uracil-DNA Glycosylase Research Articles

An ultra-sensitive and specific UCBiosensor via CRISPR-Cas12a and UDG-mediated polymerase chain reaction

DNA damage is an important cause of several diseases. Uracil DNA glycosylase (UDG) is a key enzyme in DNA damage repair and used as an early diagnostic marker and a prognostic indicator for cancer. Therefore, there is an urgent need to develop a simple, low-background, ultra-sensitive UDG activity detection method for clinical applications. At present, biosensors based on CRISPR-Cas12a have become a powerful diagnostic tool owing to their high sensitivity. Here, we have established an ultra-sensitive biosensor for detecting UDG activity based on CRISPR-Cas12a coupled UDG-mediated polymerase chain reaction (U-PCR), which has the advantages of simplicity, low background, ultra-sensitivity, and specificity. We used this biosensor to multiply amplify the UDG signal, and the detection limit reached 3.5 × 10−6 U/mL, which is one of the most sensitive methods for UDG activity detection. Finally, we detected UDG activity in the lysates of cancer cells, indicating that this method could be used to detect UDG activity in real samples. The UDG inhibition test showed that the method we established is a useful tool for screening UDG inhibitors. We believe that the UDG activity detection biosensor established in this study has potential applications in biomedical research and clinical diagnosis.

Dynamic and Reversible Decoration of DNA-Based Scaffolds.

An approach to achieving dynamic and reversible decoration of DNA-based scaffolds is demonstrated here. To do this, rationally engineered DNA tiles containing enzyme-responsive strands covalently conjugated to different molecular labels are employed. These strands are designed to be recognized and degraded by specific enzymes (i.e., Ribonuclease H, RNase H, or Uracil DNA Glycosylase, UDG) inducing their spontaneous de-hybridization from the assembled tile and replacement by a new strand conjugated to a different label. Multiple enzyme-responsive strands that specifically respond to different enzymes allow for dynamic, orthogonal, and reversible decoration of the DNA structures. As a proof-of-principle of the strategy, the possibility to orthogonally control the distribution of different labels (i.e., fluorophores and small molecules) on the same scaffold without crosstalk is demonstrated. By doing so, DNA scaffolds that display different antibody recognition patterns are obtained. The approach offers the possibility to control the decoration of higher-order supramolecular assemblies (including origami) with several functional moieties to achieve functional biomaterials with improved adaptability, precision, and sensing capabilities.

Ionic strength modulates excision of uracil by SMUG1 from nucleosome core particles

Ionic strength affects many cellular processes including the packaging of genetic material in eukaryotes. For example, chromatin fibers are compacted in high ionic strength environments as are the minimal unit of packaging in chromatin, nucleosome core particles (NCPs). Furthermore, ionic strength is known to modulate several aspects of NCP dynamics including transient unwrapping of DNA from the histone protein core, nucleosome gaping, and intra- and internucleosomal interactions of the N-terminal histone tails. Changes in NCP structure may also impact interactions of transcriptional, repair, and other cellular machinery with nucleosomal DNA. One repair process, base excision repair (BER), is impacted by NCP structure and may be further influenced by changes in ionic strength. Here we examine the effects of ionic strength on the initiation of BER using biochemical assays. Using a population of NCPs containing uracil (U) at dozens of geometric locations, excision of U by single-strand selective monofunctional uracil DNA glycosylase (SMUG1) is assessed at higher and lower ionic strengths. SMUG1 has increased excision activity in the lower ionic strength conditions. On duplex DNA, however, SMUG1 activity is largely unaffected by ionic strength except at short incubation times, suggesting that changes in SMUG1 activity are likely due to alterations in NCP structure and dynamics. These results allow us to further understand the cellular role of SMUG1 in a changing ionic environment and broadly contribute to the understanding of BER on chromatin and genomic stability.

