Integrative multi-omics identifies high risk multiple myeloma subgroup associated with significant DNA loss and dysregulated DNA repair and cell cycle pathways

María Ortiz-Estévez; Fadi Towfic; Erin Flynt; Nicholas Stong; In Sock Jang; Kai Wang; Matthew W B Trotter; Anjan Thakurta

doi:10.1186/s12920-021-01140-5

Integrative multi-omics identifies high risk multiple myeloma subgroup associated with significant DNA loss and dysregulated DNA repair and cell cycle pathways

BMC Med Genomics. 2021 Dec 18;14(1):295. doi: 10.1186/s12920-021-01140-5.

Authors

María Ortiz-Estévez^#¹, Fadi Towfic^#², Erin Flynt³, Nicholas Stong³, In Sock Jang², Kai Wang², Matthew W B Trotter¹, Anjan Thakurta⁴

Affiliations

¹ BMS Center for Innovation and Translational Research Europe (CITRE), A Bristol Myers Squibb Company, Sevilla, Spain.
² Bristol Myers Squibb, San Diego, CA, USA.
³ Bristol Myers Squibb, 181 Passaic Ave, Summit, NJ, 07901, USA.
⁴ Bristol Myers Squibb, 181 Passaic Ave, Summit, NJ, 07901, USA. anjan.thakurta@bms.com.

^# Contributed equally.

Abstract

Background: Despite significant therapeutic advances in improving lives of multiple myeloma (MM) patients, it remains mostly incurable, with patients ultimately becoming refractory to therapies. MM is a genetically heterogeneous disease and therapeutic resistance is driven by a complex interplay of disease pathobiology and mechanisms of drug resistance. We applied a multi-omics strategy using tumor-derived gene expression, single nucleotide variant, copy number variant, and structural variant profiles to investigate molecular subgroups in 514 newly diagnosed MM (NDMM) samples and identified 12 molecularly defined MM subgroups (MDMS1-12) with distinct genomic and transcriptomic features.

Results: Our integrative approach let us identify NDMM subgroups with transversal profiles to previously described ones, based on single data types, which shows the impact of this approach for disease stratification. One key novel subgroup is our MDMS8, associated with poor clinical outcome [median overall survival, 38 months (global log-rank p-value < 1 × 10^-6)], which uniquely presents a broad genomic loss (> 9% of entire genome, t-test p value < 1e-5) driving dysregulation of various transcriptional programs affecting DNA repair and cell cycle/mitotic processes. This subgroup was validated on multiple independent datasets, and a master regulator analyses identified transcription factors controlling MDMS8 transcriptomic profile, including CKS1B and PRKDC among others, which are regulators of the DNA repair and cell cycle pathways.

Conclusion: Using multi-omics unsupervised clustering we were able to discover a new high-risk multiple myeloma patient segment. This high-risk group presents diverse previously known genetic markers, but also a new characteristic defined by accumulation of genomic loss which seems to drive transcriptional dysregulation of cell cycle, DNA repair and DNA damage. Finally, our work identified various master regulators, including E2F2 and CKS1B as the genes controlling these key biological pathways.

MeSH terms

Cell Cycle / genetics
DNA Damage / genetics
DNA Repair / genetics
Genomics / methods
Humans
Multiple Myeloma* / epidemiology
Multiple Myeloma* / genetics
Risk