C-terminal region of USP7/HAUSP is critical for deubiquitination activity and contains a second mdm2/p53 binding site.

USP7, also known as the hepes simplex virus associated ubiquitin-specific protease (HAUSP), deubiquitinates both mdm2 and p53, and plays an important role in regulating the level and activity of p53. Here, we report that deletion of the TRAF-like domain at the N-terminus of USP7, previously reported to contain the mdm2/p53 binding site, has no effect on USP7 mediated deubiquitination of Ub(n)-mdm2 and Ub(n)-p53. Amino acids 208-1102 were identified to be the minimal length of USP7 that retains proteolytic activity, similar to full length enzyme, towards not only a truncated model substrate Ub-AFC, but also Ub(n)-mdm2, Ub(n)-p53. In contrast, the catalytic domain of USP7 (amino acids 208-560) has 50-700 fold less proteolytic activity towards different substrates. Moreover, inhibition of the catalytic domain of USP7 by Ubal is also different from the full length or TRAF-like domain deleted proteins. Using glutathione pull-down methods, we demonstrate that the C-terminal domain of USP7 contains additional binding sites, a.a. 801-1050 and a.a. 880-1050 for mdm2 and p53, respectively. The additional USP7 binding site on mdm2 is mapped to be the C-terminal RING finger domain (a.a. 425-491). We propose that the C-terminal domain of USP7 is responsible for maintaining the active conformation for catalysis and inhibitor binding, and contains the prime side of the proteolytic active site.

Evaluation of an antibody-free ADP detection assay: ADP-Glo.

Identification of kinase, especially protein kinase, modulators through high-throughput screening (HTS) has become a common strategy for drug discovery programs in both academia and the pharmaceutical industry. There are a number of platform technologies that can be used for measuring kinase activities. However, there is none that fits all criteria in terms of sensitivity, ATP tolerance, robustness, throughput, and cost-effectiveness. Therefore, development of a homogeneous and robust HTS assay for some kinase targets is still challenging. We recently evaluated the ADP-Glo assay from Promega. This is a homogeneous, signal increase assay that measures ADP production from a kinase reaction by coupled enzymes that first convert ADP to ATP and subsequently quantifies ATP using luciferase in the presence of luciferin. Since the unused ATP in the reaction is depleted prior to ADP to ATP conversion, this assay shows excellent sensitivity over a wide range of ATP concentrations. We demonstrate that ADP-Glo assay can be used for 2 kinase targets that belong to different classes, and compare the results of compound profiling with SPA and FP assay technologies.

A high-throughput screen measuring ubiquitination of p53 by human mdm2.

Tumor suppressor p53 is typically maintained at low levels in normal cells. In response to cellular stresses, such as DNA damage, p53 is stabilized and can stimulate responses leading to cell cycle arrest or apoptosis. Corresponding to its central role in preventing propagation of damaged cells, mutation or deletion of p53 is found in nearly 50% of all human tumors. Mdm2 (mouse-d-minute 2) and its human ortholog (hmdm2 or hdm2) catalyze the ubiquitination of p53, targeting it for degradation via the proteosome. Thus, the activity of mdm2 is inversely correlated with p53 levels. Based on this, inhibition of human mdm2 activity by a small-molecule therapeutic will lead to net stabilization of p53 and be the basis for development of a novel cancer therapeutic. Previous high-throughput screening assays of mdm2 measured the autoubiquitination activity of mdm2, which occurs in the absence of an acceptor substrate such as p53. The major drawback to this approach is that inhibitors of mdm2 autoubiquitination may lead to a net stabilization of mdm2 and thus have the opposite effect of inhibitors that interfere with p53 ubiquitination. The authors describe the development, validation, and execution of a high-throughput screening measuring the ubiquitination of p53 by mdm2, with p53 labeled with europium and the other substrate (Ub-UbcH5b) labeled with a Cy5 on the ubiquitin. After confirming that known inhibitors are detected with this assay, it was successfully automated and used to query >600,000 compounds from the GlaxoSmithKline collection for mdm2 inhibitors.

A simple assay for detection of small-molecule redox activity.

In addition to selecting molecules of pharmacological interest, high-throughput screening campaigns often generate hits of undesirable mechanism, which cannot be exploited for drug discovery as they lead to obvious problems of specificity and developability. Examples of undesirable mechanisms are target alkylation/acylation and compound aggregation. Both types of "promiscuous" mechanisms have been described in the literature, as have methods for their detection. In addition to these mechanisms, compounds can also inhibit by oxidizing susceptible enzyme targets, such as metalloenzymes and cysteine-using enzymes. However, this redox phenomenon has been documented infrequently, and an easy method for detecting this behavior is missing. In this article, the authors describe direct proof of small-molecule oxidation of a cysteine protease by liquid chromatography/tandem mass spectrometry, develop a simple assay to predict this oxidizing behavior by compounds, and show the utility of this assay by demonstrating its ability to distinguish nuisance redox compounds from well-behaved inhibitors in 3 historical GlaxoSmithKline drug discovery efforts.