Journal of Bacteriology, August 2003, p . 4657-4661, Vol . 185, No . 15

Cytosine Methylation by the SuaI Restriction-Modification System: Implications for Genetic Fidelity in a Hyperthermophilic Archaeon

Dennis W . Grogan^*

New England Biolabs, Inc., Beverly, Massachusetts 01915

Received 24 February 2003/ Accepted 2 May 2003

Cytosine DNA methyl transferases have been identified in a number of thermophilic archaea by genomic sequence analysis (7) or biochemical characterization of restriction-modification (R-M) systems (20, 21) . This is significant, because the temperature dependence of cytosine deamination argues that the deleterious genetic effects of 5mC should be especially severe for extreme thermophiles (12, 17) . In agreement with the DNA repair rationale inferred for mesophilic bacteria, G · T-specific repair enzymes have also been identified in two of these organisms (12, 27) . In the third organism, however (Sulfolobus acidocaldarius), no G · T-specific DNA cleavage has been demonstrated in cell extracts, even though cleavage was evident at a G · U base pair under the assay conditions (D . Grogan, unpublished results) .

The question of whether S . acidocaldarius has a G · T-specific glycosylase or endonuclease, though unresolved, draws attention to three apparently disparate properties of this archaeal species: (i) functioning of a GGCC-specific R-M system, designated SuaI (21), which implies the methylation of multiple cytosines throughout the chromosome; (ii) optimal growth at about 80°C (8), which implies a relatively high rate of spontaneous deamination of 5mC; and (iii) a low rate of spontaneous mutation, characterized by especially low frequencies of base pair substitutions (10, 13) . One possible reconciliation of these three properties is based on the observation that the two target genes used for the mutation rate measurements (pyrE and pyrF) lack SuaI recognition sites (10) . This fact raises the possibility that SuaI may generate 5mC at its recognition sites, which occur elsewhere in the S . acidocaldarius genome, and promote high rates of C-to-T transition at these sites . An alternative explanation is based on the observation that a number of R-M systems methylate the exocyclic N of cytosine to yield N⁴mC (14) . This modified base occurs in the DNAs of both mesophiles and thermophiles (6) and thus does not seem to correlate strongly with high growth temperature . It does, however, provide a way to protect against restriction without the genetic disadvantages of 5mC, since (i) N⁴ methylation chemically stabilizes cytosine against spontaneous deamination (2, 5) and (ii) the deamination product, uracil, is readily excised from DNA by uracil DNA glycosylases, which are widely distributed among hyperthermophilic archaea (15, 22, 23) . In order to resolve whether SuaI recognition sites represent potential mutational hot spots in the S . acidocaldarius genome not detected by previous assays, I investigated which of these two modes of C methylation is used by the SuaI system .

Sources of enzymes. Cells of wild-type S . acidocaldarius strain DG185 were grown, harvested, and stored frozen as previously described (19) . Extracts were prepared by adding the following to a thawed cell suspension: K₂HPO₄ (50 mM), KCl (0.5 M), MgSO₄ (5 mM), and sodium N-lauryl sarcosine (0.4%) . After 5 min of gentle mixing at room temperature, the mixture was centrifuged for 30 min at 13,000 x g and 4°C . The clear supernatant was removed and dialyzed overnight against 40 mM Tris-HCl (pH 7.5)-50 mM KCl; aliquots were stored frozen (-20°C) until use . For assays using oligonucleotide substrates, SuaI activity was partially purified from cell extracts by chromatography over phosphocellulose (Whatman P11), under conditions similar to those of Prangishvili et al . (21) . Two active fractions of 2.5 ml each were pooled and concentrated to 0.5 ml . An equal volume of glycerol was then added, and the preparation was stored at -20°C . Endonuclease EsaBC4I, partially purified from an overproducing E . coli strain, was generously provided by R . D . Morgan . All other enzymes were those commercially available from New England Biolabs (NEB) . Endonucleases SuaI and EsaBC4I were assayed in 1x NEB buffer 2 (50 mM NaCl, 10 mM Tris-HCl, 10 mM MgCl₂) at 70°C . Other enzymes were assayed under conditions specified by NEB .

