DNA adenine methylation of GATC sequences appeared recently in the Escherichia coli lineage

We have examined the presence of methylated adenine at GATC sequences (Dam phenotype) in the DNA of 23 eubacteria and 13 archaebacteria by using isoshizomer restriction enzymes. We have found a completely Dam+ phenotype in bacteria of nine genera related to the families Enterobacteriaceae, Parvobacteriaceae, and Vibrionaceae, and in the five cyanobacteria tested. We have found a partial Dam+ phenotype in the two archaebacteria Halobacterium saccharovorum and Methanobacterium sp. strain Ivanov. All of the other archaebacteria (three genera) and eubacteria (nine genera) tested were Dam-. Phylogenetic analysis, based on the evolutionary tree of Fox et al. (Science 209:457-463, 1980), indicates that dam methylation in the Escherichia coli lineage appeared recently in bacterial evolution and is restricted to a small range of closely related bacteria.     

Characterization of DNA adenine methylation mutants of Escherichia coli K12.

The phenotypic traits of 7 independently isolated dam mutants of Escherichia coli have been examined. The mutant strains differ from the wildtype in the following respects: (1) decreased DNA adenine methylase activity in vivo and in vitro; (2) a 14--85-fold increase in spontaneous mutability; (3) decreased survival after ultraviolet irradiation; (4) a 10--21-fold increase in spontaneous induction of lambda phage from lysogens; (5) a 3--17-fold increase in the level of recombination; and (6) inviability of double mutants containing dam- and recB- or recC-. Unmethylated fd phage chromosomes are able to replicate normally in dam- mutants. A mutant strain in which the dcm gene is deleted is viable, showing that the dcm gene product is dispensible for growth.     

Conservation of Dcm-mediated cytosine DNA methylation in Escherichia coli

In Escherichia coli, cytosine DNA methylation is catalyzed by the DNA cytosine methyltransferase (Dcm) protein and occurs at the second cytosine in the sequence 5'CCWGG3'. Although the presence of cytosine DNA methylation was reported over 35?years ago, the biological role of 5-methylcytosine in E.?coli remains unclear. To gain insight into the role of cytosine DNA methylation in E.?coli, we (1) screened the 72 strains of the ECOR collection and 90 recently isolated environmental samples for the presence of the full-length dcm gene using the polymerase chain reaction; (2) examined the same strains for the presence of 5-methylcytosine at 5'CCWGG3' sites using a restriction enzyme isoschizomer digestion assay; and (3) quantified the levels of 5-methyl-2'-deoxycytidine in selected strains using liquid chromatography tandem mass spectrometry. Dcm-mediated cytosine DNA methylation is conserved in all 162 strains examined, and the level of 5-methylcytosine ranges from 0.86% to 1.30% of the cytosines. We also demonstrate that Dcm reduces the expression of ribosomal protein genes during stationary phase, and this may explain the highly conserved nature of this DNA modification pathway.     

Pleiotropic effects of a DNA adenine methylation mutation (dam-3) in Escherichia coli K12.

The dam-3 mutation results in a five-fold reduction in the number of 6-methyl-adenine (6-meA) residues in the DNA of E. coli K12 or phage lambda. The DNA of phage fd appears to be devoid of 6-meA when propagated on dam-3 bacteria. The phenotypic differences between dam-3 and dam+ bacteria include: (i) increased free phage in lysogenic dam-3 cultures, (2) increased sensitivity to methyl methanesulfonate (MMS), (3) inviability of dam-3 lex-I strains, (4) lower molecular weight of DNA in dam-3 bacteria in the absence of DNA ligase and (5) increased rate of DNA degradation in dam-3 recA strains.     

Extent of equilibrium perturbation of the DNA helix upon enzymatic methylation of adenine residues

The extent of equilibrium perturbation of the DNA helix associated with enzymatic methylation of dA residues has been determined by the agarose gel electrophoresis band-shift method. Utilization of EcoRI methylase under conditions of reduced specificity together with Escherichia coli dam methylase permitted modification of up to 300 dA residues/plasmid pBR322 dimer. A conformational change associated with methylation was observed, with the magnitude of the transition being linear with extent of modification of relaxed DNA circles. The conformational change corresponds to an unwinding of the DNA helix by 0.5 degrees/methyl group transferred to relaxed molecules. The magnitude of the effect was independent of temperature from 5-37 degrees C indicating that it is not the consequence of a thermal transition within this range.     

