Site-selective and hydrolytic two-strand scission of double-stranded DNA using Ce(IV)/EDTA and pseudo-complementary PNA

By combining Ce(IV)/EDTA with two pseudo-complementary peptide nucleic acids (pcPNAs), both strands in double-stranded DNA were site-selectively hydrolyzed at the target site. Either plasmid DNA (4361 bp) or its linearized form was used as the substrate. When two pcPNAs invaded into the double-stranded DNA, only the designated portion in each of the two strands was free from Watson-Crick base pairing with the counterpart DNA or the pcPNA. Upon the treatment of this invasion complex with Ce(IV)/EDTA at 37 degrees C and pH 7.0, both of these single-stranded portions were selectively hydrolyzed at the designated site, resulting in the site-selective two-strand scission of the double-stranded DNA. Furthermore, the hydrolytic scission products were successfully connected with foreign double-stranded DNA by using ligase. The potential of these artificial systems for manipulation of huge DNA has been indicated.     

Site-selective and hydrolytic two-strand scission of double-stranded DNA using Ce(IV)/EDTA and pseudo-complementary PNA

By combining Ce(IV)/EDTA with two pseudo-complementary peptide nucleic acids (pcPNAs), both strands in double-stranded DNA were site-selectively hydrolyzed at the target site. Either plasmid DNA (4361 bp) or its linearized form was used as the substrate. When two pcPNAs invaded into the double-stranded DNA, only the designated portion in each of the two strands was free from Watson–Crick base pairing with the counterpart DNA or the pcPNA. Upon the treatment of this invasion complex with Ce(IV)/EDTA at 37°C and pH 7.0, both of these single-stranded portions were selectively hydrolyzed at the designated site, resulting in the site-selective two-strand scission of the double-stranded DNA. Furthermore, the hydrolytic scission products were successfully connected with foreign double-stranded DNA by using ligase. The potential of these artificial systems for manipulation of huge DNA has been indicated.     

Fabrication of DNA/RNA Hybrids Through Sequence-Specific Scission of Both Strands by pcPNA-S1 Nuclease Combination

By combining two strands of pseudo-complementary peptide nucleic acid (pcPNA) with S1 nuclease, a tool for site-selective and dual-strand scission of DNA/RNA hybrids has been developed. Both of the DNA and the RNA strands in the hybrids are hydrolyzed at desired sites to provide unique sticky ends. The scission fragments are directly ligated with other DNA/RNA hybrids by using T4 DNA ligase, resulting in the formation of desired recombinant DNA/RNA hybrids.     

DNA methylation diminishes bleomycin-mediated strand scission

Three DNA duplexes differing substantially in sequence were derived from pBR322 plasmid DNA and supercoiled SV40 DNA by digestion with appropriate restriction endonucleases. Following treatment with the restriction methylase HhaI (recognition sequence: GCGC) or HhaI and HpaII (CCGG), the unmethylated and methylated DNAs were compared as substrates for the antitumor agent bleomycin. Bleomycin-mediated strand scission was shown to diminish substantially at a number of sites in proximity to the methylated cytidine moieties, especially where multiple sites had been methylated within a DNA segment of limited size. Detailed analysis of the DNA substrates revealed that both strands of DNA within a methylated region became more refractory to cleavage by bleomycin and that the protective effect could extend as many as 14 base pairs in proximity to the 5-methylcytidine moieties. Among the methylated DNA segments that became more resistant to bleomycin cleavage was a HpaII site of SV40 DNA, methylation of which has previously been shown to diminish the synthesis of the major late viral capsid protein following microinjection into Xenopus laevis oocytes. Study of the cleavage reaction at varying salt levels suggested that diminished bleomycin strand scission may be due, at least in part, to local conformational changes of the DNA to Z form (or other non-B-form structures). The results are generally consistent with the hypothesis that one mechanism for the expression of selective therapeutic action by certain DNA damaging agents could involve the recognition of specific methylation patterns.     

