On the formation and properties of interstrand DNA-DNA cross-links forged by reaction of an abasic site with the opposing guanine residue of 5'-CAp sequences in duplex DNA

Crystal structure of a nucleoside model for the inter-strand cross-link formed by the reaction of 2'-de-oxy-guanosine and an abasic site in duplex DNA

The title compound, 9-[(2R,4S,5R)-4-hy-droxy-5-(hy-droxy-meth-yl)tetra-hydro-furan-2-yl]-2-{[(2R,4S,5R)-4-meth-oxy-5-(meth-oxy-meth-yl)tetra-hydro-furan-2-yl]amino}-1H-purin-6(9H)-one, C17H25N5O7, crystallizes with two independent mol-ecules (A and B) in the asymmetric unit. In the crystal, the guanosine moieties of mol-ecules A and B are linked by N-H⋯N and O-H⋯N hydrogen-bonding inter-actions, forming ribbons which are stacked to form columns along [100]. These columns are then linked by O-H⋯O hydrogen bonds between the ribose moieties and numerous C-H⋯O inter-actions to complete the three-dimensional structure.

Effective molarity in a nucleic acid-controlled reaction

Positioning of reactive functional groups within a DNA duplex can enable chemical reactions that otherwise would not occur to an appreciable extent. However, few studies have quantitatively defined the extent to which the enforced proximity of reaction partners in duplex DNA can favor chemical processes. Here, we measured substantial effective molarities (as high as 25M) afforded by duplex DNA to a reaction involving interstrand cross-link formation between 2'-deoxyadenosine and a 2-deoxyribose abasic (Ap) site.

Characterization of Interstrand DNA-DNA Cross-Links Using the α-Hemolysin Protein Nanopore

Nanopore-based sensors have been studied extensively as potential tools for DNA sequencing, characterization of epigenetic modifications such as 5-methylcytosine, and detection of microRNA biomarkers. In the studies described here, the α-hemolysin protein nanopore embedded in a lipid bilayer was used for the detection and characterization of interstrand cross-links in duplex DNA. Interstrand cross-links are important lesions in medicinal chemistry and toxicology because they prevent the strand separation that is required for read-out of genetic information from DNA in cells. In addition, interstrand cross-links are used for the stabilization of duplex DNA in structural biology and materials science. Cross-linked DNA fragments produced unmistakable current signatures in the nanopore experiment. Some cross-linked substrates gave irreversible current blocks of >10 min, while others produced long current blocks (10-100 s) before the double-stranded DNA cross-link translocated through the α-hemolysin channel in a voltage-driven manner. The duration of the current block for the different cross-linked substrates examined here may be dictated by the stability of the duplex region left in the vestibule of the nanopore following partial unzipping of the cross-linked DNA. Construction of calibration curves measuring the frequency of cross-link blocking events (1/τon) as a function of cross-link concentration enabled quantitative determination of the amounts of cross-linked DNA present in samples. The unique current signatures generated by cross-linked DNA in the α-HL nanopore may enable the detection and characterization of DNA cross-links that are important in toxicology, medicine, and materials science.

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.

Correlation of Thermal Stability and Structural Distortion of DNA Interstrand Cross-Links Produced from Oxidized Abasic Sites with Their Selective Formation and Repair