Uracil-DNA glycosylase efficiency is modulated by substrate rigidity

Uracil DNA-glycosylase (UNG) is a DNA repair enzyme that removes the highly mutagenic uracil lesion from DNA using a base flipping mechanism. Although this enzyme has evolved to remove uracil from diverse sequence contexts, UNG excision efficiency depends on DNA sequence. To provide the molecular basis for rationalizing UNG substrate preferences, we used time-resolved fluorescence spectroscopy, NMR imino proton exchange measurements, and molecular dynamics simulations to measure UNG specificity constants (kcat/KM) and DNA flexibilities for DNA substrates containing central AUT, TUA, AUA, and TUT motifs. Our study shows that UNG efficiency is dictated by the intrinsic deformability around the lesion, establishes a direct relationship between substrate flexibility modes and UNG efficiency, and shows that bases immediately adjacent to the uracil are allosterically coupled and have the greatest impact on substrate flexibility and UNG activity. The finding that substrate flexibility controls UNG efficiency is likely significant for other repair enzymes and has major implications for the understanding of mutation hotspot genesis, molecular evolution, and base editing.

Influence of Poly(ADP-ribose)polymerase 1 Level on the Status of Base Excision Repair in Human Cells

The base excision repair (BER) system is aimed at repair of the largest group of DNA lesions, namely of damaged bases. The main steps in BER are: recognition and removal of the aberrant base, cutting the DNA sugar-phosphate backbone, gap processing (including dNMP insertion), and DNA ligation. The precise functioning of BER depends on the regulation of each step of the process by regulatory/accessory proteins, the most important of which is poly(ADP-ribose)polymerase 1 (PARP1). PARP1 plays an important role in various processes of DNA repair, maintenance of genome integrity, and regulation of mRNA stability and decay. In this regard, PARP1 can affect BER both at the level of proteins involved in the process and at the level of expression of the mRNAs encoding them. There are no systematic data on the effect of various amounts of PARP1 on the activity of key BER proteins and the levels of mRNAs encoding them in human cells. In our work, using whole-cell extracts and RNA preparations obtained from the parental HEK293T cell line and its derivative HEK293T/P1-KD cell line with reduced PARP1 expression (shPARP1-expressing cells, PARP1 knockdown), we assessed the levels of mRNA encoding BER proteins: PARP1, PARP2, uracil DNA glycosylase (UNG2), AP endonuclease 1 (APE1), DNA polymerase β (POLβ), DNA ligase III (LIG3), and XRCC1. In parallel, the catalytic activity of these enzymes was evaluated. No significant effect of the PARP1 amount of on the mRNA levels of UNG2, APE1, POLβ, LIG3, and XRCC1 was found. At the same time, in HEK293T/P1-KD cells, the amount of PARP2 mRNA was reduced by 2 times. The activities of these enzymes in whole-cell extracts of HEK293T and HEK293T/P1-KD cells also did not differ significantly. Under the conditions of poly(ADP-ribose) synthesis, the efficiency of the reactions catalyzed by UNG2, APE1, POLβ, and LIG3 also did not change significantly. In addition, it was shown that a reduced amount of PARP1 in the extract of HEK293T/P1-KD cells does not cause fundamental changes in the nature of DNA PARylation compared to the extract of the parental HEK293T cell line.

Programmable strand displacement-driven assembly of single quantum dot nanosensor for accurately monitoring human SMUG1 uracil-DNA glycosylase at single-cell level

Human single-stranded selective monofunctional uracil glycosylase (hSMUG1) is an important uracil-DNA glycosylase (UDG) subfamily responsible for repair of uracil and oxidized pyrimidine derivatives as well as maintenance of genomic integrity. The abnormal hSMUG1 level is closely associated with various human diseases and cancers. Herein, we demonstrate for the first time the programmable strand displacement-driven assembly of single quantum-dot (QD) nanosensor for accurately monitoring hSMUG1 at single-cell level. We used an oxidation marker 5-hydroxymethyluracil (5hmU) as a novel specific catalysis site for hSMUG1. The presence of hSMUG1 catalyzes 5hmU excision to activate exponential strand-displacement cascades for producing abundant primer probes. Subsequently, primer probes induce the self-assembly of 605QD-dsDNA-Cy5 nanostructures and fluorescence resonance energy transfer (FRET) between 605QD and Cy5. The FRET signal can be quantified via single-molecule imaging. This single QD nanosensor exhibits a detection limit of 7.08 × 10−11 U/μL over a wide dynamic range of 8 orders of magnitude. Importantly, it can measure enzymatic kinetics, screen potential inhibitors, discriminate hSMUG1 expression between cancer cells and normal cells, and quantify hSMUG1 activity in various cancer cells at single-cell level, promising a new avenue for hSMUG1-related biomedical studies and clinical diagnostics.