DNA substrates. Genomic DNA of S . acidocaldarius was purified by phenol extraction and banding in a CsCl-ethidium bromide density gradient as previously described (9) . Genomic DNA of E . coli was purified by batch chromatography (DNEasy; QIAGEN) . Plasmid (pUC19) and bacteriophage DNAs were from NEB . For some experiments, these DNAs were methylated at GGCC sites by incubating 20 µg of DNA for 1 h at 37°C with 30 U of HaeIII methylase and 4 nmol of S-adenosylmethionine in a total volume of 50 µl of HaeIII methylase buffer (50 mM NaCl, 50 mM Tris-HCl [pH 8.5], 10 mM dithiothreitol) . Complete methylation was confirmed by incubating 0.5 µg of the resulting DNA for 1 h at 37°C with 10 U of HaeIII endonuclease . Agarose gel electrophoresis revealed no detectable digestion products .

Oligonucleotides containing a fluorescein label at the 3' end were synthesized by the NEB organic synthesis division by phosphoramidite coupling . The basic nucleotide sequences were 5'[AAAAACACCGGTGCGGCCGCAGACGAACGTCAAAAA]3' (upper strand) and 5'[TTTTTGACGTTCGTCTGCGGCCGCACCGGTGTTTTT]3' (lower strand) . Methylated cytosine residues (C-5 or N⁴) were incorporated into the first or second C of GGCC (italicized) during synthesis . Each single-stranded oligonucleotide was dissolved in 10 mM Tris-HCl, pH 8.3, to a concentration of 10 µM and annealed to an equimolar amount of its complement .

Cleavage assays. Genomic (640 ng), plasmid (160 ng), or bacteriophage (160 ng) DNA was incubated for 1 h with 1 µl of endonuclease diluted in diluent buffer A (50 mM KCl, 10 mM Tris-HCl [pH 7.4], 0.1 mM EDTA, 1 mM dithiothreitol, 200 µg of bovine serum albumin per ml, 50% [vol/vol] glycerol) in a total volume of 10 µl of NEB buffer 2 . Extent of cleavage was determined by agarose gel electrophoresis in 1x Tris-borate-EDTA buffer containing ethidium bromide . Fluorescently labeled double-stranded oligonucleotide (0.5 pmol) was similarly incubated with endonuclease but electrophoresed through Tris-borate-EDTA-buffered polyacrylamide gels . DNAsin both agarose and acrylamide gels were visualized with a 302-nm-wavelength transilluminator, and digital images were recorded with a charge-coupled-device camera (Alpha Innotec, Inc.)

Enzyme probes of GGCC methylation. Isoschizomers can differ with respect to their ability to cleave methylation variants of their common recognition site, providing a means to determine the methylation state of that site in natural DNAs . As differential levels of sensitivity to the position of 5mC had been observed for the GGCC-specific endonucleases HaeIII and EsaBC4I (http://rebase.neb.com), I tested these two enzymes for the effects of N⁴ methylation, using synthetic DNA substrates (see above) . Results of incubating unmethylated and four symmetrically methylated forms of GGCC are shown in Fig . 1 . R.HaeIII (HaeIII restriction endonuclease) (Fig . 1A) was blocked by either form of methylation of the inner Cs, whereas R.EsaBC4I (Fig . 1B) was blocked only by N⁴mC at this position . The combination of these two enzymes could therefore distinguish GG5mCC (cleaved only by R.EsaBC4I), GGN⁴mCC (cleaved by neither enzyme), and GGCC that was either unmethylated or methylated only on the outer C residues (cleaved by both enzymes) .

 
These differences in methylation sensitivity were then used to evaluate SuaI recognition sites in S . acidocaldarius genomic DNA . Neither R.HaeIII nor R.EsaBC4I cut S . acidocaldarius DNA, whereas R.HindP1I and R.BstUI, which recognize similar tetranucleotides, cut frequently (Fig . 2) . This result was obtained when purified genomic DNA was first digested to completion with R.HindIII (data not shown) . The activities of R.HaeIII and R.EsaBC4I under these conditions was confirmed with bacteriophage DNA (Fig . 2) and E . coli chromosomal DNA (data not shown) .

