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.     

The specific non-symmetrical sequence recognized by restriction endonuclease MboII

The restriction endonuclease MboII, isolated from Moraxella bovis (ATCC 10900), cleaves bacteriophage φX174am3 replicative form I DNA into ten fragments. The physical map of these fragments has been aligned with the sequence of φX174 DNA. There is no sequence with 2-fold rotational symmetry common to the region of all ten cleavage sites. However, the non-symmetrical sequence 5′-G-A-A-G-A-3′ 3′-C-T-T-C-T-5′ occurs near to each cleavage site. Precise mapping of the cleavages in both DNA strands at several sites places the cuts eight nucleotides to the right of the upper sequence and seven nucleotides to the right of the lower sequence.     

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.     

An expeditious method for constructing T-vectors usingEam 1105 I cassettes

An expeditious method is described for constructing T-vectors containing complementary 3′-thymidine overhangs. A T-vector was developed by cloning a 90-bpEam 1105 I cassette containing 2Eam 1105 I restriction sites into a modified pUC119 vector. TheEam 1105 I cassette was generated by PCR with 2 specific primers containing different recognition sequences ofEam 1105 I. The recombinant vector was easily converted into a T-vector by digestion of the plasmid withEam 1105 I. The cloning efficiency of the PCR product was approximately 90%. The method described here is a simple way to construct a variety of T-vectors.     

Structural Requirements forFokI-DNA Interaction and Oligodeoxyribonucleotide-instructed Cleavage

TheFokI restriction endonuclease recognizes the double-stranded (ds) 5′-GGATG-3′ site and cuts at the 9th and 13th nucleotides downstream from the 5′-3′ and 3′-5′ strands, respectively. To elucidate the interaction betweenFokI and DNA, and the effect of Mg²⁺on this interaction, we usedFokI with various combinations of dsDNA, single-stranded (ss) DNA and oligodeoxyribonucleotides (oligos) containing a double-stranded hairpin carrying theFokI recognition site. Oligo- and dsDNA-FokI interactions showed that for fully effective recognition, two or more base-pairs were required outside the 5′-GGATG-3′ site. When usingFokI with ssDNA and oligos, precise cutting with no observable byproducts was observed at the 9th or 13th nucleotide. This was independent of whether the region between the recognition and cut sites was perfectly complementary or whether there were up to four mismatches in this region, or a single mismatch within the cut site. Moreover,FokI cleavage, when followed by step-wise filling-in ofFokI cohesive ends in the dsDNA, allowedFokI to recleave such sites when two or more nucleotides were added, releasing 2-mer, 3-mer, or 4-mer single-stranded chains. Electrophoretic mobility shift assays showed that the DNA helix was bent when complexed withFokI (without Mg²⁺). Such a complex, when formed in the absence of Mg²⁺, did not accept the subsequently added Mg²⁺for several minutes. This suggests a tight, diffusion-resistant contact between the enzyme and the cognate DNA sequence. In the presence of Mg²⁺, the half-life of the complexFokI and dsDNA was 12 minutes at 22°C. In the absence of Mg²⁺, such a complex, possessing a terminally located 5′-GGATG-3′ site, had a half-life of 1.5 to 2 minutes. However, if magnesium ions were present, this complex had a stability similar to that of a complex formed with dsDNA containing a centrally located 5′-GGATG-3′ site.     

Novel specific endonuclease activity recognizing a 10-bp sequence

We report here the generation of a novel restriction endonuclease (ENase) activity with the 10-bp recognition sequence,

This specificity could be achieved by first methylating a substrate DNA with M·MamI in vivo, followed by in vitro R·DpnI restriction.     

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.     

Transposable elements associated with constitutive expression of yeast alcohol dehydrogenase II

The yeast structural gene ADR2, coding for the glucose-repressible alcohol dehydrogenase (ADHII), has been isolated by complementation of function in transformed yeast. The chromosomal DNA from nine yeast strains with cis-dominant constitutive mutations (ADR3^c) has been investigated by restriction enzyme analysis, using the cloned ADR2 DNA as a hybridization probe. Seven mutants appear to have insertions of approximately 5.6 kb near the 5′ end of the ADR2-coding region. Four of these insertions have the same restriction pattern as the yeast transposable element Tyl. Two differ from Tyl by the presence of an additional Hind III site, and a seventh insertion differs from Tyl at a number of restriction sites. All are inserted in the same orientation with respect to the structural gene. A DNA fragment containing the ADR2 gene and adjacent sequences from a constitutive mutant has been cloned and shown by heteroduplex analysis to contain an insertion near the 5′ end of the structural gene. The cloned insertion sequence hybridizes to multiple genomic DNA fragments, indicating that it contains a moderately repetitive sequence. Thus it appears that insertion of a transposable element near the 5′ terminus of the structural gene can produce constitutive expression of a normally glucose-repressed enzyme. Such insertions seem to be the most common way of generating cis-dominant constitutive mutations of ADHII.     

