Inhibition of the bromodomain of the transcriptional regulator CBP/P300 is an especially interesting new therapeutic approach in oncology. We recently disclosed in vivo chemical tool 1 (GNE-272) for the bromodomain of CBP that was moderately potent and selective over BRD4(1). In pursuit of a more potent and selective CBP inhibitor, we used structure-based design. Constraining the aniline of 1 into a tetrahydroquinoline motif maintained potency and increased selectivity 2-fold. Structure-activity relationship studies coupled with further structure-based design targeting the LPF shelf, BC loop, and KAc regions allowed us to significantly increase potency and selectivity, resulting in the identification of non-CNS penetrant 19 (GNE-781, TR-FRET IC = 0.94 nM, BRET IC = 6.2 nM; BRD4(1) IC = 5100 nΜ) that maintained good in vivo PK properties in multiple species. Compound 19 displays antitumor activity in an AML tumor model and was also shown to decrease Foxp3 transcript levels in a dose dependent manner.
SignificanceCD226 is an important activating receptor involved in mediating natural killer (NK) cell responses against tumors, but how CD226 exerts control over NK cell function is not fully understood. CD226 belongs to the poliovirus receptor (PVR)-nectin family that includes TIGIT and CD96, with TIGIT garnering much attention as a key checkpoint in T cell and NK cell antitumor responses and as an immunotherapy target. Thus, it is imperative to determine how CD226 counteracts the actions of TIGIT and CD96 with which it competes for binding to its ligands such as CD155 (PVR). We demonstrate that CD226 engagement of CD155 is required for phosphorylation of transcription factor FOXO1, resulting in inactivation of its negative regulatory control over NK cell effector function.
RO7297089 is a bispecific antibody (IgG-scFv) targeting Bcell maturation antigen (BCMA) and CD16a (FcγRIIIA) that is being developed for the treatment of multiple myeloma (MM). BCMA is exclusively expressed on plasmablasts and differentiated plasma cells (PCs), and is overexpressed on malignant PCs in MM patients. CD16a is expressed on natural killer (NK) cells, monocytes, mast cells, and macrophages. Herein, we characterized the mode of action and safety profile of RO7297089 in vitro and in vivo. RO7297089 showed potent cell killing when using BCMA+ MM tumor cell lines as target cells and human peripheral blood mononuclear cells, NK cells or macrophages as effector cells. Minimal increases in TNFα (2x) and IFNγ (4x), but not other cytokines/chemokines, were observed compared to the vehicle control treatment only in the presence of the BCMA+ MM tumor cell line up to the concentration tested. This suggests that, unlike T-cell engagers, the risk of cytokine release syndrome in patients receiving RO7297089 is low. Cynomolgus monkey is the only relevant nonclinical species for RO7297089 as it showed binding to both recombinant CD16 and BCMA with comparable affinity to human antigens. Following five weekly intravenous administrations to monkeys at 0, 15, and 50 mg/kg, RO7297089 was well tolerated. In line with the mechanism of action, there were no test article-related cytokine increases or adverse findings observed in both dose levels. Systemic exposure of RO7297089 was approximately dose proportional from 15 to 50 mg/kg. Anti-drug antibodies (ADA) were observed in some animals at both dose levels, and ADA-related decreases in concentrations were observed at only 15 mg/kg. To evaluate in vivo activity, RO7297089-related effects on total plasma sBCMA and PCs were assessed. Elevations of sBCMA levels (100x) were observed post dose at both dose levels, and these effects returned to predose levels in animals that did not maintain concentrations at 15 mg/kg, suggesting that RO7297089 bound to and stabilized circulating cynomolgus sBCMA. Time- and dose-dependent reductions in serum IgM levels were observed at both dose levels. Changes in PC numbers were not detected by immunophenotyping; however, gene expression analysis of PC markers was included and demonstrated clear reductions in mRNA expression levels of PC markers including BCMA and J-chain in blood at both dose levels, suggesting reductions in BCMA+ cells. Collectively, these studies suggest that RO7297089 selectively kills BCMA+ cells by engaging CD16a-positive immune cells and has a favorable safety profile. Citation Format: Satoko Kakiuchi-Kiyota, Melissa M. Schutten, Adeyemi O. Adedeji, Hao Cai, Robert Hendricks, Luna Liu, Sivan Cohen, Aaron M. Fullerton, Nicholas Corr, Lanlan Yu, Denise de Almeida Nagata, Shelly Zhong, Michael Dillon, Christoph Spiess, Steve R. Leong, Bing Zheng, Susanne Wingert, Uwe Reusch, Stefan Knackmuss, Thorsten Ross, Andrew Polson, Ayse M. Ovacik. Preclinical pharmacology and safety of RO7297089, a novel anti-BCMA/CD16a bispecific antibody for the treatment of multiple myeloma [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 4556.
Notch ligand Delta-like ligand 4 (DLL4) has been shown to regulate CD4 T-cell differentiation, including regulatory T cells (T). Epigenetic alterations, which include histone modifications, are critical in cell differentiation decisions. Recent genome-wide studies demonstrated that T have increased trimethylation on histone H3 at lysine 4 (H3K4me3) around the T master transcription factor, Foxp3 loci. Here we report that DLL4 dynamically increased H3K4 methylation around the Foxp3 locus that was dependent upon upregulated SET and MYDN domain containing protein 3 (SMYD3). DLL4 promoted Smyd3 through the canonical Notch pathway in iT differentiation. DLL4 inhibition during pulmonary respiratory syncytial virus (RSV) infection decreased Smyd3 expression and Foxp3 expression in T leading to increased Il17a. On the other hand, DLL4 supported Il10 expression in vitro and in vivo, which was also partially dependent upon SMYD3. Using genome-wide unbiased mRNA sequencing, novel sets of DLL4- and Smyd3-dependent differentially expressed genes were discovered, including lymphocyte-activation gene 3 (Lag3), a checkpoint inhibitor that has been identified for modulating Th cell activation. Together, our data demonstrate a novel mechanism of DLL4/Notch-induced Smyd3 epigenetic pathways that maintain regulatory CD4 T cells in viral infections.
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