Metabolic intervention targeting 6-phosphofructo-2-kinase/fructose-2,6-biphosphatase 3 (PFKFB3) using a structure-based design.

Abstract

e13518 Background: By producing fructose-2,6-bisphosphate, PFKFB3 functions as an activator of anaerobic glycolysis. PFKFB3 is both over expressed and over activated in many of the types of human cancer. Specific inhibition of the PFKFB3 enzyme results in a reduction in metabolism and cell growth in oxygen-deficient cancer environments. Methods: High-throughput screening. Medicinal Chemistry. Structure-Based Drug Design, X-ray Crystallography. NMR. Isothermal Calorimetry. Dynamic Light Scatttering. ADME. Results: A high-throughput screening of 50.000 selected compounds, by means of a biochemical assay, generated 105 hits including both ATP-and non-ATP competitive hits as identified by NMR binding experiments. The latter type was prioritized and two hits with a similar “ring-linker-ring structure” were selected for further expansions. Interestingly, although structurally similar, the two hits were found by means of X-ray crystallography to exhibit different binding modes within the fructose pocket. Based on their respective binding mode, two chemical series were developed displaying different ADME properties and PFKFB isoenzyme selectivity. Calorimetry verified a reversible strong enthalpy driven, direct binding for both chemical series. A third chemical series was developed towards yet another unoccupied binding pocket within the fructose-site, yielding a 5-fold increase in potency. Strong interactions within the new pocket were confirmed using X-ray crystallography. Our PFKFB3 inhibitors were shown to reduce tumor cell growth in vitro and to exhibit combinatory effects with Cisplatin. Conclusions: We have targeted the fructose-binding pocket of PFKFB3, developed compounds with nM binding potency and have gained a detailed understanding of SAR via structural information. The structure-based analysis has provided a good understanding of the molecular interactions, which is important for further biological/clinical positioning: e.g., combination with chemotherapy, optimization of PK properties and proof of principle in vivo.