Hijacking a key chromatin modulator creates epigenetic vulnerability for MYC-driven cancer
Zhenhua Yang, Kushani Shah, Theodore Busby, Keith Giles, Alireza Khodadadi-Jamayran, Wei Li, Hao Jiang
Zhenhua Yang, Kushani Shah, Theodore Busby, Keith Giles, Alireza Khodadadi-Jamayran, Wei Li, Hao Jiang
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Research Article Hematology Oncology

Hijacking a key chromatin modulator creates epigenetic vulnerability for MYC-driven cancer

Abstract

While the genomic binding of MYC protein correlates with active epigenetic marks on chromatin, it remains largely unclear how major epigenetic mechanisms functionally impact the tumorigenic potential of MYC. Here, we show that, compared with the catalytic subunits, the core subunits, including DPY30, of the major H3K4 methyltransferase complexes were frequently amplified in human cancers and selectively upregulated in Burkitt lymphoma. We show that DPY30 promoted the expression of endogenous MYC and was also functionally important for efficient binding of MYC to its genomic targets by regulating chromatin accessibility. Dpy30 heterozygosity did not affect normal animal physiology including lifespan, but significantly suppressed Myc-driven lymphomagenesis, as cells failed to combat oncogene-triggered apoptosis as a result of insufficient epigenetic modulation and expression of a subset of antiapoptotic genes. Dpy30 reduction also greatly impeded MYC-dependent cellular transformation, without affecting normal cell growth. These results suggest that MYC hijacks a major epigenetic pathway — H3K4 methylation — to facilitate its molecular activity in target binding and to coordinate its oncogenic program for efficient tumorigenesis, meanwhile creating “epigenetic vulnerability.” DPY30 and the H3K4 methylation pathway are thus potential epigenetic targets for treating certain MYC-driven cancers.

Authors

Zhenhua Yang, Kushani Shah, Theodore Busby, Keith Giles, Alireza Khodadadi-Jamayran, Wei Li, Hao Jiang

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Figure 8

Dpy30 is haploinsufficient for oncogenic transformation but not for cell growth.

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Dpy30 is haploinsufficient for oncogenic transformation but not for cel...
(A) WT and Dpy30+/– MEFs were assayed for growth, shown as the MTT assay results from 3 biological replicates. (B and C) Representative results of soft agar colony formation assay for HRASG12V and MYC-mediated oncogenic transformation of WT and Dpy30+/– MEFs. (B) Relative mRNA levels of DPY30, RAS, and MYC in untransduced MEFs and MEFs transduced with HRASG12V and MYC viruses were determined by qPCR and normalized to Actb from the 3 independent transformation assays shown in C and D. The levels in WT MEFs infected with HRASG12V and MYC were set to 1. (C) The percentage of colony numbers relative to WT (mean number was 59 for WT) was determined from 3 independent transformation assays using 2 different embryo-derived MEF samples for each genotype. (D) WT and Dpy30+/– MEFs transduced with HRASG12V and MYC viruses were injected into the flanks of 7 NSG mice. Each mouse received WT MEFs in 1 flank and the Dpy30+/– MEFs in the other flank. Two weeks after injection, tumors were collected (shown) and weighed. The tumor weights were plotted, and each dot represents a tumor from an animal. (E) Model illustrating the 2 different levels of regulation of MYC by DPY30 complexes. Data represent the mean ± SD (A) or + SD (B and C). **P < 0.01 and ****P < 0.0001, by 1-factor ANOVA with a post hoc t test (B) and Student’s t test (C and D).