Characterization of the Type III restriction endonuclease PstII from Providencia stuartii

A new Type III restriction endonuclease designated PstII has been purified from Providencia stuartii. PstII recognizes the hexanucleotide sequence 5′-CTGATG(N)_25-26/27-28-3′. Endonuclease activity requires a substrate with two copies of the recognition site in head-to-head repeat and is dependent on a low level of ATP hydrolysis (~40 ATP/site/min). Cleavage occurs at just one of the two sites and results in a staggered cut 25–26 nt downstream of the top strand sequence to generate a two base 5′-protruding end. Methylation of the site occurs on one strand only at the first adenine of 5′-CATCAG-3′. Therefore, PstII has characteristic Type III restriction enzyme activity as exemplified by EcoPI or EcoP15I. Moreover, sequence asymmetry of the PstII recognition site in the T7 genome acts as an historical imprint of Type III restriction activity in vivo. In contrast to other Type I and III enzymes, PstII has a more relaxed nucleotide specificity and can cut DNA with GTP and CTP (but not UTP). We also demonstrate that PstII and EcoP15I cannot interact and cleave a DNA substrate suggesting that Type III enzymes must make specific protein–protein contacts to activate endonuclease activity.     

Directional cloning of native PCR products with preformed sticky ends (Autosticky PCR)

A novel method for the directional cloning of native PCR products was developed. Abasic sites in DNA templates make DNA polymerases stall at the site during synthesis of the complementary strand. Since the 5′ ends of PCR product strands contain built-in amplification primers, abasic sites within the primers result in the formation of 5′ single-stranded overhangs at the ends of the PCR product, enabling its direct ligation to a suitably cleaved cloning vector without any further modification. This “autosticky PCR” (AS-PCR) overcomes the problems caused by end sensitivity of restriction enzymes, or internal restriction sites within the amplified sequences, and enables the generation of essentially any desired 5′ overhang.     

Classification of type-II restriction endonucleases and cloning of non-identical cohesive-end fragments without self-polymerization using nonpalindromic oligodeoxyribonucleotide adapters.

Enzymatic partial filling-in of recessed 3'-end sequences, left after digestion of DNA by the restriction endonucleases (ENases) Sau3A and SalI, with the Klenow fragment of E. coli DNA polymerase I allows the forced ligation of the resulting fragments; this technology is already used for subcloning and for genomic bank construction. To simplify and generalize its utilization, class-II ENases have been arranged into 16 different families according to the composition of the 5'-protruding sequences present after cleavage. Moreover, this system was extended to allow the joining of noncompatible ends by the use of nonpalindromic complementary oligodeoxyribonucleotides (NPCOs) containing two nucleotides protruding at each 5' end. The use of these synthetic adapters maintains all the advantages of the initial gap-filling cloning technique: only one insert can be cloned per vector molecule and no self-ligation or -polymerization can occur with any of the DNA molecules involved. Only 22 such oligodeoxyribonucleotides are needed to generate the 60 NPCO pairs necessary to ligate to each other any member of twelve ENase families when the regeneration of ENase recognition sites is not required.     

A specific endonuclease from Brevibacterium albidum

A new restriction-like endonuclease, BalI, has been partially purified from Brevibacterium albidum. This enzyme cleaves bacteriophage λ DNA at least 18 times and adenovirus-2 DNA at least 16 times, but does not cleave simian virus 40 DNA. All sites cleaved by BalI are also cut by the specific endonuclease HaeIII from Haemophilus aegyptius. The recognition sequence of BalI is 5′-T-G-G ↓ C-C-A-3′ 3′-A-C-C ↓ G-G-T-5′ and the cleavage site is indicated by the arrows.     

The DNA sequence on bacteriophage G4 recognized by the Escherichia coli B restriction enzyme.

