Importance of state of methylation of oriC GATC sites in initiation of DNA replication in Escherichia coli.

In vivo and in vitro evidence is presented implicating a function of GATC methylation in the Escherichia coli replication origin, oriC, during initiation of DNA synthesis. Transformation frequencies of oriC plasmids into E. coli dam mutants, deficient in the GATC-specific DNA methylase, are greatly reduced compared with parental dam+ cells, particularly for plasmids that must use oriC for initiation. Mutations that suppress the mismatch repair deficiency of dam mutants do not increase these low transformation frequencies, implicating a new function for the Dam methylase. oriC DNA isolated from dam- cells functions 2- to 4-fold less well in the oriC-specific in vitro initiation system when compared with oriC DNA from dam+ cells. This decreased template activity is restored 2- to 3-fold if the DNA from dam- cells is first methylated with purified Dam methylase. Bacterial origin plasmids or M13-oriC chimeric phage DNA, isolated from either base substitution or insertion dam mutants of E. coli, exhibit some sensitivity to digestion by DpnI, a restriction endonuclease specific for methylated GATC sites, showing that these dam mutants retain some Dam methylation activity. Sites of preferred cleavage are found within the oriC region, as well as in the ColE1-type origin.     

Molecular cloning, sequencing, and mapping of the bacteriophage T2 dam gene.

Bacteriophage T2 codes for a DNA-(adenine-N6)methyltransferase (Dam), which is able to methylate both cytosine- and hydroxymethylcytosine-containing DNAs to a greater extent than the corresponding methyltransferase encoded by bacteriophage T4. We have cloned and sequenced the T2 dam gene and compared it with the T4 dam gene. In the Dam coding region, there are 22 nucleotide differences, 4 of which result in three coding differences (2 are in the same codon). Two of the amino acid alterations are located in a region of homology that is shared by T2 and T4 Dam, Escherichia coli Dam, and the modification enzyme of Streptococcus pneumoniae, all of which methylate the sequence 5' GATC 3'. The T2 dam and T4 dam promoters are not identical and appear to have slightly different efficiencies; when fused to the E. coli lacZ gene, the T4 promoter produces about twofold more beta-galactosidase activity than does the T2 promoter. In our first attempt to isolate T2 dam, a truncated gene was cloned on a 1.67-kilobase XbaI fragment. This construct produces a chimeric protein composed of the first 163 amino acids of T2 Dam followed by 83 amino acids coded by the pUC18 vector. Surprisingly, the chimera has Dam activity, but only on cytosine-containing DNA. Genetic and physical analyses place the T2 dam gene at the same respective map location as the T4 dam gene. However, relative to T4, T2 contains an insertion of 536 base pairs 5' to the dam gene. Southern blot hybridization and computer analysis failed to reveal any homology between this insert and either T4 or E. coli DNA.     

Very short patch mismatch repair activity associated with gene dcm is not conferred by a plasmid coding for EcoRII methylase.

The only cytosine methylase in Escherichia coli K-12 methylates the second cytosine in the sequence CC (A/T)GG and is encoded by gene dcm. Methylation and very short patch mismatch repair activities lacking in a dcm mutant of E. coli were restored by a plasmid containing the cloned dcm gene. In contrast, plasmids with the gene for EcoRII methylase, which is a homolog of dcm, restored only cytosine methylase activity and not mismatch repair.     

The DNA [adenine-N6]methyltransferase (Dam) of bacteriophage T4

A functional bacteriophage T4 dam+ gene, which specifies a DNA [adenine-N6]methyltransferase (Dam), was cloned on a 1.8-kb HindIII fragment [Schlagman and Hattman, Gene 22 (1983) 139-156]. Sequence analysis [Macdonald and Mosig, EMBO J. 3 (1984) 2863-2871] revealed two overlapping in-phase open reading frames (ORFs). The 5' proximal ORF initiates translation at an AUG and encodes a 30-kDa polypeptide, whereas the downstream ORF initiates translation at a GUG and encodes a 26-kDa polypeptide. Analysis of BAL 31 deletions in our original dam+ clone has verified that at least one of these overlapping ORFs, in fact, encodes T4 Dam. To investigate where T4 Dam translation is initiated, we have constructed plasmids in which a tac or lambda PL promoter is placed 5' to either the longer ORF or just the shorter ORF. Only clones which contain a promoter in front of the longer ORF produce active T4 Dam. This indicates that the 26-kDa polypeptide alone cannot be T4 Dam. Additional experiments suggest that only the 30-kDa polypeptide is required for enzyme activity and that the shorter ORF is not translated in plasmid-carrying cells. We also present evidence that T4 Dam is capable of methylating 5'-GATC-3', GATm5C, and GAThmC sequences; non-canonical sites (e.g., GACC) are also methylated, but much less efficiently.     

