Base mutation analysis by a ferrocenyl naphthalene diimide derivative

An electrochemical DNA sensing technique was developed by using ferrocenyl naphthalene diimide coupled with a probe DNA-immobilized electrode. This technique enabled detection of target DNA quickly and with high sensitivity. Applicability of this technique for single nucleotide polymorphisms (SNPs) analysis was demonstrated by successful analysis of a DNA mismatch on the cancer repression gene p53 with high precision.     

Ferroceneacetyl naphthalene diimide as a new electrochemical ligand for DNA sensing.

New electrochemically active DNA ligand 1 was synthesized by the connection of ferroceneacetic acid at the terminal amino moieties of two imide substituents of naphthalene diimide. Electrochemical experiments in aqueous solution containing DMSO showed that the selectivity for double stranded DNA of 1 has increased from that of ligand 2 previously reported. The peak current of 1 shifted toward the negative side from that of 2, thereby shortening the time required for gene detection.     

Conjugates of PNA with naphthalene diimide derivatives having a broad range of DNA affinities

Peptide nucleic acids (PNAs) are neutral DNA analogues, which bind single-stranded DNA (ssDNA) strongly and with high sequence specificity. However, binding efficiency is dependent on the purine content of the PNA strand. This property make more difficult application of PNA as hybridization probes in, e.g., PNA chips, since at a set temperature the hybridization of a fraction of the DNA targets to the PNA probes does not obey Watson-Crick binding rules. The polypurine PNAs, for example, bind the mismatch containing DNA targets stronger, than the pyrimidine rich PNAs their fully complementary targets. Herein we show that PNA-DNA binding efficiency can be finely tuned by the conjugation of derivatives of naphthalene diimide (NADI) to the N-terminus of PNA using polyamide linkers of different lengths. This approach can potentially be used for the design of PNA probes, which bind their DNA targets with similar affinity independently of the PNA sequence.     

Dependence of DNA-protein cross-linking via guanine oxidation upon local DNA sequence as studied by restriction endonuclease inhibition

Oxidative damage plays a causative role in many diseases, and DNA-protein cross-linking is one important consequence of such damage. It is known that GG and GGG sites are particularly prone to one-electron oxidation, and here we examined how the local DNA sequence influences the formation of DNA-protein cross-links induced by guanine oxidation. Oxidative DNA-protein cross-linking was induced between DNA and histone protein via the flash quench technique, a photochemical method that selectively oxidizes the guanine base in double-stranded DNA. An assay based on restriction enzyme cleavage was developed to detect the cross-linking in plasmid DNA. Following oxidation of pBR322 DNA by flash quench, several restriction enzymes (PpuMI, BamHI, EcoRI) were then used to probe the plasmid surface for the expected damage at guanine sites. These three endonucleases were strongly inhibited by DNA-protein cross-linking, whereas the AT-recognizing enzyme AseI was unaffected in its cleavage. These experiments also reveal the susceptibility of different guanine sites toward oxidative cross-linking. The percent inhibition observed for the endonucleases, and their pBR322 cleavage sites, decreased in the order: PpuMI (5'-GGGTCCT-3' and 5'-AGGACCC-3') > BamHI (5'-GGATCC-3') > EcoRI (5'-GAATTC-3'), a trend consistent with the observed and predicted tendencies for guanine to undergo one-electron oxidation: 5'-GGG-3' > 5'-GG-3' > 5'-GA-3'. Thus, it appears that in mixed DNA sequences the guanine sites most vulnerable to oxidative cross-linking are those that are easiest to oxidize. These results further indicate that equilibration of the electron hole in the plasmid DNA occurs on a time scale faster than that of cross-linking.     

Copper-activated DNA photocleavage by a pyridine-linked bis-acridine intercalator

We report the synthesis of new photonuclease 4 consisting of two acridine rings joined by a pyridine-based copper binding linker. We have shown that photocleavage of plasmid DNA is markedly enhanced when this ligand is irradiated in the presence of copper(II) (419 nm, 22 degrees C, pH 7.0). Viscometric data indicate that 4 binds to DNA by monofunctional intercalation, and equilibrium dialysis provides an estimated binding constant of 1.13 x 105 M-1 for its association with calf thymus DNA. In competition dialysis experiments, 4 exhibits preferential binding to GC-rich DNA sequences. When Cu(II) is added at a ligand to metal ratio of 1:1, electrospray ionization mass spectrometry demonstrates that compound 4 undergoes complex formation, while thermal melting studies show a 10 degrees C increase in the Tm of calf thymus DNA. Groove binding and intercalation are suggested by viscometric data. Finally, colorimetric and scavenger experiments indicate that the generation of Cu(I), H2O2, and superoxide contributes to the production of DNA frank strand breaks by the Cu(II) complex of 4. Whereas the strand breaks are distributed in a relatively uniform fashion over the four DNA bases, subsequent piperidine treatment of the photolysis reactions shows that alkaline labile lesions occur predominantly at guanine.     

