Effects of the C4'-oxidized abasic site on replication in Escherichia coli. An unusually large deletion is induced by a small lesion

Intracellular Formation of a DNA Damage-Induced, Histone Post-Translational Modification Following Bleomycin Treatment

Evaluating the significance of various forms of DNA damage is complicated by discoveries that some lesions inactivate repair enzymes or produce more deleterious forms of damage. Histone lysines within nucleosomes react with the commonly produced C4'-oxidized abasic site (C4-AP) to concomitantly yield an electrophilic modification (K_MP) on lysine and DNA strand scission. We developed a chemoproteomic approach to identify K_MP in HeLa cells. More than 60 000 K_MP-modified histones are produced per cell. Using LC-MS/MS, we detected K_MP at 17 of the 57 lysine residues distributed throughout the four core histone proteins. Therefore, K_MP constitutes a DNA damage-induced, nonenzymatic histone post-translational modification. K_MP formation suggests that downstream processes resulting from DNA damage could have ramifications on cells.

The A-Rule and Deletion Formation During Abasic and Oxidized Abasic Site Bypass by DNA Polymerase θ

DNA polymerase θ (Pol θ) is implicated in various cellular processes including double-strand break repair and apurinic/apyrimidinic site bypass. Because Pol θ expression correlates with poor cancer prognosis, the ability of Pol θ to bypass the C4'-oxidized abasic site (C4-AP) and 2-deoxyribonolactone (L), which are generated by cytotoxic agents, is of interest. Translesion synthesis and subsequent extension by Pol θ past C4-AP or L and an abasic site (AP) or its tetrahydrofuran analogue (F) was examined. Pol θ conducts translesion synthesis on templates containing AP and F with similar efficiencies and follows the "A-rule," inserting nucleotides in the order A > G > T. Translesion synthesis on templates containing C4-AP and L is less efficient than AP and F, and the preference for A insertion is reduced for L and absent for C4-AP. Extension past all abasic lesions (AP, F, C4-AP, and L) was significantly less efficient than translesion synthesis and yielded deletions caused by the base one or two nucleotides downstream from the lesion being used as a template, with the latter being favored. These results suggest that bypass of abasic lesions by Pol θ is highly mutagenic.

Mutagenic Bypass of an Oxidized Abasic Lesion-Induced DNA Interstrand Cross-Link Analogue by Human Translesion Synthesis DNA Polymerases

5'-(2-Phosphoryl-1,4-dioxobutane) (DOB) is an oxidized abasic site that is produced by several antitumor agents and γ-radiolysis. DOB reacts reversibly with a dA opposite the 3'-adjacent nucleotide to form DNA interstrand cross-links (ICLs), genotoxic DNA lesions that can block DNA replication and transcription. Translesion synthesis (TLS) is an important step in several ICL repair pathways to bypass unhooked intermediates generated by endonucleolytic incision. The instability of DOB-ICLs has made it difficult to learn about their TLS-mediated repair capability and mutagenic potential. We recently developed a method for chemically synthesizing oligonucleotides containing a modified DOB-ICL analogue. Herein, we examined the capabilities of several highly relevant eukaryotic TLS DNA polymerases (pols), including human pol η, pol κ, pol ι, pol ν, REV1, and yeast pol ζ, to bypass this DOB-ICL analogue. The prelesion, translesion, and postlesion replication efficiency and fidelity were examined. Pol η showed moderate bypass activity when encountering the DOB-ICL, giving major products one or two nucleotides beyond the cross-linked template nucleotide. In contrast, DNA synthesis by the other pols was stalled at the position before the cross-linked nucleotide. Steady-state kinetic data and liquid chromatography-mass spectrometry sequencing of primer extension products by pol η unambiguously revealed that pol η-mediated bypass is highly error-prone. Together, our study provides the first set of in vitro evidence that the DOB-ICL is a replication-blocking and highly miscoding lesion. Compared to several other TLS pols examined, pol η is likely to contribute to the TLS-mediated repair of the DOB-ICL in vivo.

