Cloning and characterization of the MamI restriction-modification system from Microbacterium ammoniaphilum in Escherichia coli

The genes encoding a class-IIN restriction-modification (R-M) system (MamI, sequence specificity 5'-GATnnvnnATC-3'

from Microbacterium ammoniaphilum have been cloned in Escherichia coli. The vector used for cloning was plasmid pUC18 modified by the inclusion of three MamI recognition sites. Recombinant clones containing the mamIM gene in its genomic context became fully methylated in vivo and remained completely resistant against digestion with the R·MamI restriction endonuclease (ENase). Determination of the nucleotide (nt) sequence revealed three open reading frames with lengths of 1089 bp (ORF1), 276 bp (ORFc) and 927 bp (ORF2). On the basis of expression and deletion experiments, the 1089-bp ORF1 was assigned to mamIM encoding the M·MamI DNA methyltransferase (MTase). By amino acid sequencing of the N terminus of R·MamI and comparison of the deduced nt sequence with ORF2, the 927-bp ORF2 was identified as the mamIR gene encoding R·MamI. The 276-bp ORFc, located between mamIR and mamIM, is part of the DNA sequence downstream from mamIM shown to be necessary for controlled mamIM expression.     

Cloning and expression of the BalI restriction-modification system.

BalI, a type II restriction-modification (R-M) system from the bacterium, Brevibacterium albidum, recognizes the DNA sequence 5'-TGGCCA-3'. We cloned the genes encoding the BalI restriction endonuclease and methyltransferase and expressed them in Escherichia coli. The two genes were aligned tail-to-tail and their termination codons overlapped. BalI restriction endonuclease and methyltransferase comprise 260 and 280 amino acids, respectively, and have molecular weights of 29 043 and 31 999 Da. The amino acid sequence of BalI methyltransferase is similar to that of other m6A MTases, although it has been categorized as a m5C methyltransferase. A high expression system for the BalI restriction endonuclease was constructed in E. coli for the production of large quantities of enzyme.     

Cloning the KpnI restriction-modification system in Escherichia coli

The genes encoding the KpnI restriction and modification (R-M) system from Klebsiella pneumoniae, recognizing the sequence, 5'-GGTAC decreases C-3', were cloned and expressed in Escherichia coli. Although the restriction endonuclease (ENase)- and methyltransferase (MTase)-encoding genes were closely linked, initial attempts to clone both genes as a single DNA fragment in a plasmid vector resulted in deletions spanning all or part of the gene coding for the ENase. Initial protection of the E. coli host with MTase expressed on a plasmid was required to stabilize a compatible plasmid carrying both the ENase- and the MTase-encoding genes on a single DNA fragment. However, once established, the MTase activity can be supplied in cis to the kpnIR gene, without an extra copy of kpnIM. A chromosomal map was generated localizing the kpnIR and kpnIM genes on 1.7-kb and 3.5-kb fragments, respectively. A final E. coli strain was constructed, AH29, which contained two compatible plasmids: an inducible plasmid carrying the kpnIR gene which amplifies copy number at elevated temperatures and a pBR322 derivative expressing M.KpnI. This strain produces approx. 10 million units of R.KpnI/g of wet-weight cells, which is several 1000-fold higher than the level of R.KpnI produced by K. pneumoniae. In addition, DNA methylated with M.KpnI in vivo does not appear to be restricted by the mcrA, mcrB or mrr systems of E. coli.     

Cloning the BstVI restriction-modification system in Escherichia coli

A standard DNA modification methyltransferase (MTase) selection protocol was followed to clone the BstVI restriction and modification system from Bacillus stearothermophilus in Escherichia coli. Both genes were contained in a 4.4-kb EcoRI fragment from B. stearothermophilus V chromosomal DNA. The heterologous expression of these genes did not depend on their orientation in the vector, suggesting that the genes are expressed in E. coli under the control of promoters located on the cloned fragment. Subcloning experiments demonstrated that the bstVIR gene was expressed in the absence of its cognate MTase.     

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.     

Cloning, nucleotide sequence, and expression of the HincII restriction-modification system.

Two genes, coding for the HincII from Haemophilus influenzae Rc restriction-modification system, were cloned and expressed in Escherichia coli RR1. Their DNA sequences were determined. The HincII methylase (M.HincII) gene was 1,506 base pairs (bp) long, corresponding to a protein of 502 amino acid residues (Mr = 55,330). The HincII endonuclease (R.HincII) gene was 774 bp long, corresponding to a protein of 258 amino acid residues (Mr = 28,490). The amino acid residues predicted from the R.HincII and the N-terminal amino acid sequence of the enzyme found by analysis were identical. These methylase and endonuclease genes overlapped by 1 bp on the H. influenzae Rc chromosomal DNA. The clone, named E. coli RR1-Hinc, overproduced R.HincII. The R.HincII activity of this clone was 1,000-fold that from H. influenzae Rc. The amino acid sequence of M.HincII was compared with the sequences of four other adenine-specific type II methylases. Important homology was found between tne M.HincII and these other methylases.     