Carp edema virus in Ukraine – The evidence for the furthest east presence of CEV genogroup I in Europe

Carp edema virus (CEV) is a poxvirus infecting gills of common carp (Cyprinus carpio) and causes a deadly disease called koi sleepy disease (KSD). Currently thanks to higher vigilance and screening for its presence the virus was confirmed to be widespread on the European continent and affects both ornamental koi, farmed and feral common carp. Phylogenetic research of CEV is however in its infancy. Until recently due to the lack of available sequence information, the phylogenetic analysis was limited to a p4a gene. Based on this gene two main clades were established. The genogroup I clade is of European origin and can be found in farmed or feral common carp in Europe. However, the eastern border of the geographic range of CEV from genogroup I is not yet established, therefore we decided to obtain samples from clinically affected carp from Ukraine. Furthermore, we used sequences of the DNA binding viral core protein 8 (VP8) and of the uracil DNA glycosylase (UDGS) to confirm the existence of the genogroups I and II. The results indicate that CEV is highly prevalent in Ukraine. Phylogenetic analysis using the p4a gene showed that common carps in Ukraine are infected with CEV genogroup I. The two additional genes used for the phylogenetic analysis supported the phylogenetic findings. This confirms that common carps in continental Europe are hosts for CEV from the genogroup I and the geographic range for this virus is reaching to the most eastern parts of Ukraine.

Ultra-sensitive biosensor based on CRISPR-Cas12a and Endo IV coupled DNA hybridization reaction for uracil DNA glycosylase detection and intracellular imaging

As an essential biomarker associated with various diseases, Uracil-DNA Glycosylase (UDG) detection is vital for disease diagnosis, treatment selection, and prognosis assessment. In recent years, the signal amplification effect of the CRISPR-Cas12a trans-cleaved single-stranded DNA probe has provided an available strategy for constructing highly sensitive biosensors. However, its superior trans-cleavage activity has become a “double-edged sword” for building biosensors that can amplify the target signal while also amplifying the leakage signal, causing out of control. Therefore, the construction of structurally simple, extremely low-background, highly sensitive CRISPR-Cas12a-based biosensors is an urgent bottleneck problem in the field. Here, we applied CRISPR-Cas12a with a DNA hybridization reaction to develop a simple, rapid, low background, and highly sensitive method for UDG activity detection. It has no PAM restriction and the detection limit is as low as 2.5 × 10−6 U/mL. As far as we know, this method is one of the most sensitive methods for UDG detection. We also used this system to analyze UDG activity in tumor cells (LOD: 1 cell/uL) and to evaluate the ability to screen for UDG inhibitors. Furthermore, we verified the possibility of intracellular UDG activity imaging by transfecting the biosensors to the cells. We believe this novel sensor has good clinical application prospects and will effectively broaden the application space of CRISPR-Cas12a.

Uracil-DNA glycosylase efficiency is modulated by substrate rigidity.

DNA sequence effects have been identified for many glycosylases and alkyl-transferases that repair base mismatches, uracil bases, alkylated bases, etc. Here, we focused on understanding how DNA sequence impacts the repair of uracil, a highly mutagenic and common lesion in DNA. Uracil DNA-glycosylase (UNG) is a base excision repair enzyme that removes uracil from DNA by a base flipping mechanism. UNG excision efficiency depends on DNA sequence. We show that UNG efficiency is dictated by the intrinsic local deformability of the substrate sequence around the uracil. UNG specificity constants (kcat/KM) and DNA flexibilities were measured for an engineered set of DNA substrates. Time-resolved fluorescence spectroscopy, NMR imino proton exchange measurements, and molecular dynamics simulations of the bare DNA indicated significant differences in substrate flexibilities. We observed a strong correlation between UNG efficiency and substrate flexibility, with higher kcat/KM values measured for more flexible strands. DNA bending and base flipping were observed in simulations, with more frequent uracil flipping observed for the more bendable sequences. Experiments show that bases immediately adjacent to the uracil are allosterically coupled and have the greatest impact on substrate flexibility and resultant UNG activity. A better understanding of the fundamental principles that dictate UNG activity has broad implications in diverse fields, from cancer to evolution.

