SAT182 Effects Of An Orally Bioavailable Nonpeptide Parathyroid Hormone Receptor Type 1 (PTH1R) Antagonist In Rodent Models Of Primary Hyperparathyroidism (PHPT)

Abstract

Abstract Disclosure: A.S. Antwan: Employee; Self; Crinetics Pharmaceuticals. E. Rico-Bautista: Employee; Self; Crinetics Pharmaceuticals. J. Pontillo: Employee; Self; Crinetics Pharmaceuticals. S. Wang: Employee; Self; Crinetics Pharmaceuticals. M. Johns: Employee; Self; Crinetics Pharmaceuticals. B. Ramms: Employee; Self; Crinetics Pharmaceuticals. M.A. Fowler: Employee; Self; Crinetics Pharmaceuticals. J.B. Nguyen: Employee; Self; Crinetics. A.A. Castellanos Gonzalez: Employee; Self; Crinetics. B. Fleck: Employee; Self; Crinetics Pharmaceuticals. K. Retting: Employee; Self; Crinetics Pharmaceuticals. D. Dalvie: Employee; Self; Crinetics Pharmaceuticals. S.F. Betz: Employee; Self; Crinetics Pharmaceuticals. S. Markison: Employee; Self; Crinetics Pharmaceuticals. Primary hyperparathyroidism (PHPT) is a condition resulting from an over-secretion of parathyroid hormone (PTH) from one or more overactive parathyroid glands. PTH is a peptide hormone that regulates blood calcium concentrations through effects on bone, intestines, and kidney. PTH acts on parathyroid hormone receptor type 1 (PTH1R) in the kidney to increase calcium reabsorption and block phosphate reabsorption. The loss of phosphate ions then causes an increase in ionized calcium in the blood and cAMP in the urine. At the bone, continuous PTH infusion stimulates osteoclast activity while inhibiting osteoblast activity, leading to breakdown of bone and release of calcium into the extracellular fluid. Conditions that cause excess PTH, such as PHPT, result in elevated concentrations of plasma calcium, increased bone loss, increased fracture risk, and higher susceptibility to kidney stone development. PHPT affects approximately 100,000 patients per year, but many patients are asymptomatic and remain undiagnosed. While a partial or total parathyroidectomy may be suitable for patients diagnosed with severe cases of PHPT, there are limited treatment options for those who do not meet the criteria or do not wish to undergo surgery. The goals for medicinal treatment are to normalize blood calcium levels and urinary calcium excretion, as well as increase bone mineral density to reduce fracture risk. Blocking PTH action directly via a potent PTH1R antagonist may provide an important new therapeutic mechanism to treat patients with PHPT. Using iterative medicinal chemistry and pharmacology, Crinetics has identified several potent and orally bioavailable PTH1R antagonists with good drug-like properties. Lead molecules were evaluated in vivo in preclinical rodent models for their ability to suppress the effects of excess PTH on serum calcium, bone turnover, and cAMP levels in the kidney. One of these compounds, ANT-5, was characterized as a potent negative allosteric modulator of both human and rat PTH1R. In rats, oral administration of ANT-5 dose-dependently suppressed PTH-induced hypercalcemia. ANT-5 also suppressed PTH-stimulated urinary cAMP in rats, indicating its ability to inhibit the actions of PTH in the kidney. We further evaluated the effect of ANT-5 in a rodent model of continuous PTH infusion-induced bone turnover. Once-daily oral administration of ANT-5 mitigated PTH-induced bone resorption, suggesting that inhibiting PTH1R may have beneficial clinical effects on bone density. The culmination of these studies has led to a subset of candidate molecules that are being evaluated in safety studies to identify the compound(s) suitable for evaluation in human clinical trials. Support: Crinetics Pharmaceuticals. Presentation: Saturday, June 17, 2023