Skip to main page content

• HOME
• Current Issue
• Archive
• Alerts
• About ASM
• Contact us
• Tech Support
• Journals.ASM.org

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Reprints and Permissions Copyright Information Books from ASM Press MicrobeWorld Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Zhang, S. Articles by Sundin, G. W. Search for Related Content PubMed PubMed Citation Articles by Zhang, S. Articles by Sundin, G. W.

 Previous Article  |  Next Article 

Journal of Bacteriology, November 2004, p. 7807-7810, Vol. 186, No. 22
0021-9193/04/$08.00+0     DOI: 10.1128/JB.186.22.7807-7810.2004
Copyright © 2004, American Society for Microbiology. All Rights Reserved.

Long-Term Effect of Mutagenic DNA Repair on Accumulation of Mutations in Pseudomonas syringae B86-17

Shouan Zhang¹ and George W. Sundin^2,3,4*

National Center for Agricultural Utilization Research, USDA Agricultural Research Service, Peoria, Illinois,¹ Program in Genetics,² Center for Microbial Ecology,³ Department of Plant Pathology, Michigan State University, East Lansing, Michigan⁴

Received 15 July 2004/ Accepted 12 August 2004

Top Abstract Text References

 
Forty replicate lineages of Pseudomonas syringae B86-17 cells expressing the rulAB mutagenic DNA repair (MDR) determinant or the rulB::Km MDR-deficient mutant GWS242 were passaged through single-cell bottlenecks (60 cycles), with a UV radiation (UVR) exposure given to half of the lineages at the beginning of each cycle. After every 10th bottleneck cycle, single-colony isolates from all 80 lineages were subjected to 39 phenotypic screens, with newly arising mutations detected in 60 and 0% of UVR-exposed or non-UVR-exposed B86-17 lineages, respectively, by the 60th cycle. Cellular fitness, measured as growth rate in a minimal medium, of UVR-exposed lineages of both B86-17 and GWS242 after 60 cycles was not significantly different from that of the ancestral strains. Although UVR exposure and MDR activity increased the occurrence of mutations in cells, a significant reduction in overall fitness was not observed.

Top Abstract Text References

 
Mutators are cells with increased genomic mutation rates, typically due to inactivation of DNA mismatch repair systems. Mutators occur at unexpectedly high percentages in natural populations of bacterial pathogens, including Escherichia coli, Neisseria meningitidis, Pseudomonas aeruginosa, and Salmonella (16, 19, 23). Indeed, mutators are favored by changing environmental conditions (31), as might be experienced by pathogenic organisms during colonization and subsequent initiation of disease in a susceptible host. Mutator strains have arisen in experimental evolving populations (18, 21, 26) and are competitively favored in mixed cultures when initially present at frequencies above 5 x 10^–5 (1). Although the majority of new mutations generated within mutator cells are thought to be deleterious, these strains can be retained in populations due to an increased likelihood of generating and thus becoming physically linked with any rare beneficial mutations arising within the mutator cell (2).

Since all natural organisms are not mutators, it is clear that this lifestyle is not favored in all environments. For example, the mutation rate of organisms inhabiting constant environments is typically low (3). Additionally, in the absence of recombination, smaller populations are subject to eventual extinction due to the accumulation of deleterious mutations by genetic drift (9, 20). In experimental systems, passage of mutator E. coli and yeast populations through repeated genetic bottlenecks resulted in significant deleterious mutation accumulation and the extinction of some lineages through a process termed mutational meltdown (7, 33). However, if a mutator can revert to a nonmutator form once an adapted fitness state is reached, theoretical studies suggest that this fitness state can be maintained (30); reversion is ecologically relevant during pathogenesis, for example, a situation in which mutator strains may be favored only in certain environments and disfavored in others (8).