2-Amino purine as a probe of DNA deformability in damaged DNA.

2-Amino purine (2AP) is an isomer of adenine (6-aminopurine) that, unlike the canonical DNA bases, is highly fluorescent when free in solution. The fluorescence quantum yield of 2AP in water is 0.68, and its fluorescence intensity decay is monoexponential with a single lifetime of 10-11 ns. When incorporated into DNA, 2AP fluorescence is quenched strongly by interactions with its neighboring bases. Inter-base interactions in duplex DNA give rise to a multiexponential decay that reflects the highly heterogeneous environment sensed by the probe. We used steady-state and time-resolved 2AP fluorescence to probe DNA dynamics around a lesion. In this work, we focused on uracil, a highly mutagenic and common lesion in DNA. In the cell, uracil is removed by Uracil DNA-glycosylase (UNG). UNG excision efficiency depends on DNA sequence, and this research is part of a broader study aimed to elucidate the underlying principles that dictate UNG substrate specificity. Duplex DNA substrates were prepared by annealing uracil-containing oligonucleotides with complementary strands containing 2AP opposite to the uracil. Fluorescence lifetimes were measured with 40 ps resolution, and results were analyzed together with the measured fluorescence quantum yields to calculate the fraction of ultra-quenched 2AP molecules. A higher fraction indicates a higher fraction of highly stacked (and therefore efficiently quenched) 2AP molecules, which we interpret as evidence for a less deformable substrate. This interpretation is supported by NMR imino proton exchange measurements and molecular dynamics simulations on the same substrates.

Influence of the Poly(ADP-Ribose) Polymerase 1 Level on the Status of Base Excision Repair in Human Cells

Base excision repair (BER) is aimed at repair of damaged bases, which are the largest group of DNA lesions. The main steps of BER are recognition and removal of the aberrant base, cutting of the DNA sugar-phosphate backbone, gap processing (including dNMP insertion), and DNA ligation. The precise function of BER depends on the regulation of each step by regulatory/accessory proteins, the most important of which is poly(ADP-ribose) (PAR) polymerase 1 (PARP1). PARP1 plays an important role in DNA repair, maintenance of genome integrity, and regulation of mRNA stability and decay. PARP1 can therefore affect BER both at the level of BER proteins and at the level of their mRNAs. There is no systematic data on how the PARP1 content affects the activities of key BER proteins and the levels of their mRNAs in human cells. Whole-cell extracts and RNA preparations obtained from the parental HEK293T cell line and its derivative HEK293T/P1-KD cell line with reduced PARP1 expression (shPARP1-expressing cells, a PARP1 knockdown) were used to assess the levels of mRNAs coding for BER proteins: PARP1, PARP2, uracil DNA glycosylase (UNG2), AP endonuclease 1 (APE1), DNA polymerase β (POLβ), DNA ligase III (LIG3), and XRCC1. Catalytic activities of the enzymes were evaluated in parallel. No significant effect of the PARP1 content was observed for the mRNA levels of UNG2, APE1, POLβ, LIG3, and XRCC1. The amount of the PARP2 mRNA proved to be reduced two times in HEK293T/P1-KD cells. Activities of these enzymes in whole-cell extracts did not differ significantly between HEK293T and HEK293T/P1-KD cells. No significant change was observed in the efficiencies of the reactions catalyzed by UNG2, APE1, POLβ, and LIG3 in conditions of PAR synthesis. A DNA PARylation pattern did not dramatically change in a HEK293T/P1-KD cell extract with a reduced PARP1 content as compared with an extract of the parental HEK293T cell line.

DNA Base Excision Repair Intermediates Influence Duplex-Quadruplex Equilibrium.

