OR35-02 Novel Androgen Receptor PROTAC Degrader ARV-110 Ameliorates Androgen Mediated Renal Injury in a Mouse Model of Polycystic Ovary Syndrome

Abstract

Abstract Disclosure: J. Basnet: None. S. Rezq: None. A.M. Huffman: None. T.E. Asala: None. L.L. Yanes Cardozo: None. D.G. Romero: None. Background: Polycystic ovary syndrome (PCOS) is the most common endocrine disorder in reproductive-age women. PCOS women often have increased central adiposity, insulin resistance, and renal injury. Hyperandrogenism is prevalent in PCOS women and is associated with renal injury and dysfunction. Androgens bind to the androgen receptor (AR) to impart downstream transcriptional activity. Targeting the AR may alleviate PCOS complications; however, the use of AR blockers is limited by their severe adverse effects in females; thus, safer alternative approaches are highly needed. The novel AR Proteolysis Targeting Chimera (PROTAC) degrader ARV-110 has shown high efficacy to prevent AR signaling in prostate cancer; however, its efficacy in PCOS is unknown. Using a well-established hyperandrogenemic mouse model of PCOS, we aim to test the hypothesis that decreasing AR protein levels with ARV-110 ameliorates androgen-mediated derangements in PCOS. Methods: Three-week old female mice (C57BL/6N) were implanted with Silastic tubes filled with the androgen dihydrotestosterone (DHT, 8mg, s.c., 90 days) or vehicle (n=6/grp). Four weeks post-DHT administration, mice were treated with ARV-110 (1 mg/kg/day, s.c.) for an additional 8 weeks. Body composition (EchoMRI) and oral glucose tolerance test (OGTT) were assessed. Kidney weight was measured by gravimetry. AR, extracellular matrix (ECM) remodeling marker MMP9, pro-fibrotic marker TGF-β, renal injury markers (urinary albumin to creatinine ration (UACR), KIM1, and NGAL) were assessed by Western-blot or ELISA. Results: DHT mice showed significant (p<0.05) increases in body weight (27.3±0.6 vs 23.9±0.26 g), fat mass (4.2±0.6 vs 2.1±0.1 g), lean mass (21.6±0.2 vs 19.8±0.2 g), as well as kidney weight (491.3±7.69 vs 303.1±5.5 mg) compared to controls. DHT increased fasting glucose (183.2±25.2 vs 141.5±9.9 mg/dL, p<0.05) and impaired OGTT (AUC:34557±6255 vs 23459±1896 mg.min/dL, p<0.05). ARV-110 treatment ameliorated all aforementioned DHT-mediated changes. At the molecular level, DHT-treated mice had higher renal AR (2.5-fold) and MMP9 (1.5-fold) protein expression. DHT upregulated renal TGF-β levels (2-fold, p<0.05), UACR (966.8±160.9 vs 381.5±41.2 ng albumin/mg creatinine), and urinary KIM1 (3.5-fold) and NGAL (6-fold). ARV-110 successfully decreased renal AR protein levels by 70% in DHT mice compared to vehicle-treated DHT. Excitingly, while ARV-110 did not modulate renal TGF-β levels, it completely abolished DHT-mediated increase in renal MMP9 while significantly lowering the levels of urinary renal injury markers UACR, KIM1 and NGAL. Conclusion and significance: Our findings suggest that DHT-mediated kidney hypertrophy, associated ECM remodeling and injury are ameliorated by ARV-110 in DHT-treated mice. AR PROTACs could be a novel therapeutic approach to treat renal dysfunction in PCOS. Supported by NIH P20GM121334. Presentation Date: Sunday, June 18, 2023