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)     

Drosophila engrailed-1,10-phenanthroline chimeras as probes of homeodomain-DNA complexes.

We have converted the Drosophila engrailed homeodomain into a sequence-specific nuclease by linking the protein to the chemical nuclease 1,10-phenanthroline-copper (OP-Cu). Unique cysteines were introduced at six positions into the homeodomain by site-directed mutagenesis for the covalent attachment of OP-Cu. The varied DNA-binding affinity and specificity of these mutants and the DNA cleavage pattern of their OP-Cu derivatives allowed us to assess the crystal structure of the engrailed homeodomain-DNA complex. We have also achieved site-specific double-stranded DNA scission with one of the homeodomain mutants, E28C, which has the potential of being used to identify engrailed binding sites in the genome. Because the homeodomain is so well conserved among members of the homeodomain-containing protein family, other homeodomain proteins can be converted into nucleases by attaching OP-Cu at position 28 of their homeodomains.     

Sequence specificity of the deoxyribonuclease activity of 1,10-phenanthroline-copper ion

A statistical analysis of a data set composed of over 1600 scission events of DNA produced by the 2:1 1,10-phenanthroline-copper complex (OP-Cu) has demonstrated that the nucleotide 5' to the site of phosphodiester bond scission is a primary influence in the kinetics of cleavage at any sequence position. The scission was less affected by the 3' neighbor. For each of the sixteen possible dinucleotides, a kinetic parameter can be computed reflecting scission at the 3' nucleotide. When used to predict the scission pattern of a DNA sequence not part of the present data set, correlation coefficients of about 0.6 between predicted and observed patterns were obtained.     

Determination of nucleotide distances in RNA by means of copper phenanthroline-generated hydroxyl radical cleavage pattern.

In contrast to the commonly used Fe(II)-EDTA, bis(orthophenanthroline)-copper(I) (OP-Cu) first generates hydroxyl radicals after binding to RNA. Due to diffusion, the hydroxyl radicals can cleave neighboring nucleotides in a distance r of up to 1.5 nm to the OP-Cu binding site. Using the known structure of tRNAPhe as a reference, we show that the hydroxyl radical cleavage pattern generated by a specifically bound OP-Cu shows a 1/r dependence on the distance of the cleaved nucleotide to the OP-Cu binding site. We propose that OP-Cu is a suitable probe for obtaining data on the distances between nucleotides in RNA, which can be used in modeling the structure of the examined RNA. However, this information is restricted to about three to four bases surrounding an OP-Cu binding site.     

Scission of RNA by the chemical nuclease of 1,10-phenanthroline-copper ion: preference for single-stranded loops.

The scission of RNA by the chemical nuclease activity of 1,10-phenanthroline-copper (OP-Cu) has been studied using a lac mRNA fragment and tRNAphe as substrates. Since the chemical mechanism of scission involves oxidative attack on the ribose, scission is observed at all nucleotides including dihydrouridine and Y-bases. Specificity for single-stranded loop regions is apparent from the similarity of the reactivity of OP-Cu to the single-strand specific reagents dimethyl sulfate and diethyl pyrocarbonate using the fragment of lac mRNA as a substrate. Similar preference is observed in the reaction with tRNA although scission in the helical acceptor stem is also observed.     

1,10-Phenanthroline-copper, a footprinting reagent for single-stranded regions of RNAs.

The 1,10-phenanthroline-cuprous complex (OP-Cu) with hydrogen peroxide as a coreactant nicks the single-stranded loops and bulges of RNA stem-loop structures more rapidly than the double-stranded stems. This chemical nuclease is therefore a useful footprinting reagent for these regions and can be used to monitor both intramolecular and intermolecular hybridization of single-stranded domains. The formation of A-form structures characteristic of either RNA-RNA or RNA-DNA duplexes inhibits scission because it blocks the binding site of the coordination complex in single-stranded loops and not because the oxidatively sensitive hydrogens of the ribose moiety are blocked. The C-4' and C-1' hydrogens are accessible to solvent in A-structures.     

Specific DNA cleavage and binding by vaccinia virus DNA topoisomerase I

Cleavage of a defined linear duplex DNA by vaccinia virus DNA topoisomerase I was found to occur nonrandomly and infrequently. Approximately 12 sites of strand scission were detected within the 5372 nucleotides of pUC19 DNA. These sites could be classified as having higher or lower affinity for topoisomerase based on the following criteria. Higher affinity sites were cleaved at low enzyme concentration, were less sensitive to competition, and were most refractory to religation promoted by salt, divalent cations, and elevated temperature. Cleavage at lower affinity sites required higher enzyme concentration and was more sensitive to competition and induced religation. Cleavage site selection correlated with a pentameric sequence motif (C/T)CCTT immediately preceding the site of strand scission. Noncovalent DNA binding by topoisomerase predominated over covalent adduct formation, as revealed by nitrocellulose filter-binding studies. The noncovalent binding affinity of vaccinia topoisomerase for particular subsegments of pUC19 DNA correlated with the strength and/or the number of DNA cleavage sites contained therein. Thus, cleavage site selection is likely to be dictated by specific noncovalent DNA-protein interactions. This was supported by the demonstration that a mutant vaccinia topoisomerase (containing a Tyr----Phe substitution at the active site) that was catalytically inert and did not form the covalent intermediate, nevertheless bound DNA with similar affinity and site selectivity as the wild-type enzyme. Noncovalent binding is therefore independent of competence in transesterification. It is construed that the vaccinia topoisomerase is considerably more stringent in its cleavage and binding specificity for duplex DNA than are the cellular type I enzymes.     

