Sequential transcriptional waves and NF-κB-driven chromatin remodeling direct drug-induced dedifferentiation in cancer

Yapeng Su; Chunmei Liu; Xiang Lu; Hui Yu Chuang; Guideng Li; Shiqun Shao; Yan Kong; Jihoon W. Lee; Rachel H. Ng; Stephanie Wong; Lidia Robert; Charles Warden; Victoria Liu; Jie Chen; Zhuo Wang; Guangrong Qin; Yin Tang; Hanjun Cheng; Alphonsus H.C. Ng; Daniel Chen; Songming Peng; Min Xue; Dazy Johnson; Yu Xu; Jinhui Wang; Xiwei Wu; Ilya Shmulevich; Qihui Shi; Raphael Levine; Antoni Ribas; David Baltimore; Jun Guo; James R. Heath; Wei Wei

doi:10.1038/s41467-026-71349-4

Sequential transcriptional waves and NF-κB-driven chromatin remodeling direct drug-induced dedifferentiation in cancer

Yapeng Su
, Chunmei Liu
, Xiang Lu
, Hui Yu Chuang
, Guideng Li
, Shiqun Shao
, Yan Kong
, Jihoon W. Lee
, Rachel H. Ng
, Stephanie Wong
, Lidia Robert
, Charles Warden
, Victoria Liu
, Jie Chen
, Zhuo Wang
, Guangrong Qin
, Yin Tang
, Hanjun Cheng
, Alphonsus H.C. Ng
, Daniel Chen

Songming Peng, Min Xue, Dazy Johnson, Yu Xu, Jinhui Wang, Xiwei Wu, Ilya Shmulevich, Qihui Shi, Raphael Levine, Antoni Ribas, David Baltimore, Jun Guo, James R. Heath^*, Wei Wei^*

^*Corresponding author for this work

Institute of Chemistry

Research output: Contribution to journal › Article › peer-review

Abstract

Drug-induced dedifferentiation towards drug-tolerant persister states is a common mechanism cancer cells exploit to escape therapies, hindering durable responses. How early epigenomic and transcriptomic programs coordinate to initiate these reversible transitions remains largely unexplored. Here we employ high-temporal-resolution multi-omics profiling, information-theoretic approaches, and dynamic system modeling to probe these processes in BRAF-mutant melanoma models and patient specimens. We uncover a hysteretic transition trajectory in response to oncogene inhibition and subsequent release, driven by two tightly coupled transcriptional waves that orchestrate genome-scale chromatin reconfiguration. Modeling of these waves suggests NF-κB/RelA-driven chromatin remodeling as the underlying mechanism of cell-state dedifferentiation, which we validate experimentally. We identify RelA-target genes epigenetically modulated to drive this process and define a quantitative epigenome gauge of melanoma cell-state plasticity that supports targeting epigenetic machineries to potentiate oncogene inhibition. Across additional cancer models, oxidative stress-mediated NF-κB/RelA activation emerges as a common driver of transitions into drug-tolerant persister states, revealing a central role for NF-κB axis in coupling oxidative stress to cancer progression.

Original language	English
Article number	3228
Journal	Nature Communications
Volume	17
Issue number	1
DOIs	https://doi.org/10.1038/s41467-026-71349-4
State	Published - Dec 2026

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Publisher Copyright:
© The Author(s) 2026.

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Su, Y., Liu, C., Lu, X., Chuang, H. Y., Li, G., Shao, S., Kong, Y., Lee, J. W., Ng, R. H., Wong, S., Robert, L., Warden, C., Liu, V., Chen, J., Wang, Z., Qin, G., Tang, Y., Cheng, H., Ng, A. H. C., ... Wei, W. (2026). Sequential transcriptional waves and NF-κB-driven chromatin remodeling direct drug-induced dedifferentiation in cancer. Nature Communications, 17(1), Article 3228. https://doi.org/10.1038/s41467-026-71349-4

@article{9b12731ddb9b4ae8acedc4a4d281294d,

title = "Sequential transcriptional waves and NF-κB-driven chromatin remodeling direct drug-induced dedifferentiation in cancer",

abstract = "Drug-induced dedifferentiation towards drug-tolerant persister states is a common mechanism cancer cells exploit to escape therapies, hindering durable responses. How early epigenomic and transcriptomic programs coordinate to initiate these reversible transitions remains largely unexplored. Here we employ high-temporal-resolution multi-omics profiling, information-theoretic approaches, and dynamic system modeling to probe these processes in BRAF-mutant melanoma models and patient specimens. We uncover a hysteretic transition trajectory in response to oncogene inhibition and subsequent release, driven by two tightly coupled transcriptional waves that orchestrate genome-scale chromatin reconfiguration. Modeling of these waves suggests NF-κB/RelA-driven chromatin remodeling as the underlying mechanism of cell-state dedifferentiation, which we validate experimentally. We identify RelA-target genes epigenetically modulated to drive this process and define a quantitative epigenome gauge of melanoma cell-state plasticity that supports targeting epigenetic machineries to potentiate oncogene inhibition. Across additional cancer models, oxidative stress-mediated NF-κB/RelA activation emerges as a common driver of transitions into drug-tolerant persister states, revealing a central role for NF-κB axis in coupling oxidative stress to cancer progression.",

