Novel non-isotopic detection of MutY enzyme-recognized mismatches in DNA via ultrasensitive detection of aldehydes.

A highly sensitive method to detect traces of aldehyde-containing apurinic/apyrimidinic (AP) sites in nucleic acids has been developed. Based on this method, a novel approach to detect DNA base mismatches recognized by the mismatch repair glycosylase MutY is demonstrated. Open chain aldehydes generated in nucleic acids due to spontaneous depurination, DNA damage or base excision of mismatched adenine by MutY are covalently trapped by a new linker molecule [fluorescent aldehyde-reactive probe (FARP), a fluorescein-conjugated hydroxylamine derivative]. DNA containing AP sites is FARP-trapped, biotinylated and immobilized onto neutravidin-coated microplates. The number of FARP-trapped aldehydes is then determined via chemiluminescence using a cooled ICCD camera. AP sites induced in plasmid or genomic calf thymus DNA via mild depurination or by simple incubation at physiological conditions (pH 7, 37 degreesC) presented a linear increase in chemiluminescence signal with time. The procedure developed, from a starting DNA material of approximately 100 ng, allows detection of attomole level (10(-18) mol) AP sites, or 1 AP site/2 x 10(7) bases, and extends by 1-2 orders of magnitude the current limit in AP site detection. In order to detect MutY-recognized mismatches, nucleic acids are first treated with 5 mM hydroxylamine to remove traces of spontaneous aldehydes. Following MutY treatment and FARP-labeling, oligonucleotides engineered to have a centrally located A/G mismatch demonstrate a strong chemiluminescence signal. Similarly, single-stranded M13 DNA that forms mismatches via self-complementation (average of 3 mismatches over 7429 bases) and treated with MutY yields a signal approximately 100-fold above background. No signal was detected when DNA without mismatches was used. The current development allows sensitive, non-isotopic, high throughput screening of diverse nucleic acids for AP sites and mismatches in a microplate-based format.     

The mechanism of C-banding: depurination and β-elimination

C-banding of chromosomes involves the differential solubilization of fragmented DNA from euchromatin by three sequential treatments: 1. Acid, 2. Mild base, 3. Hot salt. The data indicate solubilization is effected by 1) depurination, 2) DNA denaturation, 3) chain breakage of the depurinated sites respectively in the three treatments. Conditions were found wherein each treatment in proper sequence was necessary for C-banding and the appropriate chemical reactions were measured in these treatment conditions. The acid treatment (0.2 N HCl) depurinates chromosomal DNA at the rate of 0.26×10^–6 purines/dalton min to an alkaline molecular weight of 10⁵ daltons but does not break the depurinated sites. Bleomycin can substitute for acid as a base removing agent. Sodium borohydride, by reducing the depurinated sugar's aldehyde thereby preventing chain breakage by the -elimination reaction, reversibly inhibits DNA-extraction. Chain breakage at the DNA's apurinic sites occurs not in the 2 min mild alkali treatment where the half-life for breakage is 26 min but in the 18 h hot salt treatment where the half-life for chain breakage is 1–2 h. Most of the DNA extraction occurs in the hot salt as 10⁵ dalton fragments as measured in formamide gradients. Bleomycin is introduced as a substitute for HCl; it removes nitrogenous bases from DNA in situ while better preserving the morphology of the final C-banded chromosomes.     

Depurination As a Yield Decreasing Mechanism in Oligodeoxynucleotide Synthesis

Abstract

The synthesis in our laboratory of very long (80–106 bases) oligodeoxynucleotides using the phosphite method of Matteucci and Caruthers in an automated DNA synthesizer indicates the true efficiency of this multiple step process. The coupling efficiency as measured by trityl cation release i s 99.5–99.8%. However the yield obtained is still below the theoretical yield calculated from the above efficiency. We have attempted t o elucidate yield decreasing mechanisms in long ol igodeoxynucleotide synthesis. Crude reaction mixtures of phosphate-deblocked oligonucleotides which had no 5′-trityl group and which were examined immediately after cleavage from the support show one major species by high resolution PAGE. Harsher hydrolysis generates a new pattern of products superimposed upon the initial ladder representing cleavage at purine residues internal to the full length oligonucleotide. In many cases the cleavage ladder is significantly more intense than the coupling ladder. Hydrolysis a t apurinic sites in ammonium hydroxide at 55° C is apparently quantitative. The implications of this study are that internal depurination does not interfere with chain propagation but directly reduces the isolated yield. The efficiency of the phosphite coupling, oxidation, demethylation, and base deprotection are not the yield limiting steps. Synthesis of even longer fragments may be achievable with a reduction in the depurination o f the propagating chain. More significantly, compounds isolated after proper hydrolysis will not contain any apurinic sites making these compounds suitable for biological use.     