C4'-oxidized (C4-AP) and C5'-oxidized abasic sites (DOB) that are produced following abstraction of a hydrogen atom from the DNA backbone reversibly form cross-links selectively with dA opposite a 3'-adjacent nucleotide, despite the comparable proximity of an opposing dA. A previous report on UvrABC incision of DNA substrates containing stabilized analogues of the ICLs derived from C4-AP and DOB also indicated that the latter is repaired more readily by nucleotide excision repair [Ghosh, S., and Greenberg, M. M. (2014) Biochemistry 53, 5958-5965]. The source for selective cross-link formation was probed by comparing the reactivity of ICL analogues of C4-AP and DOB that mimic the preferred and disfavored cross-links with that of reagents that indirectly detect distortion by reacting with the nucleobases. The disfavored C4-AP and DOB analogues were each more reactive than the corresponding preferred cross-link substrates, suggesting that the latter are more stable, which is consistent with selective ICL formation. In addition, the preferred DOB analogue is more reactive than the respective C4-AP ICL, which is consistent with its more efficient incision by UvrABC. The conclusions drawn from the chemical probing experiments are corroborated by UV melting studies. The preferred ICLs exhibit melting temperatures higher than those of the corresponding disfavored isomers. These studies suggest that oxidized abasic sites form reversible interstrand cross-links with dA opposite the 3'-adjacent thymidine because these products are more stable and the thermodynamic preference is reflected in the transition states for their formation.

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.

Characterization of Interstrand DNA-DNA Cross-Links Derived from Abasic Sites Using Bacteriophage ϕ29 DNA Polymerase

Interstrand cross-links in cellular DNA are highly deleterious lesions that block transcription and replication. We recently characterized two new structural types of interstrand cross-links derived from the reaction of abasic (Ap) sites with either guanine or adenine residues in duplex DNA. Interestingly, these Ap-derived cross-links are forged by chemically reversible processes, in which the two strands of the duplex are joined by hemiaminal, imine, or aminoglycoside linkages. Therefore, understanding the stability of Ap-derived cross-links may be critical in defining the potential biological consequences of these lesions. Here we employed bacteriophage φ29 DNA polymerase, which can couple DNA synthesis and strand displacement, as a model system to examine whether dA-Ap cross-links can withstand DNA-processing enzymes. We first demonstrated that a chemically stable interstrand cross-link generated by hydride reduction of the dG-Ap cross-link completely blocked primer extension by φ29 DNA polymerase at the last unmodified nucleobase preceding cross-link. We then showed that the nominally reversible dA-Ap cross-link behaved, for all practical purposes, like an irreversible, covalent DNA-DNA cross-link. The dA-Ap cross-link completely blocked progress of the φ29 DNA polymerase at the last unmodified base before the cross-link. This suggests that Ap-derived cross-links have the power to block various DNA-processing enzymes in the cell. In addition, our results reveal φ29 DNA polymerase as a tool for detecting the presence and mapping the location of interstrand cross-links (and possibly other lesions) embedded within regions of duplex DNA.

A simple, high-yield synthesis of DNA duplexes containing a covalent, thermally cleavable interstrand cross-link at a defined location

Interstrand DNA-DNA cross-links are highly toxic to cells because these lesions block the extraction of information from the genetic material. The pathways by which cells repair cross-links are important, but not well understood. The preparation of chemically well-defined cross-linked DNA substrates represents a significant challenge in the study of cross-link repair. Here a simple method is reported that employs "post-synthetic" modifications of commercially available 2'-deoxyoligonucleotides to install a single cross-link in high yield at a specified location within a DNA duplex. The cross-linking process exploits the formation of a hydrazone between a non-natural N(4) -amino-2'-deoxycytidine nucleobase and the aldehyde residue of an abasic site in duplex DNA. The resulting cross-link is stable under physiological conditions, but can be readily dissociated and re-formed through heating-cooling cycles.

Photouncaged Sequence-specific Interstrand DNA Cross-Linking with Photolabile 4-oxo-enal-modified Oligonucleotides

DNA cross-linking technology is an attractive tool for the detection, regulation, and manipulation of genes. In this study, a series of photolabile 4-oxo-enal-modified oligonucleotides functionalized with photosensitive ο-nitrobenzyl derivatives were rationally designed as a new kind of photocaged cross-linking agents. A comprehensive evaluation of cross-linking reactions for different nucleobases in complementary strands under different conditions suggested that the modified DNA oligonucleotides tended to form interstrand cross-linking to nucleobases with the potential of thymidine > guanosine » cytidine ~ adenosine. Different from previous literature reports that cytidine and adenosine were preferential cross-linked nucleobases with 4-oxo-enal moieties, our study represents the first example of DNA cross-linking for T and G selectivity using 4-oxo-enal moiety. The cross-linked adducts were identified and their cross-linking mechanism was also illustrated. This greatly expands the applications of 4-oxo-enal derivatives in the studies of DNA damage and RNA structure

