Restriction and modification enzymes and their recognition sequences

In-vivo-modified gonococcal plasmid pJD1. A model system for analysis of restriction enzyme sensitivity to DNA modifications

The 4207-bp cryptic plasmid (pJD1) of Neisseria gonorrhoeae has 5-methylcytosine bases present at several positions in the DNA sequence. Fortuitously, these modified bases lie in the recognition sequences of many restriction enzymes. This feature makes the cryptic plasmid a model system for assaying the effect of these modified cytosines on the activities of the following restriction endonucleases and their isoschizomers: R X AvaII, R X BamHI, R X BglI, R X Fnu4HI, R X HaeII, R X HaeIII, R X HhaI, R X HpaII, R X KpnI, R X MspI, R X NaeI, R X NarI, R X NciI, R X NgoI, R X NgoII, and R X Sau96I. Of particular interest was the finding that methylation of one of the external cytosines of the palindrome 5'-CCGG-3' prevented its cleavage by R X MspI, but not by R X HpaII as had been suggested by Walder et al. [J. Biol. Chem. (1983) 258, 1235-1241].

Consecutive DNA terminator sequencing by using enzymatically generated primers

An improved strategy for the dideoxy chain termination sequencing of M13 recombinant DNA using enzymatically generated primers is presented. It involves synchronous extension of the universal primer with the Klenow fragment of DNA polymerase I at an average rate of 200 deoxynucleoside triphosphates per minute to the immediate downstream region of a preselected restriction enzyme site. Subsequent cleavage with the restriction enzyme generates the short primers with homogeneous 5' ends which can be used for further sequencing. The next restriction sites are selected in the newly sequenced regions of DNA by means of a microcomputer. By repeating this primer extension-cleavage-sequencing strategy sequences altogether about 6 kb long from several recombinant single-stranded M13 DNAs have been determined by using twenty restriction enzymes with different specificities.

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.

Characterization of the distribution of potential short restriction fragments in nucleic acid sequence databases. Implications for an alternative to chemical synthesis of oligonucleotides

We have searched the GenBank nucleic acid sequence database for potential short restriction fragments. All possible oligonucleotides up to length five are found at least once flanked by known restriction recognition patterns. Thus, searches in the database for a specific sequence corresponding to a desired oligonucleotide would often point to one or more sources of short, retrievable fragments containing that sequence. These results underscore the potential of nucleic acid sequence databases in planning experiments.

Restriction endonucleases from Herpetosiphon giganteus: an example of the evolution of DNA recognition specificity?

We describe the partial purification and characterisation of five Type II restriction endonucleases from two strains of Herpetosiphon giganteus. One of the activities, HgiJII, was the first enzyme found that cleaves DNA at the family of related sequences 5'-G-R-G-C-Y/C-3'. This enzyme may be related to the enzyme HgiAI from a different strain of the same species, and which cleaves at the sites 5'-G-W-G-C-W/C-3'. We have shown that DNAs from the strains producing HgiAI and HgiJII are resistant to both of these restriction endonucleases. The remaining four enzymes described here share recognition and cleavage specificities with other restriction endonucleases. The evolution of Type II restriction-modification systems and their role in vivo are discussed.

Isolation and characterization of the M.EaeI modification methylase

The modification enzyme (M.EaeI) corresponding to the restriction endonuclease EaeI was partially purified from Enterobacter aerogenes PW201. The M.EaeI enzyme methylates the innermost cytosine residue in each strand of the family of related sequences that constitute the EaeI recognition site to give: 5'-Y-G-G-5mC-C-R-3' where 5mC is 5-methylcytosine. M.EaeI protects these sites against cleavage by HaeIII, and protects overlapping 5'-C-C-G-G-3' sites against cleavage by both HpaII and MspI.

Cloning and characterization of the dcm locus of Escherichia coli K-12

The dcm locus of Escherichia coli K-12 has been shown to code for a methylase that methylates the second cytosine within the sequence 5'-CC(A/T)GG-3'. This sequence is also recognized by the EcoRII restriction-modification system coded by the E. coli plasmid N3. The methylase within the EcoRII system methylates the same cytosine as the dcm protein. We have isolated, from a library of E. coli K-12 DNA, two overlapping clones that carry the dcm locus. We show that the two clones carry overlapping sequences that are present in a dcm+ strain, but are absent in a delta dcm strain. We also show that the cloned gene codes for a methylase, that it complements mutations in the EcoRII methylase, and that it protects EcoRII recognition sites from cleavage by the EcoRII endonuclease. We found no phage restriction activity associated with the dcm clones.