Cloning, expression and sequence analysis of the SphI restriction-modification system

SphI, a type II restriction-modification (R-M) system from the bacterium Streptomyces phaeochromogenes, recognizes the sequence 5′-GCATGC. The SphI methyltransferase (MTase)-encoding gene, sphIM, was cloned into Escherichia coli using MTase selection to isolate the clone. However, none of these clones contained the restriction endonuclease (ENase) gene. Repeated attempts to clone the complete ENase gene along with sphIM in one step failed, presumably due to expression of SphI ENase gene, sphIR, in the presence of inadequate expression of sphIM. The complete sphIR was finally cloned using a two-step process. PCR was used to isolate the 3′ end of sphIR from a library. The intact sphIR, reconstructed under control of an inducible promoter, was introduced into an E. coli strain containing a plasmid with the NlaIII MTase-encoding gene (nlaIIIM). The nucleotide sequence of the SphI system was determined, analyzed and compared to previously sequenced R-M systems. The sequence was also examined for features which would help explain why sphIR unlike other actinomycete ENase genes seemed to be expressed in E. coli.     

Cloning of the HhaI and HinPI restriction-modification systems

The genes for the HhaI (Roberts et al., 1976) and HinPI (Roberts, 1987) restriction-modification (R-M) systems have been cloned in pBR322. The HhaI system was isolated on a 9-kb PstI fragment, and the HinPI system was isolated on two PstI fragments of 1.5 and 4.6 kb in length. The clones were isolated by selecting for recombinant molecules that had protectively modified themselves. The HhaI and HinPI R-M systems recognize the same sequence, GCGC, but hybridization between the DNA fragments encoding them does not take place.     

Cloning and expression of the HpaI restriction-modification genes.

The genes from Haemophilus parainfluenzae encoding the HpaI restriction-modification system were cloned and expressed in Escherichia coli. From the DNA sequence, we predicted the HpaI endonuclease (R.HpaI) to have 254 amino acid residues (Mr 29,630) and the HpaI methyltransferase (M.HpaI) to have 314 amino acid residues (37,390). The R.HpaI and M.HpaI genes overlapped by 16 base pairs on the chromosomal DNA. The genes had the same orientation. The clone, named E. coli HB101-HPA2, overproduced R.HpaI. R.HpaI activity from the clone was 100-fold that from H. parainfluenzae. The amino acid sequence of M.HpaI was compared with those of other type II methyltransferases.     

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.     

Formation of MboII vectors and cassettes using asymmetric MboII linkers

Class-IIS restriction endonucleases such as MboII cleave DNA at a specified distance away from their recognition sequences. This feature was exploited to cleave DNA at previously inaccessible locations by preparing special asymmetric linker/adapters containing the MboII recognition sequence. These could be joined to DNA fragments and subsequently cleaved by MboII. Attachment of a 3' phosphate to one of the two different oligodeoxynucleotides comprising the asymmetric duplex prevented ligation at the improper end of the linker. Plasmids were constructed containing a unique BamHI or BclI site between the recognition and cleavage site of MboII. These sites were used to introduce a foreign fragment into the plasmid at a position permitting MboII to cleave within the newly inserted fragment. Once cleaved at the unique MboII site, another DNA fragment was inserted. DNA was thus inserted at a sequence not previously accessible to specific cleavage by a restriction enzyme. A cassette containing an identifiable marker, the lac operator, between two oppositely oriented MboII/BamHI linkers was made and tested in a random insertion linker mutagenesis experiment.     

Cloning and sequence comparison ofAvaI andBsoBI restriction-modification systems

AvaI andBsoBI restriction endonucleases are isoschizomers which recognize the symmetric sequence 5′CYCGRG3′ and cleave between the first C and second Y to generate a four-base 5′ extension. TheAvaI restriction endonuclease gene (avaIR) and methylase gene (avaIM) were cloned intoEscherichia coli by the methylase selection method. TheBsoBI restriction endonuclease gene (bsoBIR) and part of theBsoBI methylase gene (bsoBIM) were cloned by the “endo-blue” method (SOS induction assay), and the remainder ofbsoBIM was cloned by inverse PCR. The nucleotide sequences of the two restriction-modification (RM) systems were determined. Comparisons of the predicted amino acid sequences indicated thatAvaI andBsoBI endonucleases share 55% identity, whereas the two methylases share 41% identity. Although the two systems show similarity in protein sequence, their gene organization differs. TheavaIM gene precedesavaIR in theAvaI RM system, while thebsoBIR gene is located upstream ofbsoBIM in theBsoBI RM system. BothAvaI andBsoBI methylases contain motifs conserved among the N⁴ cytosine methylases.     

