MS-553 Therapy Inhibits BCR Signaling and Increases Survival Dependence on BCL-2 in BTK-Inhibitor Resistant CLL

Abstract

B-cell receptor (BCR) signaling pathway inhibitors and B-cell lymphoma-2 (BCL-2) antagonist venetoclax (Ven) have transformed the treatment of chronic lymphocytic leukemia (CLL), including in high-risk patients with 17p deletion and/or TP53 mutations and complex karyotype. Despite the durable remissions observed with inhibitors of Bruton's Tyrosine Kinase (BTKi), a significant proportion of patients develop resistance with acquired mutations in BTK and its downstream target phospholipase Cγ2 ( PLCG2). Patients who progress on BTKi including ibrutinib (ibr) often receive Ven but eventually relapse, underscoring an urgent need for new treatment strategies. Protein kinase C-β (PKC-ß) is a protein downstream of BCR signaling (BTK-PLCG2) and is essential for CLL cell survival and proliferation in vivo. Here we investigate MS-553, an inhibitor of PKC-ß, with a focus of combination strategies in CLL patient samples including relapsed/refractory CLL. We show that CLL cells in contact with stroma upregulate PKC-ßII, its immediate downstream effectors, pGSK and pERK as well as ß-catenin in CLL patients including those with mutant TP53 and 17p (n=8). Correspondingly, MS-553 (5µM, 48h) exposure reduced levels of p-PKC-ßII and its downstream effectors (p-ERK, p-GSK) in a dose dependent manner regardless of TP53 mutation in both CLL cells and those supported by NK.Tert (stromal cell line derived from bone marrow, BM, and mimics BM microenvironment). Pre-treatment (48h, 5µM MS-553) of stromal NK.Tert cells with MS-553 prevented the upregulation of PKC-ßII within adjacent CLL cells implicating the stroma as a major source of PKC-ß activation in CLL cells. We also tested whether MS-553 could inhibit PKC-ß signaling in CLL cells exposed to phorbol myristate acetate (PMA-400nM, 90 min), which simulates BCR activation. MS-553 (5µM, 48h) exposure caused downregulation of BTK effectors (pPKC-ßII, pERK, pGSK), BCL-2 family member proteins (MCL-1 and BCLxl), and ß-catenin (n=10). In parallel experiments, we used BH3 profiling to show that CLL cells' (n=8) exposure to MS-553 in vitro developed increased dependence on BCL-2 and BCLxl for survival (Bim, Bad, XXA1_y4ek, 5-fold± 2-fold increase) in both wild type (WT) and mutant (Mut) CLL cells, suggesting a mechanistic rationale for synergy with Ven. To confirm this, CLL cells were exposed to MS-553, Ven or a combination of MS-553 and Ven. ~3-fold and 9-fold synergistic increase in the mitochondrial dysfunction (measured by cytochrome C release, 12h, 5µM MS-553, 1nM Ven) was observed in stromal supported WT and Mut CLL respectively in MS-553 versus Ven+MS-553 treated group. Similarly, ~3-fold increase was observed in WT and Mut CLL alone group and more than 10-fold increase was found in stromal supported WT and Mut group in cell death determined as percent apoptotic index (measured by annexin V-PI staining, 18h, 5µM MS-553, 1nM Ven) in MS-553 versus Ven+MS-553 group respectively. Finally, we validated our preclinical findings in CLL samples obtained from four patients on MS-553 therapy (NCT03492125, Range = cycles 0-19, MS-553 28 days/cycle). All patients showed an increase in survival dependence towards BCL-2 and BCLxl by Cycle 3-6 of MS-553 therapy. This was accompanied by downregulation of ß-catenin, pPKC-ßII, pGSK, pERK along with BCLxl and MCL-1 after Cycle 10 or later of MS-553 therapy (data summary table1). Overall, our data provides clear evidence that MS-553 inhibits BCR signaling in vitro and in patients on MS-553 therapy. It also provides a rationale for combinations with Ven as a treatment partner based on its ability to increase survival dependence on BCL-2.