Proteolysis is a process crucial to the normal turnover of proteins in the cell. Proteases are not only involved in protein destruction, but also in protein activation and numerous cellular processes. In addition, many viruses use cellular or viral proteases for various purposes. Consequently, specific protease inhibitors are attractive drug candidates. Although there were different assays used during recent years to assess protease activities, their actions were difficult to determine under physiological conditions. In this thesis, we tried to setup a cell-based assay which determined protease activity using fluorescence resonance energy transfer (FRET). We first constructed YFP-CFP fusion protein which contained multiple cloning sites (MCS) between two fluorescent proteins. Specific protease substrate sequences were introduced in-frame into the multiple cloning sites. A specific protease FRET probe was generated. Its FRET signal was readily detected by confocal microscopy. Utilizing a mammalian cell transfection method named surfection developed by our laboratory, we can cotransfect two plasmid simultaneously into mammalian cells with high transfection efficiency. Protease with its specific FRET probe were cotransfected into 293T cells with high efficiency. With increasing protease amount, the FRET signal was apparently decreasing. For its cell-based character, we used this assay for determining inhibition ability of cell free assay proved protease inhibitor. For HIV protease, pepstatin A had been shown to be an adequate inhibitor in cell free assay. But completely losing its inhibition to HIV protease in cell-based assay was noted in this thesis. In conclusion, this assay was capable of determining protease activity in cells. It was also suitable for determining substrate specificity or the different mutant proteases activity in cells. After all, it could be used for determining protease inhibitor and had the ability to convert into high throughput format for protease inhibitor screening.