In Vitro Lesion Bypass Studies of O(4)-Alkylthymidines with Human DNA Polymerase η

Simulation for fluorescence detection of O4-methylthymidine with definite photophysical characteristics

DNA alkylation is caused by long-term exposure of cells to the environmental and endogenous alkylating agents, which can also lead to DNA mutations and therefore trigger some cancers. Since O4-methylthymidine (O4-meT), mismatched with guanine (G), is the most common but not easily repaired alkylated nucleoside, monitoring O4-meT can help to effectively reduce the occurrence of carcinogenesis. In this work, the modified G-analogues are selected as the fluorescence probe to monitor the existence of O4-meT according to its pairing characteristics. The photo-physical properties of considered G-analogues formed by ring expansion or addition of fluorophores were studied in detail. It is found that, compared with natural G, the absorption peaks of these fluorescence analogues are red-shifted (>55 nm) and the luminescence is enhanced by π-conjugation. Especially, the xG has a large Stokes shift (65 nm) with fluorescence insensitive to natural cytosine (C) and retains efficient emission after pairing, while it is sensitive to O4-meT and the quenching phenomenon occurs due to the excited state intermolecular charge transfer. Accordingly, the xG can be used as a fluorescent probe to identify the O4-meT in solution. In addition, the direct use of deoxyguanine fluorescent analogue for monitoring O4-meT was evaluated by the effects of ligating deoxyribose on absorption and fluorescence emission.

Multiscale computational investigations of the translesion synthesis bypass of tobacco-derived DNA adducts: critical insights that complement experimental biochemical studies

Among the numerous agents that damage DNA, tobacco products remain one of the most lethal and result in the most diverse set of DNA lesions. This perspective aims to provide an overview of computational work conducted to complement experimental biochemical studies on the mutagenicity of adducts derived from the most potent tobacco carcinogen, namely 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (nicotine-derived nitrosaminoketone or NNK). Lesions ranging from the smallest methylated thymine derivatives to the larger, flexible pyridyloxobutyl (POB) guanine adducts are considered. Insights are obtained from density functional theory (DFT) calculations and molecular dynamics (MD) simulations into the damaged nucleobase and nucleoside structures, the accommodation of the lesions in the active site of key human polymerases, the intrinsic base pairing potentials of the adducts, and dNTP incorporation opposite the lesions. Overall, the computational data provide atomic level information that can rationalize the differential mutagenic properties of tobacco-derived lesions and uncover important insights into the impact of adduct size, nucleobase, position, and chemical composition of the bulky moiety.

Metabolic Activation and DNA Interactions of Carcinogenic N-Nitrosamines to Which Humans Are Commonly Exposed

Carcinogenic N-nitrosamine contamination in certain drugs has recently caused great concern and the attention of regulatory agencies. These carcinogens-widely detectable in relatively low levels in food, water, cosmetics, and drugs-are well-established and powerful animal carcinogens. The electrophiles resulting from the cytochrome P450-mediated metabolism of N-nitrosamines can readily react with DNA and form covalent addition products (DNA adducts) that play a central role in carcinogenesis if not repaired. In this review, we aim to provide a comprehensive and updated review of progress on the metabolic activation and DNA interactions of 10 carcinogenic N-nitrosamines to which humans are commonly exposed. Certain DNA adducts such as O⁶-methylguanine with established miscoding properties play central roles in the cancer induction process, whereas others have been linked to the high incidence of certain types of cancers. We hope the data summarized here will help researchers gain a better understanding of the bioactivation and DNA interactions of these 10 carcinogenic N-nitrosamines and facilitate further research on their toxicologic and carcinogenic properties.

Structural Rationalization for the Nonmutagenic and Mutagenic Bypass of the Tobacco-Derived O4-4-(3-Pyridyl)-4-oxobut-1-yl-thymine Lesion by Human Polymerase η: A Multiscale Computational Study