Rapid Histone-Catalyzed DNA Lesion Excision and Accompanying Protein Modification in Nucleosomes and Nucleosome Core Particles

C5'-Hydrogen atoms are frequently abstracted during DNA oxidation. The oxidized abasic lesion 5'-(2-phosphoryl-1,4-dioxobutane) (DOB) is an electrophilic product of the C5'-radical. DOB is a potent irreversible inhibitor of DNA polymerase β, and forms interstrand cross-links in free DNA. We examined the reactivity of DOB within nucleosomes and nucleosome core particles (NCPs), the monomeric component of chromatin. Depending upon the position at which DOB is generated within a NCP, it is excised from nucleosomal DNA at a rate 275-1500-fold faster than that in free DNA. The half-life of DOB (7.0-16.8 min) in NCPs is shorter than any other abasic lesion. DOB's lifetime in NCPs is also significantly shorter than the estimated lifetime of an abasic site within a cell, suggesting that the observed chemistry would occur intracellularly. Histones also catalyze DOB excision when the lesion is present in the DNA linker region of a nucleosome. Schiff-base formation between DOB and histone proteins is detected in nucleosomes and NCPs, resulting in pyrrolone formation at the lysine residues. The lysines modified by DOB are often post-translationally modified. Consequently, the histone modifications described herein could affect the regulation of gene expression and may provide a chemical basis for the cytotoxicity of the DNA damaging agents that produce this lesion.

Oxidatively induced DNA damage and its repair in cancer

Oxidatively induced DNA damage is caused in living organisms by endogenous and exogenous reactive species. DNA lesions resulting from this type of damage are mutagenic and cytotoxic and, if not repaired, can cause genetic instability that may lead to disease processes including carcinogenesis. Living organisms possess DNA repair mechanisms that include a variety of pathways to repair multiple DNA lesions. Mutations and polymorphisms also occur in DNA repair genes adversely affecting DNA repair systems. Cancer tissues overexpress DNA repair proteins and thus develop greater DNA repair capacity than normal tissues. Increased DNA repair in tumors that removes DNA lesions before they become toxic is a major mechanism for development of resistance to therapy, affecting patient survival. Accumulated evidence suggests that DNA repair capacity may be a predictive biomarker for patient response to therapy. Thus, knowledge of DNA protein expressions in normal and cancerous tissues may help predict and guide development of treatments and yield the best therapeutic response. DNA repair proteins constitute targets for inhibitors to overcome the resistance of tumors to therapy. Inhibitors of DNA repair for combination therapy or as single agents for monotherapy may help selectively kill tumors, potentially leading to personalized therapy. Numerous inhibitors have been developed and are being tested in clinical trials. The efficacy of some inhibitors in therapy has been demonstrated in patients. Further development of inhibitors of DNA repair proteins is globally underway to help eradicate cancer.

Abasic and oxidized abasic site reactivity in DNA: enzyme inhibition, cross-linking, and nucleosome catalyzed reactions

Abasic lesions are a family of DNA modifications that lack Watson-Crick bases. The parent member of this family, the apurinic/apyrimidinic lesion (AP), occurs as an intermediate during DNA repair, following nucleobase alkylation, and from random hydrolysis of native nucleotides. In a given day, each cell produces between 10000 and 50000 AP lesions. A variety of oxidants including γ-radiolysis produce oxidized abasic sites, such as C4-AP, from the deoxyribose backbone. A number of potent, cytotoxic antitumor agents, such as bleomycin and the enediynes (e.g., calicheamicin, esperamicin, and neocarzinostatin) also lead to oxidized abasic sites in DNA. The absence of Watson-Crick bases prevents DNA polymerases from properly determining which nucleotide to incorporate opposite abasic lesions. Consequently, several studies have revealed that (oxidized) abasic sites are highly mutagenic. Abasic lesions are also chemically unstable, are prone to strand scission, and possess electrophilic carbonyl groups. However, researchers have only uncovered the consequences of the inherent reactivity of these electrophiles within the past decade. The development of solid phase synthesis methods for oligonucleotides that both place abasic sites in defined positions and circumvent their inherent alkaline lability has facilitated this research. Chemically synthesized oligonucleotides containing abasic lesions provide substrates that have allowed researchers to discover a range of interesting chemical properties of potential biological importance. For instance, abasic lesions form DNA-DNA interstrand cross-links, a particularly important family of DNA damage because they block replication and transcription absolutely. In addition, bacterial repair enzymes can convert an interstrand cross-link derived from C4-AP into a double-strand break, the most deleterious form of DNA damage. Oxidized abasic lesions can also inhibit DNA repair enzymes that remove damaged nucleotides. DNA polymerase β, an enzyme that is irreversibly inactivated, is vitally important in base excision repair and is overproduced in some tumor cells. Nucleosome core particles, the monomeric components that make up chromatin, accentuate the chemical instability of abasic lesions. In experiments using synthetic nucleosome core particles containing abasic sites, the histone proteins catalyze strand cleavage at the sites that incorporate these lesions. Furthermore, in the presence of the C4-AP lesion, strand scission is accompanied by modification of the histone protein. The reactivity of (oxidized) abasic lesions illustrates how seemingly simple nucleic acid modifications can have significant biochemical effects and may provide a chemical basis for the cytotoxicity of the chemotherapeutic agents that produce them.

