The Cdc45-MCM-GINS (CMG) helicase unwinds DNA during the elongation step of eukaryotic genome duplication and this process depends on the MCM ATPase function. Whether CMG translocation occurs on single- or double-stranded DNA and how ATP hydrolysis drives DNA unwinding remain open questions. Here we use cryo-electron microscopy to describe two subnanometre resolution structures of the CMG helicase trapped on a DNA fork. In the predominant state, the ring-shaped C-terminal ATPase of MCM is compact and contacts single-stranded DNA, via a set of pre-sensor 1 hairpins that spiral around the translocation substrate. In the second state, the ATPase module is relaxed and apparently substrate free, while DNA intimately contacts the downstream amino-terminal tier of the MCM motor ring. These results, supported by single-molecule FRET measurements, lead us to suggest a replication fork unwinding mechanism whereby the N-terminal and AAA+ tiers of the MCM work in concert to translocate on single-stranded DNA.
Deletions in mitochondrial DNA (mtDNA) are associated with diverse human pathologies including cancer, aging and mitochondrial disorders. Large-scale deletions span kilobases in length and the loss of these associated genes contributes to crippled oxidative phosphorylation and overall decline in mitochondrial fitness. There is not a united view for how mtDNA deletions are generated and the molecular mechanisms underlying this process are poorly understood. This review discusses the role of replication and repair in mtDNA deletion formation as well as nucleic acid motifs such as repeats, secondary structures, and DNA damage associated with deletion formation in the mitochondrial genome. We propose that while erroneous replication and repair can separately contribute to deletion formation, crosstalk between these pathways is also involved in generating deletions.
Oligonucleotides that hybridize to modified DNA are useful chemical tools to probe the noncovalent interactions that stabilize DNA duplexes. In an effort to better understand the interactions that influence the specificity of hybridization probes for O(6)-alkylguanine lesions, we examined a series of synthetic nucleoside analogues (BIM, Benzi, and Peri) with respect to their ability to stabilize duplex DNA comprised of native or damaged DNA oligonucleotides. The base-modified nucleoside analogues contained systematically varied hydrogen-bonding and π-stacking properties. The nucleoside probes were incorporated into DNA and paired opposite canonical bases (A, T, C, or G), O(6) -methylguanine (O(6)-MeG), O(6)-benzylguanine (O(6)-BnG), or a stable abasic site analogue (tetrahydrofuran, THF). On the basis of the free energy of duplex formation, the highest degree of stabilization was observed when Peri was paired opposite O(6)-MeG. The thermodynamic data suggest that the smaller probes stabilize DNA duplexes more through hydrogen bonding, whereas the larger probes, with a greater capacity to π stack, contribute to duplex stabilization more on the basis of base stacking. These results demonstrate that increased helix stability could be achieved when BIM, Benzi, or Peri were paired opposite damage-containing DNA rather than unmodified DNA (that is, O(6)-MeG rather than G). This knowledge is expected to be useful in the design and development of nucleoside analogues for uses in DNA-based technologies.
The ability of a DNA polymerase to replicate DNA beyond a mismatch containing a DNA lesion during postlesion DNA synthesis (PLS) can be a contributing factor to mutagenesis. In this study, we investigate the ability of Dpo4, a Y-family DNA polymerase from Sulfolobus solfataricus, to perform PLS beyond the pro-mutagenic DNA adducts O(6)-benzylguanine (O(6)-BnG) and O(6)-methylguanine (O(6)-MeG). Here, O(6)-BnG and O(6)-MeG were paired opposite artificial nucleosides that were structurally altered to systematically test the influence of hydrogen bonding and base pair size and shape on O(6)-alkylguanine PLS. Dpo4-mediated PLS was more efficient past pairs containing Benzi than pairs containing the other artificial nucleoside probes. Based on steady-state kinetic analysis, frequencies of mismatch extension were 7.4 × 10(-3) and 1.5 × 10(-3) for Benzi:O(6)-MeG and Benzi:O(6)-BnG pairs, respectively. Correct extension was observed when O(6)-BnG and O(6)-MeG were paired opposite the smaller nucleoside probes Benzi and BIM; conversely, Dpo4 did not extend past the larger nucleoside probes, Peri and Per, placed opposite O(6)-BnG and O(6)-MeG. Interestingly, Benzi was extended with high fidelity by Dpo4 when it was paired opposite O(6)-BnG and O(6)-MeG but not opposite G. These results indicate that hydrogen bonding is an important noncovalent interaction that influences the fidelity and efficiency of Dpo4 to perform high-fidelity O(6)-alkylguanine PLS.
