Pathologically, high levels of aldosterone are associated with severe cardiovascular diseases such as congestive heart failure, hypertension, and myocardial fibrosis. The inhibition of aldosterone synthase (CYP11B2) to reduce aldosterone levels has been proposed as a promising treatment for diseases related to CYP11B2 because it is the crucial enzyme in the biosynthesis of aldosterone. A series of novel pyridyl- or isoquinolinyl-substituted indolines and indoles was designed via a ligand-based approach. The synthesized compounds were tested and found to be strong CYP11B2 inhibitors. The most potent ones showed IC50 values of less than 3 nM, being similarly potent as fadrozole and LCI699. Among them, compounds 14 and 23 showed good selectivity over the highly homologous CYP11B1, with selectivity factors (SF = IC50 CYP11B1/IC50 CYP11B2) around 170; thus, they are superior to fadrozole and LCI699 (SFs < 15). These potent CYP11B2 inhibitors exhibited no inhibition (IC50 > 50 μM) of a panel of hepatic CYP enzymes including CYP1A2, CYP2C9, CYP2C19, CYP2D6, and CYP3A4 and the crucial steroidogenic enzymes, CYP17 and CYP19. Because of these advantageous profiles, compounds 14 and 23 are considered to be candidates for further in vivo evaluation.
Potent and selective CYP11B1 inhibitors could be promising therapeutics for the treatment of Cushing's syndrome. Optimization of Ref 1 (5-((1H-imidazol-1-yl)methyl)-2-phenylpyridine) led to compound 44 (5-((5-methylpyridin-3-yl)methyl)-2-phenylpyridine) with a 50-fold improved IC50 value of 2 nM toward human CYP11B1 and an enhanced inhibition of the rat enzyme (IC50 = 2440 nM) compared to Ref 1 (IC50 > 10000 nM). Furthermore, selectivities over CYP11B2, CYP17, and CYP19 were observed, as well as satisfying metabolic stability not only in human and rat plasma but also in liver S9 fraction. Investigation of cytotoxicity and inhibition of hepatic CYP2A6 and CYP3A4 showed that 44 fulfills first safety criteria and can be considered for further in vivo evaluation in rats.
Cushing's disease, characterized by elevated plasma cortisol levels, can be controlled by inhibition of 11β-hydroxylase (CYP11B1). The previously identified selective and potent CYP11B1 inhibitor 5-((5-methylpyridin-3-yl)methyl)-2-phenylpyridine Ref 7 (IC= 2 nM) exhibited promutagenic potential as well as very low oral bioavailability in rats (F = 2%) and was therefore modified to overcome these drawbacks. Successful lead optimization resulted in similarly potent and selective 5-((5-methoxypyridin-3-yl)methyl)-3-phenylisoxazole 25 (IC = 2 nM, 14-fold selectivity over CYP11B2), exhibiting a superior pharmacological profile with no mutagenic potential. Furthermore, compound 25 inhibited rat CYP11B1 (IC = 2 μM) and showed a high oral bioavailability (F = 50%) and sufficient plasma concentrations in rats, providing an excellent starting point for a proof-of-principle study.
Here we report the preclinical profile of REDX08608 our novel, potent and selective, reversible BTK inhibitor that is equipotent against wild-type and mutant C481S BTK. Bruton's tyrosine kinase (BTK) is a member of the src-related Tec family of cytoplasmic tyrosine kinases and plays a key role in the BCR signaling pathway, which is required for the development, activation and survival of B-cells. BTK is a clinically validated target to treat B-cell malignancies that are dependent on BCR signaling i.e.CLL and NHL with ibrutinib approved for the treatment of CLL, MCL and WM. Irreversible and covalent reversible BTK inhibitors such as ibrutinib, acalabrutinib and GS-4059 specifically target a cysteine residue C481 within BTK and mutations at this site clearly interfere with covalent drug binding. C481S, C481Y, C481R, C481F mutations have been reported and linked to cases of resistance that have emerged in patients with CLL progression following treatment with ibrutinib (Byrd2016, Inhye2016, Maddocks2015, Woaych2014). Redx reversible BTK inhibitor, REDX08608, aims to overcome this resistance mechanism by targeting both wild type and C481-mutated BTK. Redx have recently presented REDX06961 our BTK probe (Guisot2016, AACR#4795) and, following lead optimization, we are now disclosing REDX08608, our lead compound, a potent, reversible and selective BTK inhibitor, which displays an improved profile including superior pharmacokinetics. REDX08608, reversibly, inhibits WT and C481S BTK and displays nanomolar binding affinity and potency in biochemical and cellular-based assays. REDX08608 inhibits BTK signaling and growth in cell lines dependent on the BTK pathway such the OCI-LY10 ABC-DLBCL cell line. Importantly, REDX08608 also inhibits BTK signaling in primary CLL cells. In human whole blood and isolated human PBMCs, REDX08608 inhibits activation of B-cells at nanomolar concentrations measured by inhibition of immunoglobulin-induced CD69 in CD19+cells. REDX08608 is highly selective when tested against a panel of 468 kinases and exhibits improved target specificity with >100-fold selectivity against other Tec and Src kinase family members (ITK, TXK, BMX, TEC, BLK, CSK, FYN, HCK, LCK, SRC) and >400-fold selectivity against EGFR. REDX08608 was fully profiled through DMPK in vitro assays including metabolic stability, plasma stability, cytochrome P450 inhibition, PXR activation/cytochrome P450 activity, time dependent inhibition and cytochrome P450 reaction phenotyping. REDX08608 was shown to have an acceptable metabolic and plasma stability profile across