Development of mCherry tagged UdgX as a highly sensitive molecular probe for specific detection of uracils in DNA

EPS-Producing Bacteria Promote Aggregation in Soil Preventing the Leaching Loss of Nutrient

Leaching loss of nutrients from the agricultural field is a major concern in areas receiving excessive rainfall. The water-soluble nutrients are therefore lost due to leaching and runoff water. This leads to excessive dependence on chemical fertilizers. In this regard, the role of indigenous exopolysaccharide (EPS) producing bacteria in stabilizing the nutrient-holding capacity is far greater than conceived. The sub-Himalayan terai region, located at Cwa zone (monsoon type with dry winter, Köppen's classification) in India, which receives heavy rainfall (> 3000 mm), is a suitable location to study the role of such bacteria. A culture-dependent analysis of EPS-producing bacteria showed their comparatively lower abundance throughout the year. The EPS-associated bacterial microenvironment on vermiculite particles under aerobic and anaerobic conditions was visualized using a Confocal Laser Scanning Microscope (CLSM). The cells of EPS producers were found distributed within the EPS matrix, pushing each other away, showing a higher organic matter secretion (EPS) per unit of the bacterial cells. Since EPS has adhesive properties, the indigenous EPS-producing bacteria were amended to the soil, and the formation of macroaggregates was analyzed. Two in-house EPS-producing bacteria were used to monitor if they can reduce the leaching loss of nutrients. In vitro, assays on nutrient-holding capacity by soil-column-flow-through revealed that these bacteria-treated soil retained more nutrients. Till now, there were no reports on the role of the genus Serratia in improving the nutrient-holding capacity. For the first time, we have shown that using such soil-dwelling genera can improve the formation of stable aggregates and prevent nutrient loss.

Structural and Functional Insights into UDGs

Endogenous or exogenous DNA damage needs to be repaired, therefore, cells in all the three domains have repair pathways to maintain the integrity of their genetic material. Uracil DNA glycosylases (UDGs), also known as UNGs (uracil-DNA N-glycosylases), are part of the base-excision repair (BER) pathway. These enzymes specifically remove uracil from DNA molecules by cleaving the glycosidic bond between the uracil base and the deoxyribose sugar. UDGs can be broadly classified into six families, and each of them share conserved motifs that are critical for substrate recognition and catalysis. Recently, an unconventional UDG known as UDGX has been identified from the species Mycobacterium smegmatis, which is different from other UDG members in forming an irreversible and extremely stable complex with DNA that is resistant to even harsh denaturants such as SDS, NaOH, and heat. This suicide inactivation mechanism prevents uracil excision and might play a protective role in maintaining genome integrity, as bacterial survival under hypoxic conditions is reduced due to the overexpression of MsmUDGX. Additionally, due to the importance of UDGs, the number of structures has been resolved. Moreover, high-resolution 3D structures of apo MsmUDGX, as well as uracil and DNAbound forms, are available in PDB. This review aims to provide insights into the specific structural- functional aspects of each UDG family member for theragnostic applications.

Exploration and Application of DNA-Binding Proteins to Make a Versatile DNA-Protein Covalent-Linking Patch (D-Pclip): The Case of a Biosensing Element

DNA-protein complexes are attractive components with broad applications in various research fields, such as DNA aptamer-enzyme complexes as biosensing elements. However, noncovalent DNA-protein complexes often decrease detection sensitivity because they are highly susceptible to environmental conditions. In this study, we developed a versatile DNA-protein covalent-linking patch (D-Pclip) for fabricating covalent and stoichiometric DNA-protein complexes. We comprehensively explored the database to determine the DNA-binding ability of the candidates and selected UdgX as the only uracil-DNA glycosylase known to form covalent bonds with DNA via uracil, with a binding efficiency >90%. We integrated a SpyTag/SpyCatcher protein-coupling system into UdgX to create a universal and convenient D-Pclip. The usability of D-Pclip was shown by preparing a stoichiometric model complex of a hemoglobin (Hb)-binding aptamer and glucose oxidase (GOx) by mixing at 4 °C. The prepared aptamer-GOx complexes detected Hb in a dose-dependent manner within the clinically required detection range in buffer and human serum without any washing procedures. D-Pclip covalently connects any uracil-inserted DNA sequence and any SpyCatcher-fused protein stoichiometrically; therefore, it has a high potential for various applications.

Structural and functional coupling in cross-linking uracil-DNA glycosylase UDGX

Enzymes in uracil-DNA glycosylase (UDG) superfamily are involved in removal of deaminated nucleobases such as uracil, methylcytosine derivatives such as formylcytosine and carboxylcytosine, and other base damage in DNA repair. UDGX is the latest addition of a new class to the UDG superfamily with a sporadic distribution in bacteria. UDGX type enzymes have a distinct biochemical property of cross-linking itself to the resulting AP site after uracil removal. Built on previous biochemical and structural analyses, this work comprehensively investigated the kinetic and enzymatic properties of Mycobacterium smegmatis UDGX. Kinetics and mutational analyses, coupled with structural information, defined the roles of E52, D56, D59, F65 of motif 1, H178 of motif 2 and N91, K94, R107 and H109 of motif 3 play in uracil excision and cross-linking. More importantly, a series of quantitative analyses underscored the structural coupling through inter-motif and intra-motif interactions and subsequent functional coupling of the uracil excision and cross-linking reactions. A catalytic model is proposed, which underlies this catalytic feature unique to UDGX type enzymes. This study offers new insight on the catalytic mechanism of UDGX and provides a unique example of enzyme evolution.