Transient mutator status has been argued to represent a better cellular strategy in terms of adaptation to environmental stress (24). One such transient mutator strategy is mutagenic DNA repair (MDR) or translesion synthesis, which is encoded by determinants, such as E. coli umuDC, that are regulated by the cellular SOS DNA damage response (29). umuDC and its bacterial homologs encode specialized DNA polymerases (Pol V) that can replicate past lesions that are normally not repairable by other cellular DNA repair mechanisms (6). These inducible systems therefore only transiently increase the cellular mutation rate; this function is accompanied by a second, selectable function in that most MDR determinants confer tolerance to UV radiation (UVR). However, the effect of MDR on the accumulation of deleterious mutations has not been established. A known ecological role for MDR-mediated UVR tolerance has only been demonstrated for rulAB, an MDR determinant in P. syringae pv. syringae, a plant pathogen that inhabits sunlight-exposed plant leaf surfaces (12, 27). Our long-term goal is to understand the impact of MDR-mediated genetic alterations on cellular evolution in P. syringae and other bacterial populations. Here, we used single-cell bottleneck experiments to examine the accumulation of gene-inactivating mutations in a P. syringae pv. syringae strain, B86-17, encoding rulAB, and the near-isogenic P. syringae pv. syringae rulB::Km mutant GWS242 in the presence or absence of regular UVR exposure.

Long-term bottleneck experiments incorporating UVR exposure. The experiments were initiated with P. syringae pv. syringae B86-17, a wild-type strain that encodes the rulAB MDR determinant on an indigenous plasmid (28), or the insertional mutant P. syringae subsp. syringae GWS242 (B86-17 rulB::Km) (12). The UVR survival of GWS242 is reduced approximately three- to fivefold from that of B86-17, and UVR mutability is also reduced, although not completely eliminated (12). Single colonies of B86-17 and GWS242 were inoculated into mannitol glutamate broth (10) containing 0.25 g of yeast extract per liter (MGY) and grown overnight. Appropriate dilutions of these cultures were plated onto MGY medium, and 40 single colonies of B86-17 and GWS242 were used to initiate independent lineages that were propagated by streaking onto MGY medium. Twenty lineages each of B86-17 and GWS242 were subjected to UVR irradiation (254-nm UVC wavelength, 30 J m^–2) immediately after streaking for each cycle. The UVC dose resulted in cell survival levels of approximately 40 to 50% for B86-17 and 10 to 20% for GWS242, and is sufficient to activate expression of the rulAB determinant (12). An additional 20 lineages each of B86-17 and GWS242 were propagated identically, except these lineages were not subjected to the UVC radiation dose. Each experimental cycle consisted of propagation by streaking onto fresh MGY medium, UVC irradiation (for half of the lineages), and incubation in darkness at 25°C for 72 h. We selected the furthest single colony on the plates for the next cycle, and the experiment continued in this manner for a total of 60 cycles. A portion of each of the 40 initial colonies from each strain (B86-17 and GWS242) was amplified on MGY and stored in 15% glycerol at –70°C for use in later phenotypic analyses; single-colony isolates from each of the 80 total lineages (B86-17 and GWS242; UVC irradiated and nonirradiated) were likewise stored after 10, 20, 30, 40, 50, and 60 cycles.

