Uracil Base Research Articles

Uracil base PCR implemented for reliable DNA walking

PCR-based DNA walking is of efficacy for capturing unknown flanking genomic sequences. Here, an uracil base PCR (UB-PCR) with satisfying specificity has been devised for DNA walking. Primary UB-PCR replaces thymine base with uracil base, resulting in a primary PCR product composed of U-DNAs. A single-primer (primary nested sequence-specific primer) single-cycle amplification, using the four normal bases (adenine, thymine, cytosine, and guanine) as substrate, is then performed on the primary PCR product. Clearly, only those U-DNAs, ended by the primary nested sequence-specific primer at least at one side, will produce the corresponding normal single strands. Next, the single-cycle product undergoes uracil-DNA glycosylase treatment to destroy the U-DNAs, while the normal single strands are unaffected. Afterward, secondary even tertiary PCR is performed to exclusively enrich the target product. The feasibility of UB-PCR has been checked by obtaining unknown sequences bordering the three selected genetic sites.

DNA polymerase mediated CRISPR/Cas12a trans-cleavage for dual-mode quantification of uracil DNA glycosylase activity

Since an unusual expression of uracil-DNA glycosylase (UDG) is often associated with the pathogenesis of numerous disorders, the detection of UDG activity is regarded as a promising application in disease diagnosis. Here, we develop a DNA polymerase-mediated CRISPR/Cas12a trans cleavage strategy, which can achieve dual-mode determination of UDG activity. By introducing a hairpin DNA probe containing a single uracil base, the probe undergoes specific cleavage and elongation under the existence of UDG only, thus activating the trans cleavage of ssDNA regardless of its length and sequence. To accommodate different detection modes, the ssDNA was further modified by fluorophore-quencher pairs or designed for connecting magnetic microparticles (MMPs) and polystyrene microparticles (PMPs). Finally, the UDG activity is quantified by fluorescence signal and microparticle accumulation length on a microfluidic chip visible to the naked eye. This strategy provides a detectable minimum UDG concentration of 0.00047 U/mL for fluorescent mode and 0.0048 U/mL for microfluidic mode. Furthermore, we performed the UDG inhibition test and detected UDG activity in cell lysates, suggesting its potential for inhibitor screening and detection of UDG in biological samples.

A Photoelectrochemical Biosensor Mediated by CRISPR/Cas13a for Direct and Specific Detection of MiRNA-21.

Direct detection of miRNA is currently limited by the complex amplification and reverse transcription processes of existing methods, leading to low sensitivity and high operational demands. Herein, we developed a CRISPR/Cas13a-mediated photoelectrochemical (PEC) biosensing platform for direct and sensitive detection of miRNA-21. The direct and specific recognition of target miRNA-21 by crRNA-21 eliminates the need for pre-amplification and reverse transcription of miRNA-21, thereby preventing signal distortion and enhancing the sensitivity and precision of target detection. When crRNA-21 binds to miRNA-21, it activates the trans-cleavage activity of CRISPR/Cas13a, leading to the non-specific cleavage of biotin-modified DNA with uracil bases (biotin-rU-DNA). This cleavage prevents the biotin-rU-DNA from being immobilized on the electrode surface. As a result, streptavidin cannot attach to the electrode via specific biotin binding, reducing spatial resistance and causing a positively correlated increase in the photocurrent response. This Cas-PEC biosensor has good analytical capabilities, linear responses between 10 fM and 10 nM, a minimum detection limit of 9 fM, and an excellent recovery rate in the analysis of real human serum samples. This work presented an innovative solution for detecting other biomarkers in bioanalysis and clinical diagnostics.

