Introduction

Multiple Myeloma (MM) is the second most common hematological malignancy in the United States and accounts for ∼10,600 deaths annually. MM remains an incurable disease and almost all patients will eventually relapse and become refractory to currently available therapeutic agents. There is an unmet need for better understanding of the disease’s molecular pathways and identifying novel therapeutic targets. Sphingolipid metabolism is being increasingly recognized as a key pathway in cancer biology. In particular, sphingosine kinases (SK1 and SK2) provide a potential site for manipulation of the ceramide / sphingosine 1-phosphate (S1P) rheostat that regulates the balance between tumor cell proliferation and apoptosis, as well as tumor sensitivity to drugs. Currently, very little is known about sphingolipid metabolism in MM. We herein for the first time provide a detailed analysis of sphingolipid metabolism in MM and demonstrate the potential of targeting SK2 for the treatment of MM.

Methods

We first quantified sphingolipid metabolites and sphingolipid metabolizing genes in myeloma cell lines, in freshly isolated human primary CD138+ myeloma cells, and in a publically available gene expression dataset from MM patients. We then tested the anti-myeloma activity of SK2-specific shRNA and determined the efficacy of a selective SK2 inhibitor (ABC294640) in killing myeloma cell lines and primary human myeloma cells in vitro. The mechanistic pathway of apoptosis was analyzed by immunoblotting and flowcytometry. MM cell lines stably expressing luciferase and eGFP were generated for xenograft experiments and for in vitro co-cultures with stromal cells.

Results

From the publically available GSE6477 microarray data set, we found that one third of the genes involved in sphingolipid metabolism were significantly different in CD138+ MM cells from newly diagnosed MM patients compared to normal individuals, including SK2 and S1P receptors. In 5 MM cell lines compared to immortalized B cells (IBC), 19 key sphingolipid metabolites were measured, and we found that ceramides were significantly reduced whereas S1P was significantly increased. mRNA analyses of 11 sphingolipid metabolizing genes including S1P receptors in 7 MMs showed that SK1, SK2, and alkaline ceramidases were significantly increased compared to IBC. Furthermore, we isolated CD138+ myeloma cells from 21 MM patients and found that 13 of the patients had higher SK2 expression in CD138+ MM cells compared to CD138-cells. These data demonstrated abnormal sphingolipid metabolism and dys-regulated SK2 in myeloma cells.

We generated SK2-specific shRNA and found that SK2 shRNA down-regulated SK2 mRNA, inhibited proliferation, and induced death in myeloma cells, suggesting that SK2 is important in myeloma cell survival. We then tested the efficacy of ABC294640 (the most-advanced, non-lipid SK2 inhibitor) in 6 MM cell lines. ABC294640 inhibited myeloma cell growth with an IC50s of ∼30 μM, including steroid-resistant and doxorubicin-resistant myeloma cells. ABC294640 inhibited MM cell growth as early as 6 hours after exposure and induced apoptotic cell death as demonstrated by Annexin V staining, PARP cleavage and caspase 9 activation. ABC294640 inhibited primary human CD138+MM cells with the same efficacy as with MM cell lines, demonstrating the potential of ABC294640 for the treatment of MM. Additionally, we found that blocking S1P receptors with FTY720 (a S1PR agonist with receptor degradation) induced apoptosis in MM cells.

We performed extensive mechanistic and signaling pathway analyses and found that ABC294640 inhibited Mcl-1 and C-Myc expression, but had no effects on Bcl2. Furthermore, ABC294640 induced cell death by directing Mcl-1 to proteosomal degradation.

MM is dependent on the bone marrow niche microenvironment for survival and progression. We found that ABC294640 was effective in inducing apoptosis in MM cells even in the presence of stromal cells. Finally, we are currently testing the in vivo effect of ABC294640 alone and in combination with bortezomib, thalidomide and dexamethasone in MM xenograft model transplanted with MM cells stably expressing luciferase. Our early preliminary results were encouraging.

Conclusion

Our data demonstrate that sphingolipid metabolism is abnormal and provides an attractive target in the treatment of refractory/relapsed MM.

Disclosures:

Costa:Otsuka: Research Funding.

Author notes

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Asterisk with author names denotes non-ASH members.

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