In situ activity gel for DNA repair 3'-phosphodiesterase.

An enzyme that plays an important role in the repair of oxidative DNA damage is the 3'-phosphodiesterase. This activity, which repairs damaged DNA 3'-termini,can be detected using several available biochemical assays. We present a method to detect 3'-phosphodiesterase activity of renatured proteins immobilized in polyacrylamide gels. The model substrate, labeled with [alpha-32P]dCTP, contains 3'-phosphoglycolate termini produced by bleomycin-catalyzed cleavage of the self-complementary alternating copolymer poly(dGdC). The DNA substrate is incorporated into the gel matrix during standard SDS-PAGE. Active 3'-phosphodiesterase enzymes are detected visibly by the loss of radioactivity at a position corresponding to the mobility of the enzyme during SDS-PAGE. Using this procedure, two Escherichia coli 3'-phosphodiesterases, exonuclease III and endonuclease IV, are readily detected in crude cell extracts or as homogeneous purified proteins. Extracts of mutant cells lack activity at the positions of exonuclease III and endonuclease IV but retain activity in the position of a much larger protein (Mr approximately 100 kDa). The identification of this novel 100 kDa E.coli 3'-phosphodiesterase demonstrates the potential value of the activity gel method described here.     

Generation of single-nucleotide repair patches following excision of uracil residues from DNA.

The extent and location of DNA repair synthesis in a double-stranded oligonucleotide containing a single dUMP residue have been determined. Gently prepared Escherichia coli and mammalian cell extracts were employed for excision repair in vitro. The size of the resynthesized patch was estimated by restriction enzyme analysis of the repaired oligonucleotide. Following enzymatic digestion and denaturing gel electrophoresis, the extent of incorporation of radioactively labeled nucleotides in the vicinity of the lesion was determined by autoradiography. Cell extracts of E. coli and of human cell lines were shown to carry out repair mainly by replacing a single nucleotide. No significant repair replication on the 5' side of the lesion was observed. The data indicate that, after cleavage of the dUMP residue by uracil-DNA glycosylase and incision of the resultant apurinic-apyrimidinic site by an apurinic-apyrimidinic endonuclease activity, the excision step is catalyzed usually by a DNA deoxyribophosphodiesterase rather than by an exonuclease. Gap-filling and ligation complete the repair reaction. Experiments with enzyme inhibitors in mammalian cell extracts suggest that the repair replication step is catalyzed by DNA polymerase beta.     

Excision repair of pyrimidine dimers from simian virus 40 minichromosomes in vitro

The ability of DNA repair enzymes to carry out excision repair of pyrimidine dimers in SV40 minichromosomes irradiated with 16 to 64 J/m2 of UV light was examined. Half of the dimers were substrate for the DNA glycosylase activity of phage T4 UV endonuclease immediately after irradiation, but this limit decreased to 27% after 2 h at 0 degrees C. Moreover, the apyrimidinic (AP) endonuclease activity of the enzyme did not incise all of the AP sites created by glycosylase activity, although all AP sites were substrate for HeLa AP endonuclease II. The initial rate of the glycosylase was 40% that upon DNA. After incision by the T4 enzyme, excision was mediated by HeLa DNase V (acting with an exonuclease present in the chromatin preparation). Under physiological salt conditions, excision did not proceed appreciably beyond the damaged nucleotides in DNA or chromatin. With chromatin, about 70% of the accessible dimers were removed, but at a rate slower than for DNA. Finally, HeLa DNA polymerase beta was able to fill the short gaps created after dimer excision, and these patches were sealed by T4 DNA ligase. Overall, roughly 30% of the sites incised by the endonuclease were ultimately sealed by the ligase. The resistance of some sites was due to interference with the ligase by the chromatin structure, as only 30-40% of the nicks created in chromatin by pancreatic DNase could be sealed by T4 or HeLa DNA ligases. The overall excision repair process did not detectably disrupt the chromatin structure, since the repair label was recovered in Form I DNA present in 75 S condensed minichromosomes. Although other factors might stimulate the rate of this repair process, it appears that the enzymes utilized could carry out excision repair of chromatin to a limit near that observed at the initial rate in mammalian cells in vivo.     

