Project description:As a widely used anticancer drug, cis-diamminedichloroplatinum(II) (cisplatin) reacts with adjacent purine bases in DNA to form predominantly cis-[Pt(NH(3))(2){d(GpG)-N7(1),-N7(2)}] intrastrand cross-links. Drug resistance, one of the major limitations of cisplatin therapy, is partially due to the inherent ability of human Y-family DNA polymerases to perform translesion synthesis in the presence of DNA-distorting damage such as cisplatin-DNA adducts. To better understand the mechanistic basis of translesion synthesis contributing to cisplatin resistance, this study investigated the bypass of a single, site-specifically placed cisplatin-d(GpG) adduct by a model Y-family DNA polymerase, Sulfolobus solfataricus DNA polymerase IV (Dpo4). Dpo4 was able to bypass this double-base lesion, although, the incorporation efficiency of dCTP opposite the first and second cross-linked guanine bases was decreased by 72- and 860-fold, respectively. Moreover, the fidelity at the lesion decreased up to two orders of magnitude. The cisplatin-d(GpG) adduct affected six downstream nucleotide incorporations, but interestingly the fidelity was essentially unaltered. Biphasic kinetic analysis supported a universal kinetic mechanism for the bypass of DNA lesions catalyzed by various translesion DNA polymerases. In conclusion, if human Y-family DNA polymerases adhere to this bypass mechanism, then translesion synthesis by these error-prone enzymes is likely accountable for cisplatin resistance observed in cancer patients.

Project description:1-Nitropyrene (1-NP), an environmental pollutant, induces DNA damage in vivo and is considered to be carcinogenic. The DNA adducts formed by the 1-NP metabolites stall replicative DNA polymerases but are presumably bypassed by error-prone Y-family DNA polymerases at the expense of replication fidelity and efficiency in vivo. Our running start assays confirmed that a site-specifically placed 8-(deoxyguanosin-N(2)-yl)-1-aminopyrene (dG(1,8)), one of the DNA adducts derived from 1-NP, can be bypassed by Sulfolobus solfataricus DNA polymerase IV (Dpo4), although this representative Y-family enzyme was paused strongly by the lesion. Pre-steady-state kinetic assays were employed to determine the low nucleotide incorporation fidelity and establish a minimal kinetic mechanism for the dG(1,8) bypass by Dpo4. To reveal a structural basis for dCTP incorporation opposite dG(1,8), we solved the crystal structures of the complexes of Dpo4 and DNA containing a templating dG(1,8) lesion in the absence or presence of dCTP. The Dpo4·DNA-dG(1,8) binary structure shows that the aminopyrene moiety of the lesion stacks against the primer/template junction pair, while its dG moiety projected into the cleft between the Finger and Little Finger domains of Dpo4. In the Dpo4·DNA-dG(1,8)·dCTP ternary structure, the aminopyrene moiety of the dG(1,8) lesion, is sandwiched between the nascent and junction base pairs, while its base is present in the major groove. Moreover, dCTP forms a Watson-Crick base pair with dG, two nucleotides upstream from the dG(1,8) site, creating a complex for "-2" frameshift mutation. Mechanistically, these crystal structures provide additional insight into the aforementioned minimal kinetic mechanism.

Project description:3-Nitrobenzanthrone (3-NBA), a nitropolyaromatic hydrocarbon (NitroPAH) pollutant in diesel exhaust, is a potent mutagen and carcinogen. After metabolic activation, the primary metabolites of 3-NBA react with DNA to form dG and dA adducts. One of the three major adducts identified is N-(2'-deoxyguanosin-8-yl)-3-aminobenzanthrone (dG(C8-N-ABA)). This bulky adduct likely stalls replicative DNA polymerases but can be traversed by lesion bypass polymerases in vivo. Here, we employed running start assays to show that a site-specifically placed dG(C8-N-ABA) is bypassed in vitro by Sulfolobus solfataricus DNA polymerase IV (Dpo4), a model Y-family DNA polymerase. However, the nucleotide incorporation rate of Dpo4 was significantly reduced opposite both the lesion and the template position immediately downstream from the lesion site, leading to two strong pause sites. To investigate the kinetic effect of dG(C8-N-ABA) on polymerization, we utilized pre-steady-state kinetic methods to determine the kinetic parameters for individual nucleotide incorporations upstream, opposite, and downstream from the dG(C8-N-ABA) lesion. Relative to the replication of the corresponding undamaged DNA template, both nucleotide incorporation efficiency and fidelity of Dpo4 were considerably decreased during dG(C8-N-ABA) lesion bypass and the subsequent extension step. The lower nucleotide incorporation efficiency caused by the lesion is a result of a significantly reduced dNTP incorporation rate constant and modestly weaker dNTP binding affinity. At both pause sites, nucleotide incorporation followed biphasic kinetics with a fast and a slow phase and their rates varied with nucleotide concentration. In contrast, only the fast phase was observed with undamaged DNA. A kinetic mechanism was proposed for the bypass of dG(C8-N-ABA) bypass catalyzed by Dpo4.

