KatA, the Major Catalase, Is Critical for Osmoprotection and Virulence in Pseudomonas aeruginosa PA14
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感染与免疫杂志 2005年第7期
Department of Life Science, Sogang University, Seoul 121-742, Korea
ABSTRACT
We demonstrate that among the three monofunctional catalases of Pseudomonas aeruginosa PA14, KatA and, to a lesser extent, KatB, but not KatE, are required for resistance to peroxide and osmotic stresses. KatA is crucial for adaptation to H2O2 stress and full virulence in both Drosophila melanogaster and mice. This dismantling of catalase roles represents a specialized catalytic system primarily involving KatA in responses to adverse environmental conditions.
TEXT
Catalases are central components of the enzymatic detoxification pathways that prevent the formation of the highly reactive hydroxyl radical (HO.) by decomposing hydrogen peroxide (H2O2) and contribute to a variety of physiological processes involving adaptation and survival mechanisms. Because the toxicity of H2O2 released by phagocytes has been implicated in the host innate immune responses, bacterial pathogens exploit catalytic enzyme systems to survive the host environments. Although the involvement of catalases in virulence mechanisms has been demonstrated in many bacterial pathogens, little is known on the roles of catalases in the pathogenesis of Pseudomonas aeruginosa, an opportunistic human pathogen that is frequently associated with the alveolar surface and is most likely subjected to oxidative stresses within the pulmonary airways (1).
P. aeruginosa is a unique bacterium that has three differentially evolved monofunctional catalase genes, katA, katB, and katE, but no bifunctional catalase (catalase-peroxidase) gene on its genome (25). Like other clade 3 monofunctional catalases, the major catalase, KatA, is H2O2 inducible (4, 13, 18). The expression of a second H2O2-inducible catalase, KatB, that belongs to clade 1 is noteworthy (2, 14). The third catalase, KatE, is one of the clade 2 catalases that are highly conserved among most bacterial species (3, 14). With the exception of a Streptomyces coelicolor catalase (CatB) that plays important roles in osmoprotection and differentiation (5), little else is known about the physiological role of clade 2 catalases.
The purpose of this work is to systematically determine the roles of the three differentially evolved monofunctional catalases in stress responses and survival mechanisms of P. aeruginosa strain PA14 (20). We used nonpolar, unmarked deletion mutants of each catalase and investigated their resistance and adaptation in response to stress conditions in vitro and their virulence in Drosophila melanogaster and mice. We demonstrate that KatA plays an important role in virulence and oxidative and/or osmotic stress responses. In combination with the previously published studies (2, 10, 11, 18, 19, 26), these results suggest the specialized roles of P. aeruginosa catalases in response to environmental stresses and pathogenic interactions as well.
Construction of catalase mutants of P. aeruginosa PA14 and their resistance to H2O2. The genome sequence of the P. aeruginosa reference strain PAO1 reveals three monofunctional catalase genes, katA, katB, and katE, of different evolutionary origins, clade 3, clade 1, and clade 2, respectively (13, 14). No homologue of bifunctional catalases has been found in P. aeruginosa thus far. Isolation of the gene encoding a manganese-containing nonheme pseudocatalase from lactic acid bacteria (12) and compilation of its homologous sequences from the bacterial genome sequence databases revealed a homologous gene (PA2185 or katM after Mn-catalase) on the 12th variable segment of the PAO1 genome (21).
Most P. aeruginosa strains, including PA14, do not harbor a katM gene (28; Heo and Cho, unpublished). As summarized in Table 1, we have created seven unmarked deletions (katA, katB, katE, katAB, katAE, katBE, and katABE) in strain PA14 to systematically address the potential role of catalases in stress responses and virulence (15).
We have verified all the catalase mutants through genetic structure analyses by PCR and Southern hybridization (Fig. 1) (15), expression profiles by total catalase activity staining (15), and growth inhibition on plates containing 100 μM H2O2 (Fig. 2A). All the mutants exhibited doubling times similar to that of the wild type (15). The growth of the katA and to a lesser extent katB but not katE mutants was inhibited by H2O2. The contribution of KatB to H2O2 resistance was more evident in the katAB mutant (Fig. 2A).
The H2O2 sensitivity of the katA mutant was completely restored by introducing the pUCP18 (22)-derived plasmid containing appropriate full-length catalase constructs (Fig. 2B). In contrast, multicopy expression of the katB gene only partially restored the H2O2 resistance of the katA mutant. We conclude that the KatA is most critical in H2O2 resistance, whereas resistance mediated by KatB was only discernible when KatA expression was abolished. In contrast, katE does not affect H2O2 resistance.