Tobacco-derived pyridyloxobutyl (POB) DNA adducts are unique due to the large size and flexibility of the alkyl chain connecting the pyridyl ring to the nucleobase. Recent experimental work suggests that the O4-4-(3-pyridyl)-4-oxobut-1-yl-T (O4-POB-T) lesion can undergo both nonmutagenic (dATP) and mutagenic (dGTP) insertion by the translesion synthesis (TLS) polymerase (pol) η in human cells. Interestingly, the mutagenic rate for O4-POB-T replication is reduced compared to that for the smaller O4-methylthymine (O4-Me-T) lesion, and O4-POB-T yields a different mutagenic profile than the O2-POB-T variant (dTTP insertion). The present work uses a combination of density functional theory calculations and molecular dynamics simulations to probe the impact of the size and flexibility of O4-POB-T on pol η replication outcomes. Due to changes in the Watson-Crick binding face upon damage of canonical T, O4-POB-T does not form favorable hydrogen-bonding interactions with A. Nevertheless, dATP is positioned for insertion in the pol η active site by a water chain to the template strand, which suggests a pol η replication pathway similar to that for abasic sites. Although a favorable O4-POB-T:G mispair forms in the pol η active site and DNA duplexes, the inherent dynamical nature of O4-POB-T periodically disrupts interstrand hydrogen bonding that would otherwise facilitate dGTP insertion and stabilize damaged DNA duplexes. In addition to explaining the origin of the experimentally reported pol η outcomes associated with O4-POB-T replication, comparison to structural data for the O4-Me-T and O2-POB-T adducts highlights an emerging common pathway for the nonmutagenic replication of thymine alkylated lesions by pol η, yet underscores the broader impacts of bulky moiety size, flexibility, and position on the associated mutagenic outcomes.

Replication of DNA Containing Mirror-Image Thymidine in E. coli Cells

DNA damage can occur naturally or through environmental factors, leading to mutations in DNA replication and genomic instability in cells. Normally, natural d-nucleotides were selected by DNA polymerases. The template l-thymidine (l-T) has been shown to be bypassed by several types of DNA polymerases. However, DNA replication fidelity of nucleotide incorporation opposite l-thymidine in vivo remains unknown. Here, we constructed plasmids containing a restriction enzyme (PstI) recognition site in which the l-T lesion was site-specifically located within the PstI recognition sequence (CTGCAG). Further, we assessed the efficiencies of nucleotide incorporation opposite the l-T site and l-T lesion bypass replication in vitro and in vivo. We found that recombinants containing the l-T lesion site inhibited DNA replication. In addition, A was incorporated opposite the l-T lesion by routine PCR assay, whereas preference for nucleotide incorporation opposite the l-T site was A (13%), T (22%), C (46%), and G (19%), and no nucleotide insertion and deletions were detected in E. coli cells. In particular, a novel restriction enzyme-mediated method for detection of the mutagenic properties of DNA lesion was established, which allows us to readily detect restriction-digestion of the l-T-bearing plasmids. The study provided significant insight into how mirror-image nucleosides perturb the fidelity of DNA replication in vivo and whether they elicit mutagenic effects, which may help to understand both how DNA damage interferes with the flow of genetic information during DNA replication and development of diseases caused by gene mutation.

Replication studies of carboxymethylated DNA lesions in human cells

Metabolic activation of some N-nitroso compounds (NOCs), an important class of DNA damaging agents, can induce the carboxymethylation of nucleobases in DNA. Very little was previously known about how the carboxymethylated DNA lesions perturb DNA replication in human cells. Here, we investigated the effects of five carboxymethylated DNA lesions, i.e. O⁶-CMdG, N⁶-CMdA, N⁴-CMdC, N3-CMdT and O⁴-CMdT on the efficiency and fidelity of DNA replication in HEK293T human embryonic kidney cells. We found that, while neither N⁶-CMdA nor N⁴-CMdC blocked DNA replication or induced mutations, N3-CMdT, O⁴-CMdT and O⁶-CMdG moderately blocked DNA replication and induced substantial frequencies of T→A (81%), T→C (68%) and G→A (6.4%) mutations, respectively. In addition, our results revealed that CRISPR-Cas9-mediated depletion of Pol η resulted in significant drops in bypass efficiencies of N⁴-CMdC and N3-CMdT. Diminution in bypass efficiencies was also observed for N⁶-CMdA and O⁶-CMdG upon depletion of Pol κ, and for O⁶-CMdG upon removal of Pol ζ. Together, our study provided molecular-level insights into the impacts of the carboxymethylated DNA lesions on DNA replication in human cells, revealed the roles of individual translesion synthesis DNA polymerases in bypassing these lesions, and suggested the contributions of O⁶-CMdG, N3-CMdT and O⁴-CMdT to the mutations found in p53 gene of human gastrointestinal cancers.

