Cleavage of phosphorothioate-substituted DNA by restriction endonucleases

M13 RF DNA was synthesized in vitro in the presence of various single deoxynucleoside 5'-O-(1-thiotriphosphate) phosphorothioate analogues, and the three other appropriate deoxynucleoside triphosphates using a M13 (+)-single-stranded template, Escherichia coli DNA polymerase I and T4 DNA ligase. The resulting DNAs contained various restriction endonuclease recognition sequences which had been modified at their cleavage points in the (-)-strand by phosphorothioate substitution. The behavior of the restriction enzymes AvaI, BamHI, EcoRI, HindIII, and SalI towards these substituted DNAs was investigated. EcoRI, BamHI, and HindIII were found to cleave appropriate phosphorothioate-substituted DNA at a reduced rate compared to normal M13 RF DNA, and by a two-step process in which all of the DNA is converted to an isolable intermediate nicked molecule containing a specific discontinuity at the respective recognition site presumably in the (+)-strand. By contrast, SalI cleaved substituted DNA effectively without the intermediacy of a nicked form. AvaI, however, is only capable of cleaving the unsubstituted (+)-strand in appropriately modified DNA.     

Cleavage by restriction endonucleases MvaI and EcoRII of substrates modified in amino groups of heterocyclic bases

14-membered DNA-duplexes containing modified nucleoside residues, viz 4-N-methyldeoxycytidine (m4dC), 6-N-methyldeoxyadenosine (m6dA) or deoxyinosine (dI), in only one strand of the recognition site (CCA/TGG) of MvaI and EcoRII endonucleases were synthesized. It was shown that MvaI and EcoRII endonucleases interact with the exocyclic amino groups of the external dC residues and of the central dA residue of the recognition site exposed into the DNA major groove. These endonucleases which are isochizomers were found to possess different mechanisms of substrate cleavage. The ability of MvaI endonuclease to hydrolyze only unmodified strand of methylated duplexes allows one to make site-directed single-strand nicks in double-stranded DNA. Elimination of the 2-NH2-group located in the minor groove of DNA by substituting dI for dG had little, if any, effect on the hydrolytic activity of EcoRII and MvaI endonucleases.     

Cleavage of non-tRNA substrates by eukaryal tRNA splicing endonucleases

Eukaryal tRNA splicing endonucleases use the mature domains of pre-tRNAs as their primary recognition elements. However, they can also cleave in a mode that is independent of the mature domain, when substrates are able to form the bulge–helix–bulge structure (BHB), which is cleaved by archaeal tRNA endonucleases. We present evidence that the eukaryal enzymes cleave their substrates after forming a structure that resembles the BHB. Consequently, these enzymes can cleave substrates that lack the mature domain altogether. That raises the possibility that these enzymes could also cleave non-tRNA substrates that already have a BHB. As predicted, they can do so, both in vitro and in vivo.     

Cleavage and protection of locked nucleic acid-modified DNA by restriction endonucleases

Locked nucleic acid (LNA) is one of the most prominent nucleic acid analogues reported so far. We herein for the first time report cleavage by restriction endonuclease of LNA-modified DNA oligonucleotides. The experiments revealed that RsaI is an efficient enzyme capable of recognizing and cleaving LNA-modified DNA oligonucleotides. Furthermore, introduction of LNA nucleotides protects against cleavage by the restriction endonucleases PvuII, PstI, SacI, KpnI and EcoRI.     

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.     

Cleavage of synthetic RNA-DNA hybrids with restriction endonucleases BamH1 and Sau3A

Synthetic oligodeoxyribonucleotides, containing one or two ribonucleotides in the recognition sequence, and RNA--DNA hybrids were tested for their activity in cleavage with BamH1 and Sau3A endonucleases. The replacement of dG with G in the first position of BamH1-site (GGATCC) of one of the chains does not affect the rate of the BamH1 hydrolysis. The similar heteroduplex, containing G residue in the second position, displays a decreased rate of the BamH1 hydrolysis of the modified strand and, to a lesser extent, of the unmodified complementary strand. Oligodeoxyribonucleotides in complex with oligoribonucleotides can be cleaved with the excess of BamH1 and Sau3A, oligoribonucleotides remaining intact.     

