Unusual Growth Phase and Oxygen Tension Regulation of Oxidative Stress Protection Enzymes, Catalase and Superoxide Dismutase, in the Phytopathogen Xanthomonas oryzae pv. oryzae

The enzymes catalase and superoxide dismutase play major roles in protecting phytopathogenic bacteria from oxidative stress. In Xanthomonas species, these enzymes are regulated by both growth phase and oxygen tension. The highest enzyme levels were detected within 1 h of growth. Continued growth resulted in a decline of both enzyme activities. High oxygen tension was an inducing signal for both enzyme activities. An 80,000-Da monofunctional catalase and a manganese superoxide dismutase were the major forms of the enzymes detected at different stages of growth. The unusual regulatory patterns are common among several Xanthomonas strains tested and may be advantageous to Xanthomonas species during the initial stage of plant-microorganism interactions.     

Analysis of mutations that alter HO sensing and transcription regulation properties of a global peroxide regulator OxyR in Xanthomonas campestris pv. phaseoli

OxyR5, from a Xanthomonas campestris pv. phaseoli H(2)O(2)-resistant mutant, contains the two mutations G197D and L301R. The protein exists in its oxidized-like form in the absence of oxidants as judged by the protein's ability to activate the ahpC promoter. Analysis of DNase I footprint patterns indicates that under reducing conditions OxyR5 and OxyRG197D bind to the target site in the ahpC promoter in a manner similar to oxidized wild-type OxyR. Site-directed mutagenesis showed that OxyR5 behaves like oxidized OxyR, independent of the highly conserved C residues at positions 199 and 208 where, in normal OxyR, a disulfide bond between these residues converts the protein from its reduced to the oxidized form. The presence of aspartic acid or valine residue at position 197 caused OxyR to behave like the oxidized form in uninduced cells. Changing D197 to A or T in OxyR5 resulted in proteins with similar properties to native OxyR. In vivo, OxyR5 probably locked in an oxidized-like conformation, resulting in continuous high-level activation of target genes in the OxyR regulon.     

Copper ions potentiate organic hydroperoxide and hydrogen peroxide toxicity through different mechanisms in Xanthomonas campestris pv. campestris

Copper (Cu)-based biocides are important chemical controls for both fungal and bacterial diseases in crop fields. Here, we showed that Cu ions at a concentration of 100 μM enhanced t-butyl hydroperoxide (tBOOH) and hydrogen peroxide (H(2) O(2) ) killing of Xanthomonas campestris pv. campestris through different mechanisms. The addition of an antilipid peroxidation agent (α-tocopherol) and hydroxyl radical scavengers (glycerol and dimethyl sulphoxide) partially protected the bacteria from the Cu-enhanced tBOOH and H(2) O(2) killing, respectively. Inactivation of the alkyl hydroperoxide reductase gene rendered the mutant vulnerable to lethal doses of copper sulphate, which could be alleviated by the addition of an H(2) O(2) scavenger (pyruvate) and α-tocopherol. Taken together, the data suggest that Cu ions influence the killing effect of tBOOH through the stimulation of lipid peroxidation, while hydroxyl radical production is the underlying mechanism responsible for the Cu-ion-enhanced H(2) O(2) killing effects.     

Chemical modulation of physiological adaptation and cross-protective responses against oxidative stress in soil bacterium and phytopathogen,Xanthomonas

Soil bacteria need to adapt quickly to changes in the environmental conditions. Physiological adaptation plays an important role in microbial survival, especially under stressful conditions. Here the abilities of chemicals and pesticides to modulate physiological adaptive and cross-protective responses, that make the bacteria more resistant to oxidative stress, are examined in the soil bacterium and phytopathogen, Xanthomonas. The genetic basis for the observed stress resistance, as well as the regulatory mechanisms controlling gene expression during the process, has begun to be elucidated.

     

Characterization of Xanthomonas oryzae pv. oryzae recX, a gene that is required for high-level expression of recA

A universally primed (UP)-PCR cross hybridization assay was developed for rapid identification of isolates of Rhizoctonia solani into the correct anastomosis group (AG). Twenty-one AG tester isolates belonging to 11 AGs of R. solani were amplified with a single UP primer which generated multiple PCR fragments for each isolate. The amplified products were spotted onto a filter, immobilized and used for cross hybridization against amplification products from the different isolates. Isolates within AG subgroups cross hybridize strongly, whereas between different AGs little or no cross hybridization occurs. Sixteen Rhizoctonia isolates from diseased sugar beets and potatoes were identified using the assay. The results were supported by restriction fragment length polymorphism analysis of the ITS1-5.8S-ITS2 region of the nuclear encoded ribosomal DNA. Through standardization and use of quick non-radioactive labeling techniques, the UP-PCR cross hybridization assay has potential for routine use by modern DNA chip technology.