The influence of base pair size and shape on the fidelity of DNA polymerase-mediated extension past lesion-containing mispairs was examined. Primer extension analysis was performed with synthetic nucleosides paired opposite the pro-mutagenic DNA lesion O(6)-benzylguanine (O(6)-BnG). These data indicate that the error-prone DNA polymerase IV (Dpo4) inefficiently extended past the larger Peri:O(6)-BnG base pair, and in contrast, error-free extension was observed for the smaller BIM:O(6)-BnG base pair. Steady-state kinetic analysis revealed that Dpo4 catalytic efficiency was strongly influenced by the primer:template base pair. Compared to the C:G pair, a 1.9- and 79,000-fold reduction in Dpo4 efficiency was observed for terminal C:O(6)-BnG and BIM:G base pairs respectively. These results demonstrate the impact of geometrical size and shape on polymerase-mediated mispair extension.
Given the worldwide popularity of hair dyeing, there is an urgent need to understand the toxicities and risks associated with exposure to chemicals found in hair dye formulations. Hair dyes are categorized as oxidative and nonoxidative in terms of their chemical composition and ingredients. For several decades, the expert panel’s Cosmetic Ingredient Review (CIR) has assessed the safety of many of the chemicals used in hair dyes; however, a comprehensive review of hair dye ingredients and the risk of exposure to hair dyeing has not been documented. Herein, we review the safety of the various chemicals in oxidative and nonoxidative hair dyes, toxicities associated with hair dyeing, and the carcinogenic risks related to hair dyeing. While many compounds are considered safe for users at the concentrations in hair dyes, there are conflicting data about a large number of hair dye formulations. The CIR expert panel has ratified a number of coloring ingredients for hair dyes and banned a series of chemicals as carcinogenic to animals and unsafe for this application. The use of these chemicals as raw materials for producing hair dyes may result in the synthesis of other contaminants with potential toxicities and increased risk of carcinogenesis. It is an open question whether personal or occupational hair dyeing increases the risk of cancer; however, in specific subpopulations, a positive association between hair dye use and cancer occurrence has been reported. To address this question, a better understanding of the chemical and mechanistic basis of the reported toxicities of hair dye mixtures and individual hair dye ingredients is needed. It is anticipated that in-depth chemical and systems toxicology studies harnessing modern and emerging techniques can shed light on this public health concern in the future.
DNA synthesis, carried out by DNA polymerases, requires balancing speed and accuracy for faithful replication of the genome. High fidelity DNA polymerases contain a 3′–5′ exonuclease domain that can remove misincorporated nucleotides on the 3′ end of the primer strand, a process called proofreading. The E. coli replicative polymerase, DNA polymerase III, has spatially separated (~55 Å apart) polymerase and exonuclease subunits. Here, we report on the dynamics of E. coli DNA polymerase III proofreading in the presence of its processivity factor, the β2-sliding clamp, at varying base pair termini using single-molecule FRET. We find that the binding kinetics do not depend on the base identity at the termini, indicating a tolerance for DNA mismatches. Further, our single-molecule data and MD simulations show two previously unobserved features: (1) DNA Polymerase III is a highly dynamic protein that adopts multiple conformational states while bound to DNA with matched or mismatched ends, and (2) an exonuclease-deficient DNA polymerase III has reduced conformational flexibility. Overall, our single-molecule experiments provide high time-resolution insight into a mechanism that ensures high fidelity DNA replication to maintain genome integrity.
Faithful replication of DNA is a critical aspect in maintaining genome integrity. DNA polymerases are responsible for replicating DNA, and high-fidelity polymerases do this rapidly and at low error rates. Upon exposure to exogenous or endogenous substances, DNA can become damaged and this can alter the speed and fidelity of a DNA polymerase. In this instance, DNA polymerases are confronted with an obstacle that can result in genomic instability during replication, for example, by nucleotide misinsertion or replication fork collapse. It is important to know how DNA polymerases respond to damaged DNA substrates to understand the mechanism of mutagenesis and chemical carcinogenesis. Single-molecule techniques have helped to improve our current understanding of DNA polymerase-mediated DNA replication, as they enable the dissection of mechanistic details that can otherwise be lost in ensemble-averaged experiments. These techniques have also been used to gain a deeper understanding of how single DNA polymerases behave at the site of the damage in a DNA substrate. In this review, we evaluate single-molecule studies that have examined the interaction between DNA polymerases and damaged sites on a DNA template.■ CONTENTS
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