Single-cell multiomics reveal the scale of multilayered adaptations enabling CLL relapse during venetoclax therapy

•Multiple independent but recurring genetic and epigenetic changes drive venetoclax resistance, with marked NF-κB activation ubiquitous.•NF-κB activation is apparent within the first year of therapy, and most changes in CLL cells are sustained by ongoing venetoclax therapy. [Display omitted] Venetoc...

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Published inBlood Vol. 140; no. 20; pp. 2127 - 2141
Main Authors Thijssen, Rachel, Tian, Luyi, Anderson, Mary Ann, Flensburg, Christoffer, Jarratt, Andrew, Garnham, Alexandra L., Jabbari, Jafar S., Peng, Hongke, Lew, Thomas E., Teh, Charis E., Gouil, Quentin, Georgiou, Angela, Tan, Tania, Djajawi, Tirta M., Tam, Constantine S., Seymour, John F., Blombery, Piers, Gray, Daniel H.D., Majewski, Ian J., Ritchie, Matthew E., Roberts, Andrew W., Huang, David C.S.
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 17.11.2022
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Summary:•Multiple independent but recurring genetic and epigenetic changes drive venetoclax resistance, with marked NF-κB activation ubiquitous.•NF-κB activation is apparent within the first year of therapy, and most changes in CLL cells are sustained by ongoing venetoclax therapy. [Display omitted] Venetoclax (VEN) inhibits the prosurvival protein BCL2 to induce apoptosis and is a standard therapy for chronic lymphocytic leukemia (CLL), delivering high complete remission rates and prolonged progression-free survival in relapsed CLL but with eventual loss of efficacy. A spectrum of subclonal genetic changes associated with VEN resistance has now been described. To fully understand clinical resistance to VEN, we combined single-cell short- and long-read RNA-sequencing to reveal the previously unappreciated scale of genetic and epigenetic changes underpinning acquired VEN resistance. These appear to be multilayered. One layer comprises changes in the BCL2 family of apoptosis regulators, especially the prosurvival family members. This includes previously described mutations in BCL2 and amplification of the MCL1 gene but is heterogeneous across and within individual patient leukemias. Changes in the proapoptotic genes are notably uncommon, except for single cases with subclonal losses of BAX or NOXA. Much more prominent was universal MCL1 gene upregulation. This was driven by an overlying layer of emergent NF-κB (nuclear factor kappa B) activation, which persisted in circulating cells during VEN therapy. We discovered that MCL1 could be a direct transcriptional target of NF-κB. Both the switch to alternative prosurvival factors and NF-κB activation largely dissipate following VEN discontinuation. Our studies reveal the extent of plasticity of CLL cells in their ability to evade VEN-induced apoptosis. Importantly, these findings pinpoint new approaches to circumvent VEN resistance and provide a specific biological justification for the strategy of VEN discontinuation once a maximal response is achieved rather than maintaining long-term selective pressure with the drug. Two complementary articles shed new light on resistance to venetoclax in lymphoid malignancies. Thijssen et al use single-cell studies to reveal the multilayered nature of the mechanisms underpinning the recurrence of chronic lymphocytic leukemia in patients on long-term venetoclax, identifying a range of recurring genetic and epigenetic changes in apoptotic regulators. Overlying this heterogeneity, heightened expression of MCL1 driven by NF-κB is ubiquitous but reversible upon drug discontinuation. Thomalla and colleagues use B-lineage cell lines and patient samples to elegantly demonstrate how methylation and silencing of PUMA, a pro-apoptotic, causes failure of venetoclax. Both articles provide clinically applicable suggestions for circumventing emergent resistance to venetoclax.
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ISSN:0006-4971
1528-0020
DOI:10.1182/blood.2022016040