Influence of DNA adenine methylase on the sensitivity of Escherichia coli to near-ultraviolet radiation and hydrogen peroxide

Near-ultraviolet (NUV) radiation and hydrogen peroxide (H2O2) inactivation studies were performed on Escherichia coli K-12 DNA adenine methylation (dam) mutants and on cells that carry plasmids which overexpress Dam methylase. Lack of methylation resulted in increased sensitivity to NUV and H2O2 (a photoproduct of NUV). In a dam mutant carrying a dam plasmid, the levels of Dam enzyme and resistance to NUV and H2O2 were restored. However, using a multicopy dam+ plasmid strain, increasing the methylase above wildtype levels resulted in an increase in sensitivity of the cells rather than resistance.     

DNA Adenine Methylase Mutants of Salmonella Typhimurium and a Novel Dam-Regulated Locus

Mutants of Salmonella typhimurium lacking DNA adenine methylase were isolated; they include insertion and deletion alleles. The dam locus maps at 75 min between cysG and aroB, similar to the Escherichia coli dam gene. Dam(-) mutants of S. typhimurium resemble those of E. coli in the following phenotypes: (1) increased spontaneous mutations, (2) moderate SOS induction, (3) enhancement of duplication segregation, (4) inviability of dam recA and dam recB mutants, and (5) suppression of the inviability of the dam recA and dam recB combinations by mutations that eliminate mismatch repair. However, differences between S. typhimurium and E. coli dam mutants are also found: (1) S. typhimurium dam mutants do not show increased UV sensitivity, suggesting that methyl-directed mismatch repair does not participate in the repair of UV-induced DNA damage in Salmonella. (2) S. typhimurium dam recJ mutants are viable, suggesting that the Salmonella RecJ function does not participate in the repair of DNA strand breaks formed in the absence of Dam methylation. We also describe a genetic screen for detecting novel genes regulated by Dam methylation and a locus repressed by Dam methylation in the S. typhimurium virulence (or ``cryptic') plasmid.     

哈氏弧菌dam基因的克隆与分析

利用兼并PCR的方法克隆得到哈氏弧菌T4的DNA腺嘌呤甲基化酶(dam)基因,序列分析表明该基因编码279个氨基酸,与其它已知弧菌的Dam具有较高的同源性,其中与副溶血弧菌Dam的相同性达95%。功能检验表明所克隆的dam基因在大肠杆菌中具有DNA腺嘌呤甲基化酶活性,能够甲基化大肠杆菌染色体DNA GATC序列中的腺嘌呤。运用染色体步移法获得dam基因上游的3251 bp DNA,发现该区域含有3个基因,其与dam在染色体上的相对排列顺序为:莽草酸激酶-脱氢奎尼酸合成酶-damX-dam。对dam上游DNA序列研究发现位于翻译起点ATG上游的78bp、112bp和477bpDNA片段皆具有启动子活性,但前者的活性明显高于后二者。     

Characterization of a dam Mutant of Serratia marcescens and Nucleotide Sequence of the dam Region

The DNA of Serratia marcescens has N6-adenine methylation in GATC sequences. Among 2-aminopurine-sensitive mutants isolated from S. marcescens Sr41, one was identified which lacked GATC methylation. The mutant showed up to 30-fold increased spontaneous mutability and enhanced mutability after treatment with 2-aminopurine, ethyl methanesulfonate, or UV light. The gene (dam) coding for the adenine methyltransferase (Dam enzyme) of S. marcescens was identified on a gene bank plasmid which alleviated the 2-aminopurine sensitivity and the higher mutability of a dam-13::Tn9 mutant of Escherichia coli. Nucleotide sequencing revealed that the deduced amino acid sequence of Dam (270 amino acids; molecular mass, 31.3 kDa) has 72% identity to the Dam enzyme of E. coli. The dam gene is located between flanking genes which are similar to those found to the sides of the E. coli dam gene. The results of complementation studies indicated that like Dam of E. coli and unlike Dam of Vibrio cholerae, the Dam enzyme of S. marcescens plays an important role in mutation avoidance by allowing the mismatch repair enzymes to discriminate between the parental and newly synthesized strands during correction of replication errors.     