Restriction endonuclease activity induced by PBCV-1 virus infection of a Chlorella-like green alga

An enzyme was isolated from a eucaryotic, Chlorella-like green alga infected with the virus PBCV-1 which exhibits type II restriction endonuclease activity. The enzyme recognized the sequence GATC and cleaved DNA 5' to the G. Methylation of deoxyadenosine in the GATC sequence inhibited enzyme activity. In vitro the enzyme cleaved host Chlorella nuclear DNA but not viral DNA because host DNA contains GATC and PBCV-1 DNA contains GmATC sequences. PBCV-1 DNA is probably methylated in vivo by the PBCV-1-induced methyltransferase described elsewhere (Y. Xia and J. L. Van Etten, Mol. Cell. Biol. 6:1440-1445). Restriction endonuclease activity was first detected 30 to 60 min after viral infection; the appearance of enzyme activity required de novo protein synthesis, and the enzyme is probably virus encoded. Appearance of enzyme activity coincided with the onset of host DNA degradation after PBCV-1 infection. We propose that the PBCV-1-induced restriction endonuclease participates in host DNA degradation and is part of a virus-induced restriction and modification system in PBCV-1-infected Chlorella cells.

Host and phage-coded functions required for coliphage N4 DNA replication

Escherichia coli strains containing mutations in various deoxyribonucleic acid synthesis cistrons have been tested for their ability to support bacteriophage N4 growth and, specifically, N4 DNA synthesis. N4 DNA synthesis is independent of the activity of the products of the E. coli dnaA, dnaB, dnaC, dnaE, dnaG, and rep genes. In contrast, N4 DNA replication requires the products of the dnaF, (ribonucleotide reductase) and lig (DNA ligase) genes of E. coli. N4 DNA replication, specifically processing of short DNA fragments requires the 5'-3' exonuclease activity of the polA gene product. However, its DNA polymerizing activity is not required. In addition, the sensitivity of N4 DNA synthesis to inhibitors or temperature-sensitive mutants of E. coli DNA gyrase suggests that this activity is required for N4 DNA synthesis. To date, we have found five N4 gene products required for N4 DNA replication: dbp (a single-stranded DNA binding protein), dnp (a DNA polymerase), dns (unknown function), vRNAp (the N4 virion-associated, DNA-dependent RNA polymerase) and exo (a 5'-3' exonuclease).

A new restriction endonuclease from Spirulina platensis

Three restriction endonucleases, Sp1I, Sp1II and Sp1III have been purified partially from Spirulina platensis subspecies siamese and named. Sp1I cleaves bacteriophage lambda DNA at one site, phi X 174 RF DNA at two sites, but does not cleave pBR322 DNA. This enzyme recognizes the sequence 5'CGTACG3' 3'GCATCG5' and cuts the site indicated by the arrows. Sp1II is an isoschizomer of Tth111I and Sp1III is an isoschizomer of HaeIII.

Two unique restriction endonucleases from Neisseria lactamica

Two new site-specific endonucleases, N1a III and N1a IV, have been isolated from Neisseria lactamica. N1a III recognizes the sequence, CATG, and cleaves 3' of the sequence to produce a four base 3' extension. N1a IV recognizes the sequence, GGNNCC, and cleaves between the two N's to produce blunt ended fragments.

Identification and characterisation of PmaCI an endonuclease of novel specificity from Pseudomonas maltophila

We report the use of MonoQ FPLC (Fast Protein Liquid Chromatography) for the rapid purification of a novel Type II restriction endonuclease PmaCI, from Pseudomonas maltophila, which recognises the sequence 5'-CAC decreases GTG-3'. The resulting enzyme is free of other nucleases to a level suitable for its characterisation by multiple-substrate digestion and DNA sequencing techniques. This method appears to be widely applicable and we have used it for the isolation of restriction endonucleases of comparable purity from a range of other organisms. Also described is a rapid method for screening a library of small inserted regions in recombinant M13 molecules for the presence and subsequent screening of restriction sites of interest.

