearum GSPB 1386 and GSPB 2388

O-polysaccharides of phytopathogenic bacteria Xanthomonas campestris were isolated by mild acid degradation of the lipopolysaccharides and studied by sugar and methylation analysis, along with 1H and 13C NMR spectroscopy. The following structures of the repeating units of the polysaccharides of X. campestris pv. phaseoli var. fuscans GSPB 271 (1). and X. campestris pv. malvacearum GSPB 1386 and GSPB 2388 (2). were established:The O-polysaccharides of X. campestris are structurally similar to those of some Pseudomonas syringae strains.     

Construction and Physiological Analysis of a Xanthomonas Mutant To Examine the Role of the oxyR Gene in Oxidant-Induced Protection against Peroxide Killing

We constructed and characterized a Xanthomonas campestris pv. phaseoli oxyR mutant. The mutant was hypersensitive to H₂O₂ and menadione killing and had reduced aerobic plating efficiency. The oxidants’ induction of the catalase and ahpC genes was also abolished in the mutant. Analysis of the adaptive responses showed that hydrogen peroxide-induced protection against hydrogen peroxide was lost, while menadione-induced protection against hydrogen peroxide was retained in the oxyR mutant. These results show that X. campestris pv. phaseoli oxyR is essential to peroxide adaptation and revealed the existence of a novel superoxide-inducible peroxide protection system that is independent of OxyR.     

Expression analysis and characterization of the mutant of a growth-phase- and starvation-regulated monofunctional catalase gene from Xanthomonas campestris pv. phaseoli

Analysis of the Xanthomonas campestris pv. phaseoli (Xp) catalase profile using an activity gel revealed at least two distinct monofunctional catalase isozymes denoted Kat1 and Kat2. Kat1 was expressed throughout growth, whereas Kat2 was expressed only during the stationary phase of growth. The nucleotide sequence of a previously isolated monofunctional catalase gene, Xp katE, was determined. The deduced amino acid sequence of Xp KatE showed a high percentage identity to an atypical group of monofunctional catalases that includes the well-characterized E. coli katE. Expression of Xp katE was growth phase-dependent but was not inducible by oxidants. In addition, growth of Xp in a carbon-starvation medium induced expression of the gene. An Xp katE mutant was constructed, and analysis of its catalase enzyme pattern showed that Xp katE coded for the Kat2 isozyme. Xp katE mutant had resistance levels similar to the parental strain against peroxide and superoxide killing at both exponential and stationary phases of growth. Interestingly, the level of total catalase activity in the mutant was similar to that of the parental strain even in stationary phase. These results suggest the existence of a novel compensatory mechanism for the activity of Xp catalase isozymes.     

Xanthomonas campestris pv. campestris secretes the endoglucanases ENGXCA and ENGXCB: construction of an endoglucanase-deficient mutant for industrial xanthan production

Xanthomonas campestris pv. campestris secretes at least two cellulose-degrading endoglucanases. One of these endoglucanases is encoded by the engXCA gene of X. c. pv. campestris 8400 that was previously characterized by Gough et al. [Gene (1990) 89: 53-59]. An additional endoglucanase encoded by the engXCB gene was identified in X. c. pv. campestris 8400 and FC2. The engXCB gene product that was grouped into the endoglucanase family E contains a putative N-terminal signal peptide, suggesting a secretion by the type II secretion system. The ENGXCB protein contributed approximately 8% to the cellulase activity in xanthan preparations. Deletion of engXCA and engXCB resulted in a fivefold reduction of the cellulose-degrading activity in xanthan preparations. The cellulase activity determined in xanthan preparations of the engXCA-engXCB mutant was only slightly higher than the activity found in preparations that were subjected to heat treatment. Mutations in engXCA and engXCB did not affect the growth rate and xanthan production of X. c. pv. campestris FC2 under several cultivation conditions. The engXCA-engXCB deletion mutant is markerless, which makes this mutant a valuable strain for xanthan production and approaches aimed at inactivating further genes encoding extracellular enzymes.     