Chemical and structural characterization of interstrand cross-links formed between abasic sites and adenine residues in duplex DNA

A new type of interstrand DNA–DNA cross-link between abasic (Ap) sites and 2′-deoxyadenosine (dA) residues was recently reported, but the chemical structure and properties of this lesion were not rigorously established. Here we characterized the nucleoside cross-link remnant released by enzymatic digestion of duplex DNA containing the dA-Ap cross-link. A synthetic standard was prepared for the putative nucleoside cross-link remnant 6 in which the anomeric carbon of the 2-deoxyribose residue was connected to the exocyclic N⁶-amino group of dA. Liquid chromatography-tandem mass spectrometry (LC-MS/MS) analysis showed that the synthetic material 6 matched the authentic cross-link remnant released by enzymatic digestion of cross-linked DNA. These findings establish the chemical structure of the dA-Ap cross-link released from duplex DNA and may provide methods for the detection of this lesion in cellular DNA. Both the nucleoside cross-link remnant 6 and the cross-link in duplex DNA were quite stable at pH 7 and 37°C, suggesting that the dA-Ap cross-link could be a persistent lesion with the potential to block the action of various DNA processing enzymes.

Chemical structure and properties of interstrand cross-links formed by reaction of guanine residues with abasic sites in duplex DNA

A new type of interstrand cross-link resulting from the reaction of a DNA abasic site with a guanine residue on the opposing strand of the double helix was recently identified, but the chemical connectivity of the cross-link was not rigorously established. The work described here was designed to characterize the chemical structure and properties of dG-AP cross-links generated in duplex DNA. The approach involved characterization of the nucleoside cross-link "remnant" released by enzymatic digestion of DNA duplexes containing the dG-AP cross-link. We first carried out a chemical synthesis and complete spectroscopic structure determination of the putative cross-link remnant 9b composed of a 2-deoxyribose adduct attached to the exocyclic N(2)-amino group of dG. A reduced analogue of the cross-link remnant was also prepared (11b). Liquid chromatography-tandem mass spectrometric (LC-MS/MS) analysis revealed that the retention times and mass spectral properties of synthetic standards 9b and 11b matched those of the authentic cross-link remnants released by enzymatic digestion of duplexes containing the native and reduced dG-AP cross-link, respectively. These results establish the chemical connectivity of the dG-AP cross-link released from duplex DNA and provide a foundation for detection of this lesion in biological samples. The dG-AP cross-link in duplex DNA was remarkably stable, decomposing with a half-life of 22 days at pH 7 and 23 °C. The intrinsic chemical stability of the dG-AP cross-link suggests that this lesion in duplex DNA may have the power to block DNA-processing enzymes involved in transcription and replication.

Base excision repair enzymes protect abasic sites in duplex DNA from interstrand cross-links

Hydrolysis of the N-glycosyl bond between a nucleobase and deoxyribose leaves an abasic site within duplex DNA. The abasic site can react with exocyclic amines of nucleobases on the complementary strand to form interstrand DNA-DNA cross-links (ICLs). We find that several enzymes from the base excision repair (BER) pathway protect an abasic site on one strand of a DNA duplex from cross-linking with an amine on the opposing strand. Human alkyladenine DNA glycosylase (AAG) and Escherichia coli 3-methyladenine DNA glycosylase II (AlkA) accomplish this by binding tightly to the abasic site and sequestering it. AAG protects an abasic site opposite T, the product of its canonical glycosylase reaction, by a factor of ∼10-fold, as estimated from its inhibition of the reaction of an exogenous amine with the damaged DNA. Human apurinic/apyrimidinic site endonuclease 1 and E. coli endonuclease III both decrease the amount of ICL at equilibrium by generating a single-strand DNA nick at the abasic position as it is liberated from the cross-link. The reversibility of the reaction between amines and abasic sites allows BER enzymes to counter the potentially disruptive effects of this type of cross-link on DNA transactions.