Early steps of excision repair of cyclobutane pyrimidine dimers by the Micrococcus luteus endonuclease. A three-step incision model

The early steps of excision repair of cyclobutane pyrimidine dimers are investigated. It is demonstrated that the apurinic/apyrimidinic endonuclease associated with the Micrococcus luteus uv-specific endonuclease cleaves the phosphodiester bond on the 3' side of the deoxyribose leaving a 3' hydroxy terminus and a 5' phosphoryl terminus. This nick is not a substrate for T4 polynucleotide ligase. The 3' base-free deoxyribose terminus is not a substrate for either the polymerase or the 3' to 5' exonuclease activities of Escherichia coli DNA polymerase I. However, the 3' terminus of the nick is converted to a substrate for DNA polymerization by the action of a 5' apurinic/apyrimidinic endonuclease. A three-step model for the incision step of excision repair of cyclobutane pyrimidine dimers is presented.     

Excision repair of DNA base damage

Exposure of cells to exogenous physical and chemical agents can result in damage to the DNA bases. DNA damage can lead to mutation, malignant transformation and cell death and may possibly be involved in cellular aging. Structurally related base modifications are expected to have similar biological effects regardless of the agent responsible for their formation. The biological effects may be a consequence of the local distortion of the DNA conformation by the lesion rather than of the chemical properties of the modified base $\text{per se}$. It may be useful, therefore, to classify DNA base damage according to their effect on DNA conformation. The elucidation of the structures of the DNA lesions produced $\text{in situ}$ in the living cell represents a prerequisite for the correlation of specific lesions with the biological effects and for the study of the cellular repair processes.Excision repair represents an ubiquitous mechanism in cells for the removal of damaged residues from the DNA. The most specific first step in excision repair is the recognition of the damage by an endonuclease followed by incision of the damaged DNA strand in the proximity of the damage. Several “repair endonucleases” have been characterized from bacteria while the search for the corresponding mammalian enzymes is only beginning. The second, probably less specific step, is the exonucleolytic degradation of the damaged portion of the DNA leading to the removal of the damaged residue. In $\text{E. coli}$ the removal of both cyclobutane-type photodimers and γ-ray products of the 5,6-dihydroxy-dihydrothymine type is accomplished by the 5′→3′ exonuclease associated with polymerase I. All three $\text{E. coli}$ polymerases appear to participate in the rebuilding of the degraded portion of the DNA. Studies on the corresponding enzymes in mammalian cells have been initiated. The last step of exicison repair involves the sealing of a phosphodiester bond of the DNA backbone and is accomplished by the enzyme polynucleotide ligase in bacterial and mammalian cells.     

Enzymes involved in the repair of damaged DNA

The multitude of enzymes responsible for removing damaged nucleotides from DNA in an error-free manner is reviewed. The most direct mechanisms include enzymatically catalyzed photoreversal of cyclobutane dimers and the removal of the O⁶-methylguanine adduct from alkylated DNA by an enzyme whose presence is dependent on adaptation. The direct removal of either damaged purines or pyrimidines or partial removal of photochemically induced diadducts is catalyzed by DNA glycosylases in the absence of phosphodiester bond hydrolysis. Incision of DNA containing apurinic or apyrimidinic sites arising either spontaneously or by the action of DNA glycosylases is catalyzed by specific endonucleases. The incision of DNA containing bulky adducts is attributed to a multigenically controlled uvr system in Escherichia coli. The mechanisms of damaged nucleotide excision and reinsertion of nucleotides are controlled by unique exonuclease functions in either direct or indirect association with DNA polymerases.     