KatA is required for adaptation to H2O2 in P. aeruginosa PA14. In an attempt to investigate the roles of catalases in the adaptation to H2O2 stress, we examined the sensitivity of PA14 to H2O2 in liquid culture. Mid-logarithmic PA14 cells were pretreated with a nonlethal level of H2O2 (1 mM) for 30 min before being exposed to the killing concentration of H2O2 (100 mM). A 30-min treatment time was chosen to investigate the steady-state response rather than the early and acute responses. The viability of cells was determined at 5-min intervals. Less than 0.1% of the unadapted or naive cells remained viable 10 min after exposure to 100 mM H2O2. In contrast, when cells were pretreated with 1 mM H2O2, survival was enhanced more than 1,000-fold (Fig. 3A). The sublethal pretreatment affected the cells' growth and/or survival compared to the control (60% survival as shown in Fig. 3B) and is slightly harsher than those previously described in other bacteria (7, 8, 9, 17).
We analyzed all the catalase mutants in the adaptation experiment to determine whether catalases participate in the adaptive response to H2O2. The katA mutant was more sensitive to 1 mM H2O2 than the wild type was. Moreover, the katAB mutant was even more sensitive (<10–4 viability) to the pretreatment. Therefore, the residual survival (25%) of the katA mutant bacteria by the pretreatment may be attributed to KatB, which is in a good agreement with the results on solid agar culture (Fig. 2A). The H2O2 pretreatment enhanced the cells' resistance and viability against the killing concentration of H2O2, which was completely abolished in the katA mutant. Killing of the pretreated katB and katE mutant bacteria by 1 mM H2O2 was discernible (Fig. 3B and data not shown). This result suggests that the basal and/or inducible expression of KatA, but not KatB, is responsible for the adaptation to H2O2, despite the rapid induction of katB by H2O2 in the presence of functional KatA (19) (data not shown).
It is clear, however, that KatA and KatB have overlapping but distinct roles in oxidative stress responses, since the multicopy KatB failed to fully compensate for the absence of KatA in terms of H2O2 resistance and adaptation (data not shown). The catalytic functions involving both KatA and KatB during normal growth and oxidative stress remain to be further deciphered by combining this result with detailed and systematic gene expression analyses in each catalase mutant background with or without oxidative challenge.
KatA is preponderantly required for osmoprotection in P. aeruginosa PA14. A minor catalase (CatB) from the actinomycete S. coelicolor is known to be required for resistance to osmotic stress and differentiation (5). We tested whether P. aeruginosa catalase mutants are susceptible to osmotic stresses. As shown in Fig. 4A, KatA was critical in the resistance to KCl treatments (0.8 M and 0.9 M), whereas deletion of katB or katE had no significant effect on salt resistance. However, the different KCl sensitivities of the katA and katAB mutants, depending on the KCl concentration, suggest that KatB may play a minor role in osmoresistance as in H2O2 resistance (Fig. 2).
Since KCl increases ionic strength as well as osmotic strength, we used a nonionic osmolyte, sucrose, with comparable amounts of KCl (23). As shown in Fig. 4B, sucrose treatments at 32% (0.89 M) and 34% (0.94 M) exhibited similar results as observed in KCl treatments, uncovering the involvement of KatA in sucrose resistance, although the responses to the two different concentrations were more subtle than those in the KCl treatments, especially in the katA and katAB mutants, indicating the minor role of KatB in this condition.
The sensitive phenotype of the katA mutant was restored by trans complementation with the pUCP18-derived plasmid expressing KatA (Fig. 4C). Unlike H2O2 sensitivity, however, multicopy KatB could not restore growth of the katA mutant on salt-containing media, which may imply differential functions and/or regulations of KatA and KatB in response to osmotic stress.
It is intriguing that the cell-free culture supernatant from the wild-type culture in the stationary growth phase could restore the KCl sensitivity of the katA mutant, although we were not sure whether or not the supplied activities absent in the culture supernatant of the katA mutant were working extracellularly. Further experimentation is needed to unravel how catalases such as P. aeruginosa KatA and S. coelicolor CatB protect against osmotic stresses. Considering that the general stress responses likely require alternative sigma factors (3, 6), it will be of special interest to analyze the gene expression in response to specific and general stress conditions.
KatA is required for virulence in P. aeruginosa PA14. The in vitro oxidative and osmotic stress phenotypes of catalase mutants are most likely related to the survival pathways, and therefore likely implicated in virulence due to unfavorable conditions P. aeruginosa may encounter in the host environment. We examined whether the P. aeruginosa catalases play a role in host infection using the D. melanogaster model, since it was a simple alternative model host to evaluate P. aeruginosa virulence potentials, as measured by fly mortality and in vivo proliferation of P. aeruginosa (16, 27).
D. melanogaster infection was performed by pricking 2- to 5-day-old adult flies with 50 to 200 CFU of PA14 cells as described previously (16). Mortality was monitored at 25°C for up to 54 h postinfection (Fig. 5). Four catalase mutants (katA, katAB, katAE, and katABE) commonly deficient in KatA exhibited significant virulence attenuations in terms of delayed death kinetics (by more than 10 h) and lower mortality, whereas the remaining three mutants (katB, katE, and katBE) were as virulent as the wild type (Fig. 5A). Reintroduction of the full-length katA gene restored the attenuated virulence of the katA mutant to the wild-type level, whereas katA mutant cells harboring a multicopy plasmid expressing either KatB or KatE were still avirulent (Fig. 5B).
