ΔNp63/p73 Drive Metastatic Colonization by Controlling a Regenerative Epithelial Stem Cell Program in Quasi-mesenchymal Cancer Stem Cells

Overview

Journal Dev Cell

Publisher Cell Press

Specialties Cell Biology
Reproductive Medicine

Date 2022 Dec 20

PMID 36538894

Authors

Arthur W Lambert

Christopher Fiore

Yogesh Chutake

Elisha R Verhaar

Patrick C Strasser

Mei Wei Chen

Daneyal Farouq

Sunny Das

Xin Li

Elinor Ng Eaton

Yun Zhang

Joana Liu Donaher

Ian Engstrom

Ferenc Reinhardt

Bingbing Yuan

Sumeet Gupta

Bruce Wollison

Matthew Eaton

Brian Bierie

John Carulli

Eric R Olson

Matthew G Guenther

Robert A Weinberg

Affiliations

Soon will be listed here.

Abstract

Cancer stem cells (CSCs) may serve as the cellular seeds of tumor recurrence and metastasis, and they can be generated via epithelial-mesenchymal transitions (EMTs). Isolating pure populations of CSCs is difficult because EMT programs generate multiple alternative cell states, and phenotypic plasticity permits frequent interconversions between these states. Here, we used cell-surface expression of integrin β4 (ITGB4) to isolate highly enriched populations of human breast CSCs, and we identified the gene regulatory network operating in ITGB4 CSCs. Specifically, we identified ΔNp63 and p73, the latter of which transactivates ΔNp63, as centrally important transcriptional regulators of quasi-mesenchymal CSCs that reside in an intermediate EMT state. We found that the transcriptional program controlled by ΔNp63 in CSCs is largely distinct from the one that it orchestrates in normal basal mammary stem cells and, instead, it more closely resembles a regenerative epithelial stem cell response to wounding. Moreover, quasi-mesenchymal CSCs repurpose this program to drive metastatic colonization via autocrine EGFR signaling.

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