Cloning the DdeI restriction-modification system using a two-step method.

DdeI, a Type II restriction-modification system from the gram-negative anaerobic bacterium Desulfovibrio desulfuricans, recognizes the sequence CTNAG. The system has been cloned into E. coli in two steps. First the methylase gene was cloned into pBR322 and a derivative expressing higher levels was constructed. Then the endonuclease gene was located by Southern blot analyses; BamHI fragments large enough to contain the gene were cloned into pACYC184, introduced into a host containing the methylase gene, and screened for endonuclease activity. Both genes are stably maintained in E. coli on separate but compatible plasmids. The DdeI methylase is shown to be a cytosine methylase. DdeI methylase clones decrease in viability as methylation activity increases in E. coli RR1 (our original cloning strain). Therefore the DdeI system has been cloned and maintained in ER1467, a new E. coli cloning strain engineered to accept cytosine methylases. Finally, it has been demonstrated that a very high level of methylation was necessary in the DdeI system for successful introduction of the active endonuclease gene into E. coli.     

Nucleotide sequence of the DdeI restriction-modification system and characterization of the methylase protein.

The DdeI restriction-modification system was previously cloned and has been maintained in E. coli on two separate and compatible plasmids (1). The nucleotide sequence of the endonuclease and methylase genes has now been determined; it predicts proteins of 240 amino acids, Mr = 27,808, and 415 amino acids, Mr = 47,081, respectively. Inspection of the DNA sequence shows that the 3' end of the methylase gene had been deleted during cloning. The clone containing the complete methylase gene was made and compared to that containing the truncated gene; only clones containing the truncated form support the endonuclease gene in E. coli. Bal-31 deletion studies show that methylase expression in the Dde clones is also dependent upon orientation of the gene with respect to pBR322. The truncated and complete forms of the methylase protein were purified and compared; the truncated form appears to be more stable and active in vitro. Finally, comparison of the deduced amino acid sequence of M. DdeI with that of other known cytosine methylases shows significant regions of homology.     

Restriction of two-replicon shuttle Escherichia coli-Streptomyces plasmids in Streptomyces lividans strain 66

The shuttle Escherichia coli - Streptomyces plasmids were used to transform S. lividans 66. Plasmid DNAs isolated from this strain transform it 10-1000-fold more efficiently than DNAs from E. coli. Rare transformant cured from most restricted plasmid is more efficient recipient of plasmid DNA from E. coli and has the property of R +/- M+ mutant. Restriction in S. lividans 66 correlates with the appearance in DNA from E. coli of the sites susceptible to Scg2I restriction endonuclease. The latter was isolated earlier from recombinant strain Rcg2, a hybrid between S. griseus Kr. 15 and S. coelicolor A3(2). Scg2I possesses the recognition sequence CCTAGG, like EcoRII, MvaI and Eco dcm methylase. The DNA resistant to Scg2I cleavage retained this ability after in vitro modification by EcoRII methylase. So, the resistance of DNA to Scg2I cleavage is not connected with methylation at 4th and 5th position of second cytosine in the recognition sequence. Neither restriction of plasmid DNA in S. lividans 66 is dependent on dcm modification in E. coli, though its dependence on dam modification is not excluded. It is assumed that the restriction in S. lividans 66 is specified by endonuclease analogous to Scg2I.     

Cloning the BamHI restriction modification system.

BamHI, a Type II restriction modification system from Bacillus amyloliquefaciensH recognizes the sequence GGATCC. The methylase and endonuclease genes have been cloned into E. coli in separate steps; the clone is able to restrict unmodified phage. Although within the clone the methylase and endonuclease genes are present on the same pACYC184 vector, the system can be maintained in E. coli only with an additional copy of the methylase gene present on a separate vector. The initial selection for BamHI methylase activity also yielded a second BamHI methylase gene which is not homologous in DNA sequence and hybridizes to different genomic restriction fragments than does the endonuclease-linked methylase gene. Finally, the interaction of the BamHI system with the E. coli Dam and the Mcr A and B functions, have been studied and are reported here.     

