Cloning and characterization of katA,encoding the major monofunctional catalase from Xanthomonas campestris pv. phaseoli and characterization of the encoded catalase KatA

The first cloning and characterization of the gene katA, encoding the major catalase (KatA), from Xanthomonas is reported. A reverse genetic approach using a synthesized katA-specific DNA probe to screen a X. campestris pv. phaseoli genomic library was employed. A positively hybridizing clone designated pKat29 that contained a full-length katA was isolated. Analysis of the nucleotide sequence revealed an open reading frame of 1,521 bp encoding a 507-amino acid protein with a theoretical molecular mass of 56 kDa. The deduced amino acid sequence of KatA revealed 84% and 78% identity to CatF of Pseudomonas syringae and KatB of P. aeruginosa, respectively. Phylogenetic analysis places Xanthomonas katA in the clade I group of bacterial catalases. Unexpectedly, expression of katA in a heterologous Escherichia coli host resulted in a temperature-sensitive expression. The KatA enzyme was purified from an overproducing mutant of X. campestris and was characterized. It has apparent K(m) and V(max) values of 75 m M [H(2)O(2)] and 2.55 x 10(5) micromol H(2)O(2) micromol heme(-1) s(-1), respectively. The enzyme is highly sensitive to 3-amino-1,2,4-triazole and NaN(3), has a narrower optimal pH range than other catalases, and is more sensitive to heat inactivation.     

Analysis of growth phase regulated KatA and CatE and their physiological roles in determining hydrogen peroxide resistance in Agrobacterium tumefaciens

Agrobacterium tumefaciens possesses two catalases, a bifunctional catalase-peroxidase, KatA and a homologue of a growth phase regulated monofunctional catalase, CatE. In stationary phase cultures and in cultures entering stationary phase, total catalase activity increased 2-fold while peroxidase activity declined. katA and catE were found to be independently regulated in a growth phase dependent manner. KatA levels were highest during exponential phase and declined as cells entered stationary phase, while CatE was detectable at early exponential phase and increased during stationary phase. Only small increases in H2O2 resistance levels were detected as cells entering stationary phase. The katA mutant was more sensitive to H2O2 than the parental strain during both exponential and stationary phase. Inactivation of catE alone did not significantly change the level of H2O2 resistance. However, the katA catE double mutant was more sensitive to H2O2 during both exponential and stationary phase than either of the single catalase mutants. The data indicated that KatA plays the primary role and CatE acts synergistically in protecting A. tumefaciens from H2O2 toxicity during all phases of growth. Catalase-peroxidase activity (KatA) was required for full H2O2 resistance. The expression patterns of the two catalases in A. tumefaciens reflect their physiological roles in the protection against H2O2 toxicity, which are different from other bacteria.     

The isolation, cloning and identification of a vegetative catalase gene from Bacillus subtilis.

A Bacillus subtilis library of Tn917::lacZ insertions was screened for mutants that were unable to grow in the presence of normally sublethal concentrations of hydrogen peroxide. The identification and subsequent analysis of one mutant strain, YB2003, which carried the mutation designated kat-19, revealed that this strain was deficient in the expression of a vegetative catalase. Regions of the chromosome both 5' and 3' to the site of the Tn917 insertion, as well as the gene without the insertion (kat-19+) were cloned. The presence of the functional kat-19+ gene on a high-copy plasmid restored catalase activity to the kat-19::Tn917 strain as well as to strains of B. subtilis that carried the katA 1 mutation. While the katA+ locus is believed to represent the structural gene for the vegetative catalase of B. subtilis [Loewen and Switala, J. Bacteriol. 169 (1987) 5848-5851], the sequence analysis of the cloned kat-19+ DNA fragments revealed an open reading frame that showed significant homology between the deduced amino acid sequence of this gene product and that of known eukaryotic catalases.     

