Enhancing Chemotherapy Response Through Augmented Synthetic Lethality by Co-targeting Nucleotide Excision Repair and Cell-cycle Checkpoints

Overview

Journal Nat Commun

Specialty Biology

Date 2020 Aug 19

PMID 32807787

Citations 17

Authors

Yi Wen Kong

Erik C Dreaden

Sandra Morandell

Wen Zhou

Sanjeev S Dhara

Ganapathy Sriram

Fred C Lam

Jesse C Patterson

Mohiuddin Quadir

Anh Dinh

Kevin E Shopsowitz

Shohreh Varmeh

Omer H Yilmaz

Stephen J Lippard

H Christian Reinhardt

Michael T Hemann

Paula T Hammond

Michael B Yaffe

Affiliations

Soon will be listed here.

Abstract

In response to DNA damage, a synthetic lethal relationship exists between the cell cycle checkpoint kinase MK2 and the tumor suppressor p53. Here, we describe the concept of augmented synthetic lethality (ASL): depletion of a third gene product enhances a pre-existing synthetic lethal combination. We show that loss of the DNA repair protein XPA markedly augments the synthetic lethality between MK2 and p53, enhancing anti-tumor responses alone and in combination with cisplatin chemotherapy. Delivery of siRNA-peptide nanoplexes co-targeting MK2 and XPA to pre-existing p53-deficient tumors in a highly aggressive, immunocompetent mouse model of lung adenocarcinoma improves long-term survival and cisplatin response beyond those of the synthetic lethal p53 mutant/MK2 combination alone. These findings establish a mechanism for co-targeting DNA damage-induced cell cycle checkpoints in combination with repair of cisplatin-DNA lesions in vivo using RNAi nanocarriers, and motivate further exploration of ASL as a generalized strategy to improve cancer treatment.

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