ALBERT

Description: Destructive bone lesions due to osteolytic bone disease are a major cause of morbidity and mortality in multiple myeloma patients, occurring in more than 80% of cases. Underlying osteolytic bone disease is an uncoupling of the bone remodeling process, with an increased activity of osteoclasts and a decreased activity of osteoblasts. Current strategies to treat osteolytic bone disease focus on anti-resorptive agents, which do not rebuild bone loss. Src kinase has been implicated in both osteoclast and osteoblast function. In this study, we assessed the effect of Src inhibition with AZD0530 (saracatinib, Astra Zeneca) on the development of multiple myeloma and its associated osteolytic bone disease. We first determined Src family kinase expression in the multiple myeloma microenvironment and found that patient-derived myeloma cells express Src at low levels but disease stage does not correlate with Src expression levels. In accordance with the literature, Src mRNA expression was found to increase during osteoclast differentiation and decrease during osteoblast differentiation in publicly available microarray datasets. Next, we validated an inhibitory role of AZD0530 on osteoclast differentiation and function. At a pharmacological relevant concentration of 1 micromolar, AZD0530 inhibited the differentiation of RAW264.7 osteoclasts (Oc.N/FOV: 15.5+-1.6 treated vs. 53+-1.5 non-treated). AZD0530 treatment appeared to hamper efficient progenitor cell fusion and osteoclast polarization, reflected by a decrease of CTSK and DC-STAMP mRNA levels and a defective actin ring formation in treated cultures, which culminated in a complete inhibition of bone resorption. When assessing the effect of AZD0530 on osteoblast function we found that AZD0530 inhibits osteoblast differentiation, with a decreased expression of OSX and OCN, and alters osteoblast morphology. In vivo, AZD0530 did not alter myeloma cell bone marrow infiltration in both the 5TGM.1 (37+-6.3% AZD0530 treated vs. 25.2+-6.7% non-treated) and 5T2MM (26.1+-7.7% vs. 29.1+-6.4%) murine multiple myeloma models. However, bone health was significantly improved in both models following treatment with AZD0530. In the 5TGM.1 model multiple trabecular bone parameters were restored to levels observed in healthy control mice following AZD0530 treatment, including BV/TV (11.7+-0.3% treated vs. 6.4+-0.3% non-treated), Tb.N. (2.5+-6x10^-2/mm vs. 1.7+-9x10^-2/mm) and Tb.Th (46.2+-1micron vs. 37+-0.8micron). These results were confirmed in the 5T2MM model, which displays a more severe osteolytic bone disease. In addition, AZD0530 treatment resulted in an increase in cortical thickness (157.8+-0.8micron treated vs. 151.4+-0.7micron non-treated) and a decrease in the number and size of cortical lesions in 5TGM.1 mice. Finally, our findings were corroborated by histomorphometric analyses. In conclusion, we report a potent inhibitory effect of the Src inhibitor AZD0530 on the development of osteolytic bone disease in multiple myeloma. Our results indicate that AZD0530 exerts this effect via the modulation of both osteoclast and osteoblast function. These findings warrant further study of the feasibility and efficacy of AZD0530 to treat osteolytic bone disease in multiple myeloma patients. Disclosures No relevant conflicts of interest to declare.

Description: Background: In spite of significant progress in the outcome of multiple myeloma (MM), effective treatment options are still missing for high-risk patients. A better understanding of key mechanisms in high-risk disease is therefore a necessary prerequisite for the development of novel therapeutic options for patients with poor prognosis. Here, we evaluated maternal embryonic leucine zipper kinase (MELK) for its implications in the prognosis of MM, its interactions with genes involved in high-risk MM and the impact of MELK inhibition in vitro and in vivo. Methods: Expression levels of genes associated with high-risk MM were analyzed in two large cohorts of publically available gene expression (GEP) datasets (GSE2658 and GSE9782; n=551 and n=264, respectively) and by quantitative PCR (qPCR) in human myeloma cell lines (HMCLs). The impact of MELK inhibition was studied using a selective inhibitor of MELK (OTSSP167). MELK and OTSSP167 target genes were analyzed by qPCR and Western Blot. MELK knockdown HMCLs were generated via lentiviral transduction of MELK specific shRNA. For the in vivo experiment, C57BL/KaLwRij mice were injected intravenously with 5x105 GFP-transfected 5TGM.1 cells. Starting the day after injection, two groups of mice were treated by different doses of OTSSP167 (15mg/kg/d or 7.5mg/kg/2d) and one group received the vehicle. Treatment was administered orally. Results: MELK expression was significantly elevated in the GEP-defined high-risk proliferation (PR) associated molecular subgroup compared to healthy donor bone marrow plasma cells, but barely detected in any other GEP defined MM subgroup. Consequently, overall survival was significantly shorter in patients with high compared to low MELK levels treated within the total therapy 2 (P=0.0003), total therapy 3 (P=0.04) and the APEX trial protocol (P=0.002). Of note, MELK expression was further elevated in relapsed patients compared to baseline (GSE31161) suggesting a potential role in drug resistance. In line with their proliferative character, MELK expression was detected in 8 of 8 HMCLs. Treatment with the MELK inhibitor OTSSP167 downregulated MELK protein levels and led to a dose-dependent reduction of viability in all primary MM samples and HMCLs tested (median IC50: 10.16 nM, range: 7.6 - 15.2 nM). We observed induction of apoptosis in all HMCLs investigated, verified by mitochondrial membrane depolarization, annexin V/7-AAD staining, detection of cleaved caspase 3, and cleaved PARP. This was accompanied by downregulation of gene expression levels of IRF4 and MCL-1. In addition, OTSSP167 induced a G2/M cell cycle arrest which was linked to downregulation of cyclin B1, aurora kinase A and PLK-1. Importantly, we also observed reduced clonogenic growth of MM cells treated with OTSSP167 and the anti-myeloma activity of OTSSP167 was upheld in the presence of bone marrow stromal cells. We next sought to clarify the impact of MELK on other genes implicated in high-risk myeloma. Strikingly, treatment of HMCLs with OTSSP167 reduced MELK and PLK-1 protein levels, but also those of FOXM1, EZH2 and DEPDC1. This relationship was confirmed in HMCLs with shRNA mediated MELK knockdown. All of these genes were significantly elevated in the GEP defined PR subgroup and associated with poor outcome. Finally, the activity of OTSSP167 was analyzed in the 5TGM.1 model of MM. In vivo, we observed a dose-dependent reduction of tumor parameters by OTSSP167. Low doses of OTSSP167 significantly reduced spleen weight and serum IgG2b levels but only tended to decrease BM infiltration, while high doses of OTSSP167 significantly decreased tumor infiltration analyzed by spleen weight (267mg vs 108mg) and bone marrow infiltration (14% vs 2%, P