Base Editing Screens Define the Genetic Landscape of Cancer Drug Resistance Mechanisms

Overview

Journal Nat Genet

Specialty Genetics

Date 2024 Oct 18

PMID 39424923

Authors

Matthew A Coelho

Magdalena E Strauss

Alex Watterson

Sarah Cooper

Shriram Bhosle

Giuditta Illuzzi

Emre Karakoc

Cansu Dincer

Sara F Vieira

Mamta Sharma

Marie Moullet

Daniela Conticelli

Jonas Koeppel

Katrina McCarten

Chiara M Cattaneo

Vivien Veninga

Gabriele Picco

Leopold Parts

Josep V Forment

Emile E Voest

John C Marioni

Andrew Bassett

Mathew J Garnett

Affiliations

Soon will be listed here.

Abstract

Drug resistance is a principal limitation to the long-term efficacy of cancer therapies. Cancer genome sequencing can retrospectively delineate the genetic basis of drug resistance, but this requires large numbers of post-treatment samples to nominate causal variants. Here we prospectively identify genetic mechanisms of resistance to ten oncology drugs from CRISPR base editing mutagenesis screens in four cancer cell lines using a guide RNA library predicted to install 32,476 variants in 11 cancer genes. We identify four functional classes of protein variants modulating drug sensitivity and use single-cell transcriptomics to reveal how these variants operate through distinct mechanisms, including eliciting a drug-addicted cell state. We identify variants that can be targeted with alternative inhibitors to overcome resistance and functionally validate an epidermal growth factor receptor (EGFR) variant that sensitizes lung cancer cells to EGFR inhibitors. Our variant-to-function map has implications for patient stratification, therapy combinations and drug scheduling in cancer treatment.

Citing Articles

Multiplexed base editing identifies functional gene-variant-context interactions.

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