DsbB is required for the pathogenesis process of Xanthomonas campestris pv. campestris

The DsbA/DsbB oxidation pathway is one of the two pathways that catalyze disulfide bond formation of proteins in the periplasm of gram-negative bacteria. It has been demonstrated that DsbA is essential for multiple virulence factors of several animal bacterial pathogens. In this article, we present genetic evidence to show that the open reading frame XC_3314 encodes a DsbB protein that is involved in disulfide bond formation in periplasm of Xanthomonas campestris pv. campestris, the causative agent of crucifer black rot disease. The dsbB mutant of X. campestris pv. campestris exhibited attenuation in virulence, hypersensitive response, cell motility, and bacterial growth in planta. Furthermore, mutation in the dsbB gene resulted in ineffective type II and type III secretion systems as well as flagellar assembly. These findings reveal that DsbB is required for the pathogenesis process of X. campestris pv. campestris.     

Restoration of pathogenicity of avirulent Xanthomonas oryzae pv. oryzae and X. campestris pathovars by reciprocal complementation with the hrpXo and hrpXc genes and identification of HrpX function by sequence analyses.

The molecular basis of pathogenesis by Xanthomonas oryzae pv. oryzae has been partly elucidated by the identification of a gene, hrpXo, required for bacterial blight on rice. A mutation in hrpXo results in the loss of pathogenicity on rice and the loss of hypersensitivity on nonhosts such as Datura stramonium and radishes. Pathogenicity and its ability to cause the hypersensitive reaction is restored by complementing the mutant with the heterologous hrpXc gene derived from X. campestris pv. campestris. Conversely, hrpXo complements nonpathogenic mutants of X. campestris pv. campestris and X. campetstris pv, armoraciae. Mutants bearing the heterologous hrpX gene are restored in their abilities to cause diseases typical of their chromosomal background and not the hypersensitive reaction on their respective hosts. The hrpXo and hrpXc genes are therefore functionally equivalent, and this functional equivalence extends into X. campestris pv. armoraciae and possibly into other X. campestris pathovars, since this gene is highly conserved among eight other pathovars tested. Sequence analyses of hrpXo revealed an open reading frame of 1,452 bp with a coding capacity for a protein of 52.3 kDa. The protein contains a consensus domain for possible protein myristoylation whose consequence may result in a loss of recognition by host defense and surveillance systems.     

Characterization of the hrpF pathogenicity peninsula of Xanthomonas oryzae pv. oryzae

The hrp gene cluster of Xanthomonas spp. contains genes for the assembly and function of a type III secretion system (TTSS). The hrpF genes reside in a region between hpaB and the right end of the hrp cluster. The region of the hrpF gene of Xanthomonas oryzae pv. oryzae is bounded by two IS elements and also contains a homolog of hpaF of X. campestris pv. vesicatoria and two newly identified genes, hpa3 and hpa4. A comparison of the hrp gene clusters of different species of Xanthomonas revealed that the hrpF region is a constant yet more variable peninsula of the hrp pathogenicity island. Mutations in hpaF, hpa3, and hpa4 had no effect on virulence, whereas hrpF mutants were severely reduced in virulence on susceptible rice cultivars. The hrpF genes from X. campestris pv. vesicatoria, X. campestris pv. campestris, and X. axonopodis pv. citri each were capable of restoring virulence to the hrpF mutant of X. oryzae pv. oryzae. Correspondingly, none of the Xanthomonas pathovars with hrpF from X. oryzae pv. oryzae elicited a hypersensitive reaction in their respective hosts. Therefore, no evidence was found for hrpF as a host-specialization factor. In contrast to the loss of Bs3-dependent reactions by hrpF mutants of X. campestris pv. vesicatoria, hrpF mutants of X. oryzae pv. oryzae with either avrXa10 or avrXa7 elicited hypersensitive reactions in rice cultivars with the corresponding R genes. A double hrpFxoo-hpa1 mutant also elicited an Xa10-dependent resistance reaction. Thus, loss of hrpF, hpal, or both may reduce delivery or effectiveness of type III effectors. However, the mutations did not completely prevent the delivery of effectors from X. oryzae pv. oryzae into the host cells.     