Repair of oxidative DNA damage

Cellular genomes suffer extensive damage from exogenous agents and reactive oxygen species formed during normal metabolism. The MutT homologs (MutT/MTH) remove oxidized nucleotide precursors so that they cannot be incorporated into DNA during replication. Among many repair pathways, the base excision repair (BER) pathway is the most important cellular protection mechanism responding to oxidative DNA damage. The 8-oxoG glycosylases (Fpg or MutM/OGG) and the MutY homologs (MutY/MYH) glycosylases along with MutT/MTH protect cells from the mutagenic effects of 8-oxoG, the most stable and deleterious product known caused by oxidative damage to DNA. The key enzymes in the BER process are DNA glycosylases, which remove different damaged bases by cleavage of the N-glycosylic bonds between the bases and the deoxyribose moieties of the nucleotide residues. Biochemical and structural studies have demonstrated the substrate recognition and reaction mechanism of BER enzymes. Cocrystal structures of strated the substrate recognition and reaction mechanism of BER enzymes. Cocrystal structures of several glycosylases show that the substrate base flips out of the sharply bent DNA helix and the minor groove is widened to be accessed by the glycosylases. To complete the repair after glycosylase action, the apurinic/apyrimidinic (AP) site is further processed by an incision step, DNA synthesis, an excision step, and DNA ligation through two alternative pathways. The short-patch BER (1-nucleotide patch size) and long-patch BER (2–6-nucleotide patch size) pathways need AP endonuclease to generate a 3′ hydroxyl group but require different sets of enzymes for DNA synthesis and ligation. Protein-protein interactions have been reported among the enzymes involved in BER. It is possible that the successive players in the repair pathway are assembled in a complex to perform concerted actions. The BER pathways are proposed to protect cells and organisms from mutagenesis and carcinogenesis.     

Magnesium, essential for base excision repair enzymes, inhibits substrate binding of N-methylpurine-DNA glycosylase

N-Methylpurine-DNA glycosylase (MPG) initiates base excision repair in DNA by removing a wide variety of alkylated, deaminated, and lipid peroxidation-induced purine adducts. MPG activity and other DNA glycosylases do not have an absolute requirement for a cofactor. In contrast, all downstream activities of major base excision repair proteins, such as apurinic/apyrimidinic endonuclease, DNA polymerase beta, and ligases, require Mg(2+). Here we have demonstrated that Mg(2+) can be significantly inhibitory toward MPG activity depending on its concentration but independent of substrate type. The pre-steady-state kinetics suggests that Mg(2+) at high but physiologic concentrations decreases the amount of active enzyme concentrations. Steady-state inhibition kinetics showed that Mg(2+) affected K(m), but not V(max), and the inhibition could be reversed by EDTA but not by DNA. At low concentration, Mg(2+) stimulated the enzyme activity only with hypoxanthine but not ethenoadenine. Real-time binding experiments using surface plasmon resonance spectroscopy showed that the pronounced inhibition of activity was due to inhibition in substrate binding. Nonetheless, the glycosidic bond cleavage step was not affected. These results altogether suggest that Mg(2+) inhibits MPG activity by abrogating substrate binding. Because Mg(2+) is an absolute requirement for the downstream activities of the major base excision repair enzymes, it may act as a regulator for the base excision repair pathway for efficient and balanced repair of damaged bases, which are often less toxic and/or mutagenic than their subsequent repair product intermediates.     

Properties of damage-dependent DNA incision by nucleotide excision repair in human cell-free extracts.

Nucleotide excision repair (NER) is the primary mechanism for the removal of many lesions from DNA. This repair process can be broadly divided in two stages: first, incision at damaged sites and second, synthesis of new DNA to replace the oligonucleotide removed by excision. In order to dissect the repair mechanism, we have recently devised a method to analyze the incision reaction in vitro in the absence of repair synthesis (1). Damage-specific incisions take place in a repair reaction in which mammalian cell-free extracts are mixed with undamaged and damaged plasmids. Most of the incision events are accompanied by excision. Using this assay, we investigated here various parameters that specifically affect the level of damage-dependent incision activity by cell-free extracts in vitro. We have defined optimal conditions for the reaction and determined the kinetics of the incision with cell-free extracts from human cells. We present direct evidence that the incision step of NER is ATP-dependent. In addition, we observe that Mn2+ but no other divalent cation can substitute for Mg2+ in the incision reaction.     