Phenotypic analysis of mutation accumulation. We used 39 phenotypic tests to assay for mutations arising during the experiment in each of the 80 bacterial lineages propagated in this study (Table 1). We examined isolates from each lineage recovered after every 10th cycle. Auxotrophs were initially identified by an inability to grow on unsupplemented mannitol glutamate minimal medium; auxotrophic requirements were identified by first adding amino acid supplements in groups of three and then adding individual amino acids. All amino acids were examined except glutamic acid, which is a component of mannitol glutamate medium. Carbon sources were filter sterilized and added at 0.1% (wt/vol) to Ayers et al. minimal salt medium (25). Bacterial strains were streaked onto plates and incubated at 28°C for 7 days; growth was compared to that on plates without added carbon sources. Fluorescence on King's B medium (14), gelatin liquefaction, hydrolysis of esculin and arbutin, levan production (25), and motility on "swim agar" plates (7) were analyzed as previously described. The hypersensitive reaction (HR) tests the ability of P. syringae pv. syringae B86-17 and GWS242 (both plant pathogens on bean) to elicit a defense response in the non-host plant tobacco and is dependent upon a functional type III secretion system and functional effector proteins (15). Briefly, cell suspensions (10⁸ CFU ml^–1) were inoculated into intraveinal sections of Nicotiana tabacum leaves with a blunt syringe; the presence of localized cell death at the inoculation site 24 h after inoculation was scored as a positive reaction. Colony morphology of derived strains was assessed visually by comparison with ancestral strains on MGY plates.

View this table: [in this window] [in a new window]

TABLE 1. Phenotypes (loss of) examined to assess the accumulation of mutations in replicate lineages of P. syringae pv. syringae B86-17 and GWS242

During each of 60 cycles, colonies chosen had grown from 1 cell to approximately 1.7 x 10⁸ cells, or ca. 27 generations per cycle (1,620 generations total for the experiment). If UVR-exposed P. syringae pv. syringae B86-17 cells behaved like mutators, then we would expect to observe an increase in mutations in UVR-exposed cells relative to nonexposed cells over the course of the experiment. For example, Funchain et al. (7) tracked 100 mutator (mutS) lineages of E. coli J93 and detected at least one mutation in 38 and 67% of the lineages after 10 and 20 cycles, respectively, while mutations were not observed in wild-type lineages. Following 60 cycles, 99% of the J93 lineages had at least 1 detectable mutation with a mean of 4 to 5 mutations per lineage (7).

In our experiment, mutations in the UVR-exposed B86-17 lineages were not observed until after cycle 20 (Table 2). The increase in strains with mutations and in the total number of mutations occurred more sharply between cycles 20 and 60; however, 8 lineages (40%) with no detectable mutations remained after cycle 60 (Table 2). No mutations were observed in any lineage (B86-17 or GWS242) without UVR exposure after 60 cycles (Table 2). Strain GWS242, which has an insertional mutation within the plasmid-encoded rulB gene, was previously reported to possess a low but consistently detectable UVR mutability frequency, which was surmised to be associated with a chromosomal MDR locus (12). Six of twenty lineages of UVR-exposed GWS242 had detectable mutations after cycle 60, with a lower number of overall mutations than B86-17 (Table 2).

View this table: [in this window] [in a new window]

TABLE 2. Accumulation of mutations in P. syringae pv. syringae B86-17 and GWS242 lineages with or without periodic UVC exposure

Among UVR-exposed experimental lineages, we detected a total of 30 mutations among 12 lineages of B86-17 and 15 mutations among 6 lineages of GWS242 in this experiment. The overall pattern of phenotypes affected was not distinctly different for both B86-17 and GWS242. The most common phenotypic differences identified were alterations in colony morphology (eight B86-17 lineages and three GWS242 lineages), defects in levansucrase activity (five B86-17 lineages and four GWS242 lineages), and loss of motility (four B86-17 lineages and one GWS242 lineage). Defects in the utilization of various carbon sources constituted 11 mutations distributed among 8 B86-17 lineages and 7 mutations distributed among 4 GWS242 lineages.