 
Methylation sensitivity of R.SuaI. The observed resistance of S . acidocaldarius DNA to both R.HaeIII and R.EsaBC4I implied N⁴ methylation at the inner C residues of GGCC sites in S . acidocaldarius DNA . One possible consequence of this methylation is that the corresponding endonuclease, R.SuaI, may cleave other symmetrically methylated forms of GGCC with reasonable efficiency, as was observed for R.EsaBC4I (http://rebase.neb.com) . This situation was confirmed with synthetic substrates and various amounts of partially purified R.SuaI . Only N⁴ methylation on the inner C residue blocked cleavage by excess R.SuaI (Fig . 3A) . This result is distinct from that obtained with R.HaeIII under the same conditions (Fig . 3B) and is consistent only with N⁴ methylation of S . acidocaldarius DNA in vivo . To confirm the methylation sensitivity of SuaI, high-molecular-weight chromosomal DNA was purified from an E . coli strain expressing the EsaBC4I R-M system (R . D . Morgan, unpublished data) . This DNA was readily cleaved by R.HindIII, but treatment with crude S . acidocaldarius extract in several different restriction buffers produced no detectable endonuclease cleavage (Fig . 3C) . This result indicated that SuaI is the only R-M system detected in S . acidocaldarius and that N⁴ methylation of the inner C in the recognition site is necessary and sufficient to protect against it .

 
The relative efficiency with which R.SuaI cleaves GG5mCC was quantified more precisely using plasmid and phage DNA substrates . Unmodified and M.HaeIII (HaeIII methylase)-modified DNAs were each incubated with various dilutions of enzyme, and the equivalence of activities was identified as the generation of similar incomplete-digestion patterns; the results of one of these comparisons is shown in Fig . 4 . Three independent experiments (two using pUC19 and one using bacteriophage ) determined the number of 1:2 dilutions of enzyme that gave a partial digest of unmodified DNA equivalent to that observed with M.HaeIII-modified DNA . The average value for SuaI, 3.16 (standard deviation, 0.25), represents 11% residual activity on M.HaeIII-methylated DNA . A similar value was obtained for EsaBC4I, whereas no cleavage of the modified DNAs by excess R.HaeIII could be detected, corresponding to <0.08% of control activity .

 
Conclusions. S . acidocaldarius is the only hyperthermophilic archaeon in which the rate and spectrum of spontaneous mutation has been accurately analyzed in vivo (10, 13), making it a significant model of genetic fidelity at extremely high temperatures . The following results presented here demonstrate that SuaI uses N⁴ methylation of the inner C to protect its recognition sequence (GGCC) from restriction: (i) highly purified S . acidocaldarius genomic DNA was resistant to R.SuaI, R.HaeIII, and R.EsaBC4I but not to endonucleases specific for similar sequences occurring at similar frequencies; (ii) the only symmetrically methylated synthetic substrate that resisted cleavage by R.HaeIII and R.EsaBC4I was GGN⁴mCC; and (iii) N⁴ methylation of the inner C was necessary and sufficient to protect an oligonucleotide duplex or E . coli DNA against S . acidocaldarius extract . It should also be noted that polyclonal antibody specific for DNA containing N⁴mC binds to genomic DNA of S . acidocaldarius but not to control DNA (T . Bhatia and D . Grogan, unpublished results), which provides independent support for this conclusion .

Use of the "genetically benign" N⁴ cytosine methylation effectively discounts the SuaI system as a significant source of spontaneous mutation in S . acidocaldarius . This conclusion is further supported by observations that SuaI recognition sites are very rare in the S . acidocaldarius genome: only 84 occurrences of GGCC were found in 2.14 Mbp of genomic sequence, for example (L . Chen, K . Brügger, and R . Garrett, personal communication) . This frequency corresponds to about 0.004 mol% of N⁴mC, which explains why standard high-performance liquid chromatography analysis failed to detect modified nucleotides in hydrolysates of S . acidocaldarius DNA (9) . Similar underrepresentation of GGCC is not evident in the Sulfolobus tokodaii or Sulfolobus solfataricus genomes (http://rebase.neb.com), suggesting that certain oligonucleotides in the genomes of various Sulfolobus lineages have been subjected to rather different selective forces . Investigating this question will be greatly aided by the imminent completion of the S . acidocaldarius genomic sequence .