The virulence attenuation of the katA mutant was verified by bacterial proliferation in D. melanogaster (Fig. 6). PA14 cells proliferate almost exponentially in flies, as described by Lee et al. (16), where the linear regression analyses from the 57 data points (from live flies) gave a slope of 0.1734, which is statistically significant (r2 = 0.897). The slope corresponds to a doubling time of 1.736 h. However, not all katA cells proliferate exponentially in flies, unlike the wild type. The bacterial proliferations from 78 live flies were delayed about 6 h, and some infected flies completely cleared the bacteria (Fig. 6B).
The involvement of KatA in virulence was further verified in mammalian hosts, using the mouse peritonitis model as described previously (24). The mice were monitored from 6 to 64 h after intraperitoneal challenge with 5 x 106 CFU of bacterial cells and regarded as dead when they displayed ruffled fur, evidence of dehydration, and nonresponsiveness to stimuli. More than 90% of the mice that had been infected with the wild-type cells died within 36 h in our experimental conditions (Fig. 7). As in D. melanogaster, the katA, katAB, katAE, and katABE mutants were less virulent in the mouse peritonitis model, with 40% mice surviving the infection, exhibiting delayed killing (by more than 20 h).
Conclusion. These phenotypic analyses of the three monofunctional catalases (KatA, KatB, and KatE) in P. aeruginosa PA14 suggest that the catalytic system of KatA is crucial for oxidative and osmotic stress responses. KatA is also required for adaptation to peroxide stress and for virulence of this bacterium, which is intuitively understandable in that it is critical for stress responses as well as adaptations in vitro that may resemble unfavorable host environments. It is also explainable in part by the regulation of katA, which involves quorum-sensing circuits (11).
The pivotal roles of KatA in virulence mechanisms can be further authenticated and generalized, by investigating its involvement in virulence of other P. aeruginosa strains such as PAO1, since the multifactorial nature of virulence pathways is related with the genetic backgrounds that accounts for different virulence potentials, and its expression and regulation in conjunction with related enzymes and regulators such as RpoS and OxyR.
ACKNOWLEDGMENTS
We are grateful to Gee Lau for helpful comments.
This work was supported by grants from the 21C Frontier Microbial Genomics and Applications Center (MG05-0104-05-0) and the Korea Research Foundation (2004-015-C00505) and by a Special Research Grant from Sogang University (2002-3010) to Y.-H. Cho.
REFERENCES
1. Bodey, G. P., R. Bolivar, V. Fainstein, and L. Jadeja. 1983. Infections caused by Pseudomonas aeruginosa. Rev. Infect. Dis. 5:279-313.
2. Brown, S. M., M. L. Howell, M. L. Vasil, A. J. Anderson, and D. J. Hassett. 1995. Cloning and characterization of the katB gene of Pseudomonas aeruginosa encoding a hydrogen peroxide-inducible catalase: purification of KatB, cellular localization, and demonstration that it is essential for optimal resistance to hydrogen peroxide. J. Bacteriol. 177:6536-6544.
3. Cho, Y.-H. 1999. Gene expression and the role of catalases in Streptomyces coelicolor A3(2). Ph.D. thesis. Seoul National University, Seoul, Korea.
4. Cho, Y.-H., and J.-H. Roe. 1997. Isolation and expression of the catA gene encoding the major vegetative catalase in Streptomyces coelicolor Müller. J. Bacteriol. 179:4049-4052.
5. Cho, Y.-H., E.-J. Lee, and J.-H. Roe. 2000. A developmentally regulated catalase required for proper differentiation and osmoprotection of Streptomyces coelicolor. Mol. Microbiol. 35:150-160.
6. Cho, Y.-H., E.-J. Lee, B.-E. Ahn, and J.-H. Roe. 2001. SigB, an RNA polymerase sigma factor required for osmoprotection and proper differentiation of Streptomyces coelicolor. Mol. Microbiol. 42:205-214.
7. Christman, M. F., R. W. Morgan, F. S. Jacobson, and B. N. Ames. 1985. Positive control of a regulon for defenses against oxidative stress and some heat-shock proteins in Salmonella typhimurium. Cell 41:753-762.
8. Demple, B., J. Halbrook, and S. Linn. 1983. Escherichia coli xth mutants are hypersensitive to hydrogen peroxide. J. Bacteriol. 153:1079-1082.
9. Dowds, B. C., P. Murphy, D. J. McConnell, and K. M. Devine. 1987. Relationship among oxidative stress, growth cycle, and sporulation in Bacillus subtilis. J. Bacteriol. 169:5771-5775.
10. Hassett, D. J., E. Alsabbagh, K. Parvatiyar, M. L. Howell, R. W. Wilmott, and U. A. Ochsner. 2000. A protease-resistant catalase, KatA, released upon cell lysis during stationary phase is essential for aerobic survival of a Pseudomonas aeruginosa oxyR mutant at low cell densities. J. Bacteriol. 182:4557-4563.