Fast analysis of DNA and protein sequence on Apple IIe: restriction sites search, alignment of short sequence and dot matrix analysis

A fast restriction sites search algorithm using a quadruplet look-ahead feature has been written in 6502 assembly language code. The search time, tested on the sequence of pBR322, is 4.1 s/kilobase using a restriction site library including 112 specificities corresponding to a total site length of over 700 bases. The search for a short sequence (less than 36 bases) within a longer one (up to 9999 bases) with a given number of mismatches or gaps allowed has also been written in assembly language. Typical run time for the search of a 12 base sequence with 1, 2 or 3 gaps allowed are 6.2, 9.4 or 13.6 s/kilobase, respectively. The dot matrix analysis needs 7.5 minutes per square kilobase when using a stringency of 15 matched bases out of 25. A 7/21 matrix of two 500 amino acid proteins is obtained in 3 minutes. These three routines are included in DPSA, a general package of programs allowing manipulation and analysis of DNA and protein sequences.

A general DNA analysis program for the Hewlett-Packard Model 86/87 microcomputer

A program is described to perform general DNA sequence analysis on the Hewlett-Packard Model 86/87 microcomputer operating on 128 K of RAM. The following analytical procedures can be performed: 1. display of the sequence, in whole or part, or its complement; 2. search for specified sequences e.g. restriction sites, and in the case of the latter give fragment sizes; 3. perform a comprehensive search for all known restriction enzyme sites; 4. map sites graphically; 5. perform editing functions; 6. base frequency analysis; 7. search for repeated sequences; 8. search for open reading frames or translate into the amino acid sequence and analyse for basic and acidic amino acids, hydrophobicity, and codon usage. Two sequences, or parts thereof, can be merged in various orientations to mimic recombination strategies, or can be compared for homologies. The program is written in HP BASIC and is designed principally as a tool for the laboratory investigator manipulating a defined set of vectors and recombinant DNA constructs.

Specificity of restriction endonucleases and methylases--a review

The properties and sources of all known restriction endonucleases and methylases are listed. The enzymes are cross-indexed (Table I), classified according to their recognition sequence homologies (Table II), and characterized within Table II by the cleavage and methylation positions, the number of recognition sites on the double-stranded DNA of the bacteriophages lambda, phi X174 and M13mp7, the viruses Ad2 and SV40, the plasmids pBR322 and pBR328, and the microorganisms from which they originate. Other tabulated properties of the restriction endonucleases include relaxed specificities (integrated into Table II), the structure of the generated fragment ends (Table III), and the sensitivity to different kinds of DNA methylation (Table V). In Table IV the conversion of two- and four-base 5'-protruding ends into new recognition sequences is compiled which is obtained by the fill-in reaction with Klenow fragment of the Escherichia coli DNA polymerase I or additional nuclease S1 treatment followed by ligation of the modified fragment termini [P3]. Interconversion of restriction sites generates novel cloning sites without the need of linkers. This should improve the flexibility of genetic engineering experiments. Table VI classifies the restriction methylases according to the nature of the methylated base(s) within their recognition sequences. This table also comprises restriction endonucleases which are known to be inhibited or activated by the modified nucleotides. The detailed sequences of those overlapping restriction sites are also included which become resistant to cleavage after the sequential action of corresponding restriction methylases and endonucleases [N11, M21]. By this approach large DNA fragments can be generated which is helpful in the construction of genomic libraries. The data given in both Tables IV and VI allow the design of novel sequence specificities. These procedures complement the creation of universal cleavage specificities applying class IIS enzymes and bivalent DNA adapter molecules [P17, S82].

Production of restriction endonucleases using multicopy Hsd plasmids occurring naturally in pathogenic Escherichia coli and Shigella boydii

A convenient procedure has been devised for detection of restriction endonucleases in the Escherichia coli-Shigella group. With this procedure, two restriction endonucleases, designated Sbo 13 and Eco T22, were found and later were identified as isoschizomers of NruI and AvaIII, respectively. These endonucleases were shown to be produced from small multicopy plasmids. They were isolated from nonpathogenic E. coli into which the plasmids had been introduced by transformation, and purified from contaminating nuclease activity. The yield was high, 1,000 units/g of wet cells for Sbo 13 and 500 units/g for Eco T22. Sbo 13 and Eco T22 should be preferable to NruI and AvaIII because of the high yield and ease in handling the producer cells.

AccIII, a new restriction endonuclease from Acinetobacter calcoaceticus

A new site-specific restriction endonuclease, AccIII, was isolated from Acinetobacter calcoaceticus. AccIII recognizes T/CCGGA and cleaves at the position shown by the arrow. AccIII activity was inhibited by adenine methylation at the overlapping dam methylase recognition sequence.