author = "Yapeng Su and Chunmei Liu and Xiang Lu and Chuang, \{Hui Yu\} and Guideng Li and Shiqun Shao and Yan Kong and Lee, \{Jihoon W.\} and Ng, \{Rachel H.\} and Stephanie Wong and Lidia Robert and Charles Warden and Victoria Liu and Jie Chen and Zhuo Wang and Guangrong Qin and Yin Tang and Hanjun Cheng and Ng, \{Alphonsus H.C.\} and Daniel Chen and Songming Peng and Min Xue and Dazy Johnson and Yu Xu and Jinhui Wang and Xiwei Wu and Ilya Shmulevich and Qihui Shi and Raphael Levine and Antoni Ribas and David Baltimore and Jun Guo and Heath, \{James R.\} and Wei Wei",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = dec,

doi = "10.1038/s41467-026-71349-4",

language = "אנגלית",

volume = "17",

journal = "Nature Communications",

issn = "2041-1723",

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Su, Y, Liu, C, Lu, X, Chuang, HY, Li, G, Shao, S, Kong, Y, Lee, JW, Ng, RH, Wong, S, Robert, L, Warden, C, Liu, V, Chen, J, Wang, Z, Qin, G, Tang, Y, Cheng, H, Ng, AHC, Chen, D, Peng, S, Xue, M, Johnson, D, Xu, Y, Wang, J, Wu, X, Shmulevich, I, Shi, Q, Levine, R, Ribas, A, Baltimore, D, Guo, J, Heath, JR & Wei, W 2026, 'Sequential transcriptional waves and NF-κB-driven chromatin remodeling direct drug-induced dedifferentiation in cancer', Nature Communications, vol. 17, no. 1, 3228. https://doi.org/10.1038/s41467-026-71349-4

TY - JOUR

T1 - Sequential transcriptional waves and NF-κB-driven chromatin remodeling direct drug-induced dedifferentiation in cancer

AU - Su, Yapeng

AU - Liu, Chunmei

AU - Lu, Xiang

AU - Chuang, Hui Yu

AU - Li, Guideng

AU - Shao, Shiqun

AU - Kong, Yan

AU - Lee, Jihoon W.

AU - Ng, Rachel H.

AU - Wong, Stephanie

AU - Robert, Lidia

AU - Warden, Charles

AU - Liu, Victoria

AU - Chen, Jie

AU - Wang, Zhuo

AU - Qin, Guangrong

AU - Tang, Yin

AU - Cheng, Hanjun

AU - Ng, Alphonsus H.C.

AU - Chen, Daniel

AU - Peng, Songming

AU - Xue, Min

AU - Johnson, Dazy

AU - Xu, Yu

AU - Wang, Jinhui

AU - Wu, Xiwei

AU - Shmulevich, Ilya

AU - Shi, Qihui

AU - Levine, Raphael

AU - Ribas, Antoni

AU - Baltimore, David

AU - Guo, Jun

AU - Heath, James R.

AU - Wei, Wei

PY - 2026/12

Y1 - 2026/12

N2 - Drug-induced dedifferentiation towards drug-tolerant persister states is a common mechanism cancer cells exploit to escape therapies, hindering durable responses. How early epigenomic and transcriptomic programs coordinate to initiate these reversible transitions remains largely unexplored. Here we employ high-temporal-resolution multi-omics profiling, information-theoretic approaches, and dynamic system modeling to probe these processes in BRAF-mutant melanoma models and patient specimens. We uncover a hysteretic transition trajectory in response to oncogene inhibition and subsequent release, driven by two tightly coupled transcriptional waves that orchestrate genome-scale chromatin reconfiguration. Modeling of these waves suggests NF-κB/RelA-driven chromatin remodeling as the underlying mechanism of cell-state dedifferentiation, which we validate experimentally. We identify RelA-target genes epigenetically modulated to drive this process and define a quantitative epigenome gauge of melanoma cell-state plasticity that supports targeting epigenetic machineries to potentiate oncogene inhibition. Across additional cancer models, oxidative stress-mediated NF-κB/RelA activation emerges as a common driver of transitions into drug-tolerant persister states, revealing a central role for NF-κB axis in coupling oxidative stress to cancer progression.

AB - Drug-induced dedifferentiation towards drug-tolerant persister states is a common mechanism cancer cells exploit to escape therapies, hindering durable responses. How early epigenomic and transcriptomic programs coordinate to initiate these reversible transitions remains largely unexplored. Here we employ high-temporal-resolution multi-omics profiling, information-theoretic approaches, and dynamic system modeling to probe these processes in BRAF-mutant melanoma models and patient specimens. We uncover a hysteretic transition trajectory in response to oncogene inhibition and subsequent release, driven by two tightly coupled transcriptional waves that orchestrate genome-scale chromatin reconfiguration. Modeling of these waves suggests NF-κB/RelA-driven chromatin remodeling as the underlying mechanism of cell-state dedifferentiation, which we validate experimentally. We identify RelA-target genes epigenetically modulated to drive this process and define a quantitative epigenome gauge of melanoma cell-state plasticity that supports targeting epigenetic machineries to potentiate oncogene inhibition. Across additional cancer models, oxidative stress-mediated NF-κB/RelA activation emerges as a common driver of transitions into drug-tolerant persister states, revealing a central role for NF-κB axis in coupling oxidative stress to cancer progression.

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AN - SCOPUS:105035819276

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JO - Nature Communications

JF - Nature Communications

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M1 - 3228

ER -

Sequential transcriptional waves and NF-κB-driven chromatin remodeling direct drug-induced dedifferentiation in cancer

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