Long-range communications between DNA sites by the dimeric restriction endonuclease SgrAI

The SgrAI endonuclease displays its maximal activity on DNA with two copies of its recognition sequence, cleaving both sites concertedly. While most restriction enzymes that act concurrently at two sites are tetramers, SgrAI is a dimer in solution. Its reaction at two cognate sites involves the association of two DNA-bound dimers. SgrAI can also bridge cognate and secondary sites, the latter being certain sequences that differ from the cognate by one base-pair. The mechanisms for cognate-cognate and cognate-secondary communications were examined for sites in the following topological relationships: in cis, on plasmids with two sites in a single DNA molecule; on catenanes containing two interlinked rings of DNA with one site in each ring; and in trans, on oligoduplexes carrying either a single site or the DNA termini generated by SgrAI. Both cognate-cognate and cognate-secondary interactions occur through 3-D space and not by 1-D tracking along the DNA. Both sorts of communication arise more readily when the sites are tethered to each other, either in cis on the same molecule of DNA or by the interlinking of catenane rings, than when released from the tether. However, the dimer bound to an oligoduplex carrying either a cognate or a secondary site could be activated to cleave that duplex by interacting with a second dimer bound to the recognition site, provided both duplexes are at least 30 base-pairs long: the second dimer could alternatively be bound to the two duplexes that correspond to the products of DNA cleavage by SgrAI.     

Discrimination of phosphorylated double stranded DNA by naphthalene diimide having zinc(II) dipicolylamine complexes

Discrimination of phosphomonoesters and phosphodiesters of DNA was attempted with naphthalene diimide carrying two zinc-dipicolylamine (Dpa) units (1). The binding constant of 1 for a self-complementary octanucleotide was 1.3 × 10⁶ M⁻¹, while the value for the phosphorylated counterpart was 4.8 × 10⁶ M⁻¹. This fourfold increase in the binding constant seems to stem from higher affinity of the terminal monophosphate over the phosphodiesters of DNA as the fourth ligand for the metal in 1. Likewise, the binding constant of 1 for DNase I-treated calf thymus DNA (average size 200 bp) was twice as large as that for untreated DNA (1 kb), possibly because the terminal phosphate groups are five times abundant in the former. These findings provide a clue to developing a system where phosphomonoesters generated upon DNA nicking are discriminated specifically from intact phosphodiesters.     

Two methods to detect DNA fragments produced by restriction enzymes

This report summarizes two methods for detecting limited amounts of DNA from restriction endonuclease digests. The first is a photographic system for visualizing ethidium bromide-stained DNA fragments in agarose gels which can detect as little as 50-100 pg DNA per band. The second technique is direct sulfonation of DNA fragments bound to nylon membranes followed by visualization of the fragments by nonradioactive immunoblot methods. The immunohistochemical staining can detect 10 pg DNA per band. The direct sulfonation technique is not intended to identify specific DNA sequences; DNA-DNA hybridization with sulfonated probes has previously been described (P. Lebacq, D. Squalli, M. Duchenne, P. Poulety, and M. Johannes (1988) J. Biochem. Biophys. Methods 15, 255-266). Direct sulfonation can be used when samples are relatively free of contaminating nucleic acids and is a useful alternative to end-labeling. These highly sensitive techniques may be suitable when the DNA source is of limited quantity or in instances where radiolabeling is not permitted.     

Electrophoresis of DNA restriction fragments in poly-N-acryloyl-tris gels

Poly-N-acryloyl-tris(hydroxymethyl)aminomethane (NAT) gels were evaluated as a matrix for DNA electrophoresis. The resolution of DNA restriction fragments in three poly(NAT)-N,N'-methylenebisacrylamide (Bis) gels (4, 5, and 6%) was compared with the resolution in polyacrylamide (AA)-Bis gels of the same percentage. Poly(NAT) gels were found to give a substantially improved separation of DNA fragments larger than 200 bp. In contrast to poly(AA) gels, DNA fragments of up to 4 kbp were well resolved in the new matrix. By pulse-field electrophoresis the useful separation range of poly(NAT) gels was expanded to at least 23 kbp. For DNA fragments below 10 kbp, the resolution was better than that in a 0.7% agarose gel. Thus poly(NAT) gels are most suitable for the electrophoretic separation of DNA molecules whose size is out of the optimal fractionation range of poly(AA) or agarose gels.     