Although genomic DNA is predominantly duplex under physiological conditions, particular sequence motifs can favor the formation of alternative secondary structures, including the G-quadruplex. These structures can exist within gene promoters, telomeric DNA, and regions of the genome frequently found altered in human cancers. DNA is also subject to hydrolytic and oxidative damage, and its local structure can influence the type of damage and its magnitude. Although the repair of endogenous DNA damage by the base excision repair (BER) pathway has been extensively studied in duplex DNA, substantially less is known about repair in non-duplex DNA structures. Therefore, we wanted to better understand the effect of DNA damage and repair on quadruplex structure. We first examined the effect of placing pyrimidine damage products uracil, 5-hydroxymethyluracil, the chemotherapy agent 5-fluorouracil, and an abasic site into the loop region of a 22-base telomeric repeat sequence known to form a G-quadruplex. Quadruplex formation was unaffected by these analogs. However, the activity of the BER enzymes were negatively impacted. Uracil DNA glycosylase (UDG) and single-strand selective monofunctional uracil DNA glycosylase (SMUG1) were inhibited, and apurinic/apyrimidinic endonuclease 1 (APE1) activity was completely blocked. Interestingly, when we performed studies placing DNA repair intermediates into the strand opposite the quadruplex, we found that they destabilized the duplex and promoted quadruplex formation. We propose that while duplex is the preferred configuration, there is kinetic conversion between duplex and quadruplex. This is supported by our studies using a quadruplex stabilizing molecule, pyridostatin, that is able to promote quadruplex formation starting from duplex DNA. Our results suggest how DNA damage and repair intermediates can alter duplex-quadruplex equilibrium.

Cytosine base editing in cyanobacteria by repressing archaic Type IV uracil-DNA glycosylase.

Base editing enables precise gene editing without requiring donor DNA or double-stranded breaks. To facilitate base editing tools, a uracil DNA glycosylase inhibitor (UGI) was fused to cytidine deaminase-Cas nickase to inhibit uracil DNA glycosylase (UDG). Herein, we revealed that the bacteriophage PBS2-derived UGI of the cytosine base editor (CBE) could not inhibit archaic Type IV UDG in oligoploid cyanobacteria. To overcome the limitation of the CBE, dCas12a-assisted gene repression of the udg allowed base editing at the desired targets with up to 100% mutation frequencies, and yielded correct phenotypes of desired mutants in cyanobacteria. Compared with the original CBE (BE3), base editing was analyzed within a broader C4 to C16 window with a strong TC-motif preference. Using multiplexed CyanoCBE, while udg was repressed, simultaneous base editing at two different sites was achieved with lower mutation frequencies than single CBE. Our discovery of a Type IV UDG that is not inhibited by the UGI of the CBE in cyanobacteria and the development of dCas12a-mediated base editing should facilitate the application of base editing not only in cyanobacteria, but also in archaea and green algae that possess Type IV UDGs.

Biochemical characterization and mechanistic insight of the family IV uracil DNA glycosylase from Sulfolobus islandicus REY15A

Uracil DNA glycosylase (UDG) can remove uracil from DNA, thus playing an essential role in maintaining genomic stability. Family IV UDG members are mostly widespread in hyperthermophilic Archaea and bacteria. In this work, we characterized the family IV UDG from the hyperthermophilic crenarchaeon Sulfolobus islandicus REY15A (Sis-UDGIV) biochemically, and dissected the roles of nine conserved residues in uracil excision by mutational analyses. Biochemical data demonstrate that Sis-UDGIV displays maximum efficiency for uracil excision at 50 °C ~ 70 °C and at pH 7.0–9.0. Additionally, the enzyme has displays a weak activity without a divalent metal ion, but maximum activity with Mg2+. Our mutational analyses show that residues E48 and F55 in Sis-UDGIV are essential for uracil removal, and residues E48, F55, R87, R92 and K146 are responsible for binding DNA. Importantly, we systemically revealed the roles of four conserved cysteine residues C14, C17, C86 and C102 in Sis-UDGIV that are required for being ligands of FeS cluster in maintaining the overall protein conformation and stability by circular dichroism analyses. Overall, our work has provided insights into biochemical function and DNA-binding specificity of archaeal family IV UDGs.

Profiling Genome-Wide Specificity of dCpf1 Cytidine Base Editors Using Digenome-Seq.

