You are here: Home > Publications > 2016 > A Computationally Identified Compound Antagonizes Excess FGF-23 Signaling in Renal Tubules and a Mouse Model of Hypophosphatemia

Z. Xiao, D. Riccardi, H. A Velazquez, A. L Chin, C. R Yates, J. D Carrick, J. C Smith, J. Baudry, and L. D Quarles (2016)

A Computationally Identified Compound Antagonizes Excess FGF-23 Signaling in Renal Tubules and a Mouse Model of Hypophosphatemia

Science Signaling, 9(455):ra113.

Fibroblast growth factor–23 (FGF-23) interacts with a binary receptor complex composed of α-Klotho (α-KL) and FGF receptors (FGFRs) to regulate phosphate and vitamin D metabolism in the kidney. Excess FGF-23 production, which causes hypophosphatemia, is genetically inherited or occurs with chronic kidney disease. Among other symptoms, hypophosphatemia causes vitamin D deficiency and the bone-softening disorder rickets. Current therapeutics that target the receptor complex have limited utility clinically. Using a computationally driven, structure-based, ensemble docking and virtual high-throughput screening approach, we identified four novel compounds predicted to selectively inhibit FGF-23–induced activation of the FGFR/α-KL complex. Additional modeling and functional analysis found that Zinc13407541 bound to FGF-23 and disrupted its interaction with the FGFR1/α-KL complex; experiments in a heterologous cell expression system showed that Zinc13407541 selectivity inhibited α-KL–dependent FGF-23 signaling. Zinc13407541 also inhibited FGF-23 signaling in isolated renal tubules ex vivo and partially reversed the hypophosphatemic effects of excess FGF-23 in a mouse model. These chemical probes provide a platform to develop lead compounds to treat disorders caused by excess FGF-23.

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