Distance-based paper device coupled with uracil-rich DNA hydrogel for visual quantification of Uracil-DNA glycosylase

Uracil-DNA glycosylase (UDG), an enzyme for repairing uracil-containing DNA damage, is crucial for maintaining genomic stability. Simple and fast quantification of UDG activity is essential for biological assay and clinical diagnosis, since its aberrant level is associated with DNA damage and various diseases. Herein, we developed a fully integrated “sample in-signal out” distance-based paper analytical device (dPAD) for visual quantification of UDG using a flow-controlled uracil-rich DNA hydrogel (URDH). The uracil base sites contained in the DNA hydrogel are mis-incorporated with dUTP by rolling circle amplification (RCA), which simplifies the preparation process of the functionalized hydrogel. In the presence of UDG, the uracil in URDH can be recognized and removed to induce the permeability change of URDH, resulting in the visible distance signal along the paper channel. Using dPAD, as low as 6.4 × 10−4 U/mL of UDG (within 80 min) is visually identified without any instruments and complicated operations. This integrated dPAD is advantageous for its simplicity, cost effectiveness, and ease of use. We envision that it has the great potential for point-of-care testing (POCT) in DNA damage testing, personalized healthcare assessment, and biomedical applications.

Enzyme-Powered, Label-Free DNA Walker for Uracil-DNA Glycosylase Detection at Single-Cell Level.

Uracil-DNA glycosylase (UDG) plays a crucial role in the removal of damaged uracil bases, thereby upholding genetic stability and integrity. An enzyme-powered, label-free DNA walker was devised for UDG activity detection. Initially, a label-free DNA track, incorporating a gold nanoparticle (AuNP), multiple hairpin structures, and various swing arms, was engineered for walking mechanism. The hairpin structure was meticulously crafted to include a G-quadruplex sequence, enabling the generation of a label-free fluorescence signal. The swing arm remained inert in the absence of UDG, but became activated upon the introduction of UDG, thereby initiating the enzyme-powered walking process and generating significant dissociative G-quadruplex sequences. By integrating a selective fluorescent dye into the design, an enhanced label-free fluorescence response was achieved. The proposed DNA walker presented a direct and label-free approach for UDG detection, demonstrating exceptional sensitivity with a detection limit of 0.00004 U/mL. Using the uracil glycosylase inhibitor (UGI) as an inhibitory model, inhibitor assay was conducted with satisfactory precision. Furthermore, successful analysis of cellular UDG at the single-cell level was accomplished. Consequently, the developed DNA walker serves as a label-free, selective, and sensitive tool for UDG activity assessment, showing great potential for applications in disease diagnosis, inhibitor screening, and biomedical investigations.

Detection of the phosphorothioate oligonucleotide fomivirsen using a ligase detection reaction with polymerase chain reaction.

This study aimed to develop a simple and sensitive detection method for fomivirsen, a 21-nucleotide phosphorothioate oligonucleotide used as a nucleic acid medicine, using a ligase detection reaction. A ligation probe was designed to hybridize with fomivirsen and polymerase chain reaction (PCR) primers, with a deoxyuridine part between the primer binding sites. The probe was ligated to a circular product by Taq DNA ligase, and the resulting product was converted to a linear form through the removal of the uracil base using uracil DNA glycosylase. The linear product was then quantified using real-time PCR. The developed method could detect 0.025-6.4nM of fomivirsen in water and HeLa genomic DNA solutions and 0.6-160nM of fomivirsen in mouse serum in combination with an extraction method based on alkalinization and neutralization. This method could be useful for not only detecting fomivirsen but also other functional oligonucleotides composed of phosphorothioate oligonucleotides. In summary, this study presents a practical and effective approach to the detection of the nucleic acid medicine fomivirsen.

