The nucleotide sequence recognized by the Escherichia coli K12 restriction and modification enzymes.

The sites recognized by the Escherichia coli K12 restriction endonuclease were localized to defined regions on the genomes of phage φXsK1, φXsK2, and G4 by the marker rescue technique. Methyl groups placed on the genome of plasmid pBR322 by the E. coli K12 modification methylase were mapped in HinfI fragments 1 and 3, and HaeIII fragments 1 and 3. A homology of seven nucleotides in the configuration: 5′-A-A-C .. 6N .. G-T-G-C-3′, where 6N represents six unspecified nucleotides, was found among the DNA sequences containing the five EcoK sites of φXsK1, φXsK2, G4, and pBR322. Three lines of evidence indicate that this sequence constitutes the recognition site of the E. coli K12 restriction enzyme. The C in 5′-A-A-C and the T in 5′-G-T-G-C are locations of mutations leading to loss or gain of the site and thus are positions recognized by the enzyme. This sequence does not occur on φXam3cs70, simian virus 40 (SV40), and fd DNAs which do not possess EcoK sites, and occurs only once on φXsK1, φXsK2, and G4 DNAs, and twice on pBR322 DNA. In order to prove that all seven conserved nucleotides are essential for the recognition by the E. coli K12 restriction enzyme, the nucleotide sequences of φX174, G4, SV40, fd, and pBR322 were searched for sequences differing from the sequence 5′-A-A-C .. 6N .. G-TG-C-3′ at only one of the specified positions. It was found that sequences differing at each of the specified positions occur on DNA sequences that do not contain the EcoK sites. Thus, the recognition site of the E. coli K12 restriction enzyme has the same basic structure as that of the EcoB site (Lautenberger et al., 1978). In each case there are two domains, one containing three and the other four specific nucleotides, separated by a sequence of unspecified bases. However, the unspecified sequence in the EcoK site must be precisely six bases instead of the eight found in the EcoB site. Alignment of the EcoK and EcoB sites suggests that four of the seven specified nucleotides are conserved between the sequences recognized by these two allelic restriction and modification systems.     

Sequence specificity of the P1 modification methylase (M.Eco P1) and the DNA methylase (M.Eco dam) controlled by the Escherichia coli dam gene.

Labeled oligonucleotides have been fractionated from pancreatic DNase digests of DNA that had been methylated in vitro with the P1 modification enzyme (M·Eco P1) or with the DNA-adenine methylase (M·Eco dam) controlled by the Escherichia coli dam gene. The sequences of methylated oligonucleotides were established for M·Eco dam modification of calf thymus DNA. The results show that M·Eco dam inethylates adenine residues contained in the twofold symmetrical sequence, 5′ … G-A-T-C … 3′. The sequence for the site methylated by M·Eco P1 has also been deduced; we propose that M·Eco P1 modification produces the following methylated pentameric sequence: 5′ … A-G-A¹-C-Py … 3′ (where $\text{A}{}^1\text{= N}{}^6$ methyladenine and Py is C or T).     

DNA recognition and cleavage by the EcoP15 restriction endonuclease.

EcoP15 is a restriction-modification enzyme coded by the P15 plasmid of Escherichia coli. We have determined the sites recognized by this enzyme on pBR322 and simian virus 40 DNA. The enzyme recognizes the sequence:

In restriction, the enzyme cleaves the DNA 25 to 26 base-pairs 3′ to this sequence to leave single-stranded 5′ protrusions two bases long.     

Electron microscopic studies of the mechanism of action of the restriction endonuclease of Escherichia coli B.