Repair of N-methyl-N''-nitro-N-nitrosoguanidine-induced DNA damage by ABC excinuclease.

Escherichia coli has several overlapping DNA repair pathways which act in concert to eliminate the DNA damage caused by a diverse array of physical and chemical agents. The ABC excinuclease which is encoded by the uvrA, uvrB, and uvrC genes mediates both the incision and excision steps of nucleotide excision repair. Traditionally, this repair pathway has been assumed to be active against DNA adducts that cause major helical distortions. To determine the level of helical deformity required for recognition and repair by ABC excinuclease, we have evaluated the substrate specificity of this enzyme by using DNA damaged by N-methyl-N'-nitro-N-nitrosoguanidine. ABC excinuclease incised methylated DNA in vitro in a dose-dependent manner in a reaction that was ATP dependent and specific for the fully reconstituted enzyme. In vivo studies with various alkylation repair-deficient mutants indicated that the excinuclease participated in the repair of DNA damage induced by N-methyl-N'-nitro-N-nitrosoguanidine.     

The DNA trackwalkers: principles of lesion search and recognition by DNA glycosylases

DNA glycosylases, the pivotal enzymes in base excision repair, are faced with the difficult task of recognizing their substrates in a large excess of unmodified DNA. We present here a kinetic analysis of DNA glycosylase substrate specificity, based on the probability of error. This novel approach to this subject explains many features of DNA surveillance and catalysis of lesion excision by DNA glycosylases. This approach also is applicable to the general issue of substrate specificity. We discuss determinants of substrate specificity in damaged DNA and in the enzyme, as well as methods by which these determinants can be identified.     

Major oxidative products of cytosine are substrates for the nucleotide incision repair pathway

Most common point mutations occurring spontaneously or induced by ionizing radiation are C-->T transitions implicating cytosine as the target. Oxidative cytosine derivatives are the most abundant and mutagenic DNA damage induced by oxidative stress. Base excision repair (BER) pathway initiated by DNA glycosylases is thought to be the major pathway for the removal of these lesions. However, in alternative nucleotide incision repair (NIR) pathway the apurinic/apyrimidinic (AP) endonucleases incise DNA duplex 5' to an oxidatively damaged base in a DNA glycosylase-independent manner. Here, we characterized the substrate specificity of human major AP endonuclease, Ape1, towards 5-hydroxy-2'-deoxycytidine (5ohC) and alpha-anomeric 2'-deoxycytidine (alphadC) residues. The apparent kinetic parameters of the reactions suggest that Ape1 and the DNA glycosylases/AP lyases, hNth1 and hNeil1 repair 5ohC with a low efficiency. Nevertheless, due to the extremely high cellular concentration of Ape1, NIR was the major activity towards 5ohC in cell-free extracts. To address the physiological role of NIR function, we have characterized naturally occurring Ape1 variants including amino acids substitutions (E126A, E126D and D148E) and N-terminal truncated forms (NDelta31, NDelta35 and NDelta61). As expected, all Ape1 mutants had proficient AP endonuclease activity, however, truncated forms showed reduced NIR and 3'-->5' exonuclease activities indicating that these two functions are genetically linked and governed by the same amino acid residues. Furthermore, both Ape1-catalyzed NIR and 3'-->5' exonuclease activities generate a single-strand gap at the 5' side of a damaged base but not at an AP site in duplex DNA. We hypothesized that biochemical coupling of the nucleotide incision and exonuclease degradation may serve to remove clustered DNA damage. Our data suggest that NIR is a backup system for the BER pathway to remove oxidative damage to cytosines in vivo.     