Histone modification via rapid cleavage of C4'-oxidized abasic sites in nucleosome core particles

The C4'-oxidized abasic site is produced in DNA by a variety of oxidizing agents, including potent cytotoxic antitumor agents. Independent generation of this alkali-labile lesion at defined positions within nucleosome core particles reveals that the histone proteins increase strand scission between 130- and 550-fold. Strand scission proceeds via a Schiff base intermediate, but the DNA-protein cross-links are unstable. The oxidized abasic site is removed in its entirety from the DNA and transferred to the lysine-rich tail region of the proximal histone protein in the form of a lactam. The modification is distributed over several residues within the amino-terminal tail of the proximal histone. Transfer of DNA damage to histones could affect gene regulation.

DNA polymerase λ inactivation by oxidized abasic sites

Base excision repair (BER) plays a vital role in maintaining genomic integrity in mammalian cells. DNA polymerase λ (Pol λ) is believed to play a backup role to DNA polymerase β (Pol β) in base excision repair. Two oxidized abasic lesions that are produced by a variety of DNA-damaging agents, including several antitumor antibiotics, the C4'-oxidized abasic site following Ape1 incision (pC4-AP), and 5'-(2-phosphoryl-1,4-dioxobutane) (DOB), irreversibly inactivate Pol β and Pol λ. The interactions of DOB and pC4-AP with Pol λ are examined in detail using DNA substrates containing these lesions at defined sites. Single-turnover kinetic experiments show that Pol λ excises DOB almost 13 times more slowly than a 5'-phosphorylated 2-deoxyribose (dRP). pC4-AP is excised approximately twice as fast as DOB. The absolute rate constants are considerably slower than those reported for Pol β for the respective reactions, suggesting that Pol λ may be an inefficient backup in BER. DOB inactivates Pol λ approximately 3-fold less efficiently than it does Pol β, and the difference can be attributed to a higher K(I) (33 ± 7 nM). Inactivation of Pol λ's lyase activity by DOB also prevents the enzyme from conducting polymerization following preincubation of the protein and DNA. Mass spectral analysis of GluC-digested Pol λ inactivated by DOB shows that Lys324 is modified. There is inferential support for the idea that Lys312 may also be modified. Both residues are within the Pol λ lyase active site. When acting on pC4-AP, Pol λ achieves approximately four turnovers on average before being inactivated. Lyase inactivation by pC4-AP is also accompanied by loss of polymerase activity, and mass spectrometry indicates that Lys312 and Lys324 are modified by the lesion. The ability of DOB and pC4-AP to inactivate Pol λ provides additional evidence that these lesions are significant sources of the cytotoxicity of DNA-damaging agents that produce them.

Probing DNA interstrand cross-link formation by an oxidized abasic site using nonnative nucleotides

The C4'-oxidized abasic site (C4-AP) forms two types of interstrand cross-links with the adjacent nucleotides in DNA. Previous experiments revealed that dG does not react with the lesion and that formation of one type of cross-link is catalyzed by the opposing dA. iso-Guanosine·dC and 2-aminopurine·dT base pairs were used to determine why dG does not cross-link with C4-AP despite its well known reactivity with other bis-electrophiles. 7-Deaza-2'-deoxyadenosine was used to probe the role of the nucleotide opposite C4-AP in the catalysis of interstrand cross-link formation.

