1. Academic Validation
  2. Identification and mechanistic studies of a novel ubiquitin E1 inhibitor

Identification and mechanistic studies of a novel ubiquitin E1 inhibitor

  • J Biomol Screen. 2012 Apr;17(4):421-34. doi: 10.1177/1087057111433843.
Dana Ungermannova 1 Seth J Parker Christopher G Nasveschuk Douglas A Chapnick Andrew J Phillips Robert D Kuchta Xuedong Liu
Affiliations

Affiliation

  • 1 University of Colorado, Boulder, Colorado, CO, USA.
Abstract

Protein degradation via the ubiquitin-proteasome pathway is important for a diverse number of cellular processes ranging from cell signaling to development. Disruption of the ubiquitin pathway occurs in a variety of human diseases, including several cancers and neurological disorders. Excessive proteolysis of tumor suppressor proteins, such as p27, occurs in numerous aggressive human tumors. To discover small-molecule inhibitors that potentially prevent p27 degradation, we developed a series of screening assays, including a cell-based screen of a small-molecule compound library and two novel nucleotide exchange assays. Several small-molecule inhibitors, including NSC624206, were identified and subsequently verified to prevent p27 ubiquitination in vitro. The mechanism of NSC624206 inhibition of p27 ubiquitination was further unraveled using the nucleotide exchange assays and shown to be due to antagonizing ubiquitin activating Enzyme (E1). We determined that NSC624206 and PYR-41, a recently reported inhibitor of ubiquitin E1, specifically block ubiquitin-thioester formation but have no effect on ubiquitin adenylation. These studies reveal a novel E1 inhibitor that targets a specific step of the E1 activation reaction. NSC624206 could, therefore, be potentially useful for the control of excessive ubiquitin-mediated proteolysis in vivo.

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