Growth rate comparisons. Prolonged passage through bottlenecks is associated with loss of fitness in mutator and nonmutator lineages (11). We assessed fitness in our experiments by comparing the growth rate (measured as cell doubling time) of an isolate from each of the 20 derived lineages per treatment recovered at cycle 60 with the appropriate ancestral strains stored at the initiation of the experiment. All strains were initially removed from storage at –70°C and grown overnight in Luria-Bertani (Difco) broth; cells were then diluted 1:50 into 25 ml of MGY broth contained in a 50-ml flask and incubated at 28°C with shaking at 250 rpm. After 160 min, samples were taken every 15 min for 2.5 h; cell numbers were estimated by assessing the turbidity at 600 nm. Standard curves relating turbidity values to cell numbers were generated, and regressions were made based on growth curve data for each experimental strain. Doubling time was determined for each strain from the line drawn through the points during exponential growth. The mean doubling time of cycle 60 strains was slightly increased in all experimental groups but not significantly different from that of ancestral (cycle 0) strains (Table 3), indicating that the prolonged bottlenecks and in some cases regular UVR exposure did not exert a negative effect on the growth rate of cultures.

View this table: [in this window] [in a new window]

TABLE 3. Mean doubling time (min) of P. syringae pv. syringae B86-17 and GWS242 lineages after propagation for 60 cycles of single colony streaking

MDR determinants enhance UVR survival on host cells via translesion synthesis, an enzymatic mechanism that replicates past lesions that are otherwise not repairable by the available repertoire of DNA repair systems (32). A by-product of translesion synthesis is an increase in the cellular mutation rate, since this is a low-fidelity replication mechanism. Unlike mutators that affect DNA mismatch repair, MDR systems are inducible and may not mutate the genome randomly. Biochemical studies have shown that mutational hot spots exist and that local DNA sequence context plays an important role in the type and frequency of mutational events (summarized in reference 5). A critical factor is that the location of UVR-induced mutational hotspots is not predictable based on knowledge of the DNA sequence (5, 17). Echols (4) suggested that the role of MDR in bacteria could be that of UVR protection, a potential role in adaptive evolution, or both. Our previous results demonstrated the importance of MDR-mediated UVR protection for P. syringae and other Pseudomonas spp. (12, 13, 28, 34), and this study revealed the occurrence of mutations in UVR-exposed lineages, without apparent effect on overall fitness (measured as growth rate). In contrast to results in a previous study utilizing an E. coli mutator cell line (7), none of our lineages became extinct, and the growth rate of lineages after cycle 60 did not differ from the growth rate at cycle 0. Thus, the transient mutator strategy of UVR-induced MDR, although resulting in the generation of deleterious mutations in some lineages, may represent an effective ecological strategy in adaptive evolution in response to environmental stress. It was recently discovered that RulB, UmuC, and other bacterial MDR proteins belong to the Y family of DNA polymerases that occur from bacteria to humans (22). This knowledge indicates that an increased ecological understanding of these polymerases could have far-reaching biological implications.

 
This work was supported by a grant from the U.S. Department of Agriculture (NRI 99-35303-8056) and by the Michigan Agricultural Experiment Station.

We thank Rich Lenski for helpful comments.

 
* Corresponding author. Mailing address: Michigan State University, 103 Center for Integrated Plant Systems, East Lansing, MI 48824-1311. Phone: (517) 355-4573. Fax: (517) 353-5598. E-mail: sundin{at}msu.edu.

Top Abstract Text References

 