Long patch base excision repair compensates for DNA polymerase β inactivation by the C4'-oxidized abasic site

The C4'-oxidized abasic site (C4-AP), which is produced by a variety of damaging agents, has significant consequences for DNA. The lesion is highly mutagenic and reactive, resulting in interstrand cross-links. The base excision repair of DNA containing independently generated C4-AP was examined. C4-AP is incised by Ape1 ~12-fold less efficiently than an apurinic/apyrimidinic lesion. DNA polymerase β induces the β-elimination of incised C4-AP in ternary complexes, duplexes, and single-stranded substrate. However, excision from a ternary complex is most rapid. In addition, the lesion inactivates the enzyme after approximately seven turnovers on average by reacting with one or more lysine residues in the lyase active site. Unlike 5'-(2-phosphoryl-1,4-dioxobutane), which very efficiently irreversibly inhibits DNA polymerase β, the lesion is readily removed by strand displacement synthesis conducted by the polymerase in conjunction with flap endonuclease 1. DNA repair inhibition by C4-AP may be a partial cause of the cytotoxicity of drugs that produce this lesion.

Tandem mass spectrometry-based detection of c4'-oxidized abasic sites at specific positions in DNA fragments

Oxidative damage to DNA has been linked to aging, cancer, and other biological processes. Reactive oxygen species and various antitumor agents including bleomycin and ionizing radiation have been shown to cause oxidative DNA sugar damage. Detection of DNA lesions is important for understanding the toxicological or therapeutic consequences associated with such agents. C4'-oxidized abasic sites (C4-AP) are produced by the antitumor drug bleomycin and ionizing radiation. The currently available methods for the detection of C4-AP cannot provide both structural and sequence information. We have developed an LC-ESI-MS-based approach for specific detection and mapping of C4-AP from a mixture of lesions. We show using Fe-bleomycin-damaged DNA that C4-AP can be detected at cytosine and thymine sites by direct MS analysis. Our results reveal that collision-induced dissociation of C4-AP-containing oligonucleotides results in preferential fragmentation at C4-AP sites with the formation of the unique a* ions (18 amu more than the a-B ions) that allow mapping of the C4-AP sites. Various chemical modification strategies (e.g., reduction with NaBH4 and NaBD4 and derivatization with methoxyamine and hydrazine, followed by LC-MS analysis) were also used for unambiguous detection of C4-AP sites. Finally, we show that the methods described here can detect the presence of C4-AP at specific sites in a complex sample such as hydroxyl radical-damaged DNA. The LC-MS approach was also used for the simultaneous detection of the other C4'-oxidation end product, 3'-phosphoglycolate, at a specific site in hydroxyl radical-damaged DNA. Thus, LC-MS provides a rapid and direct approach for the detection and mapping of oxidative DNA lesions.

The mutagenicity of thymidine glycol in Escherichia coli is increased when it is part of a tandem lesion

Tandem lesions are comprised of two contiguously damaged nucleotides. Tandem lesions make up the major family of reaction products generated from a pyrimidine nucleobase radical, which are formed in large amounts by ionizing radiation. One of these tandem lesions contains a thymidine glycol lesion flanked on its 5'-side by 2-deoxyribonolactone (LTg). The replication of this tandem lesion was investigated in Escherichia coli using single-stranded genomes. LTg is a much more potent replication block than thymidine glycol and is bypassed only under SOS-induced conditions. The adjacent thymidine glycol does not significantly affect nucleotide incorporation opposite 2-deoxyribonolactone in wild-type cells. In contrast, the misinsertion frequency opposite thymidine glycol, which is negligible in the absence of 2-deoxyribonolactone, increases to 10% in wild-type cells when LTg is flanked by a 3'-dG. Experiments in which the flanking nucleotides are varied and in cells lacking one of the SOS-induced bypass polymerases indicate that the mutations are due to a mechanism in which the primer misaligns prior to bypassing the lesion, which allows for an additional nucleotide to be incorporated across from the 3'-flanking nucleotide. Subsequent realignment and extension results in the observed mutations. DNA polymerases II and IV are responsible for misalignment induced mutations and compete with DNA polymerase V which reads through the tandem lesion. These experiments reveal that incorporation of the thymidine glycol into a tandem lesion indirectly induces increases in mutations by blocking replication, which enables the misalignment-realignment mechanism to compete with direct bypass by DNA polymerase V.