Purification of Mbo II methylase (GAAGmA) from Moraxella bovis: site specific cleavage of DNA at nine and ten base pair sequences

The restriction modification methylase M. Mbo II has been purified using a sensitive oligonucleotide linker assay. The enzyme methylates the Mbo II recognition sequence* GAAGA at adenine to produce GAAGmA. M. Mbo II can be used in conjunction with the methylation dependent restriction endonuclease Dpn I (GmATC) to produce cleavage at the 10 base sequence GAAGATCTTC. When M. Mbo II is used in combination with M. Cla I (ATCGATCGAT), cleavage by Dpn I occurs at the four ten base sequences GAAGATCTTC, GAAGATCGAT, ATCGATCTTC and ATCGATCGAT, which is equivalent to a nine base recognition site. The use of combinations of adenine methylases and Dpn I to generate highly selective DNA cleavages at a variety of sequences up to fourteen base pairs is discussed.

A new site-specific endonuclease, ScaI, from Streptomyces caespitosus

A new site-specific endonuclease has been isolated from Streptomyces caespitosus and named ScaI. Based on analysis of sequences around the restriction sites in pBR322 and pBR325, the recognition sequence of ScaI endonuclease was deduced to be a new hexanucleotide 5'-AGTACT-3'. The cleavage site was determined by comparing the ScaI-cleaved product of a primer-extended M13mp18-SCA DNA, which contains an AGTACT sequence, with dideoxy chain terminator ladders of the same DNA. ScaI was found to cleave the recognition sequence between the internal T and A, leaving flush ends to the cleaved fragments.

Nucleotide sequence of the BsuRI restriction-modification system

The genes of the 5'-GGCC specific BsuRI restriction-modification system of Bacillus subtilis have been cloned and expressed in E. coli and their nucleotide sequence has been determined. The restriction and modification genes code for polypeptides with calculated molecular weights of 66,314 and 49,642, respectively. Both enzymes are coded by the same DNA strand. The restriction gene is upstream of the methylase gene and the coding regions are separated by 780 bp. Analysis of the RNA transcripts by S1-nuclease mapping indicates that the restriction and modification genes are transcribed from different promoters. Comparison of the amino acid sequences revealed no homology between the BsuRI restriction and modification enzymes. There are, however, regions of homology between the BsuRI methylase and two other GGCC specific modification enzymes, the BspRI and SPR methylases.

The nucleotide sequence of the tnpA gene completes the sequence of the Pseudomonas transposon Tn501

The nucleotide sequence of the gene (tnpA) which codes for the transposase of transposon Tn501 has been determined. It contains an open reading frame for a polypeptide of Mr = 111,500, which terminates within the inverted repeat sequence of the transposon. The reading frame would be transcribed in the same direction as the mercury-resistance genes and the tnpR gene. The amino acid sequence predicted from this reading frame shows 32% identity with that of the transposase of the related transposon Tn3. The C-terminal regions of these two polypeptides show slightly greater homology than the N-terminal regions when conservative amino acid substitutions are considered. With this sequence determination, the nucleotide sequence of Tn501 is fully defined. The main features of the sequence are briefly presented.

Universal restriction endonucleases: designing novel cleavage specificities by combining adapter oligodeoxynucleotide and enzyme moieties

Class IIS restriction endonucleases cleave double-stranded (ds) DNA at precise distances from their recognition sequences. A method is proposed which utilizes this separation between the recognition site and the cut site to allow a class IIS enzyme, e.g., FokI, to cleave practically any predetermined sequence by combining the enzyme with a properly designed oligodeoxynucleotide adapter. Such an adapter is constructed from the constant recognition site domain (a hairpin containing the ds sequence, e.g., GGATG CCTAC for FokI) and a variable, single-stranded (ss) domain complementary to the ss sequence to be cleaved (at 9 and 13 nucleotides on the paired strands from the recognition sequence in the example of FokI). The ss sequence designated to be cleaved could be provided by ss phage DNA (e.g., M13), gapped ds plasmids, or supercoiled ds plasmids that were alkali denatured and rapidly neutralized. Combination of all three components, namely the class IIS enzyme, the ss DNA target sequence, and the complementing adapter, would result in target DNA cleavage at the specific predetermined site. The target ss DNA could be converted to the precisely cleaved ds DNA by DNA polymerase, utilizing the adapter oligodeoxynucleotide as primer. This novel procedure represents the first example of changing enzyme specificity by synthetic design. A practically unlimited assortment of new restriction specificities could be produced. The method should have many specific and general applications when its numerous ramifications are exploited.