1
1. Chao, L., and E. C. Cox. 1983. Competition between high and low mutating strains of Escherichia coli. Evolution 37:125-134.[CrossRef]
2
2. de Visser, J. A. G. M. 2002. The fate of microbial mutators. Microbiology 148:1247-1252.[Free Full Text]
3
3. Drake, J. W. 1991. A constant rate of spontaneous mutation in DNA-based microbes. Proc. Natl. Acad. Sci. USA 88:7160-7164.[Abstract/Free Full Text]
4
4. Echols, H. 1981. SOS functions, cancer, and inducible evolution. Cell 25:1-2.[CrossRef][Medline]
5
5. Friedberg, E. C. (ed.). 1995. DNA repair and mutagenesis. American Society for Microbiology, Washington, D.C.
6
6. Friedberg, E. C., R. Wagner, and M. Radman. 2002. Specialized DNA polymerases, cellular survival, and the genesis of mutations. Science 296:1627-1630.[Abstract/Free Full Text]
7
7. Funchain, P., A. Yeung, J. L. Stewart, R. Lin, M. M. Slupska, and J. H. Miller. 2000. The consequences of growth of a mutator strain of Escherichia coli as measured by loss of function among multiple gene targets and loss of fitness. Genetics 154:959-970.[Abstract/Free Full Text]
8
8. Giraud, A., I. Matic, O. Tenaillon, A. Clara, M. Radman, M. Fons, and F. Taddei. 2001. Costs and benefits of high mutation rates: adaptive evolution of bacteria in the mouse gut. Science 291:2606-2608.[Abstract/Free Full Text]
9
9. Haigh, J. 1978. The accumulation of deleterious mutations in a population—Muller's ratchet. Theor. Popul. Biol. 14:251-267.[CrossRef][Medline]
10
10. Keane, P. J., A. Kerr, and P. B. New. 1970. Crown gall of stone fruit. II. Identification and nomenclature of Agrobacterium isolates. Aust. J. Biol. Sci. 23:585-595.
11
11. Kibota, T. T., and J. M. Lynch. 1996. Estimate of the genomic mutation rate deleterious to overall fitness in E. coli. Nature 381:694-696.[CrossRef][Medline]
12
12. Kim, J.-J., and G. W. Sundin. 2000. Regulation of the rulAB mutagenic DNA repair operon of Pseudomonas syringae by ultraviolet B (290 to 320 nm) radiation and analysis of rulAB-mediated mutability in vitro and in planta. J. Bacteriol. 182:6137-6144.[Abstract/Free Full Text]
13
13. Kim, J.-J., and G. W. Sundin. 2001. Construction and analysis of photolyase mutants of Pseudomonas aeruginosa and Pseudomonas syringae: contribution of photoreactivation, nucleotide excision repair, and mutagenic DNA repair to cell survival and mutability following exposure to UV-B radiation. Appl. Environ. Microbiol. 67:1405-1411.[Abstract/Free Full Text]
14
14. King, E. O., N. K. Ward, and D. E. Raney. 1954. Two simple media for the detection of pyocyanin and fluorescein. J. Lab. Clin. Med. 44:301-307.[Medline]
15
15. Lam, E., N. Kato, and M. Lawton. 2001. Programmed cell death, mitochondria, and the plant hypersensitive response. Nature 411:848-853.[CrossRef][Medline]
16
16. LeClerc, J. E., L. Baoguang, W. L. Payne, and T. A. Cebula. 1996. High mutation frequencies among Escherichia coli and Salmonella pathogens. Science 274:1208-1211.[Abstract/Free Full Text]
17
17. Livneh, Z., O. Cohen-Fix, R. Skaliter, and T. Elizur. 1993. Replication of damaged DNA and the molecular mechanisms of ultraviolet light mutagenesis. Crit. Rev. Biochem. Mol. Biol. 28:465-513.[Medline]
18
18. Mao, E. F., L. Lane, J. Lee, and J. H. Miller. 1997. Proliferation of mutators in a cell population. J. Bacteriol. 179:417-422.[Abstract/Free Full Text]
19
19. Matic, I., M. Radman, F. Taddei, B. Picard, C. Doit, E. Bingen, E. Denamur, and J. Elion. 1997. Highly variable mutation rates in commensal and pathogenic Escherichia coli. Science 277:1833-1834.[Free Full Text]
