Literature DB >> 33417832

An Embryonic Diapause-like Adaptation with Suppressed Myc Activity Enables Tumor Treatment Persistence.

Eugen Dhimolea1, Ricardo de Matos Simoes2, Dhvanir Kansara3, Aziz Al'Khafaji4, Juliette Bouyssou5, Xiang Weng6, Shruti Sharma6, Joseline Raja6, Pallavi Awate6, Ryosuke Shirasaki2, Huihui Tang2, Brian J Glassner2, Zhiyi Liu7, Dong Gao8, Jordan Bryan4, Samantha Bender4, Jennifer Roth4, Michal Scheffer2, Rinath Jeselsohn9, Nathanael S Gray9, Irene Georgakoudi7, Francisca Vazquez4, Aviad Tsherniak4, Yu Chen8, Alana Welm10, Cihangir Duy11, Ari Melnick12, Boris Bartholdy13, Myles Brown9, Aedin C Culhane14, Constantine S Mitsiades15.   

Abstract

Treatment-persistent residual tumors impede curative cancer therapy. To understand this cancer cell state we generated models of treatment persistence that simulate the residual tumors. We observe that treatment-persistent tumor cells in organoids, xenografts, and cancer patients adopt a distinct and reversible transcriptional program resembling that of embryonic diapause, a dormant stage of suspended development triggered by stress and associated with suppressed Myc activity and overall biosynthesis. In cancer cells, depleting Myc or inhibiting Brd4, a Myc transcriptional co-activator, attenuates drug cytotoxicity through a dormant diapause-like adaptation with reduced apoptotic priming. Conversely, inducible Myc upregulation enhances acute chemotherapeutic activity. Maintaining residual cells in dormancy after chemotherapy by inhibiting Myc activity or interfering with the diapause-like adaptation by inhibiting cyclin-dependent kinase 9 represent potential therapeutic strategies against chemotherapy-persistent tumor cells. Our study demonstrates that cancer co-opts a mechanism similar to diapause with adaptive inactivation of Myc to persist during treatment.
Copyright © 2020 Elsevier Inc. All rights reserved.

Entities:  

Keywords:  CDK9; CRISPR; MYC; adaptation to stress; breast cancer; cancer; diapause; drug persistence; prostate cancer; residual tumor

Mesh:

Substances:

Year:  2021        PMID: 33417832      PMCID: PMC8670073          DOI: 10.1016/j.ccell.2020.12.002

Source DB:  PubMed          Journal:  Cancer Cell        ISSN: 1535-6108            Impact factor:   31.743


  62 in total

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  31 in total

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