Primary and acquired drug resistance is a major challenge to achieving optimized clinical outcomes during cancer treatment which can arise from transcription reactivation, bypass and alteration during anticancer treatment [1-3]. Epigenetic dysregulation is emerging as a crucial component involved in drug resistance. Transcriptional adaptation during drug treatment is often mediated by inducible histone modifications, especially histone H3 lysine 27 acetylation (H3K27ac) at the distal enhancer elements, thus activating the transcription of drug resistance-associated genes [4-6]. BRD4 (bromodomain-containing protein 4), a member of the bromodomain and extra-terminal domain (BET) family, acts as a chromatin reader to regulate transcription by linking histone acetylation and core components of the transcriptional apparatus [7]. BET inhibitors (BETi), as exemplified by JQ1 and I-BET151, have been shown to suppress the growth of multiple types of tumor both in vitro and in vivo [8]. However, drug resistance associated with BETi becomes one of the major hurdles hampering the clinical applications of these promising drug candidates [8, 9]. Using BET inhibitor (BETi) resistant leukemia cells as a model system, we demonstrated herein that genome-wide enhancer remodeling played a pivotal role in driving therapeutic resistance via compensational re-expression of pro-survival genes. Capitalizing on CRISPR interference, we identified the second intron of IncRNA, PVT1, as a unique bona fidegained enhancer that restored MYCtranscription independent of BRD4 recruitment. A combined BETi and CDK7 inhibitor treatment abolished MYC transcription by impeding RNAPII loading without affecting PVT1-mediated chromatin looping at the MYClocus in BETi-resistant leukemia cells. Furthermore, recipient mice transferred with BETi-resistant murine MLL-AF9 AML cells receiving the combination treatment showed the most effective therapeutic outcomes, as characterized by prolonged overall survival and reduced tumor burdens in the spleen and bone marrow. Together, our findings have established the feasibility of targeting enhancer plasticity to overcome drug resistance associated with epigenetic therapies.

References

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Disclosures

No relevant conflicts of interest to declare.

Author notes

*

Asterisk with author names denotes non-ASH members.

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