Minor-groove-modified oligonucleotides: synthesis of decadeoxynucleotides containing hypoxanthine, N2-methylguanine and 3-deazaadenine, and their interactions with restriction endonucleases Bgl II, Sau, 3AI, and Mbo I (Nucleosides and Nucleotides Part 75).

Decadeoxynucleotides containing hypoxanthine, N2-methylguanine, 3-deazaadenine in the recognition sequences of restriction endonucleases Bgl II, Sau 3AI, and Mbo I were synthesized. These decanucleotides modified in the base moieties facing in to the minor groove were strongly resistant to hydrolysis by Bgl II and partially resistant to that of Sau 3AI and Mbo I. The decadeoxynucleotide containing 3-deazaadenine in place of adenine was bound to Bgl II strongly, whereas the nucleotides containing hypoxanthine and N2-methylguanine were bound less tightly.     

Recognition sequence of the dam methylase of Escherichia coli K12 and mode of cleavage of Dpn I endonuclease.

The recognition sequence for the dam methylase of Escherichia coli K12 has been determined directly by use of in vivo methylated ColE1 DNA or DNA methylated in vitro with purified enzyme. The methylase recognizes the symmetric tetranucleotide d(pG-A-T-C) and introduces two methyl groups per site in duplex DNA with the product of methylation being 6-methylaminopurine. This work has also demonstrated that Dpn I restriction endonuclease cleaves on the 3' side of the modified adenine within the methylated sequence to yield DNA fragments possessing fully base-paired termini. All sequences in ColE1 DNA methylated by the dam enzyme are subject to double strand cleavage by Dpn I endonuclease. Therefore, this restriction enzyme can be employed for mapping the location of sequences possessing the dam modification.     

Synthesis of decadeoxyribonucleotides containing 5-modified uracils and their interactions with restriction endonucleases Bgl II, Sau 3AI and Mbo I (nucleosides and nucleotides 82)

Decadeoxyribonucleotides containing uracil, 5-bromouracil, 5-cyanouracil and 5-ethyluracil in recognition sequences of restriction endonucleases Bgl II, Sau 3AI, Mbo I were synthesized. Decanucleotides containing 5-bromouracil in place of thymine had essentially the same susceptibility to all the restriction endonucleases. Uracil-containing decanucleotides were however very resistant to attack. Decanucleotides containing 5-cyanouracil in the recognition sequence were strongly resistant to hydrolysis by Sau 3AI, but were hydrolysed by Bgl II and Mbo I as well as the parent decanucleotide. Decanucleotides containing 5-ethyluracil were strongly resistant to hydrolysis by Sau 3AI, but were partially resistant to hydrolysis by Bgl II and Mbo I.     

Synthesis of decadeoxyribonucleotides containing N6-methyladenine, N4-methylcytosine, and 5-methylcytosine: recognition and cleavage by restriction endonucleases (nucleosides and nucleotides part 74).

The naturally-occurring modified bases, N6-methyladenine, N4-methylcytosine, and 5-methylcytosine were chemically introduced in place of the adenine or cytosine in the decadeoxyribonucleotides containing recognition sequences of Bgl II, Sau 3AI, Mbo I and Mfl I. The modified oligomers bind to the enzymes but the rates of cleavage by the enzymes are variable.     

Sse8387I, a useful eight base cutter for mammalian genome analysis (influence of methylation on the activity of Sse8387I).

To develop restriction enzymes that are useful for genome analysis, we previously performed screening and isolated Sse8387I from Streptomyces sp. strain 8387. Sse8387I is a restriction enzyme that recognizes 5'-CCTGCA/GG-3' and cleaves DNA at the site shown by the diagonal (Nucleic Acid Res., 18, 5637-5640). The present study evaluated the effects of methylation that is important when Sse8387I is used for genome analysis. Sse8387I lost cleavage activity after methylation of adenine or methylation of cytosine at any site in the recognition sequence. However, the recognition sequence of Sse8387I contains no CG sequence, which is the mammalian methylation sequence. In addition, we evaluated the effects of methylation of CG at sites other than the recognition sequence. The cleavage activity of Sse8387I was maintained even when CG sequences were present immediately before or after, or near the recognition sequence, and cytosine was methylated. These results suggest that CG methylation does not affect the cleavage activity of Sse8387I. Therefore, Sse8387I seems to be very useful for mammalian genome analysis.     

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].     

