Synthesis, thermal stability and reactivity towards 9-aminoellipticine of double-stranded oligonucleotides containing a true abasic site.
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A 13 mers abasic oligonucleotide was synthetized. It was therefore possible to compare thermal stability and reactivity of duplex oligonucleotides either with an apurinic/apyrimidinic site or without any lesion. An important decrease in the melting temperature appeared for duplexes with an abasic site. The chemical reaction of these modified oligonucleotides with the intercalating agent 9-aminoellipticine was studied by gel electrophoresis and by fluorescence. The formation of a Schiff base between 9-aminoellipticine and abasic sites was rapid and complete with duplexes at 11 degrees C. Schiff base related fluorescence and beta-elimination cleavage were more important with the apyrimidinic sites than with the apurinic ones. When compared to previous results obtained with the model d(TprpT) some unexpected behaviours appeared with longer and duplex oligonucleotides. For instance only partial beta-elimination cleavage was observed. It is likely that stacking parameters in the double helix play a great role in the studied reaction. (+info)
Physical association of the 2,6-diamino-4-hydroxy-5N-formamidopyrimidine-DNA glycosylase of Escherichia coli and an activity nicking DNA at apurinic/apyrimidinic sites.
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The 2,6-diamino-4-hydroxy-5N-formamidopyrimidine (Fapy)-DNA glycosylase of Escherichia coli, which is coded for by the fpg gene, excises purine bases with ring-opened imidazoles. In addition to the DNA glycosylase activity, we report that the Fapy-DNA glycosylase of E. coli has an associated activity, resistant to EDTA, that nicks DNA at apurinic/apyrimidinic (AP) sites. The levels of Fapy-DNA glycosylase and AP-nicking activity were parallel in crude lysates of E. coli HB101 harboring different plasmids constructed from the fpg gene. The fpg gene is different from the xth, nth, and nfo genes of E. coli, whose gene products also cleave DNA at AP sites. The Fapy-DNA glycosylase was purified to electrophoretic homogeneity. During this purification, the Fapy-DNA glycosylase copurified with an AP-nicking activity using chromatographic separations based on ion-exchange, molecular weight exclusion, and hydrophobicity. The cleavage at AP sites by the Fapy-DNA glycosylase left a 5'-phosphomonoester nucleotide at one terminus. In addition, DNA containing reduced AP sites was not nicked by the Fapy-DNA glycosylase. These data suggest that the mechanism of cleavage involved beta elimination. Therefore, this activity of the Fapy-DNA glycosylase nicking DNA at AP sites should be referred to as an AP lyase. The 3' terminus did not prime nick-translation by E. coli DNA polymerase I. However, the 3' terminus becomes a substrate for nick-translation if first allowed to react with calf intestine phosphatase or the E. coli exonuclease III. These data suggest that the repair of the Fapy lesion at least to some extent results in the formation of both 5'- and 3'-phosphomonoester nucleotides and the release of the deoxyribose. (+info)
Mechanism of DNA strand nicking at apurinic/apyrimidinic sites by Escherichia coli [formamidopyrimidine]DNA glycosylase.
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Escherichia coli [formamidopyrimidine]DNA glycosylase catalyses the nicking of both the phosphodiester bonds 3' and 5' of apurinic or apyrimidinic sites in DNA so that the base-free deoxyribose is replaced by a gap limited by 3'-phosphate and 5'-phosphate ends. The two nickings are not the results of hydrolytic processes; the [formamidopyrimidine]DNA glycosylase rather catalyses a beta-elimination reaction that is immediately followed by a delta-elimination. The enzyme is without action on a 3'-terminal base-free deoxyribose or on a 3'-terminal base-free unsaturated sugar produced by a beta-elimination reaction nicking the DNA strand 3' to an apurinic or apyrimidinic site. (+info)
Influence of abasic and anucleosidic sites on the stability, conformation, and melting behavior of a DNA duplex: correlations of thermodynamic and structural data.
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We report a complete thermodynamic characterization of the impact of abasic and anucleosidic lesions on the stability, conformation, and melting behavior of a DNA duplex. The requisite thermodynamic data were obtained by using a combination of spectroscopic and calorimetric techniques to investigate helix-to-coil transitions in a family of DNA duplexes of the form d(CGCATGAGTACGC).d(GCGTACXCATGCG), where X corresponds to a thymidine residue in the parent Watson-Crick duplex and to an abasic or anucleosidic site in the modified duplexes. The data derived from these studies reveal that incorporation of an abasic site into a DNA duplex dramatically reduces the duplex stability, transition enthalpy, and transition entropy. The magnitudes of these lesion-induced effects are greater than one would expect based on simple nearest-neighbor considerations. Nearly identical thermodynamic data are obtained when the modified duplex contains an anucleosidic site rather than an abasic site. This observation suggests that the thermodynamic impact of these lesions primarily results from removal of the base rather than the sugar ring. Significantly, the melting cooperativities of the abasic and anucleosidic derivatives are identical with each other and with the corresponding unmodified Watson-Crick parent duplex. This result suggests that the phosphodiester backbone, rather than the base-sugar network, serves as the primary propagation path for the communication of cooperative melting effects. We propose molecular interpretations for the thermodynamic data based on the structural picture that has emerged from the NMR studies of Patel and coworkers on the same family of modified and unmodified DNA duplexes [Kalnik, M.W., Chang, C.-N., Grollman, A.P. & Patel, D.J. (1988) Biochemistry 27, 924-931]. (+info)
Mechanism of cleavage of apurinic sites by 9-aminoellipticine.
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We have studied the kinetics of breakage of apurinic (AP) sites by the intercalating agent 9-aminoellipticine using fluorimetric methods with single (ss)- and double (ds)-stranded apurinic DNA. In order to understand the chemical process, high performance liquid chromatography was used to follow the reaction kinetics with the apurinic oligonucleotide model T(AP)T. The unstable intermediate, which is responsible for the beta-elimination step, is a Schiff base resulting from the interaction of the amino group of the aromatic amine with the aldehyde function of the deoxyribose moiety (AP site). Fluorescence occurs simultaneously with the breakage of both ss and ds DNA and of the oligonucleotide and arises from the formation of a conjugated double bond on the Schiff base through the beta-elimination reaction. In optimal conditions, the second order rate constant for the fluorescence build up is 15 x 10(3) min-1 M-1 for ds DNA and 0.105 x 10(3) min-1 M-1 for T(AP)T. The ability of 9-aminoellipticine to induce fluorescence and breakage of ss DNA and T(AP)T shows that intercalation is not essential for this reaction to occur. Nevertheless, the greater rate constant with DNA suggests that stacking is an important parameter for the reaction of the aromatic amine with the AP site. (+info)
Efficient transfer of large DNA fragments from agarose gels to diazobenzyloxymethyl-paper and rapid hybridization by using dextran sulfate.
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We describe a technique for transferring electrophoretically separated bands of double-stranded DNA from agarose gels to diazobenzyloxymethyl-paper. Controlled cleavage of the DNA in situ by sequential treatment with dilute acid, which causes partial depurination, and dilute alkali, which causes cleavage and separation of the strands, allows the DNA to leave the gel rapidly and completely, with an efficiency independent of its size. Covalent attachment of DNA to paper prevents losses during subsequent hybridization and washing steps and allows a single paper to be reused many times. Ten percent dextran sulfate, originally found to accelerate DNA hybridization in solution by about 10-fold [J.G. Wetmur (1975) Biopolymers 14, 2517-2524], accelerates the rate of hybridization of randomly cleaved double-stranded DNA probes to immobilized nucleic acids by as much as 100-fold, without increasing the background significantly. (+info)
Chromatin 3'-phosphatase/5'-OH kinase cannot transfer phosphate from 3' to 5' across a strand nick in DNA.
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Rat liver chromatin contains a 3'-phosphatase/5'-OH kinase which may be involved in the repair of DNA strand breaks limited by 3'-phosphate/5'-OH ends. In order to determine whether the phosphate group can be transferred directly from the 3' to the 5' position, a polynucleotide duplex was synthesized between poly (dA) and oligo (dT) segments which had 3'-[32P]phosphate and 5'-OH ends. The oligo (dT) segments were separated by simple nicks as shown by the ability of T4 DNA ligase to seal the nick after the 3'-phosphate was removed by a phosphatase and the 5' end was phosphorylated with a kinase. The chromatin 3'-phosphatase/5'-OH kinase was unable to transfer phosphate directly from the 3' to the 5' end of the oligo (dT) segments in the original duplex; ATP was needed to phosphorylate the 5'-OH end. It is concluded that the chromatin 3'-phosphatase/5'-OH kinase is unable to convert a 3'-phosphate/5'-OH nick which cannot be repaired by DNA ligase directly into a 3'-OH/5'-phosphate nick which can be repaired by DNA ligase; the chromatin enzyme rather acts in two steps: hydrolysis of the 3'-phosphate followed by ATP-mediated phosphorylation of the 5'-OH end. (+info)
A DNase for apurinic/apyrimidinic sites associated with exonuclease III of Hemophilus influenzae.
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An endonuclease purified from Hemophilus influenzae made single strand breaks in DNA containing apurinic or apyrimidinic sites but had no detectable endonuclease activity on untreated native DNA. The new 5'-termini created at the cleavage sites were base-free deoxyribose 5-phosphate residues. The enzyme preparation also catalyzed the exonucleolytic release of 5'-mononucleotides from bihelical DNA and the hydrolysis of DNA 3'-terminal phosphomonoesters. The phosphatase-exonuclease activity was indistinguishable from that reported by Gunther and Goodgal (J. Biol. Chem. (1970) 245, 5341-5349) and resembled that of exonuclease III of Escherichia coli. The endonucleolytic and exonucleolytic activities could not be separated by electrophoresis, sedimentation, or gel filtration, and they were also affected simultaneously by mutation. The enzymatic activities appear to be functions of a single monomeric protein (M(r) = 30,000). (+info)