Sharleen Friese, Tom Heinze, Franziska Ebert, Tanja Schwerdtle
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引用次数: 0
摘要
作为 DNA 修复途径的最后一个过程,DNA 连接对维持基因组稳定性和防止 DNA 链断裂累积至关重要。因此,我们的目标是建立一种能可靠评估小鼠组织蛋白质提取物中 DNA 连接能力的方法。为优化适用性,该方法避免使用放射性标记的底物,而代之以荧光标记的寡核苷酸。简而言之,将组织提取物与这些互补寡核苷酸孵育,以便在随后的凝胶电泳中将连接的链与未连接的分子分开。该方法最初用于小脑组织,以进一步阐明神经退行性疾病的可能机制。然而,由于小脑解剖结构的不均匀性,不同小脑区域的DNA连接效率差异很大,这说明所建立的检测方法只适用于同质器官。因此,小鼠肝脏组织在验证过程中显示出足够的日内和日间可重复性。在进一步的实验中,所建立的检测方法被应用于一项动物研究,研究对象包括年轻和年老(24 周和 110 周)的小鼠,结果表明 DNA 连接效率既不受性别影响,也不受年龄影响。最后,研究了体外添加微量元素铜、铁和锌对组织提取物中 DNA 连接的影响。虽然这三种金属都会抑制 DNA 连接,但它们的作用效果明显不同。总之,所建立的方法可以可靠地用于研究同源鼠组织中的 DNA 连接效率。
Establishment of a nonradioactive DNA ligation assay and its applications in murine tissues
As final process of every DNA repair pathway, DNA ligation is crucial for maintaining genomic stability and preventing DNA strand breaks to accumulate. Therefore, a method reliably assessing DNA ligation capacity in protein extracts from murine tissues was aimed to establish. To optimize applicability, the use of radioactively labeled substrates was avoided and replaced by fluorescently labeled oligonucleotides. Briefly, tissue extracts were incubated with those complementary oligonucleotides so that in an ensuing gel electrophoresis ligated strands could be separated from unconnected molecules. Originally, the method was intended for use in cerebellum tissue to further elucidate possible mechanisms of neurodegenerative diseases. However, due to its inhomogeneous anatomy, DNA ligation efficiency varied strongly between different cerebellar areas, illuminating the established assay to be suitable only for homogenous organs. Thus, for murine liver tissue sufficient intra- and interday repeatability was shown during validation. In further experiments, the established assay was applied to an animal study comprising young and old (24 and 110 weeks) mice which showed that DNA ligation efficiency was affected by neither sex nor age. Finally, the impact of in vitro addition of the trace elements copper, iron, and zinc on DNA ligation in tissue extracts was investigated. While all three metals inhibited DNA ligation, variations in their potency became evident. In conclusion, the established method can be reliably used for investigation of DNA ligation efficiency in homogenous murine tissues.
期刊介绍:
Environmental and Molecular Mutagenesis publishes original research manuscripts, reviews and commentaries on topics related to six general areas, with an emphasis on subject matter most suited for the readership of EMM as outlined below. The journal is intended for investigators in fields such as molecular biology, biochemistry, microbiology, genetics and epigenetics, genomics and epigenomics, cancer research, neurobiology, heritable mutation, radiation biology, toxicology, and molecular & environmental epidemiology.
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