Separation of large DNA restriction fragments on a size-exclusion column by a nonideal mechanism

Double-strand DNA (dsDNA) restriction fragments were chromatographed on the DuPont Bioseries GF-250 column. Two anomolous chromatographic properties were observed. (1) A triphasic dependence of retention on dsDNA chain length was observed. Small DNA fragments (less than 500 base pairs) displayed typical size exclusion, intermediate size DNA (800-5000 base pairs) eluted in the void volume, and larger DNA fragments were increasingly retained. (2) The void volume for nucleic acids was less than that for large polypeptides. The retention of moderately large DNA fragments increased linearly as the square root of the chain length over the range 5.5 to 50 kilobase pairs (ca. 3-30 X 10(6) Mr). A number of eluant manipulations were carried out in order to examine the mechanism by which the larger DNA fragments were being retained and separated. Evidence was not obtained to support either ion exchange or reverse phase as the retention mechanism. The usefulness of such a column for molecular biological manipulations is illustrated by the rapid isolation of homogeneous viral DNA fragments resected from their cloning vectors with restriction endonucleases.     

Mapping the order of DNA restriction fragments

A straightforward method was designed for mapping the order of DNA restriction fragments obtained by a double and two single digestions, without the necessity of using a computer or a radioactive label. All possible solutions compatible with a pre-set level of error in the determination of sequence lengths are obtained. The primary assumptions are given, and the appropriate modifications of the algorithm are presented as a function of any assumptions one is unable (or unwilling) to make. Use of the method in connection with end-labeled fragments is also described.     

Repeating restriction fragments of human DNA.

Human DNA digested with Hae III showed multiple repeats of a 170 base pair fragment. The most prominent band was the 340 base pair dimer, estimated to be 0.8% of the entire genome. Eco R1 and Hha I yielded fragments with similar electrophoretic mobility to the Hae III dimer. In each case this band was markedly enriched in DNA reassociating at a 0t of less than or equal to 1. Hybridization of the Hae III dimer to gels eluted on to filters demonstrated that the multiple Hae III fragments and Eco R1 fragments contained compatible sequences. These sequences may comprise a distinct subclass of DNA.     

A rapid two-dimensional fractionation of DNA restriction fragments

Genomic DNA that has been digested with a restriction endonuclease and fractionated by electrophoresis on an agarose gel can be recovered on glass-fiber filters by a new blotting scheme. The DNA fragments in each fraction are then digested with a second restriction nuclease and then separated on a slab gel, resulting in a two-dimensional display of the restriction fragments. This rapid fingerprinting technique is useful in the analysis of complex genomes and in the isolation and cloning of particular sequences.     

Characterization of yeast ribosomal DNA fragments generated by EcoR1 restriction endonuclease

Summary The action of Escherichia coli restriction endonuclease R1 (EcoR1) on DNA isolated from Saccharomyces cerevisiae (strain MAR-33) generates three predominent homogenously sized DNA fragments (species of 1.8, 2.2 and 2.5 kilo nucleotide base pairs (KB). Many DNA species of molecular weight greater than 2 million daltons can be recognized upon incomplete EcoR1 digestion of yeast DNA. Four additional DNA species ranging from 0.3–0.9 KB can be identified as the second major class of EcoR1-yeast DNA products.Hybridization with radioactive ribosomal RNA (rRNA) and competition with nonradioactive rRNA show that of the three predominent EcoR1-yeast DNA species, the 2.5 KB species hybridizes only with the 25S rRNA while the lighter 1.8 KB species hybridizes with the 18S rRNA. The intermediate DNA species of 2.2 KB hybridizes to a small extent with the 25S rRNA and could be a result of the presence of the 2.5 KB DNA species. The mass proportions and hybridization values of these 3 DNA species account for about 60% of the total ribosomal DNA (rDNA).The 5EcoR1-yeast DNA species of less than 0.9 KB (4 major and 1 minor species) hybridize to varying degrees with the 2 rRNA and can be grouped in two classes. In one class there are 3 DNA species that hybridize exclusively with the 18S rRNA. In the second class there are 2 DNA species that besides hybridizing predominently with the 25S rRNA also hybridize with the 18S rRNA. The 7 EcoR1-yeast DNA species (excluding the 2.2 KB DNA species) that hybridize with the two rRNA account for nearly a 5 million dalton DNA segment, which is very close to the anticipated gene size of rRNA precursor molecule. If the 2.2 KB DNA species is a part of the rDNA that is not transcribed or 5 sRNA then the cistron encoding the rRNA in S. cerevisiae has at least 8 EcoR1 recognition sites resulting in 8 DNA fragments upon digestion with the EcoR1. Consideration is given to the relationship of the rRNA species generated by EcoR1 digestion and the chromosomes containing ribosomal cistrons.     