Bacteriophage G4 possesses a single EcoB site located in the overlap between restriction fragments HinfI-12 and HaeIII-6. The sequence 5′-T-G-A … 8N … T-G-C-T occurs once in this segment and nowhere else in the DNA sequence of G4. Four independent G4 mutants that were not restricted by Escherichia coli B possessed the sequence 5′-T-G-A … 8N … T-G-C-C. The common sequence shared by the previously mapped EcoB sites on φXsB1, simian virus 40, f1, and fd DNAs is 5′-T-G-A … 8N … T-G-C-T … 9N … T. However, the sequence in the region of the G4 EcoB site contains an A instead of the final T conserved in these other examples. When the G4 EcoB site is aligned with the other EcoB sites, there are no conserved residues within 50 bases of the common sequence, 5′-T-G-A … 8N … T-G-C-T, except for those seven residues. The analysis of the EcoB site on G4 provides further evidence that only those seven bases are recognized by the E. coli B restriction enzyme.     

Restriction endonucleases and their applications

Restriction endonucleases are deoxyribonucleases which cleave double-stranded DNA into fragments. With only one exception, all restriction endonucleases recognize short, non-methylated DNA sequences. Restriction endonucleases can be divided into two groups based on the position of the cleavage site relative to the recognition sequence. Class I restriction endonucleases cleave double-stranded DNA at positions outside the recognition sequence and generate fragments of random size. The cleavage sites of Class II restriction endonucleases are located, in most cases, within the recognition sequence. Most of the Class II restriction endonucleases recognize 4, 5, or 6 base pair palindromes and generate fragments with either flush ends or staggered ends. DNA fragments with staggered ends contain 3, 4, or 5 nucleotide single-stranded tails called ‘sticky ends’. DNA fragments produced by Class II restriction endonuclease cleavage can be separated on gels according to their molecular weight. The fragments can be isolated from the gel and used for sequence analysis to elucidate genetic information stored in DNA. Further, an isolated fragment can be inserted into a small extrachromosomal DNA, e.g. plasmid, phage or viral DNA, and its replication and expression can be studied in clones of prokaryotic or eukaryotic cells. Restriction endonucleases and cloning technology are powerful modern tools for attacking genetic problems in medicine, agriculture and industrial microbiology.     

An efficient plasmid vector for expression cloning of large numbers of PCR fragments in <Emphasis Type="Italic">Escherichia coli</Emphasis>

The described plasmid pEamTA was designed for parallel polymerase chain reaction (PCR) cloning of open reading frames (ORFs) in Escherichia coli. It relies on the well-known TA-cloning principle, and the “T-vector” can be generated from a plasmid preparation by digestion with the restriction enzyme Eam1105I. The single 3′-T-overhangs of the vector fragment are positioned in a way that A-tailed PCR-products beginning with the start-ATG of an ORF end up in optimal position for expression from a strong tac-promoter when ligated in correct orientation. The orientation of the insert can be checked via a reconstituted NdeI site (catATG) present in correct clones. The protocol works regardless of internal restriction sites of the PCR fragment, a major advantage when cloning a number of fragments in parallel. It also does not require 5′-primer extensions and finally delivers an expression clone for the preparation of untagged protein in less than a week.     

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.     

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.     

Creation of a type IIS restriction endonuclease with a long recognition sequence

Type IIS restriction endonucleases cleave DNA outside their recognition sequences, and are therefore particularly useful in the assembly of DNA from smaller fragments. A limitation of type IIS restriction endonucleases in assembly of long DNA sequences is the relative abundance of their target sites. To facilitate ligation-based assembly of extremely long pieces of DNA, we have engineered a new type IIS restriction endonuclease that combines the specificity of the homing endonuclease I-SceI with the type IIS cleavage pattern of FokI. We linked a non-cleaving mutant of I-SceI, which conveys to the chimeric enzyme its specificity for an 18-bp DNA sequence, to the catalytic domain of FokI, which cuts DNA at a defined site outside the target site. Whereas previously described chimeric endonucleases do not produce type IIS-like precise DNA overhangs suitable for ligation, our chimeric endonuclease cleaves double-stranded DNA exactly 2 and 6nt from the target site to generate homogeneous, 5′, four-base overhangs, which can be ligated with 90% fidelity. We anticipate that these enzymes will be particularly useful in manipulation of DNA fragments larger than a thousand bases, which are very likely to contain target sites for all natural type IIS restriction endonucleases.