Digenome-seq is a powerful approach for determining the genome-wide specificity of programmable nuclease including CRISPR-Cas9 and CRISPR-Cpf1 (also known as Cas12a) and programmable deaminase including cytosine base editors (CBEs) and adenine base editors (ABEs). To define the genome-wide specificity of dLbCpf1-BE (also known as dLbCas12a-BE), genomic DNA is first incubated with dLbCpf1-BE, which induces C-to-U conversion at on-target and off-target sites, and then treated with a mixture of E. coli uracil DNA glycosylase (UDG) and Endonuclease VIII, which creates single-strand breaks (SSBs) by removing uracil in vitro. Digested genomic DNA is subjected to WGS, and then sequencing reads are aligned to the reference genome, resulting in straight alignments at on-target and off-target sites. The in vitro cleavage sites related to the straight alignments can be identified using the Digenome-seq computer tool.

Assay design for analysis of human uracil DNA glycosylase.

Human uracil DNA glycosylase (UNG2) is an enzyme whose primary function is to remove uracil bases from genomic DNA. UNG2 activity is critical when uracil bases are elevated in DNA during class switch recombination and somatic hypermutation, and additionally, UNG2 affects the efficacy of thymidylate synthase inhibitors that increase genomic uracil levels. Here, we summarize the enzymatic properties of UNG2 and its mitochondrial analog UNG1. To facilitate studies on the activity of these highly conserved proteins, we discuss three fluorescence-based enzyme assays that have informed much of our understanding on UNG2 function. The assays use synthetic DNA oligonucleotide substrates with uracil bases incorporated in the DNA, and the substrates can be single-stranded, double-stranded, or form other structures such as DNA hairpins or junctions. The fluorescence signal reporting uracil base excision by UNG2 is detected in different ways: (1) Excision of uracil from end-labeled oligonucleotides is measured by visualizing UNG2 reaction products with denaturing PAGE; (2) Uracil excision from dsDNA substrates is detected in solution by base pairing uracil with 2-aminopurine, whose intrinsic fluorescence is enhanced upon uracil excision; or (3) UNG2 excision of uracil from a hairpin molecular beacon substrate changes the structure of the substrate and turns on fluorescence by relieving a fluorescence quench. In addition to their utility in characterizing UNG2 properties, these assays are being adapted to discover inhibitors of the enzyme and to determine how protein-protein interactions affect UNG2 function.

An enzyme-free electrochemical biosensor based on NiCoP@PtCu nanozyme and multi-MNAzyme junctions for ultrasensitive Uracil-DNA glycosylase detection

Abnormal expressions of uracil-DNA glycosylase (UDG) have been associated with various diseases. We proposed a novel electrochemical biosensing platform-based strategy for UDG detection. This method combined NiCoP@PtCu nanozyme with multi-MNAzyme junctions. The U base was deleted in the presence of UDG, resulting in self-assembly of multi-MNAzyme junctions with the ability to continually cleave DNA hairpins and release various products. The products could bind the protective probes, exposing capture probes on the electrode’s surface. Moreover, the exposed probes hybridized with the sDNAs-labeled NiCoP@PtCu nanozyme, yielding a significant electrochemical signal. The established biosensor was enzyme-free and with an ultrahigh sensitivity. Benefiting from the twofold amplification of multi-MNAzyme junctions and nanozyme, the sensing technique exhibited a large dynamic range, from 0.001 to 1.0 U mL −1 and a low detection of 6.6 × 10−4 U mL −1. In addition, the method was effectively used for UDG detection in lysed cells. Therefore, the biosensor we established has broad prospects in clinical diagnosis and biomedical research.