Unusual properties of catalase A (KatA) of Pseudomonas aeruginosa PA14 are associated with its biofilm peroxide resistance

Pseudomonas aeruginosa is a ubiquitous environmental bacterium whose major catalase (KatA) is highly stable, extracellularly present, and required for full virulence as well as for peroxide resistance in planktonic and biofilm states. Here, we dismantled the function of P. aeruginosa KatA (KatA(Pa)) by comparing its properties with those of two evolutionarily related (clade 3 monofunctional) catalases from Bacillus subtilis (KatA(Bs)) and Streptomyces coelicolor (CatA(Sc)). We switched the coding region for KatA(Pa) with those for KatA(Bs) and CatA(Sc), expressed the catalases under the potential katA-regulatory elements in a P. aeruginosa PA14 katA mutant, and verified their comparable protein levels by Western blot analysis. The activities of KatA(Bs) and CatA(Sc), however, were less than 40% of the KatA(Pa) activity, suggestive of the difference in intrinsic catalatic activity or efficiency for posttranslational activity modulation in P. aeruginosa. Furthermore, KatA(Bs) and CatA(Sc) were relatively susceptible to proteinase K, whereas KatA(Pa) was highly stable upon proteinase K treatment. As well, KatA(Bs) and CatA(Sc) were undetectable in the extracellular milieu. Nevertheless, katA(Bs) and catA(Sc) fully rescued the peroxide sensitivity and osmosensitivity of the katA mutant, respectively. Both catalase genes rescued the attenuated virulence of the katA mutant in mouse acute infection and Drosophila melanogaster models. However, the peroxide susceptibility of the katA mutant in a biofilm growth state was rescued by neither katA(Bs) nor catA(Sc). Based on these results, we propose that the P. aeruginosa KatA is highly stable compared to the two major catalases from gram-positive bacteria and that its unique properties involving metastability and extracellular presence may contribute to the peroxide resistance of P. aeruginosa biofilm and presumably to chronic infections.     

转座子挽救法对苜蓿中华根瘤菌与耐盐有关基因的定位

用含Tn5转座子的质粒pRL1063a诱变苜蓿中华根瘤菌(Sinorhizobium meliloti)042BM,得到盐敏感突变株042BML-2。采用转座子挽救法对Tn5插入位点两边的序列进行克隆与测序,获得了1179bp的转座子插入位点侧翼DNA序列。在GenBank中进行序列同源性和基因定位分析,结果表明：转座子插入在一个功能未知的基因内部,此基因长6270bp。研究证明：该基因与042BM的耐盐性有关,并定名为rtsC。氨基酸疏水性分析表明,在RtsC蛋白的N端有两个跨膜区,该蛋白与细菌趋化性相关蛋白的功能域有同源性。并对RtsC蛋白在苜蓿中华根瘤菌042BM耐盐性中的作用进行了讨论。     

Purification and physical-chemical characterization of the three hydroperoxidases from the symbiotic bacterium Sinorhizobium meliloti

Three genes encoding heme hydroperoxidases (katA, katB, and katC) have been identified in the soil bacterium Sinorhizobium meliloti. The recombinant proteins were overexpressed in Escherichia coli and purified in order to achieve a spectral and kinetic characterization. The three proteins contain heme b with high-spin Fe(III). KatB is an acidic bifunctional homodimeric catalase-peroxidase exhibiting both catalase (k(cat) = 2400 s(-1)) and peroxidase activity and having a high affinity for hydrogen peroxide (apparent K(M) = 1.6 mM). KatA and KatC are acidic monofunctional homotetrameric catalases. Although different in size (KatA is a small subunit catalase while KatC is a large subunit catalase) both enzymes exhibit the same heme type and a similar affinity for H(2)O(2) (apparent K(M) values of 160 and 150 mM). However, the turnover rate of KatA (k(cat) = 279000 s(-1)) exceeds that of KatC (k(cat) = 3100 s(-1)) significantly. The kinetic parameters are in good agreement with the physiological role of these heme proteins. KatB is the housekeeping hydroperoxidase exhibiting the highest affinity for hydrogen peroxide, while KatA has the lowest H(2)O(2) affinity but the highest k(cat)/K(M) value (1.75 x 10(6) M(-1) s(-1)), in agreement with the hydrogen peroxide inducibility of the encoding gene. Moreover, the lower catalytic efficiency of KatC (2.1 x 10(4) M(-1) s(-1)) appears to be enough for growing in the stationary phase and/or under heat or salt stress (conditions that are known to favor katC expression).     