species (mouse, rat, dog, monkey and human). REDX08608 displayed no evidence of PXR activation or time dependent inhibition. IC50s were determined for human cytochrome P450s (1A2, 2D6, 2C9, 2C19 and 3A4) and were all >10 µM. Good exposure, oral bioavailability and half-life were demonstrated for REDX08608 in mouse, rat and dog, with dose linearity assessment performed in mouse (F = 73-100%, CL= 11% liver blood flow in mice; F = 55-84%, CL = 28% liver blood flow in rat; F = 85%, CL= 10% liver blood flow in dog). In vivo efficacy studies in preclinical models will also be disclosed. In conclusion, REDX08608 is a potent and selective, reversible BTK inhibitor with efficacy in lymphoma cell lines that offers the potential to target both wild-type BTK and an important emerging resistance mechanism in patients with CLL progression following ibrutinib-treatment. Disclosures Guisot: Redx Oncology Ltd - Redx Pharma Plc: Employment. Best:Redx Oncology Ltd - Redx Pharma Plc: Employment. Wright:Redx Oncology Ltd - Redx Pharma Plc: Employment. Thomason:Redx Oncology Ltd - Redx Pharma Plc: Employment. Woyach:Acerta: Research Funding; Karyopharm: Research Funding; Morphosys: Research Funding. Abet:Redx Oncology Ltd - Redx Pharma Plc: Employment. Castagna:Redx Oncology Ltd - Redx Pharma Plc: Employment. Cousin:Redx Oncology Ltd - Redx Pharma Plc: Employment. Emmerich:Redx Oncology Ltd - Redx Pharma Plc: Employment. Ho:Redx Oncology Ltd - Redx Pharma Plc: Employment. Kelly:Redx Oncology Ltd - Redx Pharma Plc: Employment. King-Tours:Redx Oncology Ltd - Redx Pharma Plc: Employment. Lyons:Redx Oncology Ltd - Redx Pharma Plc: Employment. Muller:Redx Oncology Ltd - Redx Pharma Plc: Employment. Refuerzo:Redx Oncology Ltd - Redx Pharma Plc: Employment. Sargent:Redx Oncology Ltd - Redx Pharma Plc: Employment. Talab:Redx Oncology Ltd - Redx Pharma Plc: Employment. Bingham:Redx Oncology Ltd - Redx Pharma Plc: Employment. Phillips:Redx Oncology Ltd - Redx Pharma Plc: Employment. Armer:Redx Oncology Ltd - Redx Pharma Plc: Employment.
Redx Oncology has developed novel, differentiated, reversible small molecule inhibitors of BTK, combining current best-in-class potency with improved selectivity profiles, which are suitable for oral, once daily dosing, designed to be equipotent against wild-type and C481S BTK. BTK is a member of the src-related Tec family of cytoplasmic tyrosine kinases. BTK plays a key role in the BCR signaling pathway, which is required for the development, activation and survival of B-cells. BTK inhibitors have therefore been developed with the aim of treating B-cell malignancies that are dependent on BCR signaling, such as CLL and NHL. Ibrutinib is an irreversible BTK inhibitor that has been approved for the treatment of CLL, MCL and WM. Irreversible and covalent reversible BTK inhibitors specifically target a cysteine residue C481 within BTK. Following treatment with ibrutinib, cases of secondary resistance have emerged in both CLL and MCL patients. Acquired mutations within BTK such as C481S, C481Y, C481R, C481F have been reported in the literature and clearly interfere with covalent drug binding. It has been predicted that the incidence of observed resistance will increase as clinical use outside clinical trials expands over time. Here, we present our reversible BTK inhibitor series demonstrating subnanomolar binding affinity for WT and C481S forms of BTK, that inhibits formation of pBTK in both WT and C481S BTK expressing cells. In addition, the compound demonstrated significant in vitro potency against a number of lymphoma cell lines including inhibition of BCR signaling and proliferation in OCI-Ly10 cells at nanomolar concentrations. To further investigate the binding nature of these compounds, PBMC wash out studies, measuring CD69 as a marker of B-cell activation, were used to highlight the reversible activity of these compounds. Some BTK inhibitors also inhibit ITK, which plays a critical role in FcR-stimulated NK cell function that is required for ADCC. ADCC is the mechanism that anti-CD20 antibodies, such as rituximab, are believed to activate, and ibrutinib has been shown to antagonize this mechanism in vitro. As rituximab-combination chemotherapy is today's standard of care in B-cell malignancies, it would be desirable to have a BTK inhibitor with high selectivity for BTK over ITK. At 1 μM, our lead compound is highly selective when tested against 469 kinase and did not show significant inhibition against other kinases involved in BCR signaling (e.g. Syk, Lyn). Furthermore, the compound has high selectivity versus structurally related cysteine-containing kinases (including EGFR and ITK) both in enzyme and cellular assays. Our lead compound has a favorable in vitro safety profile and drug-like properties, displaying an improved CYP profile to competitor compounds. In vivo PK demonstrated good oral bioavailability and in vivo efficacy has been demonstrated. Citation Format: Nicolas E S Guisot, Victoria Walker, Stuart A. Best, Valentina Abet, Rose Chappell, Juliette Emmerich, Kelvin Ho, James R. Kelly, Kristina Lyons, Melanie Müller, Julienne Refuerzo, Louise Sargent, Fatima Talab, Madelene Waldron, Matilda Bingham, Mary-Ann Campbell, Caroline Phillips, Richard Armer. Development of novel, selective, reversible inhibitors equipotent against wild-type and C481S Bruton's tyrosine kinase (BTK). [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 4795.
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