Nucleotide excision repair of chemically stabilized analogues of DNA interstrand cross-links produced from oxidized abasic sites

Nucleotide excision repair is a primary pathway in cells for coping with DNA interstrand cross-links (ICLs). Recently, C4'-oxidized (C4-AP) and C5'-oxidized abasic sites (DOB) that are produced following hydrogen atom abstraction from the DNA backbone were found to produce ICLs. Because some of the ICLs derived from C4-AP and DOB are too unstable to characterize in biochemical processes, chemically stable analogues were synthesized [Ghosh, S., and Greenberg, M. M. (2014) J. Org. Chem. 79, 5948-5957]. UvrABC incision of DNA substrates containing stabilized analogues of the ICLs derived from C4-AP and DOB was examined. The incision pattern for the ICL related to the C4'-oxidized abasic site was typical for UvrABC substrates. UvrABC cleaved both strands of the substrate containing the C4-AP ICL analogue, but it was a poor substrate. UvrABC incised <30% of the C4-AP ICL analogue over an 8 h period, raising the possibility that this cross-link will be inefficiently repaired in cells. Furthermore, double-strand breaks were not detected upon incision of an internally labeled hairpin substrate containing the C4-AP ICL analogue. UvrABC incised the stabilized analogue of the DOB ICL more efficiently (~20% in 1 h). Furthermore, the incision pattern was unique, and the cross-linked substrate was converted into a single product, a double-strand break. The template strand was exclusively incised on the template strand on the 3'-side of the cross-linked dA. Although the outcomes of the interaction between UvrABC and these two cross-linked substrates are different from one another, they provide additional examples of how seemingly simple lesions (C4-AP and DOB) can potentially exert significant deleterious effects on biochemical processes.

Purine biosynthetic intermediate-containing ribose-phosphate polymers as evolutionary precursors to RNA

The RNA world hypothesis proposes that RNA once functioned as the principal genetic material and biological catalyst. However, RNA is a complex molecule made up of phosphate, ribose, and nucleobase moieties, and its evolution is unclear. Yakhnin has proposed a period of prebiotic chemical evolution prior to the advent of replication and Darwinian evolution, in which macromolecules containing polyols joined by phosphodiester linkages underwent spontaneous transesterification reactions with selection for stability. Although he proposes that the nucleobases were obtained during this stage from less stable macromolecules, the ultimate source of the nucleobases is not addressed. We propose that the purine nucleobases arose in situ from simpler precursors attached to a ribose-phosphate backbone, and that the weaker and less specific intra- and interstrand interactions between these precursors were the forerunners to the base pairing and base stacking interactions of the modern RNA nucleobases. Further, in line with Granick's hypothesis of biosynthetic pathways recapitulating evolution, we propose that these simpler precursors were the same or similar to intermediates of the modern de novo purine biosynthetic pathway. We propose that successive nucleobase precursors formed progressively stronger interactions that stabilized the ribose-phosphate polymer, and that the increased stability of the parent polymer drove the selection and further chemical evolution of the purine nucleobases. Such interactions may have included hydrogen bonding between ribose hydroxyls, hydrogen bonding between carbonyl oxygens and protonated amine side groups, the intra- and interstrand coordination of metal cations, and the stacking of imidazole rings. Five of the eleven steps of the modern de novo purine biosynthetic pathway have previously been shown to have alternative nonenzymatic syntheses, while a sixth step has also been proposed to occur nonenzymatically, supporting a prebiotic origin for the pathway.