Reaction intermediates and products formed by the restriction endonuclease of Escherichia coli B with fd replicative form DNA substrates containing recognition sites in known positions and orientations have been characterized by electron microscopy. After exposure of these substrates to enzyme, loops of duplex DNA were frequently observed, usually at or near the termini. Analysis of the size and structure of the loops observed with various DNA substrates suggests that the enzyme binds initially to the recognition site then remains bound to the DNA in the region of this site while tracking towards a site of cleavage. Tracking appears to occur only on the 5′ side of the asymmetric recognition sequence, 5′ … T-G-A-(N)₈-T-G-C-T … 3′; however, the location of the cleavage sites appears to be random, at least within certain limits of distance from the recognition site. Enzyme-DNA complexes remain intact even after the double-strand cleavage is completed, and this complex acts as a potent ATPase with no obvious function. This latter reaction might represent an artifactual uncoupling of ATP hydrolysis from the tracking of the enzyme along the DNA; alternatively, it might indicate an in vivo function for the enzyme of which we are unaware.     

A new restriction endonuclease Eco31I recognizing a non-palindromic sequence

A restriction endonuclease with a novel site-specificity has been isolated from the Escherichia coli strain RFL31. The nucleotide sequences around a single Eco31I cut on pBR322 DNA and two cuts of λ DNA have been compared. A common ^5′GAGACC_3′CTCTGG sequence occurs near each cleavage site. Precise mapping of the cleavages in both DNA strands places the cuts five nucleotides to the left of the upper sequence and one nucleotide to the left of the lower sequence. This enabled us to deduce the following recognition and cleavage specificity of Eco31I: 5 ′ G G T C T C N ↓ 3 ′ C C A G A G N N N N N ↑     

Sth132I,a novel class-IIS restriction endonuclease of Streptococcus thermophilus ST132

The Sth132I restriction endonuclease (R.Sth132I) was detected in Streptococcus thermophilus ST132 and purified to near homogeneity by heparin Sepharose CL-6B affinity chromatography. Fragments from Sth132I digestion of plasmid DNA were subcloned into pUC19 in Escherichia coli DH5α and sequenced. Sequence analysis of inserts and their ligation junction sites revealed that Sth132I is a novel class-IIS restriction endonuclease, which recognizes the non-palindromic sequence5′-CCCG(N)₄-3′3′-GGGC(N)₈-5′.     

Cloning and expression of the Apa LI, Nsp I, Nsp HI, Sac I, Sca I, and Sap I restriction-modification systems in Escherichia coli

The genes encoding the ApaLI (5′-G^TGCAC-3′), NspI (5′-RCATG^Y-3′), NspHI (5′-RCATG^Y-3′), SacI (5′-GAGCT^C-3′), SapI (5′-GCTCTTCN1^-3′, 5′-^N4GAAGAGC-3′) and ScaI (5′-AGT^ACT-3′) restriction-modification systems have been cloned in E.?coli. Amino acid sequence comparison of M.ApaLI, M.NspI, M.NspHI, and M.SacI with known methylases indicated that they contain the ten conserved motifs characteristic of C5 cytosine methylases. NspI and NspHI restriction-modification systems are highly homologous in amino acid sequence. The C-termini of the NspI and NlaIII (5′-CATG-3′) restriction endonucleases share significant similarity. 5mC modification of the internal C in a SacI site renders it resistant to SacI digestion. External 5mC modification of a SacI site has no effect on SacI digestion. N4mC modification of the second base in the sequence 5′-GCTCTTC-3′ blocks SapI digestion. N4mC modification of the other cytosines in the SapI site does not affect SapI digestion. N4mC modification of ScaI site blocks ScaI digetion. A DNA invertase homolog was found adjacent to the ApaLI restriction-modification system. A DNA transposase subunit homolog was found upstream of the SapI restriction endonuclease gene.     

Characterization of DNA restriction and modification activities in Neisseria species

Type II restriction endonuclease activities detected in various Neisseria species were characterized for sequence specificity and precise site of cleavage. NsiCI isolated from N. sicca C351 cleaves the sequence 5′-GAT↓ATC-3′ (EcoRV isoschizomer); NmeCI from N. meningitidis C114 and NphI from N. pharyngis C245 cleave 5′-N↓GATCN-3′ (MboI isoschizomers); NgoPII and NgoPIII from N. gonorrhoeae P9-2 cleave at 5′-CC↓GCGG-3′ (SacII isoschizomer) and 5′-GG↓CC-3′ (HaeIII isoschizomer), respectively. Chromosomal DNA isolated from these strains and two other N. meningitidis strains (which lacked detectable endonuclease activities), was found to be refractive to cleavage by various restriction enzymes, implying the presence of methylase activities additional to those required for protection against the cellular endonucleases.     