Abstract 2066: Measuring the activity of SMUG1 DNA glycosylase with a novel sSTRIDE-SMUG1 assay

Abstract On average, spontaneous deamination of cytosine to aberrant base uracil happens 70-200 times per human genome per day. These mutagenic U/G mispairs are, however, corrected by error-free base repair (BER) initiated by uracil-DNA glycosylases. SMUG1 (single-strand selective monofunctional uracil DNA glycosylase), as one of the major glycosylases, removes uracil and oxidized pyrimidines from DNA. In spite of the name, SMUG1 removes uracil also from double-stranded DNA. Unrepaired by SMUG1 U/G mispairs are mutagenic, and alterations in SMUG1 expression levels have been linked to cancer development. Low SMUG1 transcripts are associated with poor prognosis in breast cancer and SMUG1 loss has been shown to cause PARPi resistance in HR-deficient background. Hence, tools describing SMUG1 activities in DNA damage response may provide new approaches for cancer cell treatment. We report here the development, optimization and validation of an assay measuring the activity of SMUG1. The new assay is based on the STRIDE platform technology, which enables direct and sensitive detection of single- or double-strand DNA breaks in situ, in fixed cells. sSTRIDE-SMUG1 assay detects DNA nicks localized in close proximity to the SMUG1 protein and can thus be utilized as a direct reporter of its activity. The experiments were performed in HAP1 cells. First, in untreated cells we have shown that the sSTRIDE-SMUG1 signals constitute ca. 1-2% of total single-strand DNA breaks foci detected by the classic sSTRIDE assay variant, while the negative controls have shown that the number of false-positive foci does not exceed 15% of the total number of signals. As expected, treatment of cells with a cytotoxic nucleotide hydroxymethyl-deoxyuridine (hmdU) resulted in an increase in the number of detected sSTRIDE-SMUG1 signals. To verify the specificity of the assay, SMUG1 was knocked-down in HAP1 wild-type cells using siRNA and then the level of sSTRIDE-SMUG1 signals was measured in both untreated and hmdU-treated cells. In all tested conditions, SMUG1 expression silencing has resulted in a decrease in sSTRIDE-SMUG1 foci. We believe that the sSTRIDE-SMUG1 assay can prove to be a very useful solution to study DNA repair mechanisms involving aberrant base excision. Additionally, sSTRIDE-SMUG1 measurements may be of the utmost importance in characterization of agents inducing synthetic lethality or trapping BER intermediates. Citation Format: Karolina Stepien, Franek Sierpowski, Zsombor Prucsi, Szymon Koman, Monika Jarosz, Agnieszka Waligorska, Magdalena Kordon-Kiszala, Kamil Solarczyk. Measuring the activity of SMUG1 DNA glycosylase with a novel sSTRIDE-SMUG1 assay [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 2066.

Mimic uracil–uracil base pairing: self-assembly and single crystal structure

The controllable synthesis of non-classical nucleobase pairs that can mimic partial biological behavior is very important for the in-depth study of DNA or RNA.

Test strip coupled Cas12a-assisted signal amplification strategy for sensitive detection of uracil-DNA glycosylase.

Uracil-DNA glycosylase (UDG) is a base excision repair (BER) enzyme, which catalyzes the hydrolysis of uracil bases in DNA chains that contain uracil and N-glycosidic bonds of the sugar phosphate backbone. The expression of UDG enzyme is associated with a variety of genetic diseases including cancers. Hence, the identification of UDG activity in cellular processes holds immense importance for clinical investigation and diagnosis. In this study, we employed Cas12a protein and enzyme-assisted cycle amplification technology with a test strip to establish a precise platform for the detection of UDG enzyme. The designed platform enabled amplifying and releasing the target probe by reacting with the UDG enzyme. The amplified target probe can subsequently fuse with crRNA and Cas12a protein, stimulating the activation of the Cas12a protein to cleave the signal probe, ultimately generating a fluorescent signal. This technique showed the ability for evaluating UDG enzyme activity in different cell lysates. In addition, we have designed a detection probe to convert the fluorescence signal into test strip bands that can then be observed with the naked eye. Hence, our tool presented potential in both biomedical research and clinical diagnosis related to DNA repair enzymes.

Total Synthesis of Nikkomycin Sz and Nikkomycin Soz.