11. Hassett, D. J., J. F. Ma, J. G. Elkins, T. R. McDermott, U. A. Ochsner, S. E. West, C. T. Huang, J. Fredericks, S. Burnett, P. S. Stewart, G. McFeters, L. Passador, and B. H. Iglewski. 1999. Quorum sensing in Pseudomonas aeruginosa controls expression of catalase and superoxide dismutase genes and mediates biofilm susceptibility to hydrogen peroxide. Mol. Microbiol. 34:1082-1093.
12. Igarashi, T., Y. Kono, and K. Tanaka. 1996. Molecular cloning of manganese catalase from Lactobacillus plantarum. J. Biol. Chem. 271:29521-29524.
13. Klotz, M. G., and P. C. Loewen. 2003. The molecular evolution of catalytic hydroperoxidases: evidence for multiple lateral transfer of genes between prokaryota and from bacteria into eukaryota. Mol. Biol. Evol. 20:1098-1112.
14. Klotz, M. G., G. R. Klassen, and P. C. Loewen. 1997. Phylogenetic relationships among prokaryotic and eukaryotic catalases. Mol. Biol. Evol. 14:951-958.
15. Lee, J.-S. 2005. Phenotypic analyses of of monofunctional catalases in Pseudomonas aeruginosa. M.S. thesis. Sogang University, Seoul, Korea.
16. Lee, J.-S., S.-H. Kim, and Y.-H. Cho. 2004. Dithiothreitol attenuates the pathogenic interaction between Pseudomonas aeruginosa and Drosophila melanogaster. J. Microbiol. Biotechnol. 14:367-372.
17. Lee, J.-S., Y.-C. Hah, and J.-H. Roe. 1993. The induction of oxidative enzymes in Streptomyces coelicolor upon hydrogen peroxide treatment. J. Gen. Microbiol. 139:1013-1018.
18. Ochsner, U. A., M. L. Vasil, E. Alsabbagh, K. Parvatiyar, and D. J. Hassett. 2000. Role of the Pseudomonas aeruginosa oxyR-recG operon in oxidative stress defense and DNA repair: OxyR-dependent regulation of katB-ankB, ahpB, and ahpC-ahpF. J. Bacteriol. 182:4533-4544.
19. Palma, M., D. DeLuca, S. Worgall, and L. E. Quadri. 2004. Transcriptome analysis of the response of Pseudomonas aeruginosa to hydrogen peroxide. J. Bacteriol. 186:248-252.
20. Rahme, L. G., E. J. Stevens, S. F. Wolfort, J. Shao, R. G. Tompkins, and F. M. Ausubel. 1995. Common virulence factors for bacterial pathogenicity in plants and animals. Science 268:1899-1902.
21. Robbe-Saule, V., C. Coynault, M. Ibanez-Ruiz, D. Hermant, and F. Norel. 2001. Identification of a non-haem catalase in Salmonella and its regulation by RpoS (S). Mol. Microbiol. 39:1533-1545.
22. Schweizer, H. P. 1991. Escherichia-Pseudomonas shuttle vectors derived from pUC18/19. Gene 97:109-121.
23. Shortridge, V. D., A. Lazdunski, and M. L. Vasil. 1992. Osmoprotectants and phosphate regulate expression of phospholipase C in Pseudomonas aeruginosa. Mol. Microbiol. 6:863-871.
24. Sonnleitner, E., S. Hagens, F. Rosenau, S. Wilhelm, A. Habel, K. E. Jager, and U. Blasi. 2003. Reduced virulence of a hfq mutant of Pseudomonas aeruginosa O1. Microb. Pathog. 35:217-228.
25. Stover, C. K., X. Q. Pham, A. L. Erwin, S. D. Mizoguchi, P. Warrener, M. J. Hickey, F. S. Brinkman, W. O. Hufnagle, D. J. Kowalik, M. Lagrou, R. L. Garber, L. Goltry, E. Tolentino, S. Westbrock-Wadman, Y. Yuan, L. L. Brody, S. N. Coulter, K. R. Folger, A. Kas, K. Larbig, R. Lim, K. Smith, D. Spencer, G. K. Wong, Z. Wu, I. T. Paulsen, J. Reizer, M. H. Saier, R. E. Hancock, S. Lory, and M. V. Olson. 2000. Complete genome sequence of Pseudomonas aeruginosa PAO1, an opportunistic pathogen. Nature 406:959-964.
26. Suh, S. J., L. Silo-Suh, D. E. Woods, D. J. Hassett, S. E. West, and D. E. Ohman. 1999. Effect of rpoS mutation on the stress response and expression of virulence factors in Pseudomonas aeruginosa. J. Bacteriol. 181:3890-3897.
27. Vodovar, N., C. Acosta, B. Lemaitre, and F. Boccard. 2004. Drosophila: a polyvalent model to decipher host-pathogen interactions. Trends Microbiol. 12:235-242.
