A sequence-specific endonuclease (Xmn I) from Xanthomonas manihotis.

A type II restriction endonuclease Xmn I with a novel site specificity has been isolated from Xanthomonas manihotis. Xmn I does not cleave SV40 DNA, but cleaves phi X174 DNA into three fragments, which constitute 76.61%, 18.08% and 5.31% of the total length of 5386 base pairs, and cleaves pBR322 DNA into two fragments of 55.71% and 44.29% of the entire 4362 base pairs. The nucleotide sequences around the cleavage sites made by Xmn I are not exactly homologous, but they have a common sequence of 5' GAANNNNTTC 3' according to a simple computer program analysis on nucleotide sequences of phi X174 DNA, pBR322 DNA and SV40 DNA. The results suggest that the cleavage site of Xmn I is located within its recognition sequence of 5' GAANNNNTTC 3'.     

Sse8647I, a new type II restriction endonuclease from a Streptomyces species cutting at 5'-AG/GWCCT-3'.

We isolated and characterized a new type II restriction endonuclease which recognizes the palindromic heptanucleotide sequence 5'-AGGWCCT-3' and cleaves double-stranded DNA after the first G in the sequence from a microorganism belonging to Streptomyces species. This enzyme cleaves adenovirus 2 DNA at eight sites, but does not cleave lambda phage, pBR322, pUC18 and 19, M13mp18 and 19, SV40, ColE1 and phi X174 DNAs.     

FseI, a new type II restriction endonuclease that recognizes the octanucleotide sequence 5'' GGCCGGCC 3''.

A Type II restriction endonuclease, designated FseI, has been partially purified from a Frankia species (NRRL 18528). This enzyme cleaves Adenovirus 2 DNA at three sites, but does not cleave the DNAs from bacteriophages lambda, T7, and phi X174, the animal virus SV40, pUC18 and pBR322. FseI recognizes the octanucleotide sequence 5' GGCCGG decreases CC 3' and cleaves as indicated by the arrow. The frequency of occurrence of FseI sites within sequenced regions of the human genome is similar to that for NotI sites.     

Characterization of Chlorella virus PBCV-1 CviAII restriction and modification system.

A second DNA site-specific (restriction) endonuclease (R.CviAII) and its cognate adenine DNA methyltransferase (M.CviAII) were isolated from virus PBCV-1 infected Chlorella strain NC64A cells. R.CviAII, a heteroschizomer of the bacterial restriction endonuclease NlaIII, recognizes the sequence CATG, and does not cleave CmATG sequences. However, unlike NlaIII, which cleaves after the G and does not cleave either CmATG or mCATG sequences, CviAII cleaves between the C and A and is unaffected by mCATG methylation. The M.CviAII and R.CviAII genes were cloned and their DNA sequences were determined. These genes are tandemly arranged head-to-tail such that the TAA termination codon of the M.CviAII methyltransferase gene overlaps the ATG translational start site of R.CviAII endonuclease. R.CviAII is the first chlorella virus site-specific endonuclease gene to be cloned and sequenced.     

SwaI, a unique restriction endonuclease from Staphylococcus warneri, which recognizes 5'-ATTTAAAT-3'.

A novel class-II restriction endonuclease designated SwaI was purified from Staphylococcus warneri. This enzyme cleaves adenovirus 2 DNA, SV40 DNA and M13mp7 at one site each, but does not cleave lambda, PhiX174, pBR322 or pBR328 DNA. SwaI recognizes the octanucleotide sequence 5'-ATTTAAAT-3', cleaving in the center of the recognition sequence creating blunt ended DNA fragments. SwaI was used to digest chromosomal DNA from various microorganisms and human cells.     

BsoAI--a new site specific endonuclease from Bacillus coagulans

A new site-specific endonuclease was detected in toluene lysates of Bacillus coagulans AUCM B-732 and designated as BcoAI. The enzyme was purified by fractionation of the cell-free extract in the two-phase PEG/dextran system followed by chromatography on DEAE-sepharose and phosphocellulose and shown to be free of nonspecific nucleases and phosphatases. BcoAI has three cleavage sites on lambda DNA, but does not cleave SV40, pBR322 and pUC19 DNA. BcoAI recognizes the sequence 5' CAC decreases GTG 3' on double-stranded DNA and cleaves it as indicated by the arrow to yield blunt-ended DNA fragments. Thus, BcoAI is a true isoschizomer of PmaCI from Pseudomonas maltophila C.     