Hydrogen bonding contributes to the selectivity of nucleotide incorporation opposite an oxidized abasic lesion

The ability of DNA polymerases to maintain the integrity of the genome even after it has been structurally altered is vital. There is considerable interest in determining the structural properties of the DNA template that polymerases recognize when determining which nucleotide to add to a nascent strand. Mechanistic, synthetic, and structural chemistries have been used to study how DNA polymerase activity is affected by size, shape, pi-stacking, and hydrogen bonds of the template molecules. Herein, we probe the structural aspects of abasic lesions that result in their distinct coding potential in Escherichia coli despite lacking a Watson-Crick base. In particular, we investigate why bypass of 2-deoxyribonolactone (L) results in significant amounts of dG incorporation opposite the lesion, whereas other abasic lesions (e.g., AP) adhere to the "A-rule". Experiments using synthetic analogues reveal that DNA polymerase V bypasses L and increased levels of dG incorporation result from a hydrogen bonding interaction between the carbonyl oxygen and dG. These results show that a DNA polymerase utilizes hydrogen bonding as one structural parameter when decoding an abasic lesion.

Synthesis and analysis of oligonucleotides containing abasic site analogues

DNA damage results in the formation of abasic sites from the formal hydrolysis of the glycosidic bond (AP) and several oxidized abasic lesions. Previous studies on AP sites revealed that DNA polymerases preferentially incorporated dA opposite them in approximately 80% of the replication events in Escherichia coli. These results were consistent with the hypothesis that the AP sites are noninstructive lesions due to the absence of a Watson-Crick base whose bypass adheres to the "A-rule." Recent replication studies of the oxidized abasic lesion, 2-deoxyribonolactone (L), revealed that DNA polymerase(s) does not apply the A-rule when bypassing it and incorporates large amounts of dG opposite L. These studies suggested that abasic sites such as L do direct polymerases to selectively incorporate nucleotides opposite them. However, it was not possible to determine the structural basis for this molecular recognition from these experiments. A group of oligonucleotides containing analogues of the AP and L lesions were synthesized and characterized as probes to gain insight into the structural basis for the distinct effect of 2-deoxyribonolactone on replication. These molecules will be useful tools for studying replication in cells and in vitro.

Biological properties of single chemical-DNA adducts: a twenty year perspective

The genome and its nucleotide precursor pool are under sustained attack by radiation, reactive oxygen and nitrogen species, chemical carcinogens, hydrolytic reactions, and certain drugs. As a result, a large and heterogeneous population of damaged nucleotides forms in all cells. Some of the lesions are repaired, but for those that remain, there can be serious biological consequences. For example, lesions that form in DNA can lead to altered gene expression, mutation, and death. This perspective examines systems developed over the past 20 years to study the biological properties of single DNA lesions.

Effects of Microsolvation on the Adenine−Uracil Base Pair and Its Radical Anion: Adenine−Uracil Mono- and Dihydrates

Microhydration effects upon the adenine-uracil (AU) base pair and its radical anion have been investigated by explicitly considering various structures of their mono- and dihydrates at the B3LYP/DZP++ level of theory. For the neutral AU base pair, 5 structures were found for the monohydrate and 14 structures for the dihydrate. In the lowest-energy structures of the neutral mono- and dihydrates, one and two water molecules bind to the AU base pair through a cyclic hydrogen bond via the N(9)-H and N(3) atoms of the adenine moiety, while the lowest-lying anionic mono- and dihydrates have a water molecule which is involved in noncyclic hydrogen bonding via the O4 atom of the uracil unit. Both the vertical detachment energy (VDE) and adiabatic electron affinity (AEA) of the AU base pair are predicted to increase upon hydration. While the VDE and AEA of the unhydrated AU pair are 0.96 and 0.40 eV, respectively, the corresponding predictions for the lowest-lying anionic dihydrates are 1.36 and 0.75 eV, respectively. Because uracil has a greater electron affinity than adenine, an excess electron attached to the AU base pair occupies the pi* orbital of the uracil moiety. When the uracil moiety participates in hydrogen bonding as a hydrogen bond acceptor (e.g., the N(6)-H(6a)...O(4) hydrogen bond between the adenine and uracil bases and the O(w)-H(w)...N and O(w)-H(w)...O hydrogen bonds between the AU pair and the water molecules), the transfer of the negative charge density from the uracil moiety to either the adenine or water molecules efficiently stabilizes the system. In addition, anionic structures which have C-H...O(w) contacts are energetically more favorable than those with N-H...O(w) hydrogen bonds, because the C-H...O(w) contacts do not allow the unfavorable electron density donation from the water to the uracil moiety. This delocalization effect makes the energetic ordering for the anionic hydrates very different from that for the corresponding neutrals.