28. Wolfgang, M. C., B. R. Kulasekara, X. Liang, D. Boyd, K. Wu, Q. Yang, C. G. Miyada, and S. Lory. 2003. Conservation of genome content and virulence determinants among clinical and environmental isolates of Pseudomonas aeruginosa. Proc. Natl. Acad. Sci. USA 100:8484-8489.(Ji-Sun Lee, Yun-Jeong Heo)
ABSTRACT
We demonstrate that among the three monofunctional catalases of Pseudomonas aeruginosa PA14, KatA and, to a lesser extent, KatB, but not KatE, are required for resistance to peroxide and osmotic stresses. KatA is crucial for adaptation to H2O2 stress and full virulence in both Drosophila melanogaster and mice. This dismantling of catalase roles represents a specialized catalytic system primarily involving KatA in responses to adverse environmental conditions.
TEXT
Catalases are central components of the enzymatic detoxification pathways that prevent the formation of the highly reactive hydroxyl radical (HO.) by decomposing hydrogen peroxide (H2O2) and contribute to a variety of physiological processes involving adaptation and survival mechanisms. Because the toxicity of H2O2 released by phagocytes has been implicated in the host innate immune responses, bacterial pathogens exploit catalytic enzyme systems to survive the host environments. Although the involvement of catalases in virulence mechanisms has been demonstrated in many bacterial pathogens, little is known on the roles of catalases in the pathogenesis of Pseudomonas aeruginosa, an opportunistic human pathogen that is frequently associated with the alveolar surface and is most likely subjected to oxidative stresses within the pulmonary airways (1).
P. aeruginosa is a unique bacterium that has three differentially evolved monofunctional catalase genes, katA, katB, and katE, but no bifunctional catalase (catalase-peroxidase) gene on its genome (25). Like other clade 3 monofunctional catalases, the major catalase, KatA, is H2O2 inducible (4, 13, 18). The expression of a second H2O2-inducible catalase, KatB, that belongs to clade 1 is noteworthy (2, 14). The third catalase, KatE, is one of the clade 2 catalases that are highly conserved among most bacterial species (3, 14). With the exception of a Streptomyces coelicolor catalase (CatB) that plays important roles in osmoprotection and differentiation (5), little else is known about the physiological role of clade 2 catalases.
The purpose of this work is to systematically determine the roles of the three differentially evolved monofunctional catalases in stress responses and survival mechanisms of P. aeruginosa strain PA14 (20). We used nonpolar, unmarked deletion mutants of each catalase and investigated their resistance and adaptation in response to stress conditions in vitro and their virulence in Drosophila melanogaster and mice. We demonstrate that KatA plays an important role in virulence and oxidative and/or osmotic stress responses. In combination with the previously published studies (2, 10, 11, 18, 19, 26), these results suggest the specialized roles of P. aeruginosa catalases in response to environmental stresses and pathogenic interactions as well.
Construction of catalase mutants of P. aeruginosa PA14 and their resistance to H2O2. The genome sequence of the P. aeruginosa reference strain PAO1 reveals three monofunctional catalase genes, katA, katB, and katE, of different evolutionary origins, clade 3, clade 1, and clade 2, respectively (13, 14). No homologue of bifunctional catalases has been found in P. aeruginosa thus far. Isolation of the gene encoding a manganese-containing nonheme pseudocatalase from lactic acid bacteria (12) and compilation of its homologous sequences from the bacterial genome sequence databases revealed a homologous gene (PA2185 or katM after Mn-catalase) on the 12th variable segment of the PAO1 genome (21).
Most P. aeruginosa strains, including PA14, do not harbor a katM gene (28; Heo and Cho, unpublished). As summarized in Table 1, we have created seven unmarked deletions (katA, katB, katE, katAB, katAE, katBE, and katABE) in strain PA14 to systematically address the potential role of catalases in stress responses and virulence (15).
We have verified all the catalase mutants through genetic structure analyses by PCR and Southern hybridization (Fig. 1) (15), expression profiles by total catalase activity staining (15), and growth inhibition on plates containing 100 μM H2O2 (Fig. 2A). All the mutants exhibited doubling times similar to that of the wild type (15). The growth of the katA and to a lesser extent katB but not katE mutants was inhibited by H2O2. The contribution of KatB to H2O2 resistance was more evident in the katAB mutant (Fig. 2A).
The H2O2 sensitivity of the katA mutant was completely restored by introducing the pUCP18 (22)-derived plasmid containing appropriate full-length catalase constructs (Fig. 2B). In contrast, multicopy expression of the katB gene only partially restored the H2O2 resistance of the katA mutant. We conclude that the KatA is most critical in H2O2 resistance, whereas resistance mediated by KatB was only discernible when KatA expression was abolished. In contrast, katE does not affect H2O2 resistance.
KatA is required for adaptation to H2O2 in P. aeruginosa PA14. In an attempt to investigate the roles of catalases in the adaptation to H2O2 stress, we examined the sensitivity of PA14 to H2O2 in liquid culture. Mid-logarithmic PA14 cells were pretreated with a nonlethal level of H2O2 (1 mM) for 30 min before being exposed to the killing concentration of H2O2 (100 mM). A 30-min treatment time was chosen to investigate the steady-state response rather than the early and acute responses. The viability of cells was determined at 5-min intervals. Less than 0.1% of the unadapted or naive cells remained viable 10 min after exposure to 100 mM H2O2. In contrast, when cells were pretreated with 1 mM H2O2, survival was enhanced more than 1,000-fold (Fig. 3A). The sublethal pretreatment affected the cells' growth and/or survival compared to the control (60% survival as shown in Fig. 3B) and is slightly harsher than those previously described in other bacteria (7, 8, 9, 17).