The nikkomycins Sz/Soz are a class of locked nucleoside antibiotics that share a common [5,6] trans-bicyclic core. Herein we present an efficient synthesis of these nikkomycins from diene, using neighboring group participation N-glycosylation and stereoselective oxidation state installation. This synthetic strategy overcomes several challenges due to the poor redox tolerance of the uracil base, the high strain of the trans-fused furanopyran C8 monosaccharides, and the acid-sensitive glycosidic bond when dealing with the deoxynucleotide natural product nikkomycin Sz.

Bisulfite and Nanopore Sequencing for Pseudouridine in RNA.

Nucleophilic addition of bisulfite to pyrimidine bases has been known for a half century, and the reaction has been in use for at least a quarter of a century for identifying 5-methylcytidine in DNA. This account focuses on the chemistry of bisulfite with pseudouridine, an isomer of the RNA nucleoside uridine in which the uracil base is connected to C1' of ribose via C5 instead of N1. Pseudouridine, Ψ, is the most common nucleotide modification found in cellular RNA overall, in part due to its abundance in rRNAs and tRNAs. It has a stabilizing influence on RNA structure because N1 is now available for additional hydrogen bonding and because the heterocycle is slightly better at π stacking. The isomerization of U to Ψ in RNA strands is catalyzed by 13 different enzymes in humans and 11 in E. coli; some of these enzymes are implicated in disease states which is testament to the biological importance of pseudouridine in cells. Recently, pseudouridine came into the limelight as the key modification that, after N1 methylation, enables mRNA vaccines to be delivered efficiently into human tissue with minimal generation of a deleterious immunogenic response. Here we describe the bisulfite reaction with pseudouridine which gives rise to a chemical sequencing method to map the modified base in the epitranscriptome. Unlike the reaction with cytidine, the addition of bisulfite to Ψ leads irreversibly to form an adduct that is bypassed during cDNA synthesis by reverse transcriptases yielding a characteristic deletion signature. Although there were hints to the structure of the bisulfite adduct(s) 30 to 50 years ago, it took modern spectroscopic and computational methods to solve the mystery. Raman spectroscopy along with extensive NMR, ECD, and computational work led to the assignment of the major product as the (R) diastereomer of an oxygen adduct at C1' of a ring-opened pseudouridine. Mechanistically, this arose from a succession of conjugate addition, E2 elimination, and a [2,3] sigmatropic rearrangement, all of which are stereodefined reactions. A minor reaction with excess bisulfite led to the (S) isomer of a S-adducted SO3- group. Understanding structure and mechanism aided the design of a Ψ-specific sequencing reaction and guided attempts to improve the utility and specificity of the method. Separately, we have been investigating the use of nanopore direct RNA sequencing, a single-molecule method that directly analyzes RNA strands isolated from cells after end-ligation of adaptor sequences. By combining the electrical current and base-calling data from the nanopore with dwell-time analysis from the helicase employed to deliver RNA to the nanopore, we were able to map Ψ sites in nearly all sequence contexts. This analysis was employed to find Ψ residues in the SARS-CoV-2 vRNA, to analyze the sequence context effects of mRNA vaccine synthesis via in vitro transcription, and to evaluate the impact of stress on chemical modifications in the E. coli ribosome. Most recently, we found that bisulfite treatment of RNA leading to Ψ adducts could modulate the nanopore signal to help in mapping modifications of low occupancy.

Structural basis for the selective methylation of 5-carboxymethoxyuridine in tRNA modification.