Photochemical generation of C4'-oxidized abasic site containing oligodeoxynucleotide and its efficient amine modification

[Structure: see text] We synthesized oligodeoxynucleotide (ODN, 3), which contains 4'-o-nitrobenzyloxythymidine (4) as a caged precursor of C4'-oxidized abasic site (1). Photoirradiation of 3 at 365 nm followed by amine treatment under neutral conditions afforded the lactam (2) efficiently. Duplexed ODN 3 was converted to 1 faster and more efficiently than single stranded 3, whereas amine treatment of 1 formed from single stranded 3 resulted in slightly faster lactam formation than with the duplex.

Preparation and analysis of oligonucleotides containing the c4'-oxidized abasic site and related mechanistic probes

The C4'-oxidized abasic site (C4-AP) is produced by a variety of DNA damaging agents. This alkali labile lesion can exist in up to four diastereomeric cyclic forms, in addition to the acyclic keto-aldehyde. Synthetic oligonucleotides containing the lesion were prepared from a stable photochemical precursor. Chemical integrity of the lesion containing oligonucleotides was probed using phosphodiesterase lability. Analysis of the 3',5'-phosphate diester of the monomeric lesion released from single diastereomers of photolabile precursors by 1H NMR indicates that isomerization of the hemiacetal and/or hemiketal is rapid. The syntheses and characterization of oligonucleotides containing configurationally stable analogues of C4-AP, which serve as mechanistic probes for deciphering the structural basis of the biochemical and biological effects of the C4'-oxidized abasic lesion, are also described.

Preparation and analysis of oligonucleotides containing lesions resulting from C5'-oxidation

[reaction: see text] Hydrogen atom abstraction from the C5'-position of nucleotides in DNA results in direct strand scission. The newly formed 5'-termini of the cleaved DNA consists of alkali-labile fragments of the oxidized nucleotide. One terminus contains a 5'-aldehyde as part of an otherwise undamaged nucleotide (T-al). A second more structurally distinct product that is produced in lower yields results from cleavage of the C4'-C5' carbon-carbon bond. The 1,4-dioxo-2-phosphorylbutane (DOB) is a precursor of the alkylating agent but-2-ene-1,4-dial. To facilitate studies on these lesions, methods for synthesizing oligodeoxynucleotides containing DOB or T-al at their 5'-termini were developed. The effects of these lesions on the UV-melting temperatures of duplex DNA, and their cleavage labilities were determined. T-al cleaves very slowly (t(1/2) = 100.7 h), whereas DOB has a half-life at 37 degrees C (pH 7.2) of less than 11 h. In addition, DOB forms a stable adduct very efficiently with Tris, which protects the abasic site against cleavage.

Replication of an oxidized abasic site in Escherichia coli by a dNTP-stabilized misalignment mechanism that reads upstream and downstream nucleotides

Abasic sites (AP) and oxidized abasic lesions are often referred to as noninstructive lesions because they cannot participate in Watson-Crick base pairing. The aptness of the term noninstructive for describing AP site replication has been called into question by recent investigations in E. coli using single-stranded shuttle vectors. These studies revealed that the replication of templates containing AP sites or the oxidized abasic lesions resulting from C1'- (L) and C4'-oxidation (C4-AP) are distinct from one another, suggesting that structural features other than Watson-Crick hydrogen bonds contribute to controlling replication. The first description of the replication of the abasic site resulting from formal C2'-oxidation (C2-AP) is presented here. Full-length and single-nucleotide deletion products are observed when templates containing C2-AP are replicated in E. coli. Single nucleotide deletion formation is largely dependent upon the concerted effort of pol II and pol IV, whereas pol V suppresses frameshift product formation. Pol V utilizes the A-rule when bypassing C2-AP. In contrast, pol II and pol IV utilize a dNTP-stabilized misalignment mechanism to read the upstream and downstream nucleotides when bypassing C2-AP. This is the first example in which the identity of the 3'-adjacent nucleotide is read during the replication of a DNA lesion. The results raise further questions as to whether abasic lesions are noninstructive lesions. We suggest that abasic site bypass is affected by the local biopolymer structure in addition to the structure of the lesion.