Project description:1-Nitropyrene (1-NP), a mutagen and potential carcinogen, is the most abundant nitro polyaromatic hydrocarbon in diesel exhaust, which reacts with DNA to form predominantly N-(deoxyguanosin-8-yl)-1-aminopyrene (dG(AP)). If not repaired, this DNA lesion is presumably bypassed in vivo by any of human Y-family DNA polymerases kappa (hPol?), iota (hPol?), eta (hPol?), and Rev1 (hRev1). Our running start assays demonstrated that each of these enzymes was indeed capable of traversing a site-specifically placed dG(AP) on a synthetic DNA template but that hRev1 was stopped after lesion bypass. The time required to bypass 50% of the dG(AP) sites (t(50)(bypass)) encountered by hPol?, hPol?, and hPol? was determined to be 2.5 s, 4.1 s, and 106.5 s, respectively. The efficiency order of catalyzing translesion synthesis of dG(AP) (hPol? > hPol? > hPol? ? hRev1) is the same as the order for these human Y-family enzymes to elongate undamaged DNA. Although hPol? bypassed dG(AP) efficiently, replication by both hPol? and hPol? was strongly stalled at the lesion site and at a site immediately downstream from dG(AP). By employing presteady state kinetic methods, a kinetic basis was established for polymerase pausing at these DNA template sites. Besides efficiency of bypass, the fidelity of those low-fidelity polymerases at these pause sites was also significantly decreased. Thus, if the translesion DNA synthesis of dG(AP)in vivo is catalyzed by a human Y-family DNA polymerase, e.g., hPol?, the process is certainly mutagenic.

Project description:Translesion DNA synthesis is an essential process that helps resume DNA replication at forks stalled near bulky adducts on the DNA. Benzo[a]pyrene (B[a]P) is a polycyclic aromatic hydrocarbon (PAH) that can be metabolically activated to benzo[a]pyrene diol epoxide (BPDE), which then can react with DNA to form carcinogenic DNA adducts. Here, we have used single-molecule florescence resonance energy transfer (smFRET) experiments, classical molecular dynamics simulations, and nucleotide incorporation assays to investigate the mechanism by which the model Y-family polymerase, Dpo4, bypasses a (+)-cis-B[a]P-N 2-dG adduct in DNA. Our data show that when (+)-cis-B[a]P-N 2-dG is the templating base, the B[a]P moiety is in a non-solvent exposed conformation stacked within the DNA helix, where it effectively blocks nucleotide incorporation across the adduct by Dpo4. However, when the media contains a small amount of dimethyl sulfoxide (DMSO), the adduct is able to move to a solvent-exposed conformation, which enables error-prone DNA replication past the adduct. When the primer terminates across from the adduct position, the addition of DMSO leads to the formation of an insertion complex capable of accurate nucleotide incorporation.

Project description:Platinum drugs are a mainstay of anticancer chemotherapy. Nevertheless, tumors often display inherent or acquired resistance to platinum-based treatments, prompting the search for new compounds that do not exhibit cross-resistance with current therapies. Phenanthriplatin, cis-diamminephenanthridinechloroplatinum(II), is a potent monofunctional platinum complex that displays a spectrum of activity distinct from those of the clinically approved platinum drugs. Inhibition of RNA polymerases by phenanthriplatin lesions has been implicated in its mechanism of action. The present study evaluates the ability of phenanthriplatin lesions to inhibit DNA replication, a function disrupted by traditional platinum drugs. Phenanthriplatin lesions effectively inhibit DNA polymerases ?, ?, and ? and the Klenow fragment. In contrast to results obtained with DNA damaged by cisplatin, all of these polymerases were capable of inserting a base opposite a phenanthriplatin lesion, but only Pol ?, an enzyme efficient in translesion synthesis, was able to fully bypass the adduct, albeit with low efficiency. X-ray structural characterization of Pol ? complexed with site-specifically platinated DNA at both the insertion and +1 extension steps reveals that phenanthriplatin on DNA interacts with and inhibits Pol ? in a manner distinct from that of cisplatin-DNA adducts. Unlike cisplatin and oxaliplatin, the efficacies of which are influenced by Pol ? expression, phenanthriplatin is highly toxic to both Pol ?+ and Pol ?- cells. Given that increased expression of Pol ? is a known mechanism by which cells resist cisplatin treatment, phenanthriplatin may be valuable in the treatment of cancers that are, or can easily become, resistant to cisplatin.

Project description:Heterocyclic aromatic amines produce bulky C8 guanine lesions in vivo, which interfere and disrupt DNA and RNA synthesis. These lesions are consequently strong replication blocks. In addition bulky adducts give rise to point and frameshift mutations. The translesion synthesis (TLS) DNA polymerase ? is able to bypass slowly C8 bulky adduct lesions such as the widely studied 2-aminofluorene-dG and its acetylated analogue mainly in an error-free manner. Replicative polymerases are in contrast fully blocked by the acetylated lesion. Here, we show that TLS efficiency of Pol ? depends critically on the size of the bulky adduct forming the lesion. Based on the crystal structure, we show why the bypass reaction is so difficult and we provide a model for the bypass reaction. In our model, TLS is accomplished without rotation of the lesion into the anti conformation as previously thought.