Finally, it should be noted that these results have practical implications for developing additional genetic capabilities in S . acidocaldarius . The SuaI recognition site (GGCC) is abundant in conventional vectors (22 occurrences in pUC19, for example), and transformation protocols for S . acidocaldarius have accordingly used methylation of constructs by M.HaeIII as a means to avoid SuaI restriction (1) . In the present study, however, I found SuaI to cleave M.HaeIII-modified DNA with reasonable efficiency and to be present at high levels in crude cell extracts (about 5,000 U per mg of protein) . Thus, pretreatment with M.HaeIII is not expected to provide much protection for vector sequences introduced into S . acidocaldarius cells .

This work was supported by Donald Comb (NEB) and the University of Cincinnati .

1. Aravalli, R . N., and R . A . Garrett. 1997 . Shuttle vectors for hyperthermophilic archaea . Extremophiles 1:183-191.
2. Cohen, R . M., and R . Wolfenden. 1971 . The equilibrium of hydrolytic deamination of cytidine and N⁴-methylcytidine . J . Biol . Chem . 246:7566-7568.
3. Cooper, D . N., and H . Youssoufian. 1988 . The CpG dinucleotide and human disease . Hum . Genet . 78:151-155.
4. Coulondre, C., J . H . Miller, P . J . Farabaugh, and W . Gilbert. 1978 . Molecular basis of substitution hot spots in Escherichia coli . Nature 274:775-780.
5. Ehrlich, M., K . F . Norris, R . Y . Wang, K . C . Kuo, and C . W . Gehrke. 1986 . DNA cytosine methylation and heat-induced deamination . Biosci . Rep . 6:387-393.
6. Ehrlich, M., G . G . Wilson, K . C . Kuo, and C . W . Gehrke. 1987 . N⁴-Methylcytosine as a minor base in bacterial DNA . J . Bacteriol . 169:939-943.
7. Fitz-Gibbon, S . T., H . Ladner, U . J . Kim, K . O . Stetter, M . I . Simon, and J . H . Miller. 2002 . Genome sequence of the hyperthermophilic crenarchaeon Pyrobaculum aerophilum . Proc . Natl . Acad . Sci . USA 99:984-989.
8. Grogan, D . W. 1989 . Phenotypic characterization of the archaebacterial genus Sulfolobus: comparison of five wild-type strains . J . Bacteriol . 171:6710-6719.
9. Grogan, D., P . Palm, and W . Zillig. 1990 . Isolate B12, which harbours a virus-like element, represents a new species of the archaebacterial genus Sulfolobus, Sulfolobus shibatae, sp . nov . Arch . Microbiol . 154:594-599.
10. Grogan, D . W., G . T . Carver, and J . W . Drake. 2001 . Genetic fidelity under harsh conditions: analysis of spontaneous mutation in the thermoacidophilic archaeon . Sulfolobus acidocaldarius . Proc . Natl . Acad . Sci . USA 98:7928-7933.
11. Hennecke, F., H . Kolmar, K . Brundl, and H.-J . Fritz. 1991 . The vsr gene product of E . coli K-12 is a strand- and sequence-specific DNA mismatch endonuclease . Nature 353:776-778.
12. Horst, J . P., and H . J . Fritz. 1996 . Counteracting the mutagenic effect of hydrolytic deamination of DNA 5-methylcytosine residues at high temperature: DNA mismatch N-glycosylase Mig.Mth of the thermophilic archaeon Methanobacterium thermoautotrophicum THF . EMBO J . 15:5459-5469.
13. Jacobs, K . L., and D . W . Grogan. 1997 . Rates of spontaneous mutation in an archaeon from geothermal environments . J . Bacteriol . 179:3298-3303.
14. Janulaitis, A., S . Klimasauskas, M . Petrusyte, and V . Butkus. 1983 . Cytosine modification in DNA by BcnI methylase yields N⁴-methylcytosine . FEBS Lett . 161:131-134.
15. Koulis, A., D . A . Cowan, L . H . Pearl, and R . Savva. 1996 . Uracil-DNA glycosylase activities in hyperthermophilic micro-organisms . FEMS Microbiol . Lett . 143:267-271.