Assays for determining lesion bypass efficiency and mutagenicity of site-specific DNA lesions in vivo

DNA damage, if left unrepaired, may hinder translesion synthesis, leading to cytotoxicity, and instruct a DNA polymerase to incorporate an incorrect incipient base opposite the damage, leading to mutagenicity. This chapter describes technology used to measure quantitatively the degree to which a specific type of DNA damage impedes DNA replication. The technology also quantifies the mutation frequency and specificity of such damage after replication within cells. If cells with defined defects in DNA repair are used as hosts for replication, one can pinpoint the specific enzymes or pathways of repair that are operative on specific types of DNA damage.

Mutagenic effects of abasic and oxidized abasic lesions in Saccharomyces cerevisiae

2-Deoxyribonolactone (L) and 2-deoxyribose (AP) are abasic sites that are produced by ionizing radiation, reactive oxygen species and a variety of DNA damaging agents. The biological processing of the AP site has been examined in the yeast Saccharomyces cerevisiae. However, nothing is known about how L is processed in this organism. We determined the bypass and mutagenic specificity of DNA containing an abasic site (AP and L) or the AP analog tetrahydrofuran (F) using an oligonucleotide transformation assay. The tetrahydrofuran analog and L were bypassed at 10-fold higher frequencies than the AP lesions. Bypass frequencies of lesions were greatly reduced in the absence of Rev1 or Polζ (rev3 mutant), but were only marginally reduced in the absence of Polη (rad30 mutant). Deoxycytidine was the preferred nucleotide inserted opposite an AP site whereas dA and dC were inserted at equal frequencies opposite F and L sites. In the rev1 and rev3 strains, dA was the predominant nucleotide inserted opposite these lesions. Overall, we conclude that both Rev1 and Polζ are required for the efficient bypass of abasic sites in yeast.

Measurement of the Initial Levels of DNA Damage in Human Lymphocytes Induced by 29 kV X Rays (Mammography X Rays) Relative to 220 kV X Rays and γ Rays

Experiments using the alkaline comet assay, which measures all single-strand breaks regardless of their origin, were performed to evaluate the biological effectiveness of photons with different energies in causing these breaks. The aim was to measure human lymphocytes directly for DNA damage and subsequent repair kinetics induced by mammography 29 kV X rays relative to 220 kV X rays, 137Cs gamma rays and 60Co gamma rays. The level of DNA damage, predominantly due to single-strand breaks, was computed as the Olive tail moment or percentage DNA in the tail for different air kerma doses (0.5, 0.75, 1, 1.5, 2 and 3 Gy). Fifty cells were analyzed per slide with a semiautomatic imaging system. Data from five independent experiments were transformed to natural logarithms and fitted using a multiple linear regression analysis. Irradiations with the different photon energies were performed simultaneously for each experiment to minimize interexperimental variation. Blood from only one male and one female was used. The interexperimental variation and the influence of donor gender were negligible. In addition, repair kinetics and residual DNA damage after exposure to a dose of 3 Gy were evaluated in three independent experiments for different repair times (10, 20, 30 and 60 min). Data for the fraction of remaining damage were fitted to the simple function F(d) = A/(t + A), where F(d) is the fraction of remaining damage, t is the time allowed for repair, and A (the only fit parameter) is the repair half-time. It was found that the comet assay data did not indicate any difference in the initial radiation damage produced by 29 kV X rays relative to the reference radiation types, 220 kV X rays and the gamma rays of 137Cs and 60Co, either for the total dose range or in the low-dose range. These results are, with some restrictions, consistent with physical examinations and predictions concerning, for example, the assessment of the possible difference in effectiveness in causing strand breaks between mammography X rays and conventional (150-250 kV) X rays, indicating that differences in biological effects must arise through downstream processing of the damage.