Project description:3-Nitrobenzanthrone (3-NBA), a byproduct of diesel exhaust, is highly present in the environment and poses a significant health risk. Exposure to 3-NBA results in formation of N-(2'-deoxyguanosin-8-yl)-3-aminobenzanthrone (dGC8-N-ABA), a bulky DNA lesion that is of particular importance due to its mutagenic and carcinogenic potential. If not repaired or bypassed during genomic replication, dGC8-N-ABA can stall replication forks, leading to senescence and cell death. Here we used pre-steady-state kinetic methods to determine which of the four human Y-family DNA polymerases (hPol?, hPol?, hPol?, or hRev1) are able to catalyze translesion synthesis of dGC8-N-ABAin vitro. Our studies demonstrated that hPol? and hPol? most efficiently bypassed a site-specifically placed dGC8-N-ABA lesion, making them good candidates for catalyzing translesion synthesis (TLS) of this bulky lesion in vivo. Consistently, our publication (Biochemistry 53, 5323-31) in 2014 has shown that small interfering RNA-mediated knockdown of hPol? and hPol? in HEK293T cells significantly reduces the efficiency of TLS of dGC8-N-ABA. In contrast, hPol? and hRev1 were severely stalled by dGC8-N-ABA and their potential role in vivo was discussed. Subsequently, we determined the kinetic parameters for correct and incorrect nucleotide incorporation catalyzed by hPol? at various positions upstream, opposite, and downstream from dGC8-N-ABA. Notably, nucleotide incorporation efficiency and fidelity both decreased significantly during dGC8-N-ABA bypass and the subsequent extension step, leading to polymerase pausing and error-prone DNA synthesis by hPol?. Furthermore, hPol? displayed nucleotide concentration-dependent biphasic kinetics at the two polymerase pause sites, suggesting that multiple enzyme•DNA complexes likely exist during nucleotide incorporation.

Project description:Environmental exposure and endogenous metabolism can give rise to DNA alkylation. Among alkylated nucleosides, O(4)-alkylthymidine (O(4)-alkyldT) lesions are poorly repaired in mammalian systems and may compromise the efficiency and fidelity of cellular DNA replication. To cope with replication-stalling DNA lesions, cells are equipped with translesion synthesis DNA polymerases that are capable of bypassing various DNA lesions. In this study, we assessed human DNA polymerase ? (Pol ?)-mediated bypass of various O(4)-alkyldT lesions, with the alkyl group being Me, Et, nPr, iPr, nBu, iBu, (R)-sBu, or (S)-sBu, in template DNA by conducting primer extension and steady-state kinetic assays. Our primer extension assay results revealed that human Pol ?, but not human polymerases ? and ? or yeast polymerase ?, was capable of bypassing all O(4)-alkyldT lesions and extending the primer to generate full-length replication products. Data from steady-state kinetic measurements showed that Pol ? preferentially misincorporated dGMP opposite O(4)-alkyldT lesions with a straight-chain alkyl group. The nucleotide misincorporation opposite most lesions with a branched-chain alkyl group was, however, not selective, where dCMP, dGMP, and dTMP were inserted at similar efficiencies opposite O(4)-iPrdT, O(4)-iBudT, and O(4)-(R)-sBudT. These results provide important knowledge about the effects of the length and structure of the alkyl group in O(4)-alkyldT lesions on the fidelity and efficiency of DNA replication mediated by human Pol ?.

Project description:Human DNA Pol ? is a polymerase enzyme, specialized for near error-free bypass of certain bulky chemical lesions to DNA that are derived from environmental carcinogens present in tobacco smoke, automobile exhaust and cooked food. By employing ab initio QM/MM-MD (Quantum Mechanics/Molecular Mechanics-Molecular Dynamics) simulations with umbrella sampling, we have determined the entire free energy profile of the nucleotidyl transfer reaction catalyzed by Pol ? and provided detailed mechanistic insights. Our results show that a variant of the Water Mediated and Substrate Assisted (WMSA) mechanism that we previously deduced for Dpo4 and T7 DNA polymerases is preferred for Pol ? as well, suggesting its broad applicability. The hydrogen on the 3'-OH primer terminus is transferred through crystal and solvent waters to the ?-phosphate of the dNTP, followed by the associative nucleotidyl transfer reaction; this is facilitated by a proton transfer from the ?-phosphate to the ?,?-bridging oxygen as pyrophosphate leaves, to neutralize the evolving negative charge. MD simulations show that the near error-free incorporation of dCTP opposite the major benzo[a]pyrene-derived dG lesion is compatible with the WMSA mechanism, allowing for an essentially undisturbed pentacovalent phosphorane transition state, and explaining the bypass of this lesion with little mutation by Pol ?.