Rhizobium meliloti nifN (fixF) gene is part of an operon regulated by a nifA-dependent promoter and codes for a polypeptide homologous to the nifK gene product.

An essential gene for symbiotic nitrogen fixation (fixF) is located near the common nodulation region of Rhizobium meliloti. A DNA fragment carrying fixF was characterized by hybridization with Klebsiella pneumoniae nif DNA and by nucleotide sequence analysis. The fixF gene was found to be related to K. pneumoniae nifN and was therefore renamed as the R. meliloti nifN gene. Upstream of the nifN coding region a second open reading frame was identified coding for a putative polypeptide of 110 amino acids (ORF110). By fragment-specific Tn5 mutagenesis it was shown that the nifN gene and ORF110 form an operon. The control region of this operon contains a nif promoter and also the putative nifA-binding sequence. For the deduced amino acid sequence of the nifN gene product a striking homology to the R. meliloti nifK protein was found. One cysteine residue and its adjacent amino acid sequence, which are highly conserved in the R. meliloti nifK, R. meliloti nifN, and K. pneumoniae nifN proteins, may play a role in binding the FeMo cofactor.     

Feedback regulation of an Agrobacterium catalase gene katA involved in Agrobacterium–plant interaction

Catalases are known to detoxify H2O2, a major component of oxidative stress imposed on a cell. An Agrobacterium tumefaciens catalase encoded by a chromosomal gene katA has been implicated as an important virulence factor as it is involved in detoxification of H2O2 released during Agrobacterium-plant interaction. In this paper, we report a feedback regulation pathway that controls the expression of katA in A. tumefaciens cells. We observed that katA could be induced by plant tissue sections and by acidic pH on a minimal medium, which resembles the plant environment that the bacteria encounter during the course of infection. This represents a new regulatory factor for catalase induction in bacteria. More importantly, a feedback regulation was observed when the katA-gfp expression was studied in different genetic backgrounds. We found that introduction of a wild-type katA gene encoding a functional catalase into A. tumefaciens cells could repress the katA-gfp expression over 60-fold. The katA gene could be induced by H2O2 and the encoded catalase could detoxify H2O2. In addition, the katA-gfp expression of one bacterial cell could be repressed by other surrounding catalase-proficient bacterial cells. Furthermore, mutation at katA caused a 10-fold increase of the intracellular H2O2 concentration in the bacteria grown on an acidic pH medium. These results suggest that the endogenous H2O2 generated during A. tumefaciens cell growth could serve as the intracellular and intercellular inducer for the katA gene expression and that the acidic pH could pose an oxidative stress on the bacteria. Surprisingly, one mutated KatA protein, exhibiting no significant catalase activity as a result of the alteration of two important residues at the putative active site, could partially repress the katA-gfp expression. The feedback regulation of the katA gene by both catalase activity and KatA protein could presumably maintain an appropriated level of catalase activity and H2O2 inside A. tumefaciens cells.     

Catalase (KatA) and alkyl hydroperoxide reductase (AhpC) have compensatory roles in peroxide stress resistance and are required for survival, persistence, and nasal colonization in Staphylococcus aureus