Synthesis of cross-linked DNA containing oxidized abasic site analogues

DNA interstrand cross-links are an important family of DNA damage that block replication and transcription. Recently, it was discovered that oxidized abasic sites react with the opposing strand of DNA to produce interstrand cross-links. Some of the cross-links between 2'-deoxyadenosine and the oxidized abasic sites, 5'-(2-phosphoryl-1,4-dioxobutane) (DOB) and the C4-hydroxylated abasic site (C4-AP), are formed reversibly. Chemical instability hinders biochemical, structural, and physicochemical characterization of these cross-linked duplexes. To overcome these limitations, we developed methods for preparing stabilized analogues of DOB and C4-AP cross-links via solid-phase oligonucleotide synthesis. Oligonucleotides of any sequence are attainable by synthesizing phosphoramidites in which the hydroxyl groups of the cross-linked product were orthogonally protected using photochemically labile and hydrazine labile groups. Selective unmasking of a single hydroxyl group precedes solid-phase synthesis of one arm of the cross-linked DNA. The method is compatible with commercially available phosphoramidites and other oligonucleotide synthesis reagents. Cross-linked duplexes containing as many as 54 nt were synthesized on solid-phase supports. Subsequent enzyme ligation of one cross-link product provided a 60 bp duplex, which is suitable for nucleotide excision repair studies.

Photoswitchable formation of a DNA interstrand cross-link by a coumarin-modified nucleotide

A coumarin-modified pyrimidine nucleoside (1) has been synthesized using a Cu(I)-catalyzed click reaction and incorporated into oligodeoxynucleotides (ODNs). Interstrand cross-links are produced upon irradiation of ODNs containing 1 at 350 nm. Cross-linking occurs through a [2+2] cycloaddition reaction with the opposing thymidine, 2'-deoxycytidine, or 2'-deoxyadenosine. A much higher reactivity was observed with dT than dC or dA. Irradiation of the dT-1 and dC-1 cross-linked products at 254 nm leads to a reversible ring-opening reaction, while such phenomena were not observed with dA-1 adducts. The reversible reaction is ultrafast and complete within 50-90 s. Consistent photoswitching behavior was observed over 6 cycles of irradiation at 350 nm and 254 nm. To the best of our knowledge, this is the first example of photoswitchable interstrand cross-linking formation induced by a modified pyrimidine nucleoside.

Looking beneath the surface to determine what makes DNA damage deleterious

Apurinic/apyrimidinic and oxidized abasic sites are chemically reactive DNA lesions that are produced by a variety of damaging agents. The effects of these molecules that lack a Watson-Crick base on polymerase enzymes are well documented. More recently, multiple consequences of the electrophilic nature of abasic lesions have been revealed. Members of this family of DNA lesions have been shown to inactivate repair enzymes and undergo spontaneous transformation into more deleterious forms of damage. Abasic site reactivity provides insight into the chemical basis for the cytotoxicity of DNA damaging agents that produce them and are valuable examples of how looking beneath the surface of seemingly simple molecules can reveal biologically relevant chemical complexity.

Interstrand DNA-DNA cross-link formation between adenine residues and abasic sites in duplex DNA

The loss of a coding nucleobase from the structure of DNA is a common event that generates an abasic (Ap) site (1). Ap sites exist as an equilibrating mixture of a cyclic hemiacetal and a ring-opened aldehyde. Aldehydes are electrophilic functional groups that can form covalent adducts with nucleophilic sites in DNA. Thus, Ap sites present a potentially reactive aldehyde as part of the internal structure of DNA. Here we report evidence that the aldehyde group of Ap sites in duplex DNA can form a covalent adduct with the N(6)-amino group of adenine residues on the opposing strand. The resulting interstrand DNA-DNA cross-link occurs at 5'-ApT/5'-AA sequences in remarkably high yields (15-70%) under physiologically relevant conditions. This naturally occurring DNA-templated reaction has the potential to generate cross-links in the genetic material of living cells.

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.

