Abstract
Multiple myeloma (MM) is the second most common hematological malignancy characterized by an abnormal clonal proliferation of malignant plasma cells. Despite the introduction of novels agents that have significantly improved clinical outcomes, MM patients invariably relapse. A better understanding of the drug resistance mechanisms and development of biomarkers remain of major interest to improve the treatment of patients.
In order to further investigate the mechanisms involved in resistance to proteasome inhibitors (PI), we have derived and characterized PI-resistant human myeloma cells lines (HMCLs) from different molecular subgroups including XG2BR t(12;14), XG7BR t(4;14), XG19BR t(14;16), and XG1BR t(11;14). These cell lines were cultured continuously with escalating concentrations of Bortezomib (Btz) during 12 months and showed a significant resistance to Bortezomib compared to their parental cell lines (mean IC50: Btz-resistant HMCLs =5.5nM vs parental HMCLs=2.5nM, p<0.05). Of interest, we demonstrated that Btz-resistant HMCLs are also significantly more resistant to Carfilzomib (Cfz) and Ixazomib (Ixa) PIs (mean IC50: Btz-resistant HMCLs =6nM for Cfz and =70nM for Ixa vs parental HMCLs=3nM, for Cfz, p<0.05 ; and =21nM for Ixa, p<0.05. No significant cross-resistance was observed with other therapeutic agents including melphalan, dexamethasone and IMIDs indicating that the observed drug resistance mechanisms are specifically related to PIs.
In order to understand the PIs resistance mechanisms acquired by MM cells, we used a combination of genomic approaches including whole genome sequencing, and comparative transcriptomic analysis.
Among the 40 mutations identified in Btz-resistant HMCLs compared to the parental ones, a mutation residing in the Btz-binding pocket in the proteasome beta5-subunit (PSMB5) gene was identified. This mutation has already been found in other models of PIs-resistant MM cell lines and in relapsed MM patients, and is associated to PIs- resistance by reducing the PI binding capacity and impairing the chemotrypsin-like catalytic activity of the 20S proteasome.
When we compared the gene expression profiling of Btz-resistant HMCLs with the parental ones, we identified a gene expression signature significantly enriched in nucleotide excision repair (NER) pathway with an increased expression of ERCC1, ERCC5, LIG1, POLD1 in the Btz-resistant HMCLs (FC >1.5). Since, protein ubiquitination is essential in regulation and coordination of various pathways of DNA damage recognition, signaling and repair, proteasome inhibitors affect DNA repair, overexpression of DNA repair pathways may participate in drug resistance mechanisms.
Using gene expression profiling data, we also identified a significant downregulation of 8 solute carrier protein (SLC) intake transporters (SLC6A6, SLC16A1, SLC16A14, SLC16A10, SLC25A13, SLC5A6, SLCO3A1, SLCO4A1) together with a significant upregulation of xenobiotic receptors (RXRA, RXRB) in Btz-resistant HMCLs compared to parental HMCLs (FC> or < 1.5; p value <0.05). In addition, several genes involved in antioxidant response (NQO1), and in glutathione regulation (MGST1, MGST2, GSTO1) were also overexpressed in Btz-resistant HMCLs (FC>1.5 p value <0.05).
Investigating the deregulated genes involved on energy metabolism that is often associated with resistance, we identified an upregulation of glycolytic enzymes directly involved in glycolytic metabolism (ALDOC, ENO3, HK1, PDK1, PDK3, PFKB3, PFKB4, PFKL, SLC2A1 (FC>1.5 p value <0.05) in the Btz-resistant HMCLs.
Altogether our data underline a significant deregulation of genes involved in cell metabolism and drug clearance system that allow the PI resistant-MM cells to maintain metabolic homeostasis and survival in stringent redox conditions. This is in accordance with described mechanisms linking drug resistance and glycolytic metabolism in cancers cells. Metabolomic analyzes are currently ongoing for functional validation.
Altogether, drug-resistant cell lines represent an attractive preclinical model to test molecules targeting these pathways in order to identify new therapeutic strategies to overcome PI resistance in MM.
De Boussac: Diag2Tec: Current Employment. Kassambara: Diag2Tec: Consultancy. Machura: Diag2Tec: Current Employment. Chemlal: Diag2Tec: Current Employment. Vincent: Takeda: Membership on an entity's Board of Directors or advisory committees; Celgene: Membership on an entity's Board of Directors or advisory committees; Janssen: Membership on an entity's Board of Directors or advisory committees. Herbaux: Abbvie: Honoraria, Research Funding; Roche: Honoraria; Janssen: Honoraria; Takeda: Honoraria, Research Funding. Bruyer: Diag2Tec: Current Employment. Moreaux: Diag2Tec: Consultancy.