Cloning and sequence analysis of the StsI restriction-modification gene: presence of homology to FokI restriction-modification enzymes.

StsI endonuclease (R.StsI), a type IIs restriction endonuclease found in Streptococcus sanguis 54, recognizes the same sequence as FokI but cleaves at different positions. A DNA fragment that carried the genes for R.StsI and StsI methylase (M.StsI) was cloned from the chromosomal DNA of S.sanguis 54, and its nucleotide sequence was analyzed. The endonuclease gene was 1,806 bp long, corresponding to a protein of 602 amino acid residues (M(r) = 68,388), and the methylase gene was 1,959 bp long, corresponding to a protein of 653 amino acid residues (M(r) = 76,064). The assignment of the endonuclease gene was confirmed by analysis of the N-terminal amino acid sequence. Genes for the two proteins were in a tail-to-tail orientation, separated by a 131-nucleotide intercistronic region. The predicted amino acid sequences between the StsI system and the FokI system showed a 49% identity between the methylases and a 30% identity between the endonucleases. The sequence comparison of M.StsI with various methylases showed that the N-terminal half of M.StsI matches M.NIaIII, and the C-terminal half matches adenine methylases that recognize GATC and GATATC.     

Cloning and analysis of the genes encoding the type IIS restriction-modification system HphI from Haemophilus parahaemolyticus.

The genomic region encoding the type IIS restriction-modification (R-M) system HphI (enzymes recognizing the asymmetric sequence 5'-GGTGA-3'/5'-TCACC-3') from Haemophilus parahaemolyticus were cloned into Escherichia coli and sequenced. Sequence analysis of the R-M HphI system revealed three adjacent genes aligned in the same orientation: a cytosine 5 methyltransferase (gene hphIMC), an adenine N6 methyltransferase (hphIMA) and the HphI restriction endonuclease (gene hphIR). Either methyltransferase is capable of protecting plasmid DNA in vivo against the action of the cognate restriction endonuclease. hphIMA methylation renders plasmid DNA resistant to R.Hindill at overlapping sites, suggesting that the adenine methyltransferase modifies the 3'-terminal A residue on the GGTGA strand. Strong homology was found between the N-terminal part of the m6A methyltransferasease and an unidentified reading frame interrupted by an incomplete gaIE gene of Neisseria meningitidis. The HphI R-M genes are flanked by a copy of a 56 bp direct nucleotide repeat on each side. Similar sequences have also been identified in the non-coding regions of H.influenzae Rd DNA. Possible involvement of the repeat sequences in the mobility of the HphI R-M system is discussed.     

Isolation and characterization of a HpyC1I restriction-modification system in Helicobacter pylori

Using transposon shuttle mutagenesis, we identified six Helicobacter pylori mutants from the NTUH-C1 strain that exhibited decreased adherence and cell elongation. Inverse polymerase chain reaction and DNA sequencing revealed that the same locus was interrupted in these six mutants. Nucleotide and amino acid sequences showed no homologies with H. pylori 26695 and J99 strains. This novel open reading frame contained 1617 base pairs. The amino acid sequence shared 24% identity with a putative nicking enzyme in Bacillus halodurans and 23 and 20% identity with type IIS restriction endonucleases PleI and MlyI, respectively. The purified protein, HpyC1I, showed endonuclease activity with the recognition and cleavage site 5'-CCATC(4/5)-3'. Two open reading frames were located upstream of the gene encoding HpyC1I. Together, HpyC1I and these two putative methyltransferases (M1.HpyC1I and M2.HpyC1I) function as a restriction-modification (R-M) system. The HpyC1I R-M genes were found in 9 of the 15 H. pylori strains tested. When compared with the full genome, significantly lower G + C content of HpyC1I R-M genes implied that these genes might have been acquired by horizontal gene transfer. Plasmid DNA transformation efficiencies and chromosomal DNA digestion assays demonstrated protection from HpyC1I digestion by the R-M system. In conclusion, we have identified a novel R-M system present in approximately 60% of H. pylori strains. Disruption of this R-M system results in cell elongation and susceptibility to HpyC1I digestion.     

Cloning the FnuDI, NaeI, NcoI and XbaI restriction-modification systems

Methyltransferase genes from the FnuDI, NaeI, NcoI, and XbaI restriction-modification systems have been isolated in Escherichia coli by 'shot-gun' cloning bacterial DNA fragments into plasmid vectors and selecting for protectively modified molecules that resist digestion by the corresponding restriction endonuclease.