Epimeric 2-deoxyribose lesions: Products from the improper chemical repair of 2-deoxyribose radicals

Genomic integrity is constantly challenged by DNA damaging agents such as reactive oxygen species (ROS). Consequently, DNA damage can compromise the fidelity and efficiency of essential DNA metabolic processes, including replication and transcription, which may contribute significantly to the etiology of many human diseases. Here, we review one family of DNA lesions, the epimeric 2-deoxyribose lesions, which arise from the improper chemical repair of the 2-deoxyribose radicals. Unlike most other DNA lesions, the epimeric 2-deoxyribose lesions are indistinguishable from their corresponding unmodified nucleosides in both molecular mass and chemical reactivity. We placed our emphasis of discussion on the formation of these lesions, their impact on the structure and stability of duplex DNA, their biological consequences, their potential therapeutic relevance, and future research directions about these modified nucleosides.

Spontaneous prebiotic formation of a β-ribofuranoside that self-assembles with a complementary heterocycle

The RNA World hypothesis is central to many current theories regarding the origin and early evolution of life. However, the formation of RNA by plausible prebiotic reactions remains problematic. Formidable challenges include glycosidic bond formation between ribose and the canonical nucleobases, as well as the inability of nucleosides to mutually select their pairing partners from a complex mixture of other molecules prior to polymerization. Here we report a one-pot model prebiotic reaction between a pyrimidine nucleobase (2,4,6-triaminopyrimidine, TAP) and ribose, which produces TAP-ribose conjugates in high yield (60-90%). When cyanuric acid (CA), a plausible ancestral nucleobase, is mixed with a crude TAP+ribose reaction mixture, micrometer-length supramolecular, noncovalent assemblies are formed. A major product of the TAP+ribose reaction is a β-ribofuranoside of TAP, which we term TARC. This nucleoside is also shown to efficiently form supramolecular assemblies in water by pairing and stacking with CA. These results provide a proof-of-concept system demonstrating that several challenges associated with the prebiotic emergence of RNA, or pre-RNA polymers, may not be as problematic as widely believed.

Advances in understanding the complex mechanisms of DNA interstrand cross-link repair

DNA interstrand cross-links (ICLs) are lesions caused by a variety of endogenous metabolites, environmental exposures, and cancer chemotherapeutic agents that have two reactive groups. The common feature of these diverse lesions is that two nucleotides on opposite strands are covalently joined. ICLs prevent the separation of two DNA strands and therefore essential cellular processes including DNA replication and transcription. ICLs are mainly detected in S phase when a replication fork stalls at an ICL. Damage signaling and repair of ICLs are promoted by the Fanconi anemia pathway and numerous posttranslational modifications of DNA repair and chromatin structural proteins. ICLs are also detected and repaired in nonreplicating cells, although the mechanism is less clear. A unique feature of ICL repair is that both strands of DNA must be incised to completely remove the lesion. This is accomplished in sequential steps to prevent creating multiple double-strand breaks. Unhooking of an ICL from one strand is followed by translesion synthesis to fill the gap and create an intact duplex DNA, harboring a remnant of the ICL. Removal of the lesion from the second strand is likely accomplished by nucleotide excision repair. Inadequate repair of ICLs is particularly detrimental to rapidly dividing cells, explaining the bone marrow failure characteristic of Fanconi anemia and why cross-linking agents are efficacious in cancer therapy. Herein, recent advances in our understanding of ICLs and the biological responses they trigger are discussed.

A quantitative mass spectrometry-based approach for assessing the repair of 8-methoxypsoralen-induced DNA interstrand cross-links and monoadducts in mammalian cells