Human placental apurinic/apyrimidinic endonuclease. Mechanism of action

The mechanism of action of the homogeneous preparation of human placental apurinic/apyrimidinic (AP) endonuclease, described in the previous paper (Shaper, N. L., Grafstrom, R. H., and Grossman, L. (1982) J. Biol. Chem. 257, 13455-13458), has been investigated in detail. This enzyme cleaves apyrimidinic DNA both 5' and 3' to the site of damage in a ratio of 60:40, respectively. Even though this enzyme can cleave on both sides of an internal AP site, it does not release deoxyribose 5-phosphate from terminal AP sites. However, a compound, tentatively identified as alpha, beta unsaturated deoxyribose 5-phosphate, is nonenzymatically released only from 5'-terminal AP sites, presumably by a beta-elimination mechanism.     

Novel subtype of type IIs restriction enzymes. BfiI endonuclease exhibits similarities to the EDTA-resistant nuclease Nuc of Salmonella typhimurium

The type IIs restriction enzyme BfiI recognizes the non-palindromic nucleotide sequence 5'-ACTGGG-3' and cleaves complementary DNA strands 5/4 nucleotides downstream of the recognition sequence. The genes coding for the BfiI restriction-modification (R-M) system were cloned/sequenced and biochemical characterization of BfiI restriction enzyme was performed. The BfiI R-M system contained three proteins: two N4-methylcytosine methyltransferases and a restriction enzyme. Sequencing of bisulfite-treated methylated DNA indicated that each methyltransferase modifies cytosines on opposite strands of the recognition sequence. The N-terminal part of the BfiI restriction enzyme amino acid sequence revealed intriguing similarities to an EDTA-resistant nuclease of Salmonella typhimurium. Biochemical analyses demonstrated that BfiI, like the nuclease of S. typhimurium, cleaves DNA in the absence of Mg(2+) ions and hydrolyzes an artificial substrate bis(p-nitrophenyl) phosphate. However, unlike the nonspecific S. typhimurium nuclease, BfiI restriction enzyme cleaves DNA specifically. We propose that the DNA-binding specificity of BfiI stems from the C-terminal part of the protein. The catalytic N-terminal subdomain of BfiI radically differs from that of type II restriction enzymes and is presumably similar to the EDTA-resistant nonspecific nuclease of S. typhimurium; therefore, BfiI did not require metal ions for catalysis. We suggest that BfiI represents a novel subclass of type IIs restriction enzymes that differs from the archetypal FokI endonuclease by the fold of its cleavage domain, the domain location, and reaction mechanism.     

A restriction endonuclease from Staphylococcus aureus.

A specific endonuclease, Sau 3AI, has been partially purified from Staphylococcus aureus strain 3A by DEAE-cellulose chromatography. The enzyme cleaves adenovirus type 5 DNA many times, SV40 DNA eight times but does not cleave double-stranded phi X174 DNA. It recognizes the sequence (see article) and cleaves as indicated by the arrows. Evidence is presented that this enzyme plays a role in the biological restriction-modification system of Staphylococcus aureus strain 3A.     

BbvII--a new site-specific endonuclease from Bacillus brevis 80

BbvII, a new site-specific endonuclease, has been isolated from Bacillus brevis 80 by gel-filtration and chromatography on heparin-Sepharose. The endonuclease recognizes a non-symmetrical sequence 5'-GTCTTC-3' in double-stranded DNA and cleaves DNA 3'-CAGAAG-5' in both strands outside the recognition sequence.     

A Streptomyces glaucescens endodeoxyribonuclease which shows a strong preference for CC dinucleotide.

We have characterized a deoxyribonuclease from Streptomyces glaucescens that cleaves double-stranded DNA preferably between the dinucleotide 5'-CC-3'. The cleavage specificity was demonstrated by both analysis of the terminal nucleotides of the generated fragments and DNA sequencing of partially digested DNA. Digestion of lambda DNA with this enzyme resulted in the production of double-stranded fragments with 5' and/or 3'-protruding single-stranded tails. DNase I footprinting experiments indicated that the nuclease specifically binds to its cleavage sites on the DNA under non-catalytic conditions. The enzyme is not affected by cytosine methylation in hemimethylated DNA.     