Structure and substrate recognition of the Escherichia coli DNA adenine methyltransferase

The structure of the Escherichia coli Dam DNA-(adenine-N6)-methyltransferase in complex with cognate DNA was determined at 1.89 A resolution in the presence of S-adenosyl-L-homocysteine. DNA recognition and the dynamics of base-flipping were studied by site-directed mutagenesis, DNA methylation kinetics and fluorescence stopped-flow experiments. Our data illustrate the mechanism of coupling of DNA recognition and base-flipping. Contacts to the non-target strand in the second (3') half of the GATC site are established by R124 to the fourth base-pair, and by L122 and P134 to the third base-pair. The aromatic ring of Y119 intercalates into the DNA between the second and third base-pairs, which is essential for base-flipping to occur. Compared to previous published structures of bacteriophage T4 Dam, three major new observations are made in E.coli Dam. (1) The first Gua is recognized by K9, removal of which abrogates the first base-pair recognition. (2) The flipped target Ade binds to the surface of EcoDam in the absence of S-adenosyl-L-methionine, which illustrates a possible intermediate in the base-flipping pathway. (3) The orphaned Thy residue displays structural flexibility by adopting an extrahelical or intrahelical position where it is in contact to N120.     

Initiation of DNA replication in Escherichia coli: RNase H-deficient mutants do not require the dnaA function

Summary A series of temperature-resistant revertants were isolated from strains of Escherichia coli K12 carrying a temperature-sensitive mutation in the dnaA gene. Four independent revertants were found which still carry the original ts mutation. The ability of these strains to grow at high temperature is due to a suppressor mutation, called sin. All four sin mutations are located between the genes metD and proA on the genetic map of E. coli, which suggests that they all affect the same gene. The sin suppressors, which were isolated for their ability to suppress one dnaA mutation, are also able to suppress three other temperature-sensitive dnaA mutations, but they are not able to suppress mutations in either of the two genes dnaB or dnaC. The sin suppressors alone do not confer any particular phenotype on bacteria, but they are deficient in the enzyme RNase H. On the basis of these findings we propose that the function of the dnaA protein is to protect a DNA-RNA hybrid at the origin of replication against RNase H.     

Replication cycle-coordinated change of the adenine nucleotide-bound forms of DnaA protein in Escherichia coli

The ATP-bound but not the ADP-bound form of DnaA protein is active for replication initiation at the Escherichia coli chromosomal origin. The hydrolysis of ATP bound to DnaA is accelerated by the sliding clamp of DNA polymerase III loaded on DNA. Using a culture of randomly dividing cells, we now have evidence that the cellular level of ATP-DnaA is repressed to only approximately 20% of the total DnaA molecules, in a manner depending on DNA replication. In a synchronized culture, the ATP-DnaA level showed oscillation that has a temporal increase around the time of initiation, and decreases rapidly after initiation. Production of ATP-DnaA depended on concomitant protein synthesis, but not on SOS response, Dam or SeqA. Regeneration of ATP-DnaA from ADP-DnaA was also observed. These results indicate that the nucleotide form shifts of DnaA are tightly linked with an epistatic cell cycle event and with the chromosomal replication system.     

The active site of the Escherichia coli MutY DNA adenine glycosylase.

Escherichia coli MutY is an adenine DNA glycosylase active on DNA substrates containing A/G, A/C, or A/8-oxoG mismatches. Although MutY can form a covalent intermediate with its DNA substrates, its possession of 3' apurinic lyase activity is controversial. To study the reaction mechanism of MutY, the conserved Asp-138 was mutated to Asn and the reactivity of this mutant MutY protein determined. The glycosylase activity was completely abolished in the D138N MutY mutant. The D138N mutant and wild-type MutY protein also possessed different DNA binding activities with various mismatches. Several lysine residues were identified in the proximity of the active site by analyzing the imino-covalent MutY-DNA intermediate. Mutation of Lys-157 and Lys-158 both individually and combined, had no effect on MutY activities but the K142A mutant protein was unable to form Schiff base intermediates with DNA substrates. However, the MutY K142A mutant could still bind DNA substrates and had adenine glycosylase activity. Surprisingly, the K142A mutant MutY, but not the wild-type enzyme, could promote a beta/delta-elimination on apurinic DNA. Our results suggest that Asp-138 acts as a general base to deprotonate either the epsilon-amine group of Lys-142 or to activate a water molecule and the resulting apurinic DNA then reacts with Lys-142 to form the Schiff base intermediate with DNA. With the K142A mutant, Asp-138 activates a water molecule to attack the C1' of the adenosine; the resulting apurinic DNA is cleaved through beta/delta-elimination without Schiff base formation.     