We analyzed all the catalase mutants in the adaptation experiment to determine whether catalases participate in the adaptive response to H2O2. The katA mutant was more sensitive to 1 mM H2O2 than the wild type was. Moreover, the katAB mutant was even more sensitive (<10–4 viability) to the pretreatment. Therefore, the residual survival (25%) of the katA mutant bacteria by the pretreatment may be attributed to KatB, which is in a good agreement with the results on solid agar culture (Fig. 2A). The H2O2 pretreatment enhanced the cells' resistance and viability against the killing concentration of H2O2, which was completely abolished in the katA mutant. Killing of the pretreated katB and katE mutant bacteria by 1 mM H2O2 was discernible (Fig. 3B and data not shown). This result suggests that the basal and/or inducible expression of KatA, but not KatB, is responsible for the adaptation to H2O2, despite the rapid induction of katB by H2O2 in the presence of functional KatA (19) (data not shown).
It is clear, however, that KatA and KatB have overlapping but distinct roles in oxidative stress responses, since the multicopy KatB failed to fully compensate for the absence of KatA in terms of H2O2 resistance and adaptation (data not shown). The catalytic functions involving both KatA and KatB during normal growth and oxidative stress remain to be further deciphered by combining this result with detailed and systematic gene expression analyses in each catalase mutant background with or without oxidative challenge.
KatA is preponderantly required for osmoprotection in P. aeruginosa PA14. A minor catalase (CatB) from the actinomycete S. coelicolor is known to be required for resistance to osmotic stress and differentiation (5). We tested whether P. aeruginosa catalase mutants are susceptible to osmotic stresses. As shown in Fig. 4A, KatA was critical in the resistance to KCl treatments (0.8 M and 0.9 M), whereas deletion of katB or katE had no significant effect on salt resistance. However, the different KCl sensitivities of the katA and katAB mutants, depending on the KCl concentration, suggest that KatB may play a minor role in osmoresistance as in H2O2 resistance (Fig. 2).
Since KCl increases ionic strength as well as osmotic strength, we used a nonionic osmolyte, sucrose, with comparable amounts of KCl (23). As shown in Fig. 4B, sucrose treatments at 32% (0.89 M) and 34% (0.94 M) exhibited similar results as observed in KCl treatments, uncovering the involvement of KatA in sucrose resistance, although the responses to the two different concentrations were more subtle than those in the KCl treatments, especially in the katA and katAB mutants, indicating the minor role of KatB in this condition.
The sensitive phenotype of the katA mutant was restored by trans complementation with the pUCP18-derived plasmid expressing KatA (Fig. 4C). Unlike H2O2 sensitivity, however, multicopy KatB could not restore growth of the katA mutant on salt-containing media, which may imply differential functions and/or regulations of KatA and KatB in response to osmotic stress.
It is intriguing that the cell-free culture supernatant from the wild-type culture in the stationary growth phase could restore the KCl sensitivity of the katA mutant, although we were not sure whether or not the supplied activities absent in the culture supernatant of the katA mutant were working extracellularly. Further experimentation is needed to unravel how catalases such as P. aeruginosa KatA and S. coelicolor CatB protect against osmotic stresses. Considering that the general stress responses likely require alternative sigma factors (3, 6), it will be of special interest to analyze the gene expression in response to specific and general stress conditions.
KatA is required for virulence in P. aeruginosa PA14. The in vitro oxidative and osmotic stress phenotypes of catalase mutants are most likely related to the survival pathways, and therefore likely implicated in virulence due to unfavorable conditions P. aeruginosa may encounter in the host environment. We examined whether the P. aeruginosa catalases play a role in host infection using the D. melanogaster model, since it was a simple alternative model host to evaluate P. aeruginosa virulence potentials, as measured by fly mortality and in vivo proliferation of P. aeruginosa (16, 27).
D. melanogaster infection was performed by pricking 2- to 5-day-old adult flies with 50 to 200 CFU of PA14 cells as described previously (16). Mortality was monitored at 25°C for up to 54 h postinfection (Fig. 5). Four catalase mutants (katA, katAB, katAE, and katABE) commonly deficient in KatA exhibited significant virulence attenuations in terms of delayed death kinetics (by more than 10 h) and lower mortality, whereas the remaining three mutants (katB, katE, and katBE) were as virulent as the wild type (Fig. 5A). Reintroduction of the full-length katA gene restored the attenuated virulence of the katA mutant to the wild-type level, whereas katA mutant cells harboring a multicopy plasmid expressing either KatB or KatE were still avirulent (Fig. 5B).