Rapid excision of oxidized adenine by human thymine DNA glycosylase

Oxidation of DNA bases generates mutagenic and cytotoxic lesions that are implicated in cancer and other diseases. Oxidative base lesions, including 7,8-dihydro-8-oxoguanine, are typically removed through base excision repair. In addition, oxidized deoxynucleotides such as 8-oxo-dGTP are depleted by sanitizing enzymes to preclude DNA incorporation. While pathways that counter threats posed by 7,8-dihydro-8-oxoguanine are well characterized, mechanisms protecting against the major adenine oxidation product, 7,8-dihydro-8-oxoadenine (oxoA), are poorly understood. Human DNA polymerases incorporate dGTP or dCTP opposite oxoA, producing mispairs that can cause A→C or A→G mutations. oxoA also perturbs the activity of enzymes acting on DNA and causes interstrand crosslinks. To inform mechanisms for oxoA repair, we characterized oxoA excision by human thymine DNA glycosylase (TDG), an enzyme known to remove modified pyrimidines, including deaminated and oxidized forms of cytosine and 5-methylcystosine. Strikingly, TDG excises oxoA from G⋅oxoA, A⋅oxoA, or C⋅oxoA pairs much more rapidly than it acts on the established pyrimidine substrates, whereas it exhibits comparable activity for T⋅oxoA and pyrimidine substrates. The oxoA activity depends strongly on base pairing and is 370-fold higher for G⋅oxoA versus T⋅oxoA pairs. The intrinsically disordered regions of TDG contribute minimally to oxoA excision, whereas two conserved residues (N140 and N191) are catalytically essential. Escherichia coli mismatch-specific uracil DNA-glycosylase lacks significant oxoA activity, exhibiting excision rates 4 to 5 orders of magnitude below that of its ortholog, TDG. Our results reveal oxoA as an unexpectedly efficient purine substrate for TDG and underscore the large evolutionary divergence of TDG and mismatch-specific uracil DNA-glycosylase.

Competition for DNA binding between the genome protector replication protein A and the genome modifying APOBEC3 single-stranded DNA deaminases.

The human APOBEC family of eleven cytosine deaminases use RNA and single-stranded DNA (ssDNA) as substrates to deaminate cytosine to uracil. This deamination event has roles in lipid metabolism by altering mRNA coding, adaptive immunity by causing evolution of antibody genes, and innate immunity through inactivation of viral genomes. These benefits come at a cost where some family members, primarily from the APOBEC3 subfamily (APOBEC3A-H, excluding E), can cause off-target deaminations of cytosine to form uracil on transiently single-stranded genomic DNA, which induces mutations that are associated with cancer evolution. Since uracil is only promutagenic, the mutations observed in cancer genomes originate only when uracil is not removed by uracil DNA glycosylase (UNG) or when the UNG-induced abasic site is erroneously repaired. However, when ssDNA is present, replication protein A (RPA) binds and protects the DNA from nucleases or recruits DNA repair proteins, such as UNG. Thus, APOBEC enzymes must compete with RPA to access their substrate. Certain APOBEC enzymes can displace RPA, bind and scan ssDNA efficiently to search for cytosines, and can become highly overexpressed in tumor cells. Depending on the DNA replication conditions and DNA structure, RPA can either be in excess or deficient. Here we discuss the interplay between these factors and how despite RPA, multiple cancer genomes have a mutation bias at cytosines indicative of APOBEC activity.

Detecting DNA damage in stored blood samples

Several commercially available quantitative real-time PCR (qPCR) systems enable highly sensitive detection of human DNA and provide a degradation index (DI) to assess DNA quality. From routine casework in forensic genetics, it was observed that DNA degradation in forensic samples such as blood samples stored under sub-optimal conditions leads to visible effects in multiplex analyses of short tandem repeat markers (STRs) due to decreased amplification efficiencies in longer amplicons. It was further noticed that degradation indices often remain below the value that is considered to be critical. Thus, the aim of this work was to systematically analyze this effect and to compare conventional qPCR assays with a modified qPCR approach using uracil DNA glycosylase (UNG) and DNA quality assessment methods based on electrophoresis. Blood samples were stored at three different storage temperatures for up to 316 days. Significantly increased DNA recovery was observed from samples stored at high temperatures (37 °C) compared samples stored at room temperature and 4 °C. We observed typical effects of degradation in STR analyses but no correlation between DI and storage time in any of the storage conditions. Adding UNG slightly increased the sensitivity of detecting DNA degradation in one of the qPCR kits used in this study. This observation was not confirmed when using a second qPCR system. Electrophoretic systems did also not reveal significant correlations between integrity values and time. Methods for detecting DNA degradation are usually limited to the detection of DNA fragmentation, and we conclude that degradation affecting forensic STR typing is more complex.