Oxidative-stress resistance in Staphylococcus aureus is linked to metal ion homeostasis via several interacting regulators. In particular, PerR controls the expression of a regulon of genes, many of which encode antioxidants. Two PerR regulon members, ahpC (alkylhydroperoxide reductase) and katA (catalase), show compensatory regulation, with independent and linked functions. An ahpC mutation leads to increased H2O2 resistance due to greater katA expression via relief of PerR repression. Moreover, AhpC provides residual catalase activity present in a katA mutant. Mutation of both katA and ahpC leads to a severe growth defect under aerobic conditions in defined media (attributable to lack of catalase activity). This results in the inability to scavenge exogenous or endogenously produced H2O2, resulting in accumulation of H2O2 in the medium. This leads to DNA damage, the likely cause of the growth defect. Surprisingly, the katA ahpC mutant is not attenuated in two independent models of infection, which implies reduced oxygen availability during infection. In contrast, both AhpC and KatA are required for environmental persistence (desiccation) and nasal colonization. Thus, oxidative-stress resistance is an important factor in the ability of S. aureus to persist in the hospital environment and so contribute to the spread of human disease.     

The katA catalase gene is regulated by OxyR in both free-living and symbiotic Sinorhizobium meliloti

The characterization of an oxyR insertion mutant provides evidences that katA, which encodes the unique H2O2-inducible HPII catalase, is regulated by OxyR not only in free-living Sinorhizobium meliloti but also in symbiotic S. meliloti. Moreover, oxyR is expressed independently of exogenous H2O2 and downregulates its own expression in S. meliloti.     

At least two nodD genes are necessary for efficient nodulation of alfalfa by Rhizobium meliloti

A Rhizobium meliloti DNA region (nodD1) involved in the regulation of other early nodulation genes has been delimited by directed Tn5 mutagenesis and its nucleotide sequence has been determined. The sequence data indicate a large open reading frame with opposite polarity to nodA, -B and -C, coding for a protein of 308 (or 311) amino acid residues. Tn5 insertion within the gene caused a delay in nodulation of Medicago sativa from four to seven days. Hybridization of nodD1 to total DNA of Rhizobium meliloti revealed two additional nodD sequences (nodD2 and nodD3) and both were localized on the megaplasmid pRme41b in the vicinity of the other nod genes. Genetic and DNA hybridization data, combined with nucleotide sequencing showed that nodD2 is a functional gene, while requirement of nodD3 for efficient nodulation of M. sativa could not be detected under our experimental conditions. The nodD2 gene product consists of 310 amino acid residues and shares 86.4% homology with the nodD1 protein. Single nodD2 mutants had the same nodulation phenotype as the nodD1 mutants, while a double nodD1-nodD2 mutant exhibited a more severe delay in nodulation. These results indicate that at least two functional copies of the regulatory gene nodD are necessary for the optimal expression of nodulation genes in R. meliloti.     

Rhodococcus equi's Extreme Resistance to Hydrogen Peroxide Is Mainly Conferred by One of Its Four Catalase Genes

Rhodococcus equi is one of the most widespread causes of disease in foals aged from 1 to 6 months. R. equi possesses antioxidant defense mechanisms to protect it from reactive oxygen metabolites such as hydrogen peroxide (H(2)O(2)) generated during the respiratory burst of phagocytic cells. These defense mechanisms include enzymes such as catalase, which detoxify hydrogen peroxide. Recently, an analysis of the R. equi 103 genome sequence revealed the presence of four potential catalase genes. We first constructed ΔkatA-, ΔkatB-, ΔkatC-and ΔkatD-deficient mutants to study the ability of R. equi to survive exposure to H(2)O(2)in vitro and within mouse peritoneal macrophages. Results showed that ΔkatA and, to a lesser extent ΔkatC, were affected by 80 mM H(2)O(2). Moreover, katA deletion seems to significantly affect the ability of R. equi to survive within murine macrophages. We finally investigated the expression of the four catalases in response to H(2)O(2) assays with a real time PCR technique. Results showed that katA is overexpressed 367.9 times (±122.6) in response to exposure to 50 mM of H(2)O(2) added in the stationary phase, and 3.11 times (±0.59) when treatment was administered in the exponential phase. In untreated bacteria, katB, katC and katD were overexpressed from 4.3 to 17.5 times in the stationary compared to the exponential phase. Taken together, our results show that KatA is the major catalase involved in the extreme H(2)O(2) resistance capability of R. equi.