The virulence attenuation of the katA mutant was verified by bacterial proliferation in D. melanogaster (Fig. 6). PA14 cells proliferate almost exponentially in flies, as described by Lee et al. (16), where the linear regression analyses from the 57 data points (from live flies) gave a slope of 0.1734, which is statistically significant (r2 = 0.897). The slope corresponds to a doubling time of 1.736 h. However, not all katA cells proliferate exponentially in flies, unlike the wild type. The bacterial proliferations from 78 live flies were delayed about 6 h, and some infected flies completely cleared the bacteria (Fig. 6B).
The involvement of KatA in virulence was further verified in mammalian hosts, using the mouse peritonitis model as described previously (24). The mice were monitored from 6 to 64 h after intraperitoneal challenge with 5 x 106 CFU of bacterial cells and regarded as dead when they displayed ruffled fur, evidence of dehydration, and nonresponsiveness to stimuli. More than 90% of the mice that had been infected with the wild-type cells died within 36 h in our experimental conditions (Fig. 7). As in D. melanogaster, the katA, katAB, katAE, and katABE mutants were less virulent in the mouse peritonitis model, with 40% mice surviving the infection, exhibiting delayed killing (by more than 20 h).
Conclusion. These phenotypic analyses of the three monofunctional catalases (KatA, KatB, and KatE) in P. aeruginosa PA14 suggest that the catalytic system of KatA is crucial for oxidative and osmotic stress responses. KatA is also required for adaptation to peroxide stress and for virulence of this bacterium, which is intuitively understandable in that it is critical for stress responses as well as adaptations in vitro that may resemble unfavorable host environments. It is also explainable in part by the regulation of katA, which involves quorum-sensing circuits (11).
The pivotal roles of KatA in virulence mechanisms can be further authenticated and generalized, by investigating its involvement in virulence of other P. aeruginosa strains such as PAO1, since the multifactorial nature of virulence pathways is related with the genetic backgrounds that accounts for different virulence potentials, and its expression and regulation in conjunction with related enzymes and regulators such as RpoS and OxyR.
ACKNOWLEDGMENTS
We are grateful to Gee Lau for helpful comments.
This work was supported by grants from the 21C Frontier Microbial Genomics and Applications Center (MG05-0104-05-0) and the Korea Research Foundation (2004-015-C00505) and by a Special Research Grant from Sogang University (2002-3010) to Y.-H. Cho.
REFERENCES
1. Bodey, G. P., R. Bolivar, V. Fainstein, and L. Jadeja. 1983. Infections caused by Pseudomonas aeruginosa. Rev. Infect. Dis. 5:279-313.
2. Brown, S. M., M. L. Howell, M. L. Vasil, A. J. Anderson, and D. J. Hassett. 1995. Cloning and characterization of the katB gene of Pseudomonas aeruginosa encoding a hydrogen peroxide-inducible catalase: purification of KatB, cellular localization, and demonstration that it is essential for optimal resistance to hydrogen peroxide. J. Bacteriol. 177:6536-6544.
3. Cho, Y.-H. 1999. Gene expression and the role of catalases in Streptomyces coelicolor A3(2). Ph.D. thesis. Seoul National University, Seoul, Korea.
4. Cho, Y.-H., and J.-H. Roe. 1997. Isolation and expression of the catA gene encoding the major vegetative catalase in Streptomyces coelicolor Müller. J. Bacteriol. 179:4049-4052.
5. Cho, Y.-H., E.-J. Lee, and J.-H. Roe. 2000. A developmentally regulated catalase required for proper differentiation and osmoprotection of Streptomyces coelicolor. Mol. Microbiol. 35:150-160.
6. Cho, Y.-H., E.-J. Lee, B.-E. Ahn, and J.-H. Roe. 2001. SigB, an RNA polymerase sigma factor required for osmoprotection and proper differentiation of Streptomyces coelicolor. Mol. Microbiol. 42:205-214.
7. Christman, M. F., R. W. Morgan, F. S. Jacobson, and B. N. Ames. 1985. Positive control of a regulon for defenses against oxidative stress and some heat-shock proteins in Salmonella typhimurium. Cell 41:753-762.
8. Demple, B., J. Halbrook, and S. Linn. 1983. Escherichia coli xth mutants are hypersensitive to hydrogen peroxide. J. Bacteriol. 153:1079-1082.
9. Dowds, B. C., P. Murphy, D. J. McConnell, and K. M. Devine. 1987. Relationship among oxidative stress, growth cycle, and sporulation in Bacillus subtilis. J. Bacteriol. 169:5771-5775.
10. Hassett, D. J., E. Alsabbagh, K. Parvatiyar, M. L. Howell, R. W. Wilmott, and U. A. Ochsner. 2000. A protease-resistant catalase, KatA, released upon cell lysis during stationary phase is essential for aerobic survival of a Pseudomonas aeruginosa oxyR mutant at low cell densities. J. Bacteriol. 182:4557-4563.