Sites of gamma radiation-induced DNA strand breaks after alkali treatment

When DNA is gamma-irradiated in aerated aqueous solution, strand breaks are produced during irradiation or the next few hours. Subsequent piperidine treatment gives rise to further DNA strand ruptures at alkali-labile sites. These different types of DNA chain breaks provoked by gamma-irradiation have been studied with oligonucleotides having defined sequences. The breaks selectively developed inside the DNA chain at alkali-labile sites by piperidine treatment appeared at lower doses preferentially at guanine positions and the order G greater than A greater than T greater than or equal to C was observed. The total contribution of the direct DNA chain ruptures, formed during irradiation and the next few hours, and those obtained by piperidine treatment was studied at doses ranging from 10 to 120 Gy. The chain breaks appeared preferentially at thymine positions and the order T greater than G greater than A greater than or equal to C was shown for the higher doses.     

Chlamydia pneumoniae AP endonuclease IV could cleave AP sites of double- and single-stranded DNA

Endonuclease IV gene, the only putative AP endonuclease of C. pneumoniae genome, was cloned into pET28a. Recombinant C. pneumoniae endonuclease I V (CpEndoIV) was expressed in E. coli and purified to homogeneity. CpEndoIV has endonuclease activity against apurinic/apyrimidinic sites (AP sites) of double-stranded (ds) oligonucleotides. AP endonuclease activity of CpEndoIV was promoted by divalent metal ions Mg2+ and Zn2+, and inhibited by EDTA. The natural (A, T, C and G) and modified (U, I and 8-oxo-G (GO)) bases opposite AP site had little effect on the cleavage efficiency of AP site of ds oligonucleotides by CpEndoIV. However, the CpEndoIV-dependent cleavage of AP site opposite modified base GO was strongly inhibited by Chlamydia DNA glycosylase MutY. Interestingly, the AP site in single-stranded (ss) oligonucleotides was also the effective substrate of CpEndoIV. Similar to E. coli endonuclease IV, AP endonuclease activity of CpEndoIV was also heat-stable to some extent, with a half time of 5 min at 60 degrees C.     

Action of Escherichia coli and human 5'----3' exonuclease functions at incised apurinic/apyrimidinic sites in DNA.

The 5'----3' exonuclease activity of E. coli DNA polymerase I and a related enzyme activity in mammalian cell nuclei, DNase IV, are unable to catalyse the excision of free deoxyribose-phosphate from apurinic/apyrimidinic (AP) sites incised by an AP endonuclease. Instead, the sugar phosphate residue is slowly released as part of a short oligonucleotide. These products have been characterised as dimers and trimers by comparison of their retention time on reverse-phase HPLC with reference compounds prepared by acid depurination of a dinucleotide, trinucleotide and tetranucleotide containing a 5'-terminal dAMP residue. The similar mode of action of these enzymes at 5'-incised AP sites provides an explanation for the minority of repair patches larger than one nucleotide observed when AP sites are repaired by E. coli and mammalian cell extracts in vitro and strengthens the functional analogy between the two activities.     

Bacteriophage-T4 and Micrococcus luteus UV endonucleases are not endonucleases but beta-elimination and sometimes beta delta-elimination catalysts.

Bacteriophage-T4 UV endonuclease nicks the C(3')-O-P bond 3' to AP (apurinic or apyrimidinic) sites by a beta-elimination reaction. The breakage of this bond is sometimes followed by the nicking of the C(5')-O-P bond 5' to the AP site, leaving a 3'-phosphate end; delta-elimination is proposed as a mechanism to explain this second reaction. The AP site formed when this enzyme acts on a pyrimidine dimer in a polynucleotide chain undergoes the same nicking reactions. Micrococcus luteus UV endonuclease also nicks the C(3')-O-P bond 3' to AP sites by a beta-elimination reaction. No subsequent delta-elimination was observed, but this might be due to the presence of 2-mercaptoethanol in the enzyme preparation.     