Genetic transformation of Geobacillus kaustophilus HTA426 by conjugative transfer of host-mimicking plasmids

We established an efficient transformation method for thermophile Geobacillus kaustophilus HTA426 using conjugative transfer from Escherichia coli of host-mimicking plasmids that imitate DNA methylation of strain HTA426 to circumvent its DNA restriction barriers. Two conjugative plasmids, pSTE33T and pUCG18T, capable of shuttling between E. coli and Geobacillus spp., were constructed. The plasmids were first introduced into E. coli BR408, which expressed one inherent DNA methylase gene (dam) and two heterologous methylase genes from strain HTA426 (GK1380-GK1381 and GK0343-GK0344). The plasmids were then directly transferred from E. coli cells to strain HTA426 by conjugative transfer using pUB307 or pRK2013 as a helper plasmid. pUCG18T was introduced very efficiently (transfer efficiency, 10(-5)-10(-3) recipient(-1)). pSTE33T showed lower efficiency (10(-7)-10(-6) recipient(-1)) but had a high copy number and high segregational stability. Methylase genes in the donor substantially affected the transfer efficiency, demonstrating that the host-mimicking strategy contributes to efficient transformation. The transformation method, along with the two distinguishing plasmids, increases the potential of G. kaustophilus HTA426 as a thermophilic host to be used in various applications and as a model for biological studies of this genus. Our results also demonstrate that conjugative transfer is a promising approach for introducing exogenous DNA into thermophiles.     

Cloning and structure of the BepI modification methylase.

The gene coding for a CGCG specific DNA methylase has been cloned in E. coli from Brevibacterium epidermidis. The enzyme, named BepI methylase, is probably the cognate methylase of the FnuDII isoschizomer BepI endonuclease isolated from this strain. The expression of BepI methylase in E. coli is dependent on the orientation of the cloned fragment suggesting that the gene is transcribed from a promoter on the plasmid vector. No BepI endonuclease could be detected in the clones producing BepI methylase. The nucleotide sequence of the BepI methylase gene has been determined, it predicts a protein of 403 amino acids (MR: 45,447). Analysis of the amino acid sequence deduced from the nucleotide sequence revealed similarities between the BepI methylase and other cytosine methylases. M. BepI methylates the external cytosine in its recognition sequence.     

Cloning and sequencing of a gene encoding a glutamate and aspartate carrier of Escherichia coli K-12.

A gene encoding a carrier protein for glutamate and aspartate was cloned into Escherichia coli K-12 strain BK9MDG by using the high-copy-number plasmid pBR322. The gene (designated gltP) is probably identical to a gene recently cloned from E. coli B (Y. Deguchi, I. Yamato, and Y. Anraku, J. Bacteriol. 171:1314-1319). A 1.6-kilobase DNA fragment containing gltP was subcloned into the expression plasmids pT7-5 and pT7-6, and its product was identified by a phage T7 RNA polymerase-T7 promoter coupled system (S. Tabor and C. C. Richardson, Proc. Natl. Acad. Sci. USA 82:1074-1078) as a polypeptide with an apparent mass of 38 kilodaltons. A portion of the gltP polypeptide was associated with the cytoplasmic membrane. The nucleotide sequence of the 1.6-kilobase fragment was determined. It contained an open reading frame capable of encoding a highly hydrophobic polypeptide of 395 amino acids, containing four possible transmembrane segments. Uptake of glutamate and aspartate was increased 5.5- and 4.5-fold, respectively, in strains containing gltP plasmids. Glutamate uptake was insensitive to the concentration of Na+ and was inhibited by L-cysteate and beta-hydroxyaspartate. These results suggest that gltP is a structural gene for a carrier protein of the Na(+)-independent, binding-protein-independent glutamate-aspartate transport system.     

Complementation of nitrogen-regulatory (ntr-like) mutations in Rhodobacter capsulatus by an Escherichia coli gene: cloning and sequencing of the gene and characterization of the gene product.

In vivo genetic engineering by R' plasmid formation was used to isolate an Escherichia coli gene that restored the Ntr+ phenotype to Ntr- mutants of the photosynthetic bacterium Rhodobacter capsulatus (formerly Rhodopseudomonas capsulata; J. F. Imhoff, H. G. Trüper, and N. Pfenning, Int. J. Syst. Bacteriol. 34:340-343, 1984). Nucleotide sequencing of the gene revealed no homology to the ntr genes of Klebsiella pneumoniae. Furthermore, hybridization experiments between the cloned gene and different F' plasmids indicated that the gene is located between 34 and 39 min on the E. coli genetic map and is therefore unlinked to the known ntr genes. The molecular weight of the gene product, deduced from the nucleotide sequence, was 30,563. After the gene was cloned in an expression vector, the gene product was purified. It was shown to have a pI of 5.8 and to behave as a dimer during gel filtration and on sucrose density gradients. Antibodies raised against the purified protein revealed the presence of this protein in R. capsulatus strains containing the E. coli gene, but not in other strains. Moreover, elimination of the plasmid carrying the E. coli gene from complemented strains resulted in the loss of the Ntr+ phenotype. Complementation of the R. capsulatus mutations by the E. coli gene therefore occurs in trans and results from the synthesis of a functional gene product.     