Solid-phase synthesis of pseudo-complementary peptide nucleic acids

Pseudo-complementary peptide nucleic acid (pcPNA) is a DNA analog in which modified DNA bases 2,6-diaminopurine (D) and 2-thiouracil (U(s)) 'decorate' a poly[N-(2-aminoethyl)glycine] backbone, together with guanine (G) and cytosine (C). One of the most significant characteristics of pcPNA is its ability to effect double-duplex invasion of predetermined DNA sites inducing various changes in the biological and the physicochemical properties of the DNA. This protocol describes solid-phase synthesis of pcPNA. The monomers for G and C are commercially available, but the monomers for D and U(s) need to be synthesized (or can be ordered to custom synthesis companies). Otherwise, the procedure is the same as that employed for Boc-strategy synthesis of conventional PNA. This protocol, if the synthesis of D and U(s) monomers is not factored in, takes approximately 7 d to complete.     

Chemical modification of Ce(IV)/EDTA-based artificial restriction DNA cutter for versatile manipulation of double-stranded DNA

A monophosphate group was attached to the terminus of pseudo-complementary peptide nucleic acid (pcPNA), and two of thus modified pcPNAs were combined with Ce(IV)/EDTA for site-selective hydrolysis of double-stranded DNA. The site-selective DNA scission was notably accelerated by this chemical modification of pcPNAs. These second-generation artificial restriction DNA cutters (ARCUTs) differentiated the target sequence so strictly that no scission occurred even when only one DNA base-pair was altered to another. By using two of the activated ARCUTs simultaneously, DNA substrate was selectively cut at two predetermined sites, and the desired fragment was clipped and cloned. The DNA scission by ARCUT was also successful even when the target site was methylated by methyltransferase and protected from the corresponding restriction enzyme. Furthermore, potentiality of ARCUT for manipulation of huge DNA has been substantiated by site-selective scission of genomic DNA of Escherichia coli (composed of 4,600,000bp) at the target site. All these results indicate promising applications of ARCUTs for versatile purposes.     

Effect of neocarzinostatin-induced strand scission on the template activity of DNA for DNA polymerase I.

Neocarzinostatin (NCS), an antitumor protein antibiotic that causes strand scissions of DNA both in vitro and in vivo, is shown to lower the template activity of DNA for DNA polymerase Iin vitro. There is a correlation between the extent of strand scission and the degree of inhibition, maximal inhibition of the polymerase reaction being obtained under conditions promoting maximal strand scission. These effects can be related to the concentrations of NCS and of 2-mercaptoethanol and are maximized by pretreatment of the DNA with drug. Results from polymerase assays in which the amount of drug-treated DNA template was varied at a constant level of the enzyme suggest that the sites associated with NCS-induced breaks are nonfunctional in DNA synthesis but bind DNA polymerase I. The binding of the enzyme to the inactive sites is further confirmed using [203 Hg] polymerase. It is shown that the lowering of the template activity of DNA by NCS under conditions of strand scission is due to the generation of a large number of inactive sites that block, competitively, the binding of DNA polymerase to the active sites on the template. Furthermore, the inhibition of DNA synthesis, which depends on the extent of strand breakage and on the relative amounts of template and enzyme, can be reversed by increasing the levels of template or polymerase. The finding that DNA synthesis directed by poly [d(A-T)] is much more sensitive to NCS than that primed by poly [d(G-C)] suggests that the drug preferentially interacts at regions containing adenine and/or thymine residues.     

Selective strand scission by intercalating drugs at DNA bulges

A bulge is an extra, unpaired nucleotide on one strand of a DNA double helix. This paper describes bulge-specific strand scission by the DNA intercalating/cleaving drugs neocarzinostatin chromophore (NCS-C), bleomycin (BLM), and methidiumpropyl-EDTA (MPE). For this study we have constructed a series of 5'-32P end labeled oligonucleotide duplexes that are identical except for the location of a bulge. In each successive duplex of the series, a bulge has been shifted stepwise up (from 5' to 3') one strand of the duplex. Similarly, in each successive duplex of the series, sites of bulge-specific scission and protection were observed to shift in a stepwise manner. The results show that throughout the series of bulged duplexes NCS-C causes specific scission at a site near a bulge, BLM causes specific scission at a site near a bulge, and MPE-Fe(II) causes specific scission centered around the bulge. In some sequences, NCS-C and BLM each cause bulge-specific scission at second sites. Further, bulged DNA shows sites of protection from NCS-C and BLM scission. The results are consistent with a model of bulged DNA with (1) a high-stability intercalation site at the bulge, (2) in some sequences, a second high-stability intercalation site adjacent to the first site, and (3) two sites of relatively unstable intercalation that flank the two stable intercalation sites. On the basis of our results, we propose a new model of the BLM/DNA complex with the site of intercalation on the 3' side (not in the center) of the dinucleotide that determines BLM binding specificity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Enhanced bleomycin-mediated damage of DNA opposite charged nicks. A model for bleomycin-directed double strand scission of DNA

