Shared Enhancer Gene Regulatory Networks Between Wound and Oncogenic Programs

Overview

Journal Elife

Specialty Biology

Date 2023 May 3

PMID 37133250

Authors

Swann Flochlay

Ramya Balaji

Dimitrije Stankovic

Valerie M Christiaens

Carmen Bravo Gonzalez-Blas

Seppe De Winter