Chemical synthesis and expression of a synthetic gene for the flavodoxin from Clostridium MP

A gene coding for the flavodoxin from Clostridium MP was designed, synthesized, and expressed in Escherichia coli. The sequence of the coding region was derived from the published amino acid sequence of the protein (Tanaka, M., Haniu, M., Yasunobu, K.T., and Mayhew, S. G. (1974) J. Biol. Chem. 249, 4393-4397) and was designed for optimal expression and for use of the cassette mutagenesis approach. The structural gene was subassembled in three sections, each of which was constructed by the enzymatic ligation of three complementary pairs of chemically synthesized oligodeoxyribonucleotides having short single-stranded ends complementary to that of the adjacent pair. Coligation of the three sections produced the final structural gene which consists of 420 nucleotides. The synthetic gene was cloned behind the hybrid tac promoter (Amman, E., Brosius, J., and Ptashne, M. (1983) Gene (Amst.) 25, 167-178) in the pKK223-3 vector or adjacent to the strong T7 RNA polymerase promoter in the pET-3a expression vector (Rosenberg, A.H., Lade, B. N., Chui, D-S., Lin, S-W., Dunn, J. J., and Studier, F. W. (1987) Gene (Amst.) 56, 125-135) for expression in E. coli. Upon induction with isopropyl-beta-D-thiogalactoside, the flavodoxin polypeptide was expressed from the artificial gene to levels approaching 20% of total extractable proteins using either expression system. The flavodoxin was purified from cellular extracts as the holoprotein containing bound flavin mononucleotide. The recombinant flavodoxin protein was found to have an ultraviolet/visible spectrum, amino-terminal sequence, and amino acid composition identical to the wild-type flavodoxin protein purified from Clostridium MP. This work represents the first chemical synthesis and expression in E. coli of an artificial gene coding for a bacterial flavodoxin.     

The isolation and characterization of the Escherichia coli DNA adenine methylase (dam) gene.

The E. coli dam (DNA adenine methylase) enzyme is known to methylate the sequence GATC. A general method for cloning sequence-specific DNA methylase genes was used to isolate the dam gene on a 1.14 kb fragment, inserted in the plasmid vector pBR322. Subsequent restriction mapping and subcloning experiments established a set of approximate boundaries of the gene. The nucleotide sequence of the dam gene was determined, and analysis of that sequence revealed a unique open reading frame which corresponded in length to that necessary to code for a protein the size of dam. Amino acid composition derived from this sequence corresponds closely to the amino acid composition of the purified dam protein. Enzymatic and DNA:DNA hybridization methods were used to investigate the possible presence of dam genes in a variety of prokaryotic organisms.     

Cloning of the BamHI methyl transferase gene from Bacillus amyloliquefaciens

We wish to report the initial characterization of a recombinant clone containing the BamHI methylase gene. Genomic chromosomal DNA purified from Bacillus amyloliquefaciens was partially cleaved with HindIII, fractionated by size, and cloned into pSP64. Plasmid DNA from this library was challenged with BamHI endonuclease and transformed into Escherichia coli HB101. A recombinant plasmid pBamM6.5 and a subclone pBamM2.5 were shown to contain the BamHI methylase gene based on three independent observations. Both plasmids were found to be resistant to BamHI endonuclease cleavage, and chromosomal DNA isolated from E. coli HB101 cells harboring either of the plasmids pBamM6.5 or pBamM2.5 was resistant to cleavage by BamHI endonuclease. In addition, DNA isolated from lambda phage passaged through E. coli HB101 containing either plasmid was also resistant to BamHI cleavage. Expression of the BamHI methylase gene is dependent on orientation in pSP64. In these clones preliminary evidence indicates that methylase gene expression may be under the direction of the plasmid encoded LacZ promoter.