The anticancer drug, bleomycin, causes both single and double strand scission of duplex DNA in vitro, with double strand scission occurring in excess of that expected from the random accumulation of single strand nicks. The mechanism of the preferential double strand scission of DNA by bleomycin has been investigated through the synthesis of a series of double hairpin and linear oligonucleotides designed to contain a single nick-like structure at a defined site to serve as models of bleomycin-damaged duplex DNA. The 3' and/or 5' hydroxyls flanking the nick have been phosphorylated to model the increased negative charge at a bleomycin-generated nick. The ability of bleomycin to cleave the intact strand opposite the nick was then determined by autoradiography. The results demonstrate that phosphorylation at either the 3' or 5' hydroxyl, and especially when both sites are phosphorylated, strongly enhances selective cleavage by bleomycin of the opposite strand. These experiments indicate that bleomycin-mediated double strand scission is a form of self-potentiation in which the high affinity of bleomycin for the initially generated nicked sites leads to a greatly enhanced probability of scission of the strand opposite those sites.     

Identification of individual sex-factor DNA strands and their replication during conjugation in thermosensitive DNA mutants of Escherichia coli

Covalent circular sex-factor DNA has been isolated from donor and recipient cells during the conjugation of normal and temperature-sensitive DNA mutants of Escherichia coli. Single strands of sex-factor DNA were centrifuged in cesium chloride-poly(U,G) gradients to give two components that have been identified by annealing experiments as the separated complementary strands. When matings are performed with either DNA temperature-sensitive donor or recipient cells, the inhibition of vegetative DNA synthesis at the restrictive temperature does not interfere with transfer and circularization of the sex-factor DNA. If DNA is isolated from temperature-sensitive donor cells mated at the restrictive temperature, a specific stimulation of sex-factor DNA synthesis can be demonstrated. By separating the complementary strands of the sex-factor in a cesium chloride-poly (U,G) gradient, this DNA synthesis has been found to be asymmetric. The sex-factor DNA strand which is synthesized in the donor has the same polarity as the strand which is transferred to the recipient.     

DNA strand scission by the antitumor protein neocarzinostatin

The antibiotic protein, neocarzinostatin, induces the scission of DNA strands $\text{in vivo}$ and $\text{in vitro}$. HeLa cell DNA prelabelled with [¹⁴C] thymidine is cut into large pieces with a peak at 80–90S when cells are incubated with 0.5 to 5.0 μg/ml of highly purified neocarzinostatin. Incubation of the antibiotic (0.5 μg/ml) with [³H] SV40 DNA in the presence of 2-mercaptoethanol results in the conversion of superhelical DNA I to nicked circular duplex DNA II. At high levels of drug, smaller fragments of linear DNA are produced. Strand breaks are detected in both neutral and alkaline sucrose gradients, indicating that drug susceptibility is not due to alkali-labile bonds.     

DNA scission and repair during pachytene in Lilium

Sedimentation characteristics of native and denatured DNA were determined for sequential stages of meiosis in Lilium. Degradation of DNA during its preparation for analysis was minimized by extracting it from meiocytes that had been converted to protoplasts. Native DNA sedimented with a major peak in the 250s region of a glycerol gradient. The profiles for all meiotic stages were essentially the same. Denatured DNA showed a bimodal profile at pachytene (104s and 62s) and a more or less unimodal profile at other stages (104s). The difference was consistently observed regardless of the particular techniques used for preparation and measurement. The 62s component was not observed in achiasmatic cells or in cells which had been arrested by cycloheximide at prepachytene stages. Isotopic studies of pachytene DNA synthesis showed that DNA label accumulated in the 100s region and that it was present in both the old and new strands derived from premeiotic S-phase. The significance of the endogenous nicking of DNA is related to the timing and mechanics of crossing-over.     