Restriction of bacteriophage lambda by Escherichia coli K

Derivatives of phage lambda, for which the numbers and positions of the recognition sites for endonuclease R. Eco_k are known, were used as substrates for the Escherichia coli K restriction system in vivo and in vitro. A single unmodified recognition site was sufficient for a DNA molecule to be bound and broken by the K restriction enzyme. Although discrete fragments of DNA were not produced, the breaks were made preferentially in the proximity of the recognition site. Breakage of a DNA molecule with only one recognition site required a 10 to 40-fold higher concentration of restriction enzyme than breakage of a DNA molecule with two or more recognition sites, but these substrates were all equally effective in a binding assay for the enzyme.The polynucleotide kinase reaction provided no evidence for new 5′-terminal sequences generated by restriction in vitro; the 5′ termini were either refractory to the polynucleotide kinase reaction or had no sequence specificity.     

Engineering BspQI nicking enzymes and application of N.BspQI in DNA labeling and production of single-strand DNA

BspQI is a thermostable Type IIS restriction endonuclease (REase) with the recognition sequence 5′GCTCTTC N1/N4 3′. Here we report the cloning and expression of the bspQIR gene for the BspQI restriction enzyme in Escherichia coli. Alanine scanning of the BspQI charged residues identified a number of DNA nicking variants. After sampling combinations of different amino acid substitutions, an Nt.BspQI triple mutant (E172A/E248A/E255K) was constructed with predominantly top-strand DNA nicking activity. Furthermore, a triple mutant of BspQI (Nb.BspQI, N235A/K331A/R428A) was engineered to create a bottom-strand nicking enzyme. In addition, we demonstrated the application of Nt.BspQI in optical mapping of single DNA molecules. Nt or Nb.BspQI-nicked dsDNA can be further digested by E. coli exonuclease III to create ssDNA for downstream applications. BspQI contains two potential catalytic sites: a top-strand catalytic site (Ct) with a D-H-N-K motif found in the HNH endonuclease family and a bottom-strand catalytic site (Cb) with three scattered Glu residues. BlastP analysis of proteins in GenBank indicated a putative restriction enzyme with significant amino acid sequence identity to BspQI from the sequenced bacterial genome Croceibacter atlanticus HTCC2559. This restriction gene was amplified by PCR and cloned into a T7 expression vector. Restriction mapping and run-off DNA sequencing of digested products from the partially purified enzyme indicated that it is an EarI isoschizomer with 6-bp recognition, which we named CatHI (CTCTTC N1/N4).     

Creating seamless junctions independent of restriction sites in PCR cloning

A method is described for the efficient cloning of any given DNA sequence into any desired location without the limitation of naturally occurring restriction sites. The technique employs the polymerase chain reaction (PCR) combined with the capacity of the type-IIS restriction endonuclease (ENase) Eam1104I to cut outside its recognition sequence. Primers that contain the Eam1104I recognition site (5′-CTCTTC) are used to amplify the DNA fragments being manipulated. Because the ENase is inhibited by site-specific methylation in the recognition sequence, all internal Eam1104I sites present in the DNA can be protected by performing the PCR amplification in the presence of 5-methyl-deoxycytosine (^m5dCTP). The primer-encoded Eam1104I sites are not affected by the modified nucleotides (nt) since the newly synthesized strand does not contain any cytosine residues in the recognition sequence. In addition, the ENase's ability to cleave several bases downstream from its recognition site allows the removal of superfluous, terminal sequences from the amplified DNA fragments, resulting in 5′ overhangs that are defined by the nt present within the cleavage site. Thus, the elimination of extraneous nt and the generation of unique, non-palindromic sticky ends permits the formation of seamless junctions in a directional fashion during the subsequent ligation event.     

