B cell transcriptional coactivator POU2AF1 (BOB-1) modulates the protein synthesis and offers a potential vulnerability in multiple myeloma.

Background Multiple Myeloma (MM) is a disease driven by numerous genetic and epigenetic alterations, however true drivers of the disease have yet to be identified. Methods To identify new dependencies and actionable therapeutic targets in MM we integrated gene expression and genetic dependency (CRISPR KO). Results We found that many of the specific and potent dependencies in MM are transcription factors, especially those establishing plasma cell identity. Among others, the POU2AF1 gene, which encodes the OCA-B/BOB-1, a B cell transcriptional coactivator protein, represented the most striking dependency in MM. Although BOB-1 is expressed throughout B-cell development, we found it to be highly expressed in CD138+ plasma cells from patients with precursor conditions (MGUS and SMM) as well and established MM compared to normal plasma cells (NPC). Loss-of-function studies using shRNA, siRNAs as well as antisense GapMers specific for BOB-1 confirmed significant impact on MM cell viability. Transcriptomic analysis by RNA-sequencing revealed a small set of genes commonly modulated in MM cell lines upon BOB-1 depletion, including the XBP1- BHLHA15 axis involved in lipid synthesis and unfolded protein response (UPR). Interestingly, among the genes most significantly upregulated by BOB-1 depletion was heme oxygenase 1 (HMOX1), that was affected via the NRF2/Keap1 pathway. We observed that HMOX1 expression is significantly lower in MM cells from patients compared to normal plasma cells and correlates with poor clinical outcome, suggesting important role in MM. Moreover, we found that siRNA depletion of HMOX1 reverted the inhibition of MM cell growth caused by BOB-1 KD, confirming significant role for HMOX1 in the BOB-1 addiction observed in MM cells. Next, we performed gene set enrichment analysis (GSEA) and observed ribosome biogenesis pathways and mRNA translation and elongation processes, along with WNT and senescence pathways, to be significantly enriched among genes modulated by BOB-1 depletion in MM cells. Since high protein load is a feature of MM, we evaluated the role of BOB-1 in the translational efficiency of MM cells. In MM cell lines, BOB-1 knockdown decreased de novo protein synthesis, while its overexpression significantly enhances protein synthesis compared to control cells. As MM is characterized by excess production of monoclonal immunoglobulins, we evaluated impact of BOB-1 perturbation on intracellular kappa and lambda light chains production. We observed changes in the intracellular abundance of the light chains with BOB-1 modulation in all MM cell lines tested. As a result, BOB-1 depletion was associated with induction of resistance to proteasome inhibition. Conclusion In conclusion, we report BOB1 as a specific dependency in MM cells with potential role on modulating the protein load/capacity balance in MM cells and therefore the sensitivity to proteasome inhibition.