Polyamine derivatives as selective RNaseA mimics

Site-selective scission of ribonucleic acids (RNAs) has attracted considerable interest, since RNA is an intermediate in gene expression and the genetic material of many pathogenic viruses. Polyamine-imidazole conjugates for site-selective RNA scission, without free imidazole, were synthesized and tested on yeast phenylalanine transfer RNA. These molecules catalyze RNA hydrolysis non-randomly. Within the polyamine chain, the location of the imidazole residue, the numbers of nitrogen atoms and their relative distances have notable influence on cleavage selectivity. A norspermine derivative reduces the cleavage sites to a unique location, in the anticodon loop of the tRNA, in the absence of complementary sequence. Experimental results are consistent with a cooperative participation of an ammonium group of the polyamine moiety, in addition to it’s binding to the negatively charged ribose-phosphate backbone, as proton source, and the imidazole moiety as a base. There is correlation between the location of the magnesium binding sites and the RNA cleavage sites, suggesting that the protonated nitrogens of the polycationic chain compete with some of the magnesium ions for RNA binding. Therefore, the cleavage pattern is specific of the RNA structure. These compounds cleave at physiological pH, representing novel reactive groups for antisense oligonucleotide derivatives or to enhance ribozyme activity.     

Studies on the binding of lambda Int protein to attachment site DNA: identification of a tight-binding site in the P'' region.

We have used three approaches to studying the interaction of lambda Int protein with bacteriophage attachment site DNA, POP': location of binding sites by retention of DNA fragments in a filter binding assay, reconstruction of a binding site by DNA synthesis and protection of a binding site from an exonuclease. Retention of restriction fragments on nitrocellulose filters in the presence of Int protein was used to locate binding sites. A high affinity binding site lies in P' between base pairs -6 and +173 from the center of the common core sequence, and low affinity sites are found in the 200 base pair region left of position -6. Reconstruction of the high affinity binding site region from the right using primed DNA synthesis and testing for filter binding in the presence of Int protein shows that sequences sufficient for tight binding of Int protein lie to the right of position +66. When attachment site DNA is protected by bound Int protein against digestion by exonuclease III, four Int dependent protection bands are seen in positions +58, +68, +79 and +88. This can be interpreted either as showing that four Int protein monomers bind to the high affinity region in series, or as evidence for wrapping of the DNA around Int protein, leading to structural changes resembling those occurring to DNA in nucleosomes.     

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.     

Characterization of interaction between DNA and 4',6-diamidino-2-phenylindole by optical spectroscopy

We have examined the interaction between 4',6-diamidino-2-phenylindole (DAPI) and DNA using flow linear dichroism (LD), circular dichroism (CD), and fluorescence techniques. We show the presence of two spectroscopically distinct binding sites at low binding ratios with saturation values of 0.025 and 0.17, respectively. In both sites DAPI is bound with its long axis approximately parallel to the grooves of the DNA helix. Resolution of CD spectra shows that an exciton component is present at higher binding ratios, which we attribute to the interaction of two accidentally close-lying DAPI molecules. We also find evidence that DAPI, at least in the high-affinity site, binds preferentially to AT-rich regions. From the spectroscopic results, supported by structural considerations, we can completely exclude that DAPI is bound to DNA by intercalation. Binding geometries and site densities are consistent with a location of DAPI in the grooves of DNA, with the high-affinity site most probably in the minor groove.     

Artificial restriction DNA cutter for site-selective scission of double-stranded DNA with tunable scission site and specificity

The artificial restriction DNA cutter (ARCUT) method to cut double-stranded DNA at designated sites has been developed. The strategy at the base of this approach, which does not rely on restriction enzymes, is comprised of two stages: (i) two strands of pseudo-complementary peptide nucleic acid (pcPNA) anneal with DNA to form 'hot spots' for scission, and (ii) the Ce(IV)/EDTA complex acts as catalytic molecular scissors. The scission fragments, obtained by hydrolyzing target phosphodiester linkages, can be connected with foreign DNA using DNA ligase. The location of the scission site and the site-specificity are almost freely tunable, and there is no limitation to the size of DNA substrate. This protocol, which does not include the synthesis of pcPNA strands, takes approximately 10 d to complete. The synthesis and purification of the pcPNA, which are covered by a related protocol by the same authors, takes an additional 7 d, but pcPNA can also be ordered from custom synthesis companies if necessary.     