Escherichia coli RuvC protein is an endonuclease that resolves the Holliday structure.

Genetic evidence suggests that the Escherichia coli ruvC gene is involved in DNA repair and in the late step of RecE and RecF pathway recombination. To study the biochemical properties of RuvC protein, we overproduced and highly purified the protein. By employing model substrates, we examined the possibility that RuvC protein is an endonuclease that resolves the Holliday structure, an intermediate in genetic recombination in which two double-stranded DNA molecules are linked by single-stranded crossover. RuvC protein cleaves cruciform junctions, which are formed by the extrusion of inverted repeat sequences from a supercoiled plasmid and which are structurally analogous to Holliday junctions, by introducing nicks into strands with the same polarity. The nicked ends are ligated by E.coli or T4 DNA ligases. Analysis of the cleavage sites suggests that DNA topology rather than a particular sequence determines the cleavage site. RuvC protein also cleaves Holliday junctions which are formed between gapped circular and linear duplex DNA by the function of RecA protein. However, it does not cleave a synthetic four-way junction that does not possess homology between arms. The active form of RuvC protein, as studied by gel filtration, is a dimer. This is mechanistically suited for an endonuclease involved in swapping DNA strands at the crossover junctions. From these properties of RuvC protein and the phenotypes of the ruvC mutants, we infer that RuvC protein is an endonuclease that resolves Holliday structures in vivo.     

Resolution of the RNA editing gRNA-directed endonuclease from two other endonucleases of Trypanosoma brucei mitochondria.

RNA editing in kinetoplastids, the specific insertion and deletion of U residues, requires endonuclease cleavage of the pre-mRNA at each cycle of insertion/deletion. We have resolved three endoribonuclease activities from Trypanosoma brucei mitochondrial extracts that cleave CYb pre-mRNA specifically. One of these, which sediments at approximately 20S and is not affected substantially by DTT, has all the features of the editing endonuclease. It cleaves CYb pre-edited or partially edited mRNA only when annealed to the anchor region of a cognate guide RNA (gRNA), and it cleaves accurately just 5' of the duplex region. Its specificity is for the 5' end of extended duplex RNA regions, and this prevents cleavage of the gRNA or other positions in the mRNA. This gRNA-directed nuclease is evidently the same activity that functions in A6 pre-mRNA editing. However, it is distinct and separable from a previously observed DTT-requiring endonuclease that sediments similarly under certain conditions, but does not cleave precisely at the first editing site in either the presence or absence of a gRNA. The editing nuclease is also distinct from a DTT-inhibited endonuclease that cleaves numerous free pre-mRNAs at a common structure in the region of the first editing site.     

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.     

Characterization of AloI, a restriction-modification system of a new type.

We report the properties of the new AloI restriction and modification enzyme from Acinetobacter lwoffi Ks 4-8 that recognizes the DNA target 5' GGA(N)6GTTC3' (complementary strand 5' GAAC(N)6TCC3'), and the nucleotide sequence of the gene encoding this enzyme. AloI is a bifunctional large polypeptide (deduced M(r) 143 kDa) revealing both DNA endonuclease and methyltransferase activities. Depending on reaction cofactors, AloI cleaves double-stranded DNA on both strands, seven bases on the 5' side, and 12-13 bases on the 3' side of its recognition sequence, and modifies adenine residues in both DNA strands in the target sequence yielding N6-methyladenine. For cleavage activity AloI maintains an absolute requirement for Mg(2+) and does not depend on or is stimulated by either ATP or S-adenosyl-L-methionine. Modification function requires the presence of S-adenosyl-L-methionine and is stimulated by metal ions (Ca(2+)). The C-terminal and central parts of the protein were found to be homologous to certain specificity (HsdS) and modification (HsdM) subunits of type I R-M systems, respectively. The N-terminal part of the protein possesses the putative endonucleolytic motif DXnEXK of restriction endonucleases. The deduced amino acid sequence of AloI shares significant homology with polypeptides encoding HaeIV and CjeI restriction-modification proteins at the N-terminal and central, but not at the C-terminal domains. The organization of AloI implies that its evolution involved fusion of an endonuclease and the two subunits, HsdM and HsdS, of type I restriction enzymes. According to the structure and function properties AloI may be regarded as one more representative of a newly emerging group of HaeIV-like restriction endonucleases. Discovery of these enzymes opens new opportunities for constructing restriction endonucleases with a new specificity.     