DNA strand scission by activated bleomycin group antibiotics

The bleomycins (BLMs) are a structurally related group of antitumor antibiotics used clinically for the treatment of certain malignancies. The mechanism of action of the BLM is believed to involve DNA strand scission, a process that requires O2 and an appropriate metal ion; the therapeutically relevant metal is probably iron or copper. DNA strand scission by activated Fe X BLM involves oxygenation C-4' of deoxyribose and leads to two sets of products. One set results from scission of the C-3'--C-4' bond of deoxyribose, with concomitant cleavage of the DNA chain. The other set of products consists of free bases and an alkali-labile lesion, the latter of which leads to DNA chain cleavage on subsequent treatment with base. The structures of all of these degradation products have now been established by direct comparison with authentic synthetic samples. Also studied was the activation of BLM with (mono)oxygen surrogates such as iodosobenzene. The chemistry of the activated BLM so formed was remarkably similar to that of activated cytochrome P-450 and structurally related metalloporphyrins, which suggests a mechanistic analogy between the two. Remarkably, both Fe X BLM and Cu X BLM were also shown to be activated by NADPH cytochrome P-450 reductase in a transformation that was dependent on metal ion, O2 and NADPH.     

Strand scission of DNA in KB cells by macromomycin.

Macromomycin, an antitumor protein, produces strand scission of DNA in KB cells, which might appear to correlate with its concommitant inhibition of thymidine and uridine incorporation into nucleic acids. However, an acetyl derivative of macromomycin does not cause the same extent of strand breakage, yet it shows inhibitory and cytotoxic properties similar to the native protein. This is also seen in a derivative of macromomycin resulting from its reaction with the Bolton-Hunter reagent. Cesalin, another antitumor protein, does not possess DNA cleavage activity.     

An improved DNA sequencing strategy

A modification of Hong's systematic DNA sequencing strategy is described. The original procedure has been simplified and transfectant yield increased. After DNase I limited cleavage in the presence of Mn2+, the single-cut linear DNA does not have to be separated from supercoiled or open circular DNA on an agarose gel. After ligation, the DNA is digested with a second restriction endonuclease for which a unique cleavage site resides between the insert and the first restriction endonuclease cutting site. The original intact DNA is linearized whereas the deleted subclone is not. The background is decreased to an undetectable level. This DNA sequencing strategy was tested on a 1.4-kb DNA fragment containing the araC regulatory gene from Erwinia carotovora. A set of subclones sufficient to sequence the fragment on both strands was produced in 2 days and the yield was at least 60-fold higher than in the original protocol.     

A gold nanoparticle-based chronocoulometric DNA sensor for amplified detection of DNA

We report a protocol for the amplified detection of target DNA by using a chronocoulometric DNA sensor (CDS). Electrochemistry is known to be rapid, sensitive and cost-effective; it thus offers a promising approach for DNA detection. Our CDS protocol is based on a 'sandwich' detection strategy, involving a capture probe DNA immobilized on a gold electrode and a reporter probe DNA loaded on gold nanoparticles (AuNPs). Each probe flanks one of two fragments of the target sequence. A single DNA hybridization event brings AuNPs, along with hundreds of reporter probes, in the proximity of the electrode. We then employ chronocoulometry to interrogate [Ru(NH3)6]3+ electrostatically bound to the captured DNA strands. This AuNP-amplified DNA sensor can selectively detect as low as femtomolar (zeptomoles) concentrations of DNA targets and conveniently analyze a breast cancer-associated BRCA-1 mutant DNA. The time range for the entire protocol is approximately 3 d, whereas the DNA sensing takes less than 2 h to complete.     