DNA abasic lesions in a different light: solution structure of an endogenous topoisomerase II poison

Topoisomerase II is the target for several anticancer drugs that "poison" the enzyme and convert it to a cellular toxin by increasing topoisomerase II-mediated DNA cleavage. In addition to these "exogenous topoisomerase II poisons," DNA lesions such as abasic sites act as "endogenous poisons" of the enzyme. Drugs and lesions are believed to stimulate DNA scission by altering the structure of the double helix within the cleavage site of the enzyme. However, the structural alterations that enhance cleavage are unknown. Since abasic sites are an intrinsic part of the genetic material, they represent an attractive model to assess DNA distortions that lead to altered topoisomerase II function. Therefore, the structure of a double-stranded dodecamer containing a tetrahydrofuran apurinic lesion at the +2 position of a topoisomerase II DNA cleavage site was determined by NMR spectroscopy. Three major features distinguished the apurinic structure ( = 0.095) from that of wild-type ( = 0.077). First, loss of base stacking at the lesion collapsed the major groove and reduced the distance between the two scissile phosphodiester bonds. Second, the apurinic lesion induced a bend that was centered about the topoisomerase II cleavage site. Third, the base immediately opposite the lesion was extrahelical and relocated to the minor groove. All of these structural alterations have the potential to influence interactions between topoisomerase II and its DNA substrate.     

Repair of the major lesion resulting from C5'-oxidation of DNA

Oxidation of the C5'-position of DNA results in direct strand scission. The 3'-fragments produced contain DNA lesions at their 5'-termini. The major DNA lesion contains an aldehyde at its C5'-position, but its nucleobase is unmodified. Excision of the lesion formed from oxidation of thymidine (T-al) is achieved by strand displacement synthesis by DNA polymerase β (Pol β) in the presence or absence of flap endonuclease 1 (FEN1). Pol β displaces T-al and thymidine with comparable efficiency, but less so than a chemically stabilized abasic site analogue (F). FEN1 cleaves the flaps produced during strand displacement synthesis that are two nucleotides or longer. A ternary complex containing T-al is also a substrate for the bacterial UvrABC nucleotide excision repair system. The sites of strand scission are identical in ternary complexes containing T-al, thymidine, or F. UvrABC incision efficiency of these ternary complexes is comparable as well but significantly slower than a duplex substrate containing a bulky substituted thymidine. However, cleavage occurs only on the 5'-fragment and does not remove the lesion. These data suggest that unlike many lesions the redundant nature of base excision and nucleotide excision repair systems does not provide a means for removing the major damage product produced by agents that oxidize the C5'-position. This may contribute to the high cytotoxicity of drugs that oxidize the C5'-position in DNA.     

The effect of various inhibitors of DNA synthesis on the repair of DNA photoproducts

The effect on DNA repair of several inhibitors of DNA synthesis has been investigated in CHO cells. Three assays were employed following ultraviolet irradiation of G1 cells: unscheduled DNA synthesis, removal of antibody binding sites and alkaline elution. Cytosine arabinoside and aphidicolin were found to reduce unscheduled DNA synthesis in a dose-dependent manner without affecting the removal of antibody-binding sites. Strand rejoining was also inhibited. These results are consistent with the hypothesis that inhibition is due to premature chain termination during repair synthesis some time after excision of the lesion. Conversely, inhibition of unscheduled DNA synthesis by novobiocin is paralleled by inhibition of excision of the lesion. However, no inhibition of incision was apparent. Since nalidixic acid, an inhibitor of topoisomerase II, did not inhibit excision, it is unlikely that the primary site of action of novobiocin is this topoisomerase. The possibility that a second topoisomerase and/or a polymerase are affected is discussed in the light of previously published data.     

Novel approach for the effective determination of DNA scission site using the Sanger method

This paper describes the effective determination of DNA scission site using a novel approach that is based on the Sanger method of nucleotide sequencing. The DNA scission site is determined by contrast with the nucleotide sequence of the DNA. Here, instead of the traditional Maxam-Gilbert method for the determination of the DNA sequence, we utilized the Sanger method and studied its effectiveness in the determination of DNA scission sites. Using this method, the determination of DNA scission site becomes more facile and exact. And the total time for the determination is reduced nearly by half in comparison to the Maxam-Gilbert method. Further advantages of this novel approach include the reduced risks of radiation exposure for researchers and contamination of the apparatus.     

The effect of various inhibitors of DNA synthesis on the repair of DNA photoproducts

The effect on DNA repair of several inhibitors of DNA synthesis has been investigated in CHO cells. Three assays were employed following ultraviolet irradiation of G₁ cells: unscheduled DNA synthesis, removal of antibody binding sites and alkaline elution. Cytosine arabinoside and aphidicolin were found to reduce unscheduled DNA synthesis in a dose-dependent manner without affecting the removal of antibody-binding sites. Strand rejoining was also inhibited. These results are consistent with the hypothesis that inhibition is due to premature chain termination during repair synthesis some time after excision of the lesion. Conversely, inhibition of unscheduled DNA synthesis by novobiocin is paralleled by inhibition of excision of the lesion. However, no inhibition of incision was apparent. Since nalidixic acid, an inhibitor of topoisomerase II, did not inhibit excision, it is unlikely that the primary site of action of novobiocin is this topoisomerase. The possibility that a second topoisomerase and/or a polymerase are affected is discussed in the light of previously published data.