PCR-based detection of Xanthomonas campestris pv. phaseoli var. fuscans in plant material and its differentiation from X. c. pv. phaseoli

A PCR-based method was developed for the specific detection of Xanthomonas campestris pv. phaseoli var. fuscans from plant material. Primers Xf1 and Xf2, based on a sequence conserved amplified region (SCAR) derived from RAPD PCR analysis of X. c. pv. phaseoli var. fuscans , amplified a DNA fragment of 450 bp from all such isolates. In contrast, no amplification product was obtained from any X. c. pv. phaseoli isolates, or from any other DNAs tested. As few as 10 cells of X. c . pv. phaseoli var. fuscans (equivalent to about 100 fg DNA) could be detected in vitro . In planta , following an initial inoculation of as little as one cell, an amplification product was generated after only 2 d of incubation, allowing highly sensitive detection 10 d before disease symptoms were observed. Moreover, the failure to amplify DNA from X. c . pv. phaseoli isolates shows that these primers provide a rapid, improved method to differentiate these two varieties using PCR.     

The role of a bifunctional catalase-peroxidase KatA in protection of Agrobacterium tumefaciens from menadione toxicity

Agrobacterium tumefaciens is an aerobic plant pathogenic bacterium that is exposed to reactive oxygen species produced either as by-products of aerobic metabolism or by the defense systems of host plants. The physiological function of the bifunctional catalase-peroxidase (KatA) in the protection of A. tumefaciens from reactive oxygen species other than H(2)O(2) was evaluated in the katA mutant (PB102). Unexpectedly, PB102 was highly sensitive to the superoxide generator menadione. The expression of katA from a plasmid vector complemented the menadione-hypersensitive phenotype. A. tumefaciens possesses an additional catalase gene, a monofunctional catalase encoded by catE. Neither inactivation nor high-level expression of the catE gene altered the menadione resistance level. Moreover, heterologous expression of the catalase-peroxidase-encoding gene katG from Burkholderia pseudomallei, but not the monofunctional catalase gene katE from Xanthomonas campestris could restore normal levels of menadione resistance to PB102. A recent observation suggests that the menadione resistance phenotype involves increased activities of organic peroxide-metabolizing enzymes. Heterologous expression of X. campestris alkyl hydroperoxide reductase from a plasmid vector failed to complement the menadione-sensitive phenotype of PB102. The level of menadione resistance shows a direct correlation with the level of peroxidase activity of KatA. This is a novel role for KatA and suggests that resistance to menadione toxicity is mediated by a new, and as yet unknown, mechanism in A. tumefaciens.     

Identification of Xanthomonas campestris pv. campestris galactose utilization genes from transcriptome data

A 70 mer oligonucleotide microarray was constructed to analyze genome-wide expression profiles of Xanthomonas campestris pv. campestris B100, a plant-pathogenic bacterium that is industrially employed to produce the exopolysaccharide xanthan gum which has many applications as a stabilizing, thickening, gelling, and emulsifying agent in food, pharmaceutical, and cosmetic industries. As an application example, global changes of gene expression were monitored during growth of X. campestris pv. campestris B100 on two different carbon sources. Exponential growing bacterial cultures were incubated either for 1h or permanently in minimal medium supplemented with 1% galactose in comparison to growth in minimal medium supplemented with 1% glucose. Six genes were identified that were significantly increased in gene expression under both growth conditions. These genes were located in three distinguished chromosomal regions in operon-like gene clusters. Genes from these clusters encode secreted glycosidases, which were predicted to be specific for galactose-containing carbohydrates, as well as transport proteins probably located in the outer and inner cell membrane. Finally genes from one cluster code for cytoplasmic enzymes of a metabolic pathway specific for the breakdown of galactose to intermediates of glycolysis.