Nickel impairs the repair of UV- and MNNG-damaged DNA

Nickel(II) is reported to be genotoxic, but the mechanisms underlying its genotoxicity are largely unknown. It can interfere with DNA repair and this may contribute to its genotoxicity. We studied the effect of nickel chloride on the repair of DNA damaged by UV radiation or N-methyl-N-nitro-N-nitrosoguanidine (MNNG) in human lymphocytes using the alkaline comet assay. Nickel(II) at 1 microM caused an accumulation of DNA breaks during repair incubation, which could follow from the inhibition of the polymerization/ligation step of UV-damaged DNA repair. On the other hand, nickel(II) inhibited the formation of transient DNA breaks brought by the repair process after incubation with MNNG at 5 microM, which might follow from interference with the recognition/incision step of excision repair. Additionally, nickel at 1 microM inhibited the activity of formamidopyrimidine-DNA glycosylase (Fpg) and 3-methyladenine-DNA glycosylase II (Alk A), enzymes involved in DNA excision repair. A decrease in endonuclease III (Endo III) activity was observed at 2 and 5 microM of nickel chloride. Our results suggest that nickel(II) at non-cytotoxic concentrations can inhibit various steps of DNA excision repair, and this may contribute to its genotoxicity.     

DNA damage excision repair in microplate wells with chemiluminescence detection: development and perspectives

The development of in vitro repair assays with human cell-free extracts led to new insights on the mechanism of excision of DNA damage which consists of incision/excision and repair synthesis/ligation. We have adapted the repair synthesis reaction with cells extracts incubated with damaged plasmid DNA performed in liquid phase to solid phase by DNA adsorption into microplate wells. Since cells extracts are repair competent in base excision and nucleotide excision repair, all types of substrate DNA lesions were detected with chemiluminescence measurement after incorporation of biotin-deoxynucleotide during the repair synthesis step. Derivatives of our initial 3D-assay (DNA damage detection) have been set up to: i) screen antioxidative compounds and NER inhibitors; ii) capture genomic DNA (3D(Cell)-assay) that allows detection of alkylated base and consequently determines the kinetics of the cellular repair; and iii) immunodetect the repair proteins in an ELISA reaction (3D(Rec)-assay). The 3D derived assays are presented and discussed.     

Characterization of DNA metabolizing enzymes in situ following polyacrylamide gel electrophoresis

We have detected the in situ activities of DNA glycosylase, endonuclease, exonuclease, DNA polymerase, and DNA ligase using a novel polyacrylamide activity gel electrophoresis procedure. DNA metabolizing enzymes were resolved through either native or SDS-polyacrylamide gels containing defined 32P-labeled oligonucleotides annealed to M13 DNA. After electrophoresis, these enzymes catalyzed in situ reactions and their [32P]DNA products were resolved from the gel by a second dimension of electrophoresis through a denaturing DNA sequencing gel. Detection of modified (degraded or elongated) oligonucleotide chains was used to locate various enzyme activities. The catalytic and physical properties of Novikoff hepatoma DNA polymerase beta were found to be similar under both in vitro and in situ conditions. With 3'-terminally matched and mismatched [32P]DNA substrates in the same activity gel, DNA polymerase and/or 3' to 5' exonuclease activities of Escherichia coli DNA polymerase I (large fragment), DNA polymerase III (holoenzyme), and exonuclease III were detected and characterized. In addition, use of matched and mismatched DNA primers permitted the uncoupling of mismatch excision and chain extension steps. Activities first detected in nondenaturing activity gels as either multifunctional or multimeric enzymes were also identified in denaturing activity gels, and assignment of activities to specific polypeptides suggested subunit composition. Furthermore, DNA substrates cast within polyacrylamide gels were successfully modified by the exogenous enzymes polynucleotide kinase and alkaline phosphatase before and after in situ detection of E. coli DNA ligase activity, respectively. Several restriction endonucleases and the tripeptide (Lys-Trp-Lys), which acts as an apurinic/apyrimidinic endonuclease, were able to diffuse into gels and modify DNA. This ability to create intermediate substrates within activity gels could prove extremely useful in delineating the steps of DNA replication and repair pathways.     