A simple procedure for parallel sequence analysis of both strands of 5'-labeled DNA

Ligation of a 5'-labeled DNA restriction fragment results in a circular DNA molecule carrying the two 32Ps at the reformed restriction site. Double digestions of the circular DNA with the original enzyme and a second restriction enzyme cleavage near the labeled site allows direct chemical sequencing of one 5'-labeled DNA strand. Similar double digestions, using an isoschizomer that cleaves differently at the 32P-labeled site, allows direct sequencing of the now 3'-labeled complementary DNA strand. It is possible to directly sequence both strands of cloned DNA inserts by using the above protocol and a multiple cloning site vector that provides the necessary restriction sites. The simultaneous and parallel visualization of both DNA strands eliminates sequence ambiguities. In addition, the labeled circular molecules are particularly useful for single-hit DNA cleavage studies and DNA footprint analysis. As an example, we show here an analysis of the micrococcal nuclease-induced breaks on the two strands of the somatic 5S RNA gene of Xenopus borealis, which suggests that the enzyme may recognize and cleave small AT-containing palindromes along the DNA helix.     

Effect of Caffeine on DNA Synthesis in Mammalian Cells

Alkaline sucrose sedimentation studies of DNA from mouse lymphoma cells (L5178Y) treated with caffeine have demonstrated the following effects. Caffeine (at a concentration of 1.6 mM) does not introduce strand breaks into preformed DNA nor does it inhibit the rejoining of γ-ray-induced strand breaks. Although it does not affect the over-all rate of DNA synthesis, pulse labeling experiments show that the DNA strands synthesized in its presence are smaller than those made in its absence. This could be the result of (a) DNA being made in shorter replicating units or (b) small gaps in the daughter DNA strands within normal-sized replicating units. These two alternative models were indirectly distinguished as follows. After a pulse label with thymidine-³H in the presence of caffeine, cells were incubated without caffeine in bromodeoxyuridine (BrdUrd). During this incubation, growing strands are elongated and hypothetical gaps (model b) filled in with bromuracil (BrUra)-substituted DNA. The BrUra-containing DNA segments will now be of different lengths on the two models. With smaller replicating units (a) the “elongation segments” will be somewhat smaller than but the same order of magnitude as those in untreated cells, whereas with small gaps (b) the “filled-in gap segments” would be expected to be at least an order of magnitude smaller. The BrUra-containing regions of DNA can be selectively broken open by exposing the cells to light at 313 nm. The exposure required to break open the BUra-substituted regions is inversely related to, and hence gives a measure of, the size of these regions. In caffeine-treated cells these regions were found to be somewhat smaller than but of comparable size with those in untreated cells; this is consistent with the DNA being synthesized in smaller units and argues against the presence of small gaps in the daughter strands.     

Restriction enzyme-free mutagenesis via the light regulation of DNA polymerization

The effects of photocaged nucleosides on the DNA polymerization reaction was investigated, finding that most polymerases are unable to recognize and read through the presence of a single caging group on the DNA template. Based on this discovery, a new method of introducing mutations into plasmid DNA via a light-mediated mutagenesis protocol was developed. This methodology is advantageous over several common approaches in that it requires the use of only two polymerase chain reaction primers, and does not require any restriction sites or use of restriction enzymes. Additionally, this approach enables not only site-directed mutations, but also the insertion of DNA strands of any length into plasmids and the deletion of entire genes from plasmids.     

G4 DNA replication: I. Origin of synthesis of the viral and complementary DNA strands

The break in the complementary DNA strand of early G4 replicative form II DNA (RFII) and in the viral DNA strand of late RFII DNA was located using two single cleavage restriction enzymes (EcoRI and PstI) and by limited nick translation of the break using DNA polymerase I and ³²P-labelled deoxyribonucleotides followed by digestion with the restriction enzymes HaeIII and HindII. The break in the complementary DNA strand was unique and in HaeIII Z5 close to the EcoRI cleavage site whereas the break in the viral DNA strand was on the other side of the molecule in HaeIII Z2 approxiately 50% away from the EcoRI cleavage site. Distribution of a short ³H pulse in early G4 replicating intermediates that were synthesising both DNA strands at the same time showed that synthesis of the strands started on opposite sides of the molecule and proceeded in opposite convergent directions, suggesting that initiation of synthesis of the two strands was independent and not unified in a single growing fork.