The use of phosphorothioate-modified DNA in restriction enzyme reactions to prepare nicked DNA

The RF IV form of M13 DNA was synthesized enzymatically in vitro, using the viral (+)strand as template, to contain phosphorothioate-modified internucleotidic linkages of the Rp configuration on the 5' side of every base of a particular type in the newly-synthesized (-)strand. Twenty nine restriction enzymes were then tested for their reactions with the appropriate modified DNA types having a phosphorothioate linkage placed exactly at the cleavage site(s) of these enzymes in the (-)strand. Eleven of the seventeen restriction enzymes tested that had recognition sequences of five bases or more could be used to convert the phosphorothioate DNA entirely into the nicked form, either by simply allowing the reaction to go to completion with excess enzyme (Ava I, Ava II, Ban II, Hind II, Nci I, Pst I or Pvu I) or by stopping the reaction at the appropriate time before the nicked DNA is linearized (Bam HI, Bgl I, Eco RI or Hind III). Only modification of the exact cleavage site in the (-)strand could block linearization by the first class of enzymes. The results presented imply that the restriction enzyme-directed nicking of phosphorothioate M13 DNA occurs exclusively in the (+)strand.     

Recognition sequences of restriction endonucleases and methylases--a review

The properties and sources of all known endonucleases and methylases acting site-specifically on DNA are listed. The enzymes are crossindexed (Table I), classified according to homologies within their recognition sequences (Table II), and characterized within Table II by the cleavage and methylation positions, the number of recognition sites on the 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 (Table III), the structure of the restriction fragment ends (Table IV), and the sensitivity to different kinds of DNA methylation (Table V). Table VI classifies the methylases according to the nature of the methylated base(s) within their recognition sequences. This table also comprises those restriction endonucleases, which are known to be inhibited by the modified nucleotides. Furthermore, this review includes a restriction map of bacteriophage lambda DNA based on sequence data. Table VII lists the exact nucleotide positions of the cleavage sites, the length of the generated fragments ordered according to size, and the effects of the Escherichia coli dam- and dcmI-coded methylases M X Eco dam and M X Eco dcmI on the particular recognition sites.     

O6-methylguanine in place of guanine causes asymmetric single-strand cleavage of DNA by some restriction enzymes

The interactions of restriction enzymes with their cognate DNA recognition sequences present a model for protein-DNA interactions. We have investigated the effect of O6-methylguanine on restriction enzyme cleavage of DNA; O6-methylguanine is a carcinogenic lesion and a structural analogue of the biological restriction inhibitor N6-methyladenine. O6-Methylguanine was synthesized into oligonucleotides at unique positions. The oligonucleotides were purified and analyzed by high-pressure liquid chromatography to assure that, within the limits of our detection, O6-methylguanine was the only modified base present. These oligonucleotides were annealed with their complement so that cytosine, and in one case thymine, opposed O6-methylguanine. DNA cleavage by restriction enzymes that recognize a unique DNA sequence, HpaII, HhaI, HinPI, NaeI, NarI, PvuII, and XhoI, was inhibited by a single O6-methylguanine in place of guanine (adenine for PvuII) within the appropriate recognition sequences. However, only the modified strand was nicked by HpaII, NaeI, and XhoI with O6-methylguanine at certain positions, indicating asymmetric strand cleavage. For all the restriction enzymes studied but AhaII, BanI, and NarI, lack of double- or single-strand cleavage correlated with inability of the O6-methylguanine-containing recognition sequence to measurably bind enzyme. None of the restriction enzymes studied were inhibited by O6-methylguanine outside their cognate recognition sequences.     

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.     

Cleavage of adenine-modified functionalized DNA by type II restriction endonucleases

A set of 6 base-modified 2′-deoxyadenosine derivatives was incorporated to diverse DNA sequences by primer extension using Vent (exo-) polymerase and the influence of the modification on cleavage by diverse restriction endonucleases was studied. While 8-substituted (Br or methyl) adenine derivatives were well tolerated by the restriction enzymes and the corresponding sequences were cleaved, the presence of 7-substituted 7-deazaadenine in the recognition sequence resulted in blocking of cleavage by some enzymes depending on the nature and size of the 7-substituent. All sequences with modifications outside of the recognition sequence were perfectly cleaved by all the restriction enzymes. The results are useful both for protection of some sequences from cleavage and for manipulation of functionalized DNA by restriction cleavage.     

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'.     

A stretch of "late" SV40 viral DNA about 400 bp long which includes the origin of replication is specifically exposed in SV40 minichromosomes.