Eukaryotic endonuclease VIII-Like proteins: New components of the base excision DNA repair system

Base excision DNA repair is necessary for removal of damaged nucleobases from the genome and their replacement with normal nucleobases. Base excision repair is initiated by DNA glycosylases, the enzymes that cleave the N-glycosidic bonds of damaged deoxynucleotides. Until recently, only eight DNA glycosylases with different substrate specificity were known in human cells. In 2002, three new human DNA glycosylases (NEIL1, NEIL2, and NEIL3) were discovered, all homologous to endonuclease VIII, a bacterial protein, which also participates in DNA repair. The role of these enzymes remains mostly unknown. In this review we discuss recent data on the substrate specificity of the NEIL enzymes, their catalytic mechanism, structure, interactions with other components of DNA repair system, and possible biological role in preventing diseases associated with DNA damage.     

Excision repair of adozelesin-N3 adenine adduct by 3-methyladenine-DNA glycosylases and UvrABC nuclease

Adozelesin is a synthetic analog of the antitumor antibiotic CC-1065, which alkylates the N3 of adenine in the minor groove in a sequence-selective manner. Since the cytotoxic potency of a DNA alkylating agent can be modulated by DNA excision repair system, we investigated whether nucleotide excision repair (NER) and base excision repair (BER) enzymes are able to excise the bulky DNA adduct induced by adozelesin. The UvrABC nuclease and 3-methyladenine-DNA glycosylase, that exhibit a broad spectrum of substrate specificity, were selected as typical NER and BER enzymes, respectively. The adozelesin-DNA adduct was first formed in the radiolabeled restriction DNA fragment and its excision by purified repair enzymes was monitored on a DNA sequencing gel. The treatment of the DNA adduct with a purified UvrABC nuclease and sequencing gel analysis of cleaved DNA showed that UvrABC nuclease was able to incise the adozelesin adduct. The incision site corresponded to the general nuclease incision site. Excision of this adduct by 3-methyladenine-DNA glycosylases was determined following the treatment of the DNA adduct with a homogeneous recombinant bacterial, rat and human 3-methyladenine-DNA glycosylases. Abasic sites generated by DNA glycosyalses were cleaved by the associated lyase activity of the E. coli formamidopyrimidine-DNA glycosylase (Fpg). Resolution of cleaved DNA on a sequencing gel showed that the DNA glycosylase from different sources could not release the N3-adenine adducts. A cytotoxicity assay using E. coli repair mutant strains showed that E. coli mutant strains defective in the uvrA gene were more sensitive to cell killing by adozelesin than E. coli mutant strain defective in the alkA gene or the wild type. These results suggest that the NER pathway seems to be the major excision repair system in protecting cells from the cytotoxicity of adozelesin.     

A mouse DNA repair enzyme (APEX nuclease) having exonuclease and apurinic/apyrimidinic endonuclease activities: purification and characterization.

A mouse repair enzyme having priming activity on bleomycin-damaged DNA for DNA polymerase was purified to apparent homogeneity and characterized. The enzyme extracted from permeabilized mouse ascites sarcoma (SR-C3H/He) cells with 0.2 M potassium phosphate buffer (pH 7.5) was purified by successive chromatographies on phosphocellulose, DEAE-cellulose, phosphocellulose (a second time), Sephadex G-100, single-stranded DNA cellulose and hydroxyapatite. The purified enzyme has an Mr of 34,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Enzymatical studies indicated that it is a multifunctional enzyme having exonuclease, apurinic/apyrimidinic endonuclease and phosphatase activities, similar to Escherichia coli exonuclease III. This enzyme is tentatively designated as APEX nuclease for apurinic/apyrimidinic endonuclease and exonuclease activities. The amino acid composition, amino-terminal amino acid sequence and an internal amino acid sequence of APEX nuclease are determined.