20
20. Muller, H. J. 1964. The relation of recombination to mutational advance. Mutat. Res. 1:2-9.
21
21. Notley-McRobb, L., S. Seeto, and T. Ferenci. 2002. Enrichment and elimination of mutY mutators in Escherichia coli populations. Genetics 162:1055-1062.[Abstract/Free Full Text]
22
22. Ohmori, H., E. C. Friedberg, R. P. P. Fuchs, M. F. Goodman, F. Hanaoka, D. Hinkle, T. A. Kunkel, C. W. Lawrence, Z. Livneh, T. Nohmi, L. Prakash, S. Prakash, T. Todo, G. C. Walker, Z. Wang, and R. Woodgate. 2001. The Y-family of DNA polymerases. Mol. Cell 8:7-8.[CrossRef][Medline]
23
23. Oliver, A., R. Canton, P. Campo, F. Baquero, and J. Blazquez. 2000. High frequency of hypermutable Pseudomonas aeruginosa in cystic fibrosis lung infection. Science 288:1251-1253.[Abstract/Free Full Text]
24
24. Radman, M. 1999. Enzymes of evolutionary change. Nature 401:866-869.[CrossRef][Medline]
25
25. Schaad, N. W., J. B. Jones, and W. Chun (ed.). 2001. Laboratory guide for the identification of plant pathogenic bacteria, 3rd ed. APS Press, St. Paul, Minn.
26
26. Sniegowski, P. D., P. J. Gerrish, and R. E. Lenski. 1997. Evolution of high mutation rates in experimental populations of E. coli. Nature 387:703-705.[CrossRef][Medline]
27
27. Sundin, G. W., S. P. Kidambi, M. Ullrich, and C. L. Bender. 1996. Resistance to ultraviolet light in Pseudomonas syringae: sequence and functional analysis of the plasmid-encoded rulAB genes. Gene 177:77-81.[CrossRef][Medline]
28
28. Sundin, G. W., and J. Murillo. 1999. Functional analysis of the Pseudomonas syringae rulAB determinant in tolerance to ultraviolet B (290 to 320 nm) radiation and distribution of rulAB among P. syringae pathovars. Environ. Microbiol. 1:75-87.[CrossRef][Medline]
29
29. Sutton, M. D., B. T. Smith, V. G. Godoy, and G. C. Walker. 2000. The SOS response: recent insights into umuDC-dependent mutagenesis and DNA damage tolerance. Annu. Rev. Genet. 34:479-497.[CrossRef][Medline]
30
30. Taddei, F., I. Matic, B. Godelle, and M. Radman. 1997. Role of mutator alleles in adaptive evolution. Nature 387:700-703.[CrossRef][Medline]
31
31. Travis, J. M. J., and E. R. Travis. 2002. Mutator dynamics in fluctuating environments. Proc. R. Soc. Lond. B 269:591-597.[Medline]
32
32. Wang, Z. W. 2001. Translesion synthesis by the UmuC family of DNA polymerases. Mutat. Res. 486:59-70.[Medline]
33
33. Zeyl, C., M. Mizesko, and J. A. G. M. de Visser. 2001. Mutational meltdown in laboratory yeast populations. Evolution 55:909-917.[CrossRef][Medline]
34
34. Zhang, S., and G. W. Sundin. 2004. Mutagenic DNA repair potential in Pseudomonas spp., and characterization of the rulAB_Pc operon from the highly mutable strain Pseudomonas cichorii 302959. Can. J. Microbiol. 50:29-39.[CrossRef][Medline]

---

Journal of Bacteriology, November 2004, p. 7807-7810, Vol. 186, No. 22
0021-9193/04/$08.00+0     DOI: 10.1128/JB.186.22.7807-7810.2004
Copyright © 2004, American Society for Microbiology. All Rights Reserved.

This article has been cited by other articles:

• Weigand, M. R., Sundin, G. W. (2009). Long-Term Effects of Inducible Mutagenic DNA Repair on Relative Fitness and Phenotypic Diversification in Pseudomonas cichorii 302959. Genetics 181: 199-208 [Abstract] [Full Text]  

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Reprints and Permissions Copyright Information Books from ASM Press MicrobeWorld Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Zhang, S. Articles by Sundin, G. W. Search for Related Content PubMed PubMed Citation Articles by Zhang, S. Articles by Sundin, G. W.