Physical mapping of plasmid pDB101: A potential vector plasmid for molecular cloning in streptococci

A physical map of the streptococcal macrolides, lincomycin, and streptogramin B (MLS) resistance plasmid pDB101 was constructed using six different restriction endonucleases. Ten recognition sites were found for HindIII, seven for HindII, eight for HaeII, and one each for EcoRI, HpaII, and KpnI. The localization of the restriction cleavage sites was determined by double and triple digestions of the plasmid DNA or sequential digestions of partial cleavage products and isolated restriction fragments, and all sites were aligned with a single EcoRI reference site. Plasmid pDB101 meets all requirements essential for a potential molecular cloning vehicle in streptococci; i.e., single restriction sites, a MLS selection marker, and a multiple plasmid copy number. The vector plasmid described here makes it possible to clone selectively any fragment of DNA cleaved with EcoRI, HpaII, or KpnI, or since the sites are close to each other in map position, any combination of two of these restriction enzymes.     

Characterization of an Extremely Thermostable Restriction Enzyme, PspGI, from a Pyrococcus Strain and Cloning of the PspGI Restriction-Modification System in Escherichia coli

An extremely thermostable restriction endonuclease, PspGI, was purified from Pyrococcus sp. strain GI-H. PspGI is an isoschizomer of EcoRII and cleaves DNA before the first C in the sequence 5′ ^CCWGG 3′ (W is A or T). PspGI digestion can be carried out at 65 to 85°C. To express PspGI at high levels, the PspGI restriction-modification genes (pspGIR and pspGIM) were cloned in Escherichia coli. M.PspGI contains the conserved sequence motifs of α-aminomethyltransferases; therefore, it must be an N4-cytosine methylase. M.PspGI shows 53% similarity to (44% identity with) its isoschizomer, M.MvaI from Micrococcus variabilis. In a segment of 87 amino acid residues, PspGI shows significant sequence similarity to EcoRII and to regions of SsoII and StyD4I which have a closely related recognition sequence (5′ ^CCNGG 3′). PspGI was expressed in E. coli via a T7 expression system. Recombinant PspGI was purified to near homogeneity and had a half-life of 2 h at 95°C. PspGI remained active following 30 cycles of thermocycling; thus, it can be used in DNA-based diagnostic applications.     

Sse9I restriction-modification system: Organization of genes and structural comparison of proteins

The nucleotide sequence was established for the operon of the Sse9I type II restriction-modification system of Sporosarcina species 9D. The enzymes of the Sse9I system recognize the 5′-AATT-3′ tetranucleotide. The operon includes three genes, sse9IC-sse9IR-sse9IM, which are transcribed unidirectionally and code, respectively, for the controller protein (C.Sse9I), restriction endonuclease (R.Sse9I), and DNA methyltransferase (M.Sse9I). The region immediately upstream of sse9IC was found to contain a conserved nucleotide sequence (C box) providing a binding site for C. Sse9I. The amino acid sequences of C.Sse9I and R.Sse9I were compared with those of related proteins. In the case of R.Sse9I, the highest homology was observed with the R.MunI (5′-CAATTG-3′) and R.EcoRI (5′-GAATTC-3′) regions that harbor the amino acid residues involved in recognizing the AATT inner tetranucleotide. The sse9IR gene was cloned in an expression vector, and recombinant R.Sse 9I was isolated.     

