Abstract P2-09-17: Allosteric inhibitors of the proteasome: A new concept for breast cancer treatment

• Published in: Cancer research (Chicago, Ill.) Vol. 73; no. 24_Supplement; pp. P2 - P2-09-17
• Main Authors: Osmulski, PA, Gaczynska, M
• Format: Journal Article
• Language: English
• Published: 15.12.2013
• ISSN: 0008-5472; 1538-7445
• DOI: 10.1158/0008-5472.SABCS13-P2-09-17

Abstract Proteasome is an essential protease of the proteasome-ubiquitin pathway, responsible for maintaining intracellular proteostasis. It is a multifunctional, multisubunit enzyme built from interchangeable modules and intricately regulated on the molecular and cellular levels. Proteasome inhibitors display proapoptotic properties, preferentially aimed at cancerous cells. Consequently, targeted therapy with bortezomib, the competitive inhibitor of the proteasome, has been very successful with refractory/relapsed multiple myeloma and with lymphomas. Unfortunately, breast cancers performed disappointingly in clinical trials with bortezomib. We propose that a new generation of small-molecule proteasome inhibitors distinct from bortezomib may prove successful with breast cancers. In contrast to bortezomib which directly blocks proteasome active sites, the new inhibitors are allosteric ligands binding to noncatalytic sites and disrupting the enzyme's function by targeting long-distance transfer of structural signals within the enzyme's molecule. The advantages of allosteric ligands, now rapidly gaining popularity in targeted drug design, include versatility of molecular actions, defying drug resistance mechanisms, and usually high specificity with low toxicity. For example, one of the small-molecule allosteric ligands we created compromises interactions between the catalytic core proteasome and its regulatory sub-assembly 19S (“cap”, regulatory particle) responsible for recognizing and processing the majority of intracellular protein substrates tagged for degradation by polyubiquitin. We found that treatment with nanomolar concentration of the compound induced cell death in Mcf7 human breast cancer cultured cells. Interestingly, this cell line is known for its resistance to bortezomib treatment. Even more, treatment with the allosteric ligand together with bortezomib produced a synergistic effect and sensitized the Mcf7 cells to the actions of competitive inhibitor. Remarkable, the cytotoxic effects of allosteric ligand or its combination with bortezomib were not observed with the noncancerous human breast cell line, Mcf10A. Summarizing, allosteric regulation of the proteasome by small-molecule ligands, alone or in combination with established drugs competitively inhibiting proteasome, seem to be a promising strategy to utilize proteasome as a drug target in breast cancers. Citation Information: Cancer Res 2013;73(24 Suppl): Abstract nr P2-09-17.