Posttranscriptional modifications of tRNA are widely conserved in all domains of life. Especially, those occurring within the anticodon often modulate translational efficiency. Derivatives of 5-hydroxyuridine are specifically found in bacterial tRNA, where 5-methoxyuridine and 5-carboxymethoxyuridine are the major species in Gram-positive and Gram-negative bacteria, respectively. In certain tRNA species, 5-carboxymethoxyuridine can be further methylated by CmoM to form the methyl ester. In this report, we present the X-ray crystal structure of Escherichia coli CmoM complexed with tRNASer1, which contains 5-carboxymethoxyuridine at the 5'-end of anticodon (the 34th position of tRNA). The 2.22 Å resolution structure of the enzyme-tRNA complex reveals that both the protein and tRNA undergo local conformational changes around the binding interface. Especially, the hypomodified uracil base is flipped out from the canonical stacked conformation enabling the specific molecular interactions with the enzyme. Moreover, the structure illustrates that the enzyme senses exclusively the anticodon arm region of the substrate tRNA and examines the presence of key determinants, 5-carboxymethoxyuridine at position 34 and guanosine at position 35, offering molecular basis for the discriminatory mechanism against non-cognate tRNAs.

Complete mitochondrial genome of Mentha spicata L. reveals multiple chromosomal configurations and RNA editing events

Mentha spicata L. is a valuable plant that yields spearmint oil, widely utilized in the pharmaceutical, chemical, and cosmetic industries. The mitochondrial genome (mitogenome) is an essential material for molecular breeding and evolution studies. Here, the mitogenome of M. spicata was assembled by combining Nanopore and Illumina reads. It consisted of a linear chromosome (Ch1) and two circular chromosomes (Ch2 and Ch3). Furthermore, we showed two pairs of repeats (R1 and R2) mediated recombinations resulting in multiple chromosomal configurations. The R1-mediated-recombination generated a large molecule formed by joining Ch2 and Ch1. Similarly, the R2-mediated-recombination generated a large molecule formed by joining Ch3 and Ch1. Then, we identified 17 mitochondrial plastid DNAs (MTPTs) by comparing the mitogenome and cpgenome. The MTPT14 was conserved in multiple species, which has undergone the same evolutionary process as the two organellar genomes among M. spicata, Hesperelaea palmeri and Castilleja paramensis. Based on the RNA-seq reads, 246 RNA editing sites were predicted, resulting in the conversion of cytosine to uracil bases. Furthermore, we successfully validated 40 out of 43 predicted sites. This project reported a complex structure of the M. spicata mitogenome resulting from repeat-mediated recombinations, which will provide valuable information for gene function study and the breeding of different varieties.

Analysis of nerve growth factor (NGF) gene methylation in patients with schizophrenia

According to the neurotrophin hypothesis, schizophrenia can be caused by neurotrophic factors. One of these neurotrophic factors is the nerve growth factor (NGF), which has a critical role in cognitive functions. The present study aimed to investigate the NGF gene promoter methylation pattern in patients with schizophrenia and healthy individuals. Participants included patients with schizophrenia (84 males and 38 females) and healthy controls (96 males and 48 females). Blood samples were collected from all of the subjects in treated tubes for DNA extraction. The determination of the methylation pattern of the NGF gene CpG island-2 was based on the principle that bisulfite treatment of DNA results in the conversion of unmethylated bases of cytosine into uracil bases. The results showed no significant difference in the DNA methylation status for the NGF gene CpG island-2 in patients with schizophrenia and healthy individuals. Also, no significant difference was observed in the methylated and unmethylated status for the NGF gene CpG island-2 region when patients were compared with clinical parameters. In addition, relative NGF mRNA expression was significantly lower in patients with schizophrenia compared to healthy controls. However, no significant difference was observed in methylated and unmethylated status in the NGF mRNA expression. Although clinical evidence indicates a decrease in serum NGF levels in patients with schizophrenia, in the present study, there was no difference in the methylation status of the NGF gene promoter CpG island-2 between patients with schizophrenia and healthy individuals.

Escherichia coli DNA repair helicase Lhr is also a uracil-DNA glycosylase.