Analysis of class II (hydrolytic) and class I (beta-lyase) apurinic/apyrimidinic endonucleases with a synthetic DNA substrate.

We have developed simple and sensitive assays that distinguish the main classes of apurinic/apyrimidinic (AP) endonucleases: Class I enzymes that cleave on the 3' side of AP sites by beta-elimination, and Class II enzymes that cleave by hydrolysis on the 5' side. The distinction of the two types depends on the use of a synthetic DNA polymer that contains AP sites with 5'-[32P]phosphate residues. Using this approach, we now show directly that Escherichia coli endonuclease IV and human AP endonuclease are Class II enzymes, as inferred previously on the basis of indirect assays. The assay method does not exhibit significant interference by nonspecific nucleases or primary amines, which allows the ready determination of different AP endonuclease activities in crude cell extracts. In this way, we show that virtually all of the Class II AP endonuclease activity in E. coli can be accounted for by two enzymes: exonuclease III and endonuclease IV. In the yeast Saccharomyces cerevisiae, the Class II AP endonuclease activity is totally dependent on a single enzyme, the Apn1 protein, but there are probably multiple Class I enzymes. The versatility and ease of our approach should be useful for characterizing this important class of DNA repair enzymes in diverse systems.     

Mva1269I: a monomeric type IIS restriction endonuclease from Micrococcus varians with two EcoRI- and FokI-like catalytic domains

Type II restriction endonuclease Mva1269I recognizes an asymmetric DNA sequence 5'-GAATGCN / -3'/5'-NG / CATTC-3' and cuts top and bottom DNA strands at positions, indicated by the "/" symbol. Most restriction endonucleases require dimerization to cleave both strands of DNA. We found that Mva1269I is a monomer both in solution and upon binding of cognate DNA. Protein fold-recognition analysis revealed that Mva1269I comprises two "PD-(D/E)XK" domains. The N-terminal domain is related to the 5'-GAATTC-3'-specific restriction endonuclease EcoRI, whereas the C-terminal one resembles the nonspecific nuclease domain of restriction endonuclease FokI. Inactivation of the C-terminal catalytic site transformed Mva1269I into a very active bottom strand-nicking enzyme, whereas mutants in the N-terminal domain nicked the top strand, but only at elevated enzyme concentrations. We found that the cleavage of the bottom strand is a prerequisite for the cleavage of the top strand. We suggest that Mva1269I evolved the ability to recognize and to cleave its asymmetrical target by a fusion of an EcoRI-like domain, which incises the bottom strand within the target, and a FokI-like domain that completes the cleavage within the nonspecific region outside the target sequence. Our results have implications for the molecular evolution of restriction endonucleases, as well as for perspectives of engineering new restriction and nicking enzymes with asymmetric target sites.     

R.SspD5I is a neoschizomer of HphI producing blunt end DNA fragments

The strain Staphylococcus species D5 produces a restriction enzyme. It is the neoschizomer of HphI endonuclease, which cleaves DNA at a distance of eight nucleotides from the recognition sequences producing blunt end DNA fragments: 5'-GGTGA8N /-3' and 3'-CCACT8N /-5'.     

Isolation and characterization of endonuclease J: a sequence-specific endonuclease cleaving immunoglobulin genes.

An endonuclease activity which cleaves close to the recombination sites of the immunoglobulin JK segments was found in extracts of chicken bursa of Fabricius and characterized after partial purification. The enzyme preparation also cleaved a VK segment at its 3' end. A similar activity was found in mouse liver, mouse myelomas and Hela cells. The enzyme designated as endonuclease J introduces double-stranded cleavages preferentially at sequences containing G clusters of pBR322 as well as the JK segments. However, not all the G clusters were cleaved by endonuclease J, suggesting that the enzyme recognizes additional sequences. Deletion of the conserved nonamer (GGTTTTTGT) located immediately 5' to the JK4 segment drastically reduced the cleavage activity of its immediate downstream G cluster. Although biological function of endonuclease J is not clear at this stage, the possibilities of its involvement in the immunoglobulin gene recombination and general recombination were discussed.