Oxygen-insensitive nitroreductases of Escherichia coli do not reduce 3-nitrotyrosine

The oxygen-insensitive nitroreductases nfsA and nfsB are known to reduce para-nitrated aromatic compounds. We tested the hypothesis that these nitroreductases are capable of reducing 3-nitrotyrosine in proteins and peptides, as well as in free amino acids using wild-type and nfsA nfsB mutant strains of Escherichia coli. E. coli homogenates were incubated with nitrated proteins and the level of 3-nitrotyrosine immunoreactivity was assayed by Western blotting. Assay conditions that allow the nitroreductases to rapidly reduce nitrofurantoin did not result in the modification of 3-nitrotyrosine in protein, peptide, or free amino acid. Stimulation of nfsA nfsB activity with paraquat had no effect on 3-nitrotyrosine reduction. Nonlethal exposure of E. coli to peroxynitrite/CO(2) resulted in the reproducible nitration of tyrosine residues in endogenous proteins. The degree of 3-nitrotyrosine immunoreactivity over the 2-h postexposure period did not differ between mutant and wild-type strains. These results indicate that the nfsA and nfsB enzymes do not reduce 3-nitrotyrosine.     

Mechanism of adenine toxicity in Escherichia coli

The mechanism of adenine toxicity in an hpt gpt strain of Escherichia coli that is extremely sensitive to adenine inhibition was investigated. Adenine-resistant derivatives had secondary mutations in adeninephosphoribosyltransferase or the purR repressor. Growth studies with various purine salvage pathway mutants and the ability of guanosine to prevent adenine toxicity indicated that adenine exerts its toxic effects by depleting guanine nucleotide pools. In the presence of adenine, ATP pools increased twofold in wild-type cells and stabilized after 5 min. In contrast, ATP pools continued to rise in hpt gpt cells up to 25 min and increased sevenfold after adenine addition. hpt gpt cells were shown to have higher levels of adeninephosphoribosyltransferase than did the wild-type cells. In response to adenine addition, GTP pools dropped three- to fourfold in all strains tested. Although GTP levels returned to near normal values in wild-type cells after 35 min, no restoration of GTP pools was observed in the hpt gpt strain during this period. Measurements of guanine pools before and after the addition of adenine indicated that guaninephosphoribosyltransferase plays an important role in maintaining GTP pools by converting the free guanine to GMP during guanine nucleotide depletion.     

DNA methylation influences trpR promoter activity in Escherichia coli K-12

Summary Methylation of adenine in the GATC-sequence of the-35 region of the trpR promoter decreases activity by 2–3 fold.     

Methylation of adenine residues in DNA of eukaryotes

Like in bacteria, DNA in these organisms is subjected to enzymatic modification (methylation) both at adenine and cytosine residues. There is an indirect evidence that adenine DNA methylation takes place also in animals. In plants m6A was detected in total, mitochondrial and nuclear DNAs; in plants one and the same gene (DRM2) can be methylated both at adenine and cytosine residues. ORF homologous to bacterial adenine DNA-methyltransferases are present in nuclear DNA of protozoa, yeasts, insects, nematodes, higher plants, vertebrates and other eukaryotes. Thus, adenine DNA-methyltransferases can be found in the various evolutionary distant eukaryotes. First N6-adenine DNA-methyltransferase (wadmtase) of higher eukaryotes was isolated from vacuolar fraction of vesicles obtained from aging wheat coleoptiles; in the presence of S-adenosyl-L-methionine this Mg2+ -, Ca2+ -dependent enzyme de novo methylates first adenine residue in TGATCA sequence in single- and double-stranded DNA but it prefers single-stranded DNA structures. Adenine DNA methylation in eukaryotes seems to be involved in regulation of both gene expression and DNA replication including replication of mitochondrial DNA. It can control persistence of foreign DNA in a cell and seems to be an element of R-M system in plants. Thus, in eukaryotic cell there are, at least, two different systems of the enzymatic DNA methylations (adenine and cytosine ones) and a special type of regulation of gene functioning based on the combinatory hierarchy of these interdependent genome modifications.     

Detection of two essential sulfhydryl residues in Escherichia coli B glycogen synthase

Results presented indicate that two distinct essential sulfhydryl residues are present in the Escherichia coli B glycogen synthase. One residue is modified by iodoacetic acid and can be protected by ADP or ADPglucose. The other site can be modified by 5,5′-dithiobis (2-nitrobenzoic acid) and is protected by glycogen. Each reagent appears to be specific for a given site and thus allows the two sites to be distingushed.     

Correlation of DNA adenine methylase activity with spontaneous mutability in Escherichia coli K-12

Using a multicopy plasmid in which the tac promoter has been placed in front of the dam gene of Escherichia coli K-12, we show that levels of DNA adenine methylase activity are correlated with the spontaneous mutation frequency.     

Location of DNA methylation genes on the Escherichia coli K-12 genetic map

Summary The genes responsible for DNA adenine methylation (dam) and DNA cytosine methylation (dcm) have been mapped on the E. coli K-12 genetic map. The dam gene is situated at min 65 and the gene order cysG-(trpS, dam)-aro B inferred. The dcm gene is located at min 37.5 and the gene order is supD-dcm-flaA1. In F merodiploids, the dam and dcm alleles are recessive.