Interstrand cross-links (ICLs) are highly toxic DNA lesions that block transcription and replication by preventing strand separation. ICL-inducing agents were among the earliest and are still the most widely used forms of chemotherapeutic drugs. Because of the repair of DNA ICLs, the therapeutic efficacy of the DNA cross-linking agents is often reduced by the development of chemoresistance in patients. Thus, it is very important to understand how various DNA ICLs are repaired. Such studies are currently hampered by the lack of an analytical method for monitoring directly the repair of DNA ICLs in cells. Here we report a high-performance liquid chromatography coupled with tandem mass spectrometry (LC-MS/MS) method, together with the isotope dilution technique, for assessing the repair of 8-methoxypsoralen (8-MOP)-induced DNA ICLs, as well as monoadducts (MAs), in cultured mammalian cells. We found that, while there were substantial decreases in the levels of ICL and MAs in repair-competent cells 24 h after 8-MOP/UVA treatment, there was little repair of 8-MOP-ICLs and -MAs in xeroderma pigmentosum, complementation group A-deficient human skin fibroblasts and excision repair cross-complementing rodent repair deficiency, complementation group 1-deficient Chinese hamster ovary cells over a 24 h period. This result provided unequivocal evidence supporting the notion that the 8-MOP photoadducts are substrates for nucleotide excision repair in mammalian cells. This is one of the first few reports about the application of LC-MS/MS for assessing the repair of DNA ICLs. The analytical method developed here, when combined with genetic manipulation, will also facilitate the assessment of the roles of other DNA repair pathways in removing these DNA lesions, and the method can also be generally applicable for investigating the repair of other types of DNA ICLs in mammalian cells.

DNA-N-glycosylases process novel O-glycosidic sites in DNA

After the hydrolysis of the N-glycosyl bond between a damaged base and C1' of a deoxyribosyl moiety of DNA, human alkyladenine DNA glycosylase (AAG) and Escherichia coli 3-methyladenine DNA glycosylase II (AlkA) bind tightly to their abasic DNA products, potentially protecting these reactive species. Here we show that both AAG and AlkA catalyze reactions between bound abasic DNA and small, primary alcohols to form novel DNA-O-glycosides. The synthesis reactions are reversible, as the DNA-O-glycosides are converted back into abasic DNA upon being incubated with AAG or AlkA in the absence of alcohol. AAG and AlkA are therefore able to hydrolyze O-glycosidic bonds in addition to N-glycosyl bonds. The newly discovered DNA-O-glycosidase activities of both enzymes compare favorably with their known DNA-N-glycosylase activities: AAG removes both methanol and 1,N(6)-ethenoadenine (εA) from DNA with single-turnover rate constants that are 2.9 × 10(5)-fold greater than the corresponding uncatalyzed rates, whereas the rate enhancement of 3.7 × 10(7) for removal of methanol from DNA by AlkA is 300-fold greater than its rate enhancement for removal of εA from DNA. Although the biological significance of the DNA-O-glycosidase reactions is not known, the evolution of new DNA repair pathways may be aided by enzymes that practice catalytic promiscuity, such as these two unrelated DNA glycosylases.

Nucleosome core particle-catalyzed strand scission at abasic sites

The reactivity of apurinic/apyrimidinic (AP) sites at different locations within nucleosome core particles was examined. AP sites are greatly destabilized in nucleosome core particles compared to free DNA. Their reactivity varied ~5-fold with respect to the location within the nucleosome core particles but followed a common mechanism involving formation of a Schiff base between histone proteins and the lesion. The identity of the histone protein(s) involved in the reaction and the reactivity of the corresponding DNA-protein cross-links varied with the location of the abasic site, indicating that while the relative rate constants for individual steps varied in a complex manner, the overall mechanism remained the same. The source of the accelerated reactivity was probed using nucleosomes containing AP89 and histone H3 and H4 variants. Mutating the five lysine residues in the amino tail region of histone H4 to arginines reduced the rate constant for disappearance almost 15-fold. Replacing histidine 18 with an alanine reduced AP reactivity more than 3-fold. AP89 in a nucleosome core particle composed of the H4 variant containing both sets of mutations reacted only <4-fold faster than it did in naked DNA. These experiments reveal that nucleosome-catalyzed reaction at AP89 is a general phenomenon and that the lysine rich histone tails, whose modification is integrally involved in epigenetics, are primarily responsible for this chemistry.