Guanine tetraplex formation by short DNA fragments containing runs of guanine and cytosine.

Using CD spectroscopy, guanine tetraplex formation was studied with short DNA fragments in which cytosine residues were systematically added to runs of guanine either at the 5' or 3' ends. Potassium cations induced the G-tetraplex more easily with fragments having the guanine run at the 5' end, which is just an opposite tendency to what was reported for (G+T) oligonucleotides. However, the present (G+C) fragments simultaneously adopted other conformers that complicated the analysis. We demonstrate that repeated freezing/thawing, performed at low ionic strength, is a suitable method to exclusively stabilize the tetraplex in the (G+C) DNA fragments. In contrast to KCl, the repeated freeze/thaw cycles better stabilized the tetraplex with fragments having the guanine run on the 3' end. The tendency of guanine blocks to generate the tetraplex destabilized the d(G5).d(C5) duplex whose strands dissociated, giving rise to a stable tetraplex of (dG5) and single-stranded (dC5). In contrast to d(G3C3) and d(G5C5), repeated freezing/thawing induced the tetraplex even with the self-complementary d(C3G3) or d(C5G5); hence the latter oligonucleotides preferred the tetraplex to the apparently very stable duplex. The tetraplexes only included guanine blocks while the 5' end cytosines interfered neither with the tetraplex formation nor the tetraplex structure.     

Quantitation of specific fragments in DNA restriction digests: application to the cohesive fragments in lambda DNA digests

A procedure for the quantitation of reactions between specific members of a set of DNA restriction fragments is presented. Quantitation of the cohesive fragments in NruI nuclease digests of lambda DNA is used as an example. Restriction fragments are resolved on agarose gels and their amounts are estimated from densitometer scans of photographic negatives of ethidium bromide-stained gels. A linear relationship is found between the peak height of given fragment on the scan and the logarithm of the molecular weight of the fragment, arising in part from the stoichiometry of the digest; this relationship allows simple interpolation between the peak heights of the nonreacting fragments in each gel lane to determine the theoretical maximal amount of each reactive fragment in that gel lane. Similar procedures should be applicable to enzymatic ligation or to site-specific cleavage of specific restriction fragments or to autoradiographic detection of the fragments. Since each lane of the gel is analyzed independently, the method is largely self-correcting for variations in amounts applied to the gel.     

Processing of triplex-directed psoralen DNA interstrand crosslinks by recombination mechanisms

Gene targeting via homologous recombination (HR) is an important application in biotechnology and medicine. However, in mammalian cells HR is much less efficient than random integration. Triplex-forming oligonucleotides (TFOs) linked to DNA damaging agents (e.g. psoralen) can stimulate HR, providing the potential to improve gene therapy applications. To elucidate factors affecting TFO-directed psoralen interstrand crosslink (ICL)-induced recombination, we constructed a series of plasmids with duplicated supF reporter genes, each containing an inactivating deletion, to measure HR frequencies in mammalian cells. Our results indicated that TFO-directed ICL-induced recombination frequencies were higher in the plasmids with larger distances between duplicated supF genes than with a smaller separation distance. However, the position of the ICL relative to the reporter genes did not affect HR frequencies. Recombination spectra were altered by the distance between supF copies. Although single-strand annealing (SSA) recombinants were predominant in all plasmid substrates, the plasmid with the shortest interval (60 bp) revealed a significant proportion of gene conversions (GCs). GCs occurred exclusively in the gene containing the shortest deletion, regardless of the distance between supF genes, ICL position or deletion orientation. Our analyses indicated that SSA is the predominant mechanism of ICL processing of these substrates in mammalian cells.     

Cloning DNA restriction endonuclease fragments with protruding single-stranded ends

A new method of in vitro recombination was employed to construct plasmids containing lac promoter fragments 64 bp and 144 bp long. The 64 bp HpaII-HhaI fragment contains the binding site for the catabolite activator protein (CAP). The HpaII-HaeIII 144 bp fragment includes the binding sites for RNA polymerase, the lac repressor and CAP. The method utilizes the ability of T4 DNA polymerase to make flush-ended DNA either by filling in a recessed 3'-end or by exonucleolytic removal of a protruding 3'-end. The treated fragments were then blunt-end ligated to the filled-in EcoRI cloning sites of the plasmids pVH51 and pBR322 using T4 ligase. In this process, the EcoRI sites were regenerated on the fragment ends thus facilitating the subsequent isolation of the fragments from their cloning vectors.