Abstract A39: Pomhex, a cell-permeable high potency enolase inhibitor with utility for collateral lethality treatment of cancer

Glycolysis inhibition is an active area of investigation for the treatment of cancer. However, few compounds have progressed beyond the cell culture stage. We have recently demonstrated that genomic passenger deletion of the glycolytic enzyme Enolase 1 (ENO1) leaves gliomas harboring such deletions solely reliant on ENO2, rendering them exquisitely sensitive to enolase inhibitors Collateral Lethality. However, the tool compound that we employed for these in vitro studies, Phosphonoacetohydroxamate (PhAH), has very poor pharmacological properties and was ineffective in vivo. We recently reported that a structural analogue of PhAH, the natural phosphonate antibiotic SF2312, is a high potency inhibitor of Enolase. While more potent than PhAH, SF2312 remains poorly cell permeable. Here, we generated a Pivaloyloxymethyl (POM) ester pro-drug derivative of SF2312, termed POMSF, which increased the potency in cell based systems by ~50-fold. POMSF is selectively active against ENO1-deleted glioma cells in culture at ~19 nM, versus μM for SF2312. However, POMSF displayed poor aqueous stability. A derivative of POMSF, termed POMHEX, showed greater stability and its active form, HEX, showed 4-fold preference for ENO1 over ENO2. Labeled 13C-glucose tracing shows that POMHEX inhibits glycolysis at the Enolase step in all cell lines tested, but with ~100-fold greater potency in ENO1-deleted lines. POMHEX selectively killed ENO1-deleted glioma cells with an IC50 <30nM, whilst non-delet...
Source: Molecular Cancer Therapeutics - Category: Cancer & Oncology Authors: Tags: Finding Synthetic Lethal Interactions through Functional Genomics: Poster Presentations - Proffered Abstracts Source Type: research