Cloning and sequence analysis of the plasmid-borne genes encoding the Eco29kI restriction and modification enzymes

The Eco29kI restriction-modification system (RMS2) has been found to be localized on the plasmid pECO29 occurring naturally in the Escherichia coli strain 29k (Pertzev, A.V., Ruban, N.M., Zakharova, M.V., Beletskaya, I.V., Petrov, S.I., Kravetz, A.N., Solonin, A.S., 1992. Eco29kI, a novel plasmid encoded restriction endonuclease from Escherichia coli. Nucleic Acids Res. 20, 1991). The genes coding for this RMS2, a SacII isoschizomer recognizing the sequence CCGCGG have been cloned in Escherichia coli K802 and sequenced. The DNA sequence predicts the restriction endonuclease (ENase) of 214 amino acids (aa) (24 556 Da) and the DNA-methyltransferase (MTase) of 382 aa (43 007 Da) where the genes are separated by 2 bp and arranged in tandem with eco29kIR preceding eco29kIM. The recombinant plasmid with eco29kIR produces a protein of expected size. ṀEco29kI contains all the conserved aa sequence motifs characteristic of m⁵C-MTases. Remarkably, its variable region exhibits a significant similarity to the part of the specific target-recognition domain (TRD) from ṀBssHII—multispecific m⁵C-MTase (Schumann, J.J., Walter, J., Willert, J., Wild, C., Koch D., Trautner, T.A., 1996. ṀBssHII: a multispecific cytosine-C5-DNA-methyltransferase with unusual target recognizing properties. J. Mol. Biol. 257, 949–959), which recognizes five different sites on DNA (HaeII, MluI, Cfr10I, SacII and BssHII), and the comparison of the nt sequences of its variable regions allowed us to determine the putative TRD of ṀEco29kI.     

An electron microscopic method for studying and mapping the region of weak sequence homology between simian virus 40 and polyoma DNAs.

A procedure for investigating the possibility of small amounts of partial DNA sequence homology between two defined DNA molecules has been developed and used to test for sequence homology between simian virus 40 and polyoma DNAs. This procedure, which does not necessitate the use of separated viral DNA strands, involves the construction of hybrid DNA molecules containing a simian virus 40 DNA molecule covalently joined to a polyoma DNA molecule, using the sequential action of EcoRI restriction endonuclease and Escherichia coli DNA ligase. Denaturation of such hybrid DNA molecules then makes it possible to examine intramolecularly rather than intermolecularly renatured molecules. Visualization of these intramolecularly renatured “snapback” molecules with duplex regions of homology by electron microscopy reveals a 15% region of weak sequence homology. This region is denatured at about 35 °C below the melting temperature of simian virus 40 DNA and therefore corresponds to about 75% homology. This region was mapped on both the simian virus 40 and polyoma genomes by the use of Hemophilus parainfluenzae II restriction endonuclease cleavage of the simian virus 40 DNA prior to EcoRI cleavage and construction of the hybrid molecule. The 15% region of weak homology maps immediately to the left of the EcoRI restriction endonuclease cleavage site in the simian virus 40 genome and halfway around from the EcoRI restriction endonuclease cleavage site in the polyoma genome.     

C.EcoO109I,a regulatory protein for production of EcoO109I restriction endonuclease,specifically binds to and bends DNA upstream of its translational start site

The EcoO109I restriction-modification system, which recognizes 5′-(A/G)GGNCC(C/T)-3′, has been cloned, and contains convergently transcribed endonuclease and methylase. The role and action mechanism of the gene product, C.EcoO109I, of a small open reading frame located upstream of ecoO109IR were investigated in vivo and in vitro. The results of deletion analysis suggested that C.EcoO109I acts as a positive regulator of ecoO109IR expression but has little effect on ecoO109IM expression. Assaying of promoter activity showed that the expression of ecoO109IC was regulated by its own gene product, C.EcoO109I. C.EcoO109I was overproduced as a His-tag fusion protein in recombinant Escherichia coli HB101 and purified to homogeneity. C.EcoO109I exists as a homodimer, and recognizes and binds to the DNA sequence 5′-CTAAG(N)₅CTTAG-3′ upstream of the ecoO109IC translational start site. It was also shown that C.EcoO109I bent the target DNA by 54 ± 4°.