Examination of DNA fragments produced from either formaldehyde-fixed or unfixed SV40 minichromosomes by multiple-cut restriction endonucleases has led to the following major results: Exhaustive digestion of unfixed minichromosomes with Hae III generated all ten major limit-digest DNA fragments as well as partial cleavage products. In striking contrast to this result, Hae III acted on formaldehyde-fixed minichromosomes to yield only one of the limit-digest fragments, F, which is located in the immediate vicinity of the origin of replication, spanning nucleotides 5169 and 250 on the DNA sequence map of Reddy et al. (1978). This 300 base pair (bp) fragment was released as naked DNA from formaldehyde-fixed, Hae III-digested minichromosomes following treatment either by pronase-SDS or by SDS alone. In the latter case, the remainder of the minichromosome retained its compact configuration as assayed by both sedimentational and electrophoretic methods. In minichromosomes, the F fragment is therefore not only accessible to Hae III at its ends, but is also neither formaldehyde cross-linked into any SDS-resistant nucleoprotein structure nor topologically "locked" within the compact minichromosomal particle. This same fragment was preferentially produced during the early stages of digestion of unfixed minichromosomes with Hae III, and its final yield in the exhaustive Hae III digest was significantly higher than that of other limit-digest fragments. Similar results were obtained upon digestion of either unfixed or formaldehyde-fixed minichromosomes with Alu I. In particular, of approximately twenty major limit-digest DNA fragments, only two fragments (F and P, encompassing nucleotides 5146 to 190, and 190 to 325, respectively) were produced by Alu I from the formaldehyde-fixed minichromosomes. All other restriction endonucleases tested (Mbo I, Mbo II, Hind III, Hin II+III and Hinf I), for which there are no closely spaced recognition sequences in the above mentioned regions of the SV40 genome, did not produce any significant amount of limit-digest DNA fragments from formaldehyde-fixed minichromosomes. These findings, taken together with our earlier data on the preferential exposure of the origin of replication in SV40 minichromosomes (Varshavsky, Sundin and Bohn, 1978), strongly suggest that a specific region of the "late" SV40 DNA approximately 400 bp long is uniquely exposed in the compact minichromosome. It is of interest that, in addition to the origin of replication, this region contains binding sites for T antigen (Tjian, 1977), specific tandem repeated sequences and apparently also the promoters for synthesis of late SV40 mRNAs (Fiers et al., 1978; Reddy et al., 1978).     

Substrate recognition by the Pvu II endonuclease: binding and cleavage of CAG5mCTG sites.

The Pvu II restriction endonuclease (R. Pvu II) cleaves CAG downward arrowCTG sequences as indicated, leaving blunt ends. Its cognate methyltransferase (M. Pvu II) generates N4-methylcytosine, yielding CAGN4mCTG, though the mechanism by which this prevents cleavage by R. Pvu II is unknown. The heterologous 5-methylcytosinemethylation CAG5mCTG has also been reported to prevent cleavage by R. Pvu II and this has been used in some cloning methods. Since this heterologousmethylation occurs at the native methylated base, it can provide insights into the detection of DNAmethylation by R. Pvu II. We found that the cloned gene for R. Pvu II could not stably transform cells protected only by M. Alu I (AG5mCT) and then determined that R. Pvu II cleaves CAG5mCTG in vitro, even when both strands are methylated. DNase I footprint analysis and competition experiments reveal that R. Pvu II binds to CAG5mCTG specifically, though with reduced affinity relative to the unmethylated sequence. These results provide biochemical support for the publishedstructures of R. Pvu II complexed with DNA containing CAGCTG and CAG5-iodoCTG and support a model for how methylation interferes with DNA cleavage by this enzyme.     

Molecular evidence for a fourth species within the Isotoma viridis group (Insecta, Collembola)

For identification of single species within the Isotoma viridis group, we present polymerase chain reaction–restriction fragment length polymorphism (PCR–RFLP) as a fast and efficient DNA-based molecular method. We used five PCR primers amplifying the cytochrome oxidase II (COII) region (760 bp) of the mitochondrial DNA. The sequences clearly separated four species ( I. viridis , I. riparia , I. anglicana and I. caerulea ) out of samples from Norway, Sweden, Germany and Switzerland. Examination of genetic variation and phylogenetic relationship did not support the separation of two colour pattern forms of I. viridis into distinct species. For RFLP, several restriction enzymes were tested for their ability to produce not only species-specific restriction fragment patterns but to discriminate more than one species per enzyme used with as few cleavage sites as possible. Such a design should render a clear fragment pattern when performing a double digest. These demands appear to be fulfilled best by the combination of the restriction enzymes Mfe I, Nci I and one of Aci I, Bst EII, Nde I, or Sfc I. From the enzymes tested in a previous study, Ase I proved to be reliable, whereas Mbo I can no longer be recommended.     

