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引用次数: 0
摘要
当细胞遇到外源性和内源性压力(如长时间干燥、电离辐射和基因毒性化学物质)时,DNA 就会发生损伤。人们一直在努力检测体内和体外的 DNA 损伤,以确定或量化损伤程度。人们普遍认为,单链 DNA(ssDNA)是 DNA 损伤的重要副产品之一,可触发下游调控。最近的一项研究发现,PprI 能有效识别 ssDNA,并在存在 ssDNA 的情况下在裂解位点区(CSR)环上的特定位点裂解 DdrO,从而实现去势球菌的抗辐射性。利用这一特性,我们开发了一种基于荧光共振能量转移(FRET)的体外 DNA 损伤定量检测方法。DdrO 蛋白的 N 端和 C 端分别与 eYFP 和 eCFP 融合,两者之间的 FRET 效率可作为裂解效率和 ssDNA 浓度的指标。构建了ssDNA浓度与FRET效率之间的标准曲线,并对应用实例进行了测试,验证了该方法的有效性。
A novel DNA damage detection method based on a distinct DNA damage response system
DNA damage occurs when cells encounter exogenous and endogenous stresses such as long periods of desiccation, ionizing radiation and genotoxic chemicals. Efforts have been made to detect DNA damage in vivo and in vitro to characterize or quantify the damage level. It is well accepted that single-stranded DNA (ssDNA) is one of the important byproducts of DNA damage to trigger the downstream regulation. A recent study has revealed that PprI efficiently recognizes ssDNA and cleaves DdrO at a specific site on the cleavage site region (CSR) loop in the presence of ssDNA, which enables the radiation resistance of Deinococcus. Leveraging this property, we developed a quantitative DNA damage detection method in vitro based on fluorescence resonance energy transfer (FRET). DdrO protein was fused with eYFP and eCFP on the N-terminal and C-terminal respectively, between which the FRET efficiency serves as an indicator of cleavage efficiency as well as the concentration of ssDNA. The standard curve between the concentration of ssDNA and the FRET efficiency was constructed, and application examples were tested, validating the effectiveness of this method.
期刊介绍:
Microbial Biotechnology publishes papers of original research reporting significant advances in any aspect of microbial applications, including, but not limited to biotechnologies related to: Green chemistry; Primary metabolites; Food, beverages and supplements; Secondary metabolites and natural products; Pharmaceuticals; Diagnostics; Agriculture; Bioenergy; Biomining, including oil recovery and processing; Bioremediation; Biopolymers, biomaterials; Bionanotechnology; Biosurfactants and bioemulsifiers; Compatible solutes and bioprotectants; Biosensors, monitoring systems, quantitative microbial risk assessment; Technology development; Protein engineering; Functional genomics; Metabolic engineering; Metabolic design; Systems analysis, modelling; Process engineering; Biologically-based analytical methods; Microbially-based strategies in public health; Microbially-based strategies to influence global processes
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