Cleavage of synthetic substrates containing non-nucleotide inserts by restriction endonucleases. Change in the cleavage specificity of endonuclease SsoII.

A study was made of the interaction between restriction endonucleases recognizing CCNGG (SsoII and ScrFI) or CCA/TGG (MvaI and EcoRII) DNA sequences and a set of synthetic substrates containing 1,3-propanediol, 1,2-dideoxy-D-ribofuranose or 9-[1'-hydroxy-2'-(hydroxymethyl)ethoxy] methylguanine (gIG) residues replacing either one of the central nucleosides or dG residues in the recognition site. The non-nucleotide inserts (except for gIG) introduced into the recognition site both increase the efficiency of SsoII and change its specificity. A cleavage at the noncanonical position takes place, in some cases in addition to the correct ones. Noncanonical hydrolysis by SsoII occurs at the phosphodiester bond adjacent to the point of modification towards the 5'-end. With the guanine base returned (the substrate with gIG), the correct cleavage position is restored. ScrFI specifically cleaves all the modified substrates. DNA duplexes with non-nucleotide inserts (except for the gIG-containing duplex) are resistant to hydrolysis by MvaI and EcoRII. Prompted by the data obtained we discuss the peculiarities of recognition by restriction endonucleases of 5-membered DNA sequences which have completely or partially degenerated central base pairs. It is suggested that SsoII forms a complex with DNA in an 'open' form.     

Cleavage of Epstein-Barr virus DNA by restriction endonucleases EcoRI, HindIII and BamI.

The cleavage of the DNAs of the B95-8 and P3HR-1 virus strains of Epstein-Barr virus by the restriction endonucleases EcoRI, HindIII and BamI was investigated using a new technique for quantitative evaluation of the fluorescence of ethidium stained DNA fragments separated on agarose gels. The results obtained with B95-8 DNA showed that in addition to the limited repetitions of nucleotide sequences observed in the EcoRI and HindIII cleavage patterns, the molecule contained a BamI fragment with a molecular mass of 2.0 megadaltons which was present in a total of about 11 copies and localized to a limited part of the DNA molecule. The same sequences were also present in the P3HR-1 DNA albeit in a lower molar ratio. P3HR-1 DNA yielded restriction enzyme cleavage patterns suggesting DNA sequence heterogeneity of P3HR-1 virus. No fragment was present in more than about 4 copies per molecule of P3HR-1 DNA. Comparison of the restriction enzyme cleavage patterns of P3HR-1 and B95-8 DNA revealed a high degree of structural homology emphasized by nucleic acid hybridization experiments with EBV complementary RNA synthesized in vitro.     

Cleavage of mispaired heteroduplex DNA substrates by numerous restriction enzymes

The utility of restriction endonucleases as a tool in molecular biology is in large part due to the high degree of specificity with which they cleave well-characterized DNA recognition sequences. The specificity of restriction endonucleases is not absolute, yet many commonly used assays of biological phenomena and contemporary molecular biology techniques rely on the premise that restriction enzymes will cleave only perfect cognate recognition sites. In vitro, mispaired heteroduplex DNAs are commonly formed, especially subsequent to polymerase chain reaction amplification. We investigated a panel of restriction endonucleases to determine their ability to cleave mispaired heteroduplex DNA substrates. Two straightforward, non-radioactive assays are used to evaluate mispaired heteroduplex DNA cleavage: a PCR amplification method and an oligonucleotide-based assay. These assays demonstrated that most restriction endonucleases are capable of site-specific double-strand cleavage with heteroduplex mispaired DNA substrates, however, certain mispaired substrates do effectively abrogate cleavage to undetectable levels. These data are consistent with mispaired substrate cleavage previously reported for Eco RI and, importantly, extend our knowledge of mispaired heteroduplex substrate cleavage to 13 additional enzymes.     

Cleavage of viral DNA by restriction endonucleases stimulates the type II CRISPR-Cas immune response

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Cleavage map of BK virus DNA with restriction endonucleases MboI and HaeIII.