DNA glycosylases protect genetic fidelity during DNA replication by removing potentially mutagenic chemically damaged DNA bases. Bacterial Lhr proteins are well-characterized DNA repair helicases that are fused to additional 600-700 amino acids of unknown function, but with structural homology to SecB chaperones and AlkZ DNA glycosylases. Here, we identify that Escherichia coli Lhr is a uracil-DNA glycosylase (UDG) that depends on an active site aspartic acid residue. We show that the Lhr DNA helicase activity is functionally independent of the UDG activity, but that the helicase domains are required for fully active UDG activity. Consistent with UDG activity, deletion of lhr from the E. coli chromosome sensitized cells to oxidative stress that triggers cytosine deamination to uracil. The ability of Lhr to translocate single-stranded DNA and remove uracil bases suggests a surveillance role to seek and remove potentially mutagenic base changes during replication stress.

Colorimetric and electrochemical dual-signal detection of uracil-DNA glycosylase using functionalized pure DNA hydrogel on paper-based analytical devices

The development of simple and accurate detection of uracil-DNA glycosylase (UDG) is of great significance for early clinical diagnosis and biomedical research. Here, we on the first effort introduced the uracil bases into the rolling circle amplification (RCA) reaction to produce the functionalized pure DNA hydrogel (PDH) for UDG detection. During RCA process, methylene blue (MB) molecules as the indicators were encapsulated into PDH. The addition of UDG can remove the uracil bases of PDH to generate abasic sites, which are further cleaved with the assistance of apurinic/apyrimidinic endonuclease (APE), thus resulting in the dissociation of PDH to release blue MB. By combining with the paper analytical devices as the signal readout platform, a colorimetric and electrochemical dual-signal biosensor was constructed for convenient and accurate detection of UDG. The proposed MB@PDH-based dual-signal sensing system exhibited good selectivity and high sensitivity with a detection limit of 6.4 × 10−4 U/mL (electrochemical method). It was also demonstrated that this sensing system showed excellent performance in UDG inhibitor screening, thus providing great potential in UDG-related disease diagnosis and drug discovery.

Divergent structures of Mammalian and gammaherpesvirus uracil DNA glycosylases confer distinct DNA binding and substrate activity

Uracil DNA glycosylase (UNG) removes mutagenic uracil base from DNA to initiate base excision repair (BER). The result is an abasic site (AP site) that is further processed by the high-fidelity BER pathway to complete repair and maintain genome integrity. The gammaherpesviruses (GHVs), human Kaposi sarcoma herpesvirus (KSHV), Epstein-Barr virus (EBV), and murine gammaherpesvirus 68 (MHV68) encode functional UNGs that have a role in viral genome replication. Mammalian and GHVs UNG share overall structure and sequence similarity except for a divergent amino-terminal domain and a leucine loop motif in the DNA binding domain that varies in sequence and length. To determine if divergent domains contribute to functional differences between GHV and mammalian UNGs, we analyzed their roles in DNA interaction and catalysis. By utilizing chimeric UNGs with swapped domains we found that the leucine loop in GHV, but not mammalian UNGs facilitates interaction with AP sites and that the amino-terminal domain modulates this interaction. We also found that the leucine loop structure contributes to differential UDGase activity on uracil in single- versus double-stranded DNA. Taken together we demonstrate that the GHV UNGs evolved divergent domains from their mammalian counterparts that contribute to differential biochemical properties from their mammalian counterparts.

A novel biosensor based on tetrahedral DNA nanostructure and terminal deoxynucleotidyl transferase-assisted amplification strategy for fluorescence analysis of uracil-DNA glycosylase activity

