A liquid chromatography-mass spectrometric assay for measuring activity of human 8-oxoguanine-DNA glycosylase

Activatable Self-Dissociation of Watson-Crick Structures with Fluorescent Nucleotides for Sensing Multiple Human Glycosylases at Single-Cell Level

Nucleobase oxidation and alkylation can destroy Watson-Crick base-pairing to challenge the genomic integrity. Human 8-oxoguanine glycosylase 1 (hOGG1) and alkyladenine glycosylase (hAAG) are evolved to counter these two cytotoxic lesions through base-excision repair, and their deregulations are implicated with multifactorial diseases and cancers. Herein, we demonstrate activatable self-dissociation of Watson-Crick structures with fluorescent nucleotides for sensing multiple human glycosylases at single-cell level. The presence of hOGG1 and hAAG catalyzes 8-oxoG and deoxyinosine removal in functional probe 1 to release two trigger probes (1 and 2). Then, trigger probes hybridize with functional probe 2 to activate the autocatalytic degradation of functional probes 2 (Cycle I) and 3 (Cycle II), replicating abundant trigger probes (1-4) and releasing two fluorophores (2-aminopurine (2-AP) and pyrrolo-dC (P-dC)). New trigger probes (1, 2) and (3, 4), in turn, hybridize with free functional probes 2 and 3, repeating Cycles I and II turnovers. Through multicycle self-dissociation of Watson-Crick structures, 2-AP and P-dC are exponentially accumulated for the simultaneous quantification of hOGG1 and hAAG. This nanodevice exhibits high sensitivity with a detection limit of 2.9 × 10^-3 U/mL for hOOG1 and 1.5 × 10^-3 U/mL for hAAG, and it can measure enzymatic kinetics, identify potential inhibitors, discriminate glycosylases between cancer and normal cell lines, and even quantify glycosylase activities in a single HeLa cell. Moreover, this assay may be rapidly and isothermally performed in one tube with only one tool enzyme in a quencher-free manner, promising a simple and powerful platform for multiple human glycosylase detection.

Recent advances in biosensor for DNA glycosylase activity detection

Base excision repair (BER) is vital for maintaining the integrity of the genome under oxidative damage. DNA glycosylase initiates the BER pathway recognizes and excises the mismatched substrate base leading to the apurinic/apyrimidinic site generation, and simultaneously breaks the single-strand DNA. As the aberrant activity of DNA glycosylase is associated with numerous diseases, including cancer, immunodeficiency, and atherosclerosis, the detection of DNA glycosylase is significant from bench to bedside. In this review, we summarized novel DNA strategies in the past five years for DNA glycosylase activity detection, which are classified into fluorescence, colorimetric, electrochemical strategies, etc. We also highlight the current limitations and look into the future of DNA glycosylase activity monitoring.

A controlled T7 transcription-driven symmetric amplification cascade machinery for single-molecule detection of multiple repair glycosylases

Genomic oxidation and alkylation are two of the most important forms of cytotoxic damage that may induce mutagenesis, carcinogenicity, and teratogenicity. Human 8-oxoguanine (hOGG1) and alkyladenine DNA glycosylases (hAAG) are responsible for two major forms of oxidative and alkylative damage repair, and their aberrant activities may cause repair deficiencies that are associated with a variety of human diseases, including cancers. Due to their complicated catalytic pathways and hydrolysis mechanisms, simultaneous and accurate detection of multiple repair glycosylases has remained a great challenge. Herein, by taking advantage of unique features of T7-based transcription and the intrinsic superiorities of single-molecule imaging techniques, we demonstrate for the first time the development of a controlled T7 transcription-driven symmetric amplification cascade machinery for single-molecule detection of hOGG1 and hAAG. The presence of hOGG1 and hAAG can remove damaged 8-oxoG and deoxyinosine, respectively, from the dumbbell substrate, resulting in breaking of the dumbbell substrate, unfolding of two loops, and exposure of two T7 promoters simultaneously. The T7 promoters can activate symmetric transcription amplifications with the unfolded loops as the templates, inducing efficient transcription to produce two different single-stranded RNA transcripts (i.e., reporter probes 1 and 2). Reporter probes 1 and 2 hybridize with signal probes 1 and 2, respectively, to initiate duplex-specific nuclease-directed cyclic digestion of the signal probes, liberating large amounts of Cy3 and Cy5 fluorescent molecules. The released Cy3 and Cy5 molecules can be simply measured by total internal reflection fluorescence-based single-molecule detection, with the Cy3 signal indicating the presence of hOGG1 and the Cy5 signal indicating the presence of hAAG. This method exhibits good specificity and high sensitivity with a detection limit of 3.52 × 10-8 U μL-1 for hOGG1 and 3.55 × 10-7 U μL-1 for hAAG, and it can even quantify repair glycosylases at the single-cell level. Moreover, it can be applied for the measurement of kinetic parameters, the screening of potential inhibitors, and the detection of repair glycosylases in human serum, providing a new paradigm for repair enzyme-related biomedical research, drug discovery, and clinical diagnosis.

Construction of a self-directed replication system for label-free and real-time sensing of repair glycosylases with zero background

Genomic DNA damage and repair are involved in multiple fundamental biological processes, including metabolism, disease, and aging. Inspired by the natural repair mechanism in vivo, we demonstrate for the first time the construction of a self-directed replication system for label-free and real-time sensing of repair glycosylases with zero background. The presence of DNA glycosylase can catalyze the excision repair of the damaged base, successively autostarting the self-directed replication through recycling polymerization extension and strand-displacement DNA synthesis for the generation of exponentially amplified dsDNAs. The resultant dsDNA products can be label-free and real-time monitored with SYBR Green I as the fluorescent indicator. Owing to the high efficiency of self-directed exponential replication and the absolute zero background resulting from the efficient inhibition of nonspecific amplification induced by multiple primer-dependent amplification, this strategy exhibits high sensitivity with a detection limit of 1 × 10-8 U μL-1 in vitro and 1 cell in vivo, and it can be further used to screen inhibitors, quantify DNA glycosylase from diverse cancer cells, and even monitor various repair enzymes by simply changing the specific damaged base in the DNA template. Importantly, this assay can be performed in a label-free, real-time and isothermal manner with the involvement of only a single type of polymerase, providing a simple, robust and universal platform for repair enzyme-related biomedical research and clinical therapeutics.