Cell-based bioluminescent assays for all three proteasome activities in a homogeneous format.

A luminescent method to individually measure the chymotrypsin-like, trypsin-like, or caspase-like activities of the proteasome in cultured cells was developed. Each assay uses a specific luminogenic peptide substrate in a buffer optimized for cell permeabilization, proteasome activity, and luciferase activity. Luminescence is generated in a coupled-enzyme format in which proteasome cleavage of the peptide conjugated substrate generates aminoluciferin, which is a substrate for luciferase. The homogeneous method eliminates the need to prepare individual cell extracts as samples. Luminogenic proteasome substrates and buffer formulations enabled development of a single reagent addition method with adequate sensitivity for 96- and 384-well plate formats. Proteasome trypsin-like specificity was enhanced by incorporating a mixture of protease inhibitors that significantly reduce nonspecific serum and cellular backgrounds. The assays were used to determine EC(50) values for the specific proteasome inhibitors epoxomicin and bortezomib for each of the catalytic sites using a variety of cancer lines. These cell-based proteasome assays are direct, simple, and sensitive, making them ideal for high-throughput screening.

A homogeneous assay to measure live and dead cells in the same sample by detecting different protease markers.

A method to simultaneously determine the relative numbers of live and dead cells in culture by introducing a combination of two fluorogenic substrates or a fluorogenic and a luminogenic protease substrate into the sample is described. The method is based on detection of differential ubiquitous proteolytic activities associated with intact viable cells and cells that have lost membrane integrity. A cell-permeable peptide aminofluorocoumarin substrate detects protease activity restricted to intact viable cells. Upon cell death, the viable cell protease marker becomes inactive. An impermeable peptide rhodamine 110 (or aminoluciferin) conjugated substrate detects protease activity from nonviable cells that have lost membrane integrity. The multiplex assay can detect 200 dead cells in a population of 10,000 viable cells. The protease substrate reagents do not damage viable cells over the course of the assay, thus the method can be multiplexed further with other assays in a homogeneous format. Ratiometric measurement of viable and dead cells in the same sample provides an internal control that can be used to normalize data from other cell-based assays.

Homogeneous, bioluminescent protease assays: caspase-3 as a model.

Using caspase-3 as a model, the authors have developed a strategy for highly sensitive, homogeneous protease assays suitable for high-throughput, automated applications. The assay uses peptide-conjugated aminoluciferin as the protease substrate and a firefly luciferase that has been molecularly evolved for increased stability. By combining the proluminescent caspase-3 substrate, Z-DEVD-aminoluciferin, with a stabilized luciferase in a homogeneous format, the authors developed an assay that is significantly faster and more sensitive than fluorescent caspase-3 assays. The assay has a single-step format, in which protease cleavage of the substrate and luciferase oxidation of the aminoluciferin occurs simultaneously. Because these processes are coupled, they rapidly achieve steady state to maintain stable luminescence for several hours. Maximum sensitivity is attained when this steady state occurs; consequently, this coupled-enzyme system results in a very rapid assay. The homogeneous format inherently removes trace contamination by free aminoluciferin, resulting in extremely low background and yielding exceptionally high signal-to-noise ratios and excellent Z' factors. Another advantage of a luminescent format is that it avoids problems of cell autofluorescence or fluorescence interference that can be associated with synthetic chemical and natural product libraries. This bioluminescent, homogeneous format should be widely applicable to other protease assays.