1. The base excision repair (BER) pathway plays a key role in protecting the genome from DNA damage. In BER, DNA glycosylases are the critical enzymes that recognize and remove damaged and/or mispaired bases from DNA. Current methods to measure enzyme activities are mostly indirect and time-consuming. Thus, it is very helpful to develop a direct and rapid method to assay DNA glycosylases. Here we introduce a method based on molecular beacon (MB) DNA probe. MBs are hairpin-shaped nucleic acid probes labelled with a 5’-fluorophore and a 3’-quencher in which the fluorophore is held in close proximity to the quencher. Following removal of the modified base of the MB, the fluorophore is separated from the quencher and fluorescence can be detected as a function of time. Two modified beacons containing of uracil and hypoxanthine have been used to validate the assay on purified proteins with success. However, while applying the assay to cell extracts, the results were interfered by non-specific nuclease activities. Then we design a cFRET probe based on fluorescence resonance energy transfer (FRET) which might be reflectory non-specific nuclease digestion in cell extracts. However, we demonstrated the purified protein successfully and cell extracts still cleaved cFRET probes non-specifically. We hope we can discover an approach to escape interference of nuclease in cell extracts and we can monitor DNA glycosylase activities in real-time. In conclusion, molecular beacons and FRET probes are promising tools for monitoring DNA glycosylase activities in real-time. However, a stable measure need to be developed to avoid the interference of non-specific nuclease activities in cell extracts. 2、 Mismatch repair (MMR) stabilizes the genome by correction of DNA biosynthetic errors, by ensuring the fidelity of genetic recombination, and in mammalian cells by participation in the cellular response to some classes of DNA damage. Escherichia coli mismatch repair has been reconstituted using purified components. Analysis of nuclear extracts of human cells has indicated a similar excision repair mechanism for nick-directed mismatch correction in higher cells, and several reconstituted systems that rely on purified human proteins have been described, such as hMutSα、hMutSβ、hMutLα. Recently, scientists discovered that nickel (II) could be inhibitors of DNA repair. Nickel can greatly enhance the mutagenicity and genotoxicity of compounds in cigarette by inhibiting the nucleotide excision repair pathway in human cells. We have confirmed that nickel could inhibit MMR of E. coli and human and presumed that nickel inhibited repair before MutH incision of the MMR in E. coli. However, there is no evidence of mechanism of nickel inhibiting MMR in human cells. To investigate the inhibitory patch of nickel, we analyzed intermediates of limiting repair reaction by denaturing gel electrophoresis. We found that nickel inhibited repair before excision and nickel could inhibit the activity of DNA ligase. These results provide us a way to demonstrate the inhibitory mechanism. We can focus on the specific protein or the specific step of MMR to clarify the mechanism of nickel inhibiting human MMR.