Targeted cancer therapy induces APOBEC fuelling the evolution of drug resistance

Manasi K. Mayekar; Deborah R. Caswell; Natalie I. Vokes; Emily K. Law; Wei Wu; William Hill; Eva Grönroos; Andrew Rowan; Maise Al Bakir; Caroline E. McCoach; Collin M. Blakely; Nuri A. Temiz; A. Nagano; D. Lucas Kerr; Julia Rotow; Franziska Haderk; Michelle Dietzen; Carlos Martinez Ruiz; Bruna Almeida; Lauren Čech; Beatrice Gini; Joanna Przewrocka; Christopher Moore; Miguel Murillo; Björn Bakker; Brandon Rule; Cameron Durfee; Shigeki Nanjo; Lisa Tan; Lindsay K. Larson; Prokopios P. Argyris; William L. Brown; Johnny Yu; Carlos F. Gómez; Philippe Gui; Rachel I. Vogel; Elizabeth A. Yu; Nicholas J. Thomas; Subramanian Venkatesan; Sebastijan Hobor; Su Kit Chew; Nnennaya Kanu; Nicholas McGranahan; Eliezer M. Van Allen; Julian Downward; Reuben S. Harris; Trever G. Bivona; Charles Swanton

doi:10.1101/2020.12.18.423280

Targeted cancer therapy induces APOBEC fuelling the evolution of drug resistance

Manasi K. Mayekar(University of California, San Francisco), Deborah R. Caswell(The Francis Crick Institute), Natalie I. Vokes(The University of Texas MD Anderson Cancer Center), Emily K. Law(University of Minnesota), Wei Wu(University of California, San Francisco), William Hill(The Francis Crick Institute), Eva Grönroos(The Francis Crick Institute), Andrew Rowan(The Francis Crick Institute), Maise Al Bakir(The Francis Crick Institute), Caroline E. McCoach(University of California, San Francisco), Collin M. Blakely(University of California, San Francisco), Nuri A. Temiz(University of Minnesota), A. Nagano(The Francis Crick Institute), D. Lucas Kerr(University of California, San Francisco), Julia Rotow(Dana-Farber Cancer Institute), Franziska Haderk(University of California, San Francisco), Michelle Dietzen(Cancer Research UK), Carlos Martinez Ruiz(Cancer Research UK), Bruna Almeida(The Francis Crick Institute), Lauren Čech(University of California, San Francisco), Beatrice Gini(University of California, San Francisco), Joanna Przewrocka(The Francis Crick Institute), Christopher Moore(The Francis Crick Institute), Miguel Murillo(The Francis Crick Institute), Björn Bakker(The Francis Crick Institute), Brandon Rule(The Francis Crick Institute), Cameron Durfee(University of Minnesota), Shigeki Nanjo(University of California, San Francisco), Lisa Tan(University of California, San Francisco), Lindsay K. Larson(University of Minnesota), Prokopios P. Argyris(University of Minnesota), William L. Brown(University of Minnesota), Johnny Yu(University of California, San Francisco), Carlos F. Gómez(University of California, San Francisco), Philippe Gui(University of California, San Francisco), Rachel I. Vogel(University of Minnesota), Elizabeth A. Yu(University of California, San Francisco), Nicholas J. Thomas(University of California, San Francisco), Subramanian Venkatesan(The Francis Crick Institute), Sebastijan Hobor(The Francis Crick Institute), Su Kit Chew(Cancer Research UK), Nnennaya Kanu(Cancer Research UK), Nicholas McGranahan(Cancer Research UK), Eliezer M. Van Allen(Dana-Farber Cancer Institute), Julian Downward(The Francis Crick Institute), Reuben S. Harris(University of Minnesota), Trever G. Bivona(University of California, San Francisco), Charles Swanton(The Francis Crick Institute)

bioRxiv (Cold Spring Harbor Laboratory)

December 18, 2020

10.1101/2020.12.18.423280

Cited by 19Open Access

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Abstract

Introductory paragraph The clinical success of targeted cancer therapy is limited by drug resistance that renders cancers lethal in patients 1-4 . Human tumours can evolve therapy resistance by acquiring de novo genetic alterations and increased heterogeneity via mechanisms that remain incompletely understood 1 . Here, through parallel analysis of human clinical samples, tumour xenograft and cell line models and murine model systems, we uncover an unanticipated mechanism of therapy-induced adaptation that fuels the evolution of drug resistance. Targeted therapy directed against EGFR and ALK oncoproteins in lung cancer induced adaptations favoring apolipoprotein B mRNA-editing enzyme, catalytic polypeptide (APOBEC)-mediated genome mutagenesis. In human oncogenic EGFR -driven and ALK -driven lung cancers and preclinical models, EGFR or ALK inhibitor treatment induced the expression and DNA mutagenic activity of APOBEC3B via therapy-mediated activation of NF-κB signaling. Moreover, targeted therapy also mediated downregulation of certain DNA repair enzymes such as UNG2, which normally counteracts APOBEC-catalyzed DNA deamination events. In mutant EGFR -driven lung cancer mouse models, APOBEC3B was detrimental to tumour initiation and yet advantageous to tumour progression during EGFR targeted therapy, consistent with TRACERx data demonstrating subclonal enrichment of APOBEC-mediated mutagenesis. This study reveals how cancers adapt and drive genetic diversity in response to targeted therapy and identifies APOBEC deaminases as future targets for eliciting more durable clinical benefit to targeted cancer therapy.

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