New restriction endonuclease CviRI cleaves DNA at TG/CA sequences.

A new type II restriction endonuclease, CviRI, was isolated from virus XZ-6E infected chlorella cells. CviRI is the first restriction endonuclease to recognize the sequence 5'-TGCA-3' and cleaves DNA between the G and C residues to produce blunt-end termini. Methylation of the adenine or cytosine in 5'-TGCA-3' sequences prevents CviRI cleavage. Due to its sequence specificity, CviRI may be especially useful for detecting mutant alleles of many heritable human genetic diseases.     

Modification methylase M.Sau3239I from Streptomyces aureofaciens 3239

By chromatography on phosphocellulose and Heparin-Sepharose the modification methylase M.Sau3239I was detected and partly purified from cells of Streptomyces aureofaciens 3239. Methylation by this enzyme protects DNA from cleavage by the restriction endonuclease R.Sau3239I. The enzyme catalyzes methylation of adenine to N-6-methyladenine in the 5'-CTCGmAG-3' recognition sequence.     

Taq52 I, a novel and thermostable type II restriction endonuclease from the genus Thermus, recognising the pentanucleotide sequence GC(A or T)GC and cleaving DNA between the first and second bases of the recognition sequence: G decreased or reduced C(A or T)GC.

127 isolates of the genus Thermus, from neutral and alkaline hot water springs on four continents, have been screened for the presence of restriction endonuclease activity. An isolate (YS52) from Yellowstone National Park, USA, showed a high level of restriction endonuclease activity when a cell free extract was incubated with lambda phage DNA at 65 degrees C. A Type II restriction endonuclease (Taq52 I) has been partially purified from this isolate and the recognition and cleavage site determined. Taq52 I has a novel interrupted palindromic tetranucleotide recognition sequence GCWGC, where W can be either adenine (A) or thymine (T). It hydrolyses the phosphodiester bond in both strands of the substrate between the first and second bases of the recognition sequence: 5'G decreased or reduced CWGC3', producing three-base 5'-OH overhangs (sticky ends). The enzyme has a pH optimum of 7.0, requires 8 mM MgCl2 for maximum activity and is thermally stable, retaining full enzyme activity following incubation at 79 degrees C for 10 min. Taq52 I not only represents a new addition to the Type II restriction endonucleases, but also increases the small list of thermostable restriction endonucleases.     

Submicromolar free calcium modulates dexamethasone binding to the glucocorticoid receptor

The relative distribution of bound cis- and trans-(NH₃)₂PtCl₂ at specific sites in SV40 DNA is evaluated by monitoring the extent to which five restriction endonucleases, each of which cleave at a single, unique site, are inhibited as a result of the DNA modification. The order of cleavage inhibition is Bgl 1 ? Bam HI > Hpa II, Kpn I > Eco RI. Both isomers produce a comparable effect for any particular endonuclease. Inhibition correlates with the % (G+C) content within and about the recognition sequences. That modified sequences immediately adjacent to the recognition sequence influence cleavage is further supported by differential cleavage observed with the multicut Hind III endonuclease. The binding of cis-(NH₃)₂PtCl₂ at the hyper-reactive Bgl 1 site may well be directly responsible for inhibiting SV40 replication.     

Two new restriction endonucleases DraII and DraIII from Deinococcus radiophilus.

In addition to recently characterized DraI (1), two new Type II restriction endonucleases, DraII and DraIII, with novel site-specificities were isolated and purified from Deinococcus radiophilus ATCC 27603. DraII and DraIII recognize the hepta- and nonanucleotide sequences (sequence in text) The cleavage sites within both strands are indicated by arrows. The recognition sequences were established by mapping of the cleavage sites on pBR322 (DraII) and fd109 RF DNA (DraIII). The sequence specifities were confirmed by computer-assisted restriction analyses of the generated fragment patterns of the sequenced DNA's of the bacteriophages lambda, phi X174 RF, M13mp8 RF and fd109 RF, the viruses Adeno2 and SV40, and the plasmids pBR322 and pBR328. The cleavage positions within the recognition sequences were determined by sequencing experiments.