11. Hassett, D. J., J. F. Ma, J. G. Elkins, T. R. McDermott, U. A. Ochsner, S. E. West, C. T. Huang, J. Fredericks, S. Burnett, P. S. Stewart, G. McFeters, L. Passador, and B. H. Iglewski. 1999. Quorum sensing in Pseudomonas aeruginosa controls expression of catalase and superoxide dismutase genes and mediates biofilm susceptibility to hydrogen peroxide. Mol. Microbiol. 34:1082-1093.
12. Igarashi, T., Y. Kono, and K. Tanaka. 1996. Molecular cloning of manganese catalase from Lactobacillus plantarum. J. Biol. Chem. 271:29521-29524.
13. Klotz, M. G., and P. C. Loewen. 2003. The molecular evolution of catalytic hydroperoxidases: evidence for multiple lateral transfer of genes between prokaryota and from bacteria into eukaryota. Mol. Biol. Evol. 20:1098-1112.
14. Klotz, M. G., G. R. Klassen, and P. C. Loewen. 1997. Phylogenetic relationships among prokaryotic and eukaryotic catalases. Mol. Biol. Evol. 14:951-958.
15. Lee, J.-S. 2005. Phenotypic analyses of of monofunctional catalases in Pseudomonas aeruginosa. M.S. thesis. Sogang University, Seoul, Korea.
16. Lee, J.-S., S.-H. Kim, and Y.-H. Cho. 2004. Dithiothreitol attenuates the pathogenic interaction between Pseudomonas aeruginosa and Drosophila melanogaster. J. Microbiol. Biotechnol. 14:367-372.
17. Lee, J.-S., Y.-C. Hah, and J.-H. Roe. 1993. The induction of oxidative enzymes in Streptomyces coelicolor upon hydrogen peroxide treatment. J. Gen. Microbiol. 139:1013-1018.
18. Ochsner, U. A., M. L. Vasil, E. Alsabbagh, K. Parvatiyar, and D. J. Hassett. 2000. Role of the Pseudomonas aeruginosa oxyR-recG operon in oxidative stress defense and DNA repair: OxyR-dependent regulation of katB-ankB, ahpB, and ahpC-ahpF. J. Bacteriol. 182:4533-4544.
19. Palma, M., D. DeLuca, S. Worgall, and L. E. Quadri. 2004. Transcriptome analysis of the response of Pseudomonas aeruginosa to hydrogen peroxide. J. Bacteriol. 186:248-252.
20. Rahme, L. G., E. J. Stevens, S. F. Wolfort, J. Shao, R. G. Tompkins, and F. M. Ausubel. 1995. Common virulence factors for bacterial pathogenicity in plants and animals. Science 268:1899-1902.
21. Robbe-Saule, V., C. Coynault, M. Ibanez-Ruiz, D. Hermant, and F. Norel. 2001. Identification of a non-haem catalase in Salmonella and its regulation by RpoS (S). Mol. Microbiol. 39:1533-1545.
22. Schweizer, H. P. 1991. Escherichia-Pseudomonas shuttle vectors derived from pUC18/19. Gene 97:109-121.
23. Shortridge, V. D., A. Lazdunski, and M. L. Vasil. 1992. Osmoprotectants and phosphate regulate expression of phospholipase C in Pseudomonas aeruginosa. Mol. Microbiol. 6:863-871.
24. Sonnleitner, E., S. Hagens, F. Rosenau, S. Wilhelm, A. Habel, K. E. Jager, and U. Blasi. 2003. Reduced virulence of a hfq mutant of Pseudomonas aeruginosa O1. Microb. Pathog. 35:217-228.
25. Stover, C. K., X. Q. Pham, A. L. Erwin, S. D. Mizoguchi, P. Warrener, M. J. Hickey, F. S. Brinkman, W. O. Hufnagle, D. J. Kowalik, M. Lagrou, R. L. Garber, L. Goltry, E. Tolentino, S. Westbrock-Wadman, Y. Yuan, L. L. Brody, S. N. Coulter, K. R. Folger, A. Kas, K. Larbig, R. Lim, K. Smith, D. Spencer, G. K. Wong, Z. Wu, I. T. Paulsen, J. Reizer, M. H. Saier, R. E. Hancock, S. Lory, and M. V. Olson. 2000. Complete genome sequence of Pseudomonas aeruginosa PAO1, an opportunistic pathogen. Nature 406:959-964.
26. Suh, S. J., L. Silo-Suh, D. E. Woods, D. J. Hassett, S. E. West, and D. E. Ohman. 1999. Effect of rpoS mutation on the stress response and expression of virulence factors in Pseudomonas aeruginosa. J. Bacteriol. 181:3890-3897.
27. Vodovar, N., C. Acosta, B. Lemaitre, and F. Boccard. 2004. Drosophila: a polyvalent model to decipher host-pathogen interactions. Trends Microbiol. 12:235-242.
28. Wolfgang, M. C., B. R. Kulasekara, X. Liang, D. Boyd, K. Wu, Q. Yang, C. G. Miyada, and S. Lory. 2003. Conservation of genome content and virulence determinants among clinical and environmental isolates of Pseudomonas aeruginosa. Proc. Natl. Acad. Sci. USA 100:8484-8489.(Ji-Sun Lee, Yun-Jeong Heo)