Tetrahedral DNA nanostructure (TDN), as a classical bionanomaterial, which not only has excellent structural stability and rigidity, but also possesses high programmability due to strict base-pairs complementation, is widely used in various biosensing and bioanalysis fields. In this study, we first constructed a novel biosensor based on Uracil DNA glycosylase (UDG) -triggered collapse of TDN and terminal deoxynucleotidyl transferase (TDT)-induced insertion of copper nanoparticles (CuNPs) for fluorescence and visual analysis of UDG activity. In the presence of the target enzyme UDG, the uracil base modified on the TDN were specifically identified and removed to produce an abasic site (AP site). Endonuclease IV (Endo.IV) could cleave the AP site, making the TDN collapse and generating 3′-hydroxy (3′-OH), which were then elongated under the assistance of TDT to produce poly (T) sequences. Finally, Copper (II) sulfate (Cu2+) and l-Ascorbic acid (AA) were added to form CuNPs using poly (T) sequences as templates (T-CuNPs), resulting in a strong fluorescence signal. This method exhibited good selectivity and high sensitivity with a detection limit of 8.6 × 10−5 U/mL. Moreover, the strategy has been successfully applied to the screening of UDG inhibitors and the detection of UDG activity in complex cell lysates, which means that it has promising applications in clinical diagnosis and biomedical research.

Rolling circle transcription and CRISPR/Cas12a-assisted versatile bicyclic cascade amplification assay for sensitive uracil-DNA glycosylase detection

Uracil-DNA glycosylase (UDG) is pivotal in maintaining genome integrity and aberrant expressed UDG is highly relevant to numerous diseases. Sensitive and accurate detecting UDG is critically significant for early clinical diagnosis. In this research, we demonstrated a sensitive UDG fluorescent assay based on rolling circle transcription (RCT)/CRISPR/Cas12a-assisted bicyclic cascade amplification strategy. Target UDG catalyzed to remove uracil base of DNA dumbbell-shape substrate probe (SubUDG) to produce an apurinic/apyrimidinic (AP) site, at which SubUDG was cleaved by apurinic/apyrimidinic endonuclease (APE1) subsequently. The exposed 5′-PO4 was ligated with the free 3′-OH terminus to form an enclosed DNA dumbbell-shape substrate probe (E-SubUDG). E-SubUDG functioned as a template can actuate T7 RNA polymerase-mediated RCT signal amplification, generating multitudes of crRNA repeats. The resultant Cas12a/crRNA/activator ternary complex activated the activity of Cas12a, causing a significantly enhanced fluorescence output. In this bicyclic cascade strategy, target UDG was amplified via RCT and CRISPR/Cas12a, and the whole reaction was completed without complex procedures. This method enabled sensitive and specific monitor UDG down to 0.0005 U/mL, screen corresponding inhibitors, and analyze endogenous UDG in A549 cells at single-cell level. Importantly, this assay can be extended to analyze other DNA glycosylase (hAAG and Fpg) by altering the recognition site in DNA substrates probe rationally, thereby offering a potent tool for DNA glycosylase-associated clinical diagnosis and biomedical research.

Replication Protein A Enhances Kinetics of Uracil DNA Glycosylase on ssDNA and Across DNA Junctions: Explored with a DNA Repair Complex Produced with SpyCatcher/SpyTag Ligation.

DNA repair proteins participate in extensive protein-protein interactions that promote the formation of DNA repair complexes. To understand how complex formation affects protein function during base excision repair, we used SpyCatcher/SpyTag ligation to produce a covalent complex between human uracil DNA glycosylase (UNG2) and replication protein A (RPA). Our covalent "RPA-Spy-UNG2" complex could identify and excise uracil bases in duplex areas next to ssDNA-dsDNA junctions slightly faster than the wild-type proteins, but this was highly dependent on DNA structure, as the turnover of the RPA-Spy-UNG2 complex slowed at DNA junctions where RPA tightly engaged long ssDNA sections. Conversely, the enzymes preferred uracil sites in ssDNA where RPA strongly enhanced uracil excision by UNG2 regardless of ssDNA length. Finally, RPA was found to promote UNG2 excision of two uracil sites positioned across a ssDNA-dsDNA junction, and dissociation of UNG2 from RPA enhanced this process. Our approach of ligating together RPA and UNG2 to reveal how complex formation affects enzyme function could be applied to examine other assemblies of DNA repair proteins.