16. Kulakauskas, S., J . M . Barsomian, A . Lubys, R . J . Roberts, and G . G . Wilson. 1994 . Organization and sequence of the HpaII restriction-modification system and adjacent genes . Gene 142:9-15.
17. Lindahl, T., and T . Nyberg. 1974 . Heat-induced deamination of cytosine residues in deoxyribonucleic acid . Biochemistry 13:3405-3410.
18. Lutsenko, E., and A . S . Bhagwat. 1999 . Principle causes of hot spots for cytosine to thymine mutations at sites of cytosine methylation in growing cells: a model, its experimental support, and applications . Mutat . Res . 437:11-20.
19. Maiorano, J . N., and D . W . Grogan. 1999 . Extremely thermostable orotidine-5'-monophosphate decarboxylase from the archaeon Sulfolobus acidocaldarius . FEMS Microbiol . Lett . 174:81-87.
20. Nölling, J., and W . M . de Vos. 1992 . Characterization of the archaeal, plasmid-encoded type II restriction-modification system MthT1 from Methanobacterium thermoformicicum THF: homology to the bacterial NgoPII system from N . gonorrhoeae. J . Bacteriol . 174:5719-5726.
21. Prangishvili, D . A., R . P . Vashakidze, M . G . Chelidze, and I . Y . Gabriadze. 1985 . A restriction endonuclease SuaI from the thermoacidophilic archaebacterium Sulfolobus acidocaldarius . FEBS Lett . 192:57-60.
22. Sandigursky, M., and W . A . Franklin. 2000 . Uracil-DNA glycosylase in the extreme thermophile Archaeoglobus fulgidus . J . Biol . Chem . 275:19146-19149.
23. Sartori, A . A., P . Schar, S . Fitz-Gibbon, J . H . Miller, and J . Jiricny. 2001 . Biochemical characterization of uracil processing activities in the hyperthermophilic archaeon Pyrobaculum aerophilum . J . Biol . Chem . 276:29979-29986.
24. Shen, J . C., W . M . Rideout III, and P . A . Jones. 1992 . High frequency mutagenesis by a DNA methyltransferase . Cell 71:1073-1080.
25. Shen, J . C., W . M . Rideout III, and P . A . Jones. 1994 . The rate of hydrolytic deamination of 5-methyl cytosine in double-stranded DNA . Nucleic Acids Res . 22:972-976.
26. Yang, A . S., J . C . Shen, J . M . Zingg, S . Mi, and P . A . Jones. 1995 . HhaI and HpaI DNA methyltransferases bind DNA mismatches, methylate uracil and block DNA repair . Nucleic Acids Res . 23:1380-1387.
27. Yang, H., S . Fitz-Gibbon, E . M . Marcotte, J . H . Tai, E . C . Hyman, and J . H . Miller. 2000 . Characterization of a thermostable DNA glycosylase specific for U/G and T/G mismatches from the hyperthermophilic archaeon Pyrobaculum aerophilum . J . Bacteriol . 182:1272-1279.
28. Zhang, X., and C . K . Mathews. 1994 . Effect of DNA cytosine methylation upon deamination-induced mutagenesis in a natural target sequence in duplex DNA . J . Biol . Chem . 269:7066-7069.

Free Online Full-text Article

What Is Protein?, What Is Botulism?, What Is Salmonella?, What is Food Microbiology?, What Is Bioassay?, c, Microbiology, e, Microbe, s, Bacteriology, e, Microbes, i, Microorganism, o, Bacillus subtilis, n, Microbial, a, Antibiotics, r, Schizosaccharomyces, c, Cryptococci, e, Vibriosis, n, Vibriosis, e, Thermophiles, a, Antibiotics, c, S. cerevisiae, e, Enterobacteriacea, a, Gram positive, i, Candida pseudotropicalis, a, Phage, o, O157, r, Multidrug resistant, r, Thermophiles, s, Amikacin, c, Streptococci, c, Cell cultures, e, Microorganisms




 

© 2005 Transgalactic Ltd (manufacturer of Bioscreen C software) | Privacy Statement | P.O. Box 1393, 00101 Helsinki, Finland, phone: +358 9 85172920, fax: +358 9 8749481, e-mail: microbiology@bionewsonline.com
 

Last modified: May 25, 2005