Replicative Bypass Studies of α-Anomeric Lesions of 2'-Deoxyribonucleosides in Vitro

Genomic integrity is constantly challenged by a variety of endogenous and exogenous DNA damaging agents, which can lead to the formation of 10⁴-10⁵ DNA lesions per cell per day. Reactive oxygen species (ROS) represent a major type of DNA damaging agent. Specifically, a hydroxyl radical can attack the C1' position of 2-deoxyribose, and the ensuing carbon-centered radical, if improperly repaired, can cause the inversion of stereochemical configuration at the C1' to give α-anomeric lesions. In this study, we assessed the replicative bypass of α-dA, α-dT, α-dC, and α-dG in template DNA by conducting primer extension assays with the use of purified translesion synthesis DNA polymerases. Our results revealed that human polymerase (Pol) η, but not human Pol κ, Pol ι, or yeast Pol ζ, was capable of bypassing all of the α-dN lesions and extending the primer to generate full-length replication products. Data from steady-state kinetic measurements showed that Pol η was the most efficient in inserting the correct nucleotides opposite the modified nucleosides, with the relative efficiencies of nucleotide incorporation following the order of α-dA > α-dG > α-dT > α-dC. Additionally, human Pol η was found to misincorporate dTMP opposite α-dT and dCMP opposite α-dC at frequencies of 66% and 24%, respectively, whereas α-dA and α-dG were weakly miscoding. These findings provided important knowledge about the effects these α-dN lesions have on the fidelity and efficiency of DNA replication mediated by human Pol η.

Replicative Bypass of O2-Alkylthymidine Lesions in Vitro

DNA alkylation represents a major type of DNA damage and is generally unavoidable due to ubiquitous exposure to various exogenous and endogenous sources of alkylating agents. Among the alkylated DNA lesions, O²-alkylthymidines (O²-alkyldT) are known to be persistent and poorly repaired in mammalian systems and have been shown to accumulate in the esophagus, lung, and liver tissue of rats treated with tobacco-specific N-nitrosamines, i.e., 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and N'-nitrosonornicotine (NNN). In this study, we assessed the replicative bypass of a comprehensive set of O²-alkyldT lesions, with the alkyl group being a Me, Et, nPr, iPr, nBu, iBu, or sBu, in template DNA by conducting primer extension assays with the use of major translesion synthesis DNA polymerases. The results showed that human Pol η and, to a lesser degree, human Pol κ, but not human polymerase ι or yeast polymerase ζ, were capable of bypassing all O²-alkyldT lesions and extending the primer to generate full-length replication products. Data from steady-state kinetic measurements showed that human Pol η exhibited high frequencies of misincorporation of dCMP opposite those O²-alkyldT lesions bearing a longer straight-chain alkyl group. However, the nucleotide misincorporation opposite branched-chain lesions was not selective, with dCMP, dGMP, and dTMP being inserted at similar efficiencies, though the total frequencies of nucleotide misincorporation opposite the branched-chain lesions differed and followed the order of O²-iPrdT > O²-iBudT > O²-sBudT. Together, the results from the present study provided important knowledge about the effects of the length and structure of the alkyl group in the O²-alkyldT lesions on the fidelity and efficiency of DNA replication mediated by human Pol η.

Translesion synthesis of O4-alkylthymidine lesions in human cells

Environmental exposure, endogenous metabolism and cancer chemotherapy can give rise to alkylation of DNA, and the resulting alkylated thymidine (alkyldT) lesions were found to be poorly repaired and persistent in mammalian tissues. Unrepaired DNA lesions may compromise genomic integrity by inhibiting DNA replication and inducing mutations in these processes. In this study, we explored how eight O⁴-alkyldT lesions, with the alkyl group being a Me, Et, nPr, iPr, nBu, iBu, (R)-sBu and (S)-sBu, are recognized by DNA replication machinery in HEK293T human embryonic kidney cells. We found that the O⁴-alkyldT lesions are moderately blocking to DNA replication, with the bypass efficiencies ranging from 20 to 33% in HEK293T cells, and these lesions induced substantial frequencies T→C transition mutation. We also conducted the replication experiments in the isogenic cells where individual translesion synthesis (TLS) DNA polymerases were depleted by the CRISPR/Cas9 genome editing method. Our results showed that deficiency in Pol η or Pol ζ, but not Pol κ or Pol ι, led to pronounced drops in bypass efficiencies for all the O⁴-alkyldT lesions except O⁴-MedT. In addition, depletion of Pol ζ resulted in significant decreases in T→C mutation frequencies for all the O⁴-alkyldT lesions except O⁴-MedT and O⁴-nBudT. Thus, our study provided important new knowledge about the cytotoxic and mutagenic properties of the O⁴-alkyldT lesions and defined the roles of TLS polymerases in bypassing these lesions in human cells.