UdgX-Mediated Uracil Sequencing at Single-Nucleotide Resolution

As an aberrant base in DNA, uracil is generated by either deoxyuridine (dU) misincorporation or cytosine deamination, and involved in multiple physiological and pathological processes. Genome-wide profiles of uracil are important for study of these processes. Current methods for whole-genome mapping of uracil all rely on uracil-DNA N-glycosylase (UNG) and are limited in resolution, specificity, and/or sensitivity. Here, we developed a UdgX cross-linking and polymerase stalling sequencing ("Ucaps-seq") method to detect dU at single-nucleotide resolution. First, the specificity of Ucaps-seq was confirmed on synthetic DNA. Then the effectiveness of the approach was verified on two genomes from different sources. Ucaps-seq not only identified the enrichment of dU at dT sites in pemetrexed-treated cancer cells with globally elevated uracil but also detected dU at dC sites within the "WRC" motif in activated B cells which have increased dU in specific regions. Finally, Ucaps-seq was utilized to detect dU introduced by the cytosine base editor (nCas9-APOBEC) and identified a novel off-target site in cellular context. In conclusion, Ucaps-seq is a powerful tool with many potential applications, especially in evaluation of base editing fidelity.

Base-Resolution Analysis of Deoxyuridine at the Genome Scale Based on the Artificial Incorporation Modified Nucleobase

Deamination of cytosine and dUMP misincorporation have been found to be capable of producing uracil in the genome. This study presents the AI-seq (artificial incorporation modified nucleobase for sequencing), a "base substitution", which not only is capable of profiling uracil at single-nucleotide resolution and showing its centromeric enrichment but could also reveal that the identified uracil sites are derived from cytosine deamination. All the results indicate the potential biological significance of uracil as the epigenetic modification.

Detection of Genomic Uracil Patterns

The appearance of uracil in the deoxyuridine moiety of DNA is among the most frequently occurring genomic modifications. Three different routes can result in genomic uracil, two of which do not require specific enzymes: spontaneous cytosine deamination due to the inherent chemical reactivity of living cells, and thymine-replacing incorporation upon nucleotide pool imbalances. There is also an enzymatic pathway of cytosine deamination with multiple DNA (cytosine) deaminases involved in this process. In order to describe potential roles of genomic uracil, it is of key importance to utilize efficient uracil-DNA detection methods. In this review, we provide a comprehensive and critical assessment of currently available uracil detection methods with special focus on genome-wide mapping solutions. Recent developments in PCR-based and in situ detection as well as the quantitation of genomic uracil are also discussed.

Visualization of uracils created by APOBEC3A using UdgX shows colocalization with RPA at stalled replication forks

The AID/APOBEC enzymes deaminate cytosines in single-stranded DNA (ssDNA) and play key roles in innate and adaptive immunity. The resulting uracils cause mutations and strand breaks that inactivate viruses and diversify antibody repertoire. Mutational evidence suggests that two members of this family, APOBEC3A (A3A) and APOBEC3B, deaminate cytosines in the lagging-strand template during replication. To obtain direct evidence for the presence of these uracils, we engineered a protein that covalently links to DNA at uracils, UdgX, for mammalian expression and immunohistochemistry. We show that UdgX strongly prefers uracils in ssDNA over those in U•G or U:A pairs, and localizes to nuclei in a dispersed form. When A3A is expressed in these cells, UdgX tends to form foci. The treatment of cells with cisplatin, which blocks replication, causes a significant increase in UdgX foci. Furthermore, this protein- and hence the uracils created by A3A- colocalize with replication protein A (RPA), but not with A3A. Using purified proteins, we confirm that RPA inhibits A3A by binding ssDNA, but despite its overexpression following cisplatin treatment, RPA is unable to fully protect ssDNA created by cisplatin adducts. This suggests that cisplatin treatment of cells expressing APOBEC3A should cause accumulation of APOBEC signature mutations.

Genome-wide alterations of uracil distribution patterns in human DNA upon chemotherapeutic treatments

Numerous anti-cancer drugs perturb thymidylate biosynthesis and lead to genomic uracil incorporation contributing to their antiproliferative effect. Still, it is not yet characterized if uracil incorporations have any positional preference. Here, we aimed to uncover genome-wide alterations in uracil pattern upon drug treatments in human cancer cell line models derived from HCT116. We developed a straightforward U-DNA sequencing method (U-DNA-Seq) that was combined with in situ super-resolution imaging. Using a novel robust analysis pipeline, we found broad regions with elevated probability of uracil occurrence both in treated and non-treated cells. Correlation with chromatin markers and other genomic features shows that non-treated cells possess uracil in the late replicating constitutive heterochromatic regions, while drug treatment induced a shift of incorporated uracil towards segments that are normally more active/functional. Data were corroborated by colocalization studies via dSTORM microscopy. This approach can be applied to study the dynamic spatio-temporal nature of genomic uracil.