Specific cleavage of BK virus (MM) DNA with restriction endonuclease MboI gives rise to 10 fragments. Two techniques were used to determine the location of these fragments on the viral genome with respect to the three known sites for HindIII cleavage. In the first method, reciprocal digestion, individual MboI fragments were digested with HindIII and individual HindIII fragments were digested with MboI. In the second method, single-end 32P-labeled HindIII subfragments were partially digested with MboI, and then the sizes of the radioactive partial products were used to deduce the nearest neighboring fragment. Information from these two methods is more than adequate to map all the MboI enzyme sites. Cleavage of BK virus (MM) DNA with restriction enzyme HaeIII produces 21 fragments. With the aid of the same two methods, these fragments have also been ordered with respect to the known map locations of the HindIII and MboI sites.     

Cleavage of adeno-associated virus DNA with Sali,Psti and Haeii restriction endonucleases.

Duplex AAV-2 DNA was digested with SalI, PstI or HaeII restriction endonucleases and the cleavage sites were mapped. SalI cleaves AAV DNA at 0.310 map units, PstI at 0.106, 0.422 and 0.914 and the five HaeII sites were mapped at 0.110. 0.156, 0.181, 0.536 and 0.600 map units. These cleavage products will be useful for the isolation of specific regions from the AAV DNA, located outside of the stably transcribed region of the genome, and will also help to map more complex restriction enzyme cleavages.     

Type I restriction endonucleases are true catalytic enzymes

Type I restriction endonucleases are intriguing, multifunctional complexes that restrict DNA randomly, at sites distant from the target sequence. Restriction at distant sites is facilitated by ATP hydrolysis-dependent, translocation of double-stranded DNA towards the stationary enzyme bound at the recognition sequence. Following restriction, the enzymes are thought to remain associated with the DNA at the target site, hydrolyzing copious amounts of ATP. As a result, for the past 35 years type I restriction endonucleases could only be loosely classified as enzymes since they functioned stoichiometrically relative to DNA. To further understand enzyme mechanism, a detailed analysis of DNA cleavage by the EcoR124I holoenzyme was done. We demonstrate for the first time that type I restriction endonucleases are not stoichiometric but are instead catalytic with respect to DNA. Further, the mechanism involves formation of a dimer of holoenzymes, with each monomer bound to a target sequence and, following cleavage, each dissociates in an intact form to bind and restrict subsequent DNA molecules. Therefore, type I restriction endonucleases, like their type II counterparts, are true enzymes. The conclusion that type I restriction enzymes are catalytic relative to DNA has important implications for the in vivo function of these previously enigmatic enzymes.     

Chromosomal aberrations induced by restriction endonucleases

Restriction endonucleases (REs) are able to induce chromosomal aberrations in Chinese hamster ovary (CHO) cells. The G1 phase of the cell cycle seems to be especially sensitive for the induction of chromosomal aberrations by REs. The different capacities of REs to induce chromosomal aberrations are probably correlated with the number of recognition sites in the genome.     

A general assay for restriction endonucleases and other DNA-modifying enzymes with plasmid substrates

A procedure for measuring the activities of enzymes that alter the covalent structure of DNA is described. The assay utilizes covalently closed circles of DNA as the substrate and yields quantitative data on the fraction of this DNA converted to both open-circle and linear forms.     

Inhibition of restriction endonucleases by commercial polysaccharides

Commercial polysaccharide preparations were investigated for their restriction enzyme-inhibitory activities. Dextran sulfate (S content 18.5%) and laminaran from Eisenia arborea (0.88%) had marked inhibitory activity and haparin (13.1%) and ξ-, κ-, and λ-carrageenans (3.0, 3.8, and 4.3%) showed moderate inhibition. The effects of sulfation level and the structure of the carbohydrate moiety on the inhibitory activity were discussed.     

Induction of sister-chromatid exchanges by restriction endonucleases

Restriction endonucleases Cfo 1, Pvu II, Sma I, Hpa II, Taq I and Hae III were tested for their ability to induce SCEs in CHO cells. The results indicate that the DNA double-strand breaks induced during S-phase by these enzymes lead to an increase in the frequencies of SCEs.