Probing distance and electrical potential within a protein pore with tethered DNA

DNA molecules tethered inside a protein pore can be used as a tool to probe distance and electrical potential. The approach and its limitations were tested with alpha-hemolysin, a pore of known structure. A single oligonucleotide was attached to an engineered cysteine to allow the binding of complementary DNA strands inside the wide internal cavity of the extramembranous domain of the pore. The reversible binding of individual oligonucleotides produced transient current blockades in single channel current recordings. To probe the internal structure of the pore, oligonucleotides with 5' overhangs of deoxyadenosines and deoxythymidines up to nine bases in length were used. The characteristics of the blockades produced by the oligonucleotides indicated that single-stranded overhangs of increasing length first approach and then thread into the transmembrane beta-barrel. The distance from the point at which the DNA was attached and the internal entrance to the barrel is 43 A, consistent with the lengths of the DNA probes and the signals produced by them. In addition, the tethered DNAs were used to probe the electrical potential within the protein pore. Binding events of oligonucleotides with an overhang of five bases or more, which threaded into the beta-barrel, exhibited shorter residence times at higher applied potentials. This finding is consistent with the idea that the main potential drop is across the alpha-hemolysin transmembrane beta-barrel, rather than the entire length of the lumen of the pore. It therefore explains why the kinetics and thermodynamics of formation of short duplexes within the extramembranous cavity of the pore are similar to those measured in solution, and bolsters the idea that a "DNA nanopore" provides a useful means for examining duplex formation at the single molecule level.     

Cleavage of single- and double-stranded DNAs containing an abasic residue by Escherichia coli exonuclease III (AP endonuclease VI).

The Escherichia coli exonuclease III (AP endonuclease VI) is a DNA-repair enzyme that hydrolyzes the phosphodiester bond 5' to an abasic site in DNA. To study how the enzyme recognizes the abasic site, we used oligonucleotides containing a synthetic abasic site at any desired position in the sequence. We prepared oligonucleotides containing an abasic residue such as 2'-deoxyribosylformamide, 2'-deoxyribose, 1',2'-dideoxy ribofuranose or propanediol. Duplex oligonucleotides containing an abasic residue used in this study were cleaved on the 5' side of the abasic site by exonuclease III in spite of the varieties of the bases opposite and adjacent to the abasic site. In addition, we observed that the enzyme cleaved single-stranded oligonucleotides containing an abasic site on the 5' side of the abasic site. These findings suggest that the enzyme may principally recognize the DNA-pocket formed at an abasic site. The indole ring of the tryptophan 212 residue of the exonuclease III is probably intercalated to the abasic site. The tryptophan in the vicinity of the catalytic site is conserved in the type II AP endonuclease from various organisms.     

Kinetic studies on depurination and detritylation of CPG-bound intermediates during oligonucleotide synthesis.

Fully protected CPG-immobilized monomer, dimer and trimer oligonucleotides were used to study depurination during the chemical synthesis of oligonucleotides. Disappearance of the oligonucleotide during acid exposure time relative to an internal thymidine standard not subject to depurination was monitored by reverse phase HPLC analysis. Depurination half-times obtained for dichloroacetic acid (DCA) and trichloroacetic acid (TCA) in methylene chloride were found to be 3% DCA >> 15% DCA > 3% TCA. In order to understand the implications of depurination during DNA synthesis, the detritylation kinetics of model compounds DMT-dG-pT dimer and DMT-[17mer] mixed-base sequence were also measured. These results improve our ability to properly balance the contradictory goals of obtaining maximum detritylation with minimum depurination in oligonucleotide synthesis.     

HYDROLYSIS OF BULGED NUCLEOTIDES IN HYBRIDS FORMED BY RNA AND IMIDAZOLE-DERIVATIZED OLIGO-2′-O-METHYLRIBONUCLEOTIDES

In order to enhance the efficacy of small antisense molecules, we examined a series of antisense oligonucleotides derivatized with functional groups designed to enable them to hydrolyze their RNA target. Solid phase synthetic methods were used to prepare imidazole-derivatized antisense oligo-2′-O-methylribonucleotides. Upon binding, these oligonucleotides create internal bulged bases in the target RNA that serve as sites for hydrolysis. We observed that an oligonucleotide derivatized with a side chain containing two imidazole groups was capable of hydrolyzing 58% of its RNA target when incubated with the target for 48 hours at 37°C and physiological pH.     

Hydrolysis of bulged nucleotides in hybrids formed by RNA and imidazole-derivatized oligo-2'-O-methylribonucleotides

In order to enhance the efficacy of small antisense molecules, we examined a series of antisense oligonucleotides derivatized with functional groups designed to enable them to hydrolyze their RNA target. Solid phase synthetic methods were used to prepare imidazole-derivatized antisense oligo-2'-O-methylribonucleotides. Upon binding, these oligonucleotides create internal bulged bases in the target RNA that serve as sites for hydrolysis. We observed that an oligonucleotide derivatized with a side chain containing two imidazole groups was capable of hydrolyzing 58% of its RNA target when incubated with the target for 48 hours at 37°C and physiological pH.     

Slow base excision by human alkyladenine DNA glycosylase limits the rate of formation of AP sites and AP endonuclease 1 does not stimulate base excision

The base excision repair pathway removes damaged DNA bases and resynthesizes DNA to replace the damage. Human alkyladenine DNA glycosylase (AAG) is one of several damage-specific DNA glycosylases that recognizes and excises damaged DNA bases. AAG removes primarily damaged adenine residues. Human AP endonuclease 1 (APE1) recognizes AP sites produced by DNA glycosylases and incises the phophodiester bond 5' to the damaged site. The repair process is completed by a DNA polymerase and DNA ligase. If not tightly coordinated, base excision repair could generate intermediates that are more deleterious to the cell than the initial DNA damage. The kinetics of AAG-catalyzed excision of two damaged bases, hypoxanthine and 1,N6-ethenoadenine, were measured in the presence and absence of APE1 to investigate the mechanism by which the base excision activity of AAG is coordinated with the AP incision activity of APE1. 1,N6-ethenoadenine is excised significantly slower than hypoxanthine and the rate of excision is not affected by APE1. The excision of hypoxanthine is inhibited to a small degree by accumulated product, and APE1 stimulates multiple turnovers by alleviating product inhibition. These results show that APE1 does not significantly affect the kinetics of base excision by AAG. It is likely that slow excision by AAG limits the rate of AP site formation in vivo such that AP sites are not created faster than can be processed by APE1.     

Correlation of bistranded clustered abasic DNA lesion processing with structural and dynamic DNA helix distortion

Clustered apurinic/apyrimidinic (AP; abasic) DNA lesions produced by ionizing radiation are by far more cytotoxic than isolated AP lesion entities. The structure and dynamics of a series of seven 23-bp oligonucleotides featuring simple bistranded clustered damage sites, comprising of two AP sites, zero, one, three or five bases 3′ or 5′ apart from each other, were investigated through 400 ns explicit solvent molecular dynamics simulations. They provide representative structures of synthetically engineered multiply damage sites-containing oligonucleotides whose repair was investigated experimentally (Nucl. Acids Res. 2004, 32:5609-5620; Nucl. Acids Res. 2002, 30: 2800–2808). The inspection of extrahelical positioning of the AP sites, bulge and non Watson–Crick hydrogen bonding corroborates the experimental measurements of repair efficiencies by bacterial or human AP endonucleases Nfo and APE1, respectively. This study provides unprecedented knowledge into the structure and dynamics of clustered abasic DNA lesions, notably rationalizing the non-symmetry with respect to 3′ to 5′ position. In addition, it provides strong mechanistic insights and basis for future studies on the effects of clustered DNA damage on the recognition and processing of these lesions by bacterial or human DNA repair enzymes specialized in the processing of such lesions.     

Base-excision repair of oxidative DNA damage by DNA glycosylases

Oxidative damage to DNA caused by free radicals and other oxidants generate base and sugar damage, strand breaks, clustered sites, tandem lesions and DNA-protein cross-links. Oxidative DNA damage is mainly repaired by base-excision repair in living cells with the involvement of DNA glycosylases in the first step and other enzymes in subsequent steps. DNA glycosylases remove modified bases from DNA, generating an apurinic/apyrimidinic (AP) site. Some of these enzymes that remove oxidatively modified DNA bases also possess AP-lyase activity to cleave DNA at AP sites. DNA glycosylases possess varying substrate specificities, and some of them exhibit cross-activity for removal of both pyrimidine- and purine-derived lesions. Most studies on substrate specificities and excision kinetics of DNA glycosylases were performed using oligonucleotides with a single modified base incorporated at a specific position. Other studies used high-molecular weight DNA containing multiple pyrimidine- and purine-derived lesions. In this case, substrate specificities and excision kinetics were found to be different from those observed with oligonucleotides. This paper reviews substrate specificities and excision kinetics of DNA glycosylases for removal of pyrimidine- and purine-derived lesions in high-molecular weight DNA.     

An AP site can protect against the mutagenic potential of 8-oxoG when present within a tandem clustered site in E. coli

Ionizing radiation induces clustered DNA damaged sites, defined as two or more lesions formed within one or two helical turns of the DNA through passage of a single radiation track. It is now established that clustered DNA damage sites are found in cells and present a challenge to the repair machinery of the cell but to date, most studies have investigated the effects of bi-stranded lesions. A subset of clustered DNA damaged sites exist in which two or more lesions are present in tandem on the same DNA strand. In this study synthetic oligonucleotides containing an AP site 1, 3 or 5 bases 5' or 3' to 8-oxo-7,8-dihydroguanine (8-oxoG) on the same DNA strand were synthesized as a model of a tandem clustered damaged sites. It was found that 8-oxoG retards the incision of the AP site by exonuclease III (Xth) and formamidopyrimidine DNA glycosylase (Fpg). In addition the rejoining of the AP site by xrs5 nuclear extracts is impaired by the presence of 8-oxoG. The mutation frequency arising from 8-oxoG within a tandem clustered site was determined in both wild type and mutant E. coli backgrounds. In wild-type, nth, fpg and mutY null E. coli, the mutation frequency is slightly elevated when an AP site is in tandem to 8-oxoG, compared with when 8-oxoG is present as a single lesion. Interestingly, in the double mutant mutY/fpg null E. coli, the mutation frequency of 8-oxoG is reduced when an AP site is present in tandem compared with when 8-oxoG is present as a single lesion. This study demonstrates that tandem lesions can present a challenge to the repair machinery of the cell.     

Non-Enzymatic Depurination of Nucleic Acids: Factors and Mechanisms

Depurination has attracted considerable attention since a long time for it is closely related to the damage and repair of nucleic acids. In the present study, depurination using a pool of 30-nt short DNA pieces with various sequences at diverse pH values was analyzed by High Performance Liquid Chromatography (HPLC). Kinetic analysis results showed that non-enzymatic depurination of oligodeoxynucleotides exhibited typical first-order kinetics, and its temperature dependence obeyed Arrhenius’ law very well. Our results also clearly showed that the linear relationship between the logarithms of rate constants and pH values had a salient point around pH 2.5. Interestingly and unexpectedly, depurination depended greatly on the DNA sequences. The depurination of poly (dA) was found to be extremely slow, and thymine rich sequences depurinated faster than other sequences. These results could be explained to some extent by the protonation of nucleotide bases. Moreover, two equations were obtained based on our data for predicting the rate of depurination under various conditions. These results provide basic data for gene mutagenesis and nucleic acids metabolism in acidic gastric juice and some acidic organelles, and may also help to rectify some misconceptions about depurination.     

Excision of 5'-terminal deoxyribose phosphate from damaged DNA is catalyzed by the Fpg protein of Escherichia coli.

Homogeneous Fpg protein of Escherichia coli has DNA glycosylase activity which excises some purine bases with damaged imidazole rings, and an activity excising deoxyribose (dR) from DNA at abasic (AP) sites leaving a gap bordered by 5'- and 3'-phosphoryl groups. In addition to these two reported activities, we show that the Fpg protein also catalyzes the excision of 5'-terminal deoxyribose phosphate (dRp) from DNA, which is the principal product formed by the incision of AP endonucleases at abasic sites. Moreover, the rate of the Fpg protein catalysis for the 2,6-diamino-4-hydroxy-5-formamidopyrimidine-DNA glycosylase activity is slower than the activities excising dR from abasic sites and dRp from abasic sites preincised by endonucleases. The product released by the Fpg protein in the excision of 5'-terminal dRp from an abasic site preincised by an AP endonuclease is a single base-free unsaturated dRp, suggesting that the excision results from beta-elimination. The release of 5'-terminal dRp by crude extracts of E. coli from wild type and fpg-mutant strains shows that the Fpg protein is one of the major EDTA-resistant activities catalyzing this reaction.     

Efficiency of incision of an AP site within clustered DNA damage by the major human AP endonuclease.

A major DNA lesion induced by ionizing radiation and formed on removal of oxidized base lesions by various glycosylases is an apurinic/apyrimidinic site (AP site). The presence of an AP site within clustered DNA damage, induced following exposure to ionizing radiation or radiomimetic anticancer agents, may present a challenge to the repair machinery of the cell, if the major human AP endonuclease, HAP1, does not efficiently incise the AP site. In this study, specific oligonucleotide constructs containing an AP site located at several positions opposite to another damage [5,6-dihydrothymine (DHT), 8-oxoG, AP site, or various types of single strand breaks] on the complementary strand were used to determine the relative efficiency of the purified HAP1 protein in incising an AP site(s) from clustered DNA damage. A base damage (DHT and 8-oxoG) on the opposite strand has little or no influence on the rate of incision of an AP site by HAP1. In contrast, the presence of either a second AP site or various types of single strand breaks, when located one or three bases 3' to the base opposite to the AP site, has a strong inhibitory effect on the efficiency of incision of an AP site. The efficiency of binding of HAP1 to an AP site is reduced by approximately 1 order of magnitude if a single strand break (SSB) is located one or three bases 3' to the site opposite to the AP site on the complementary strand. If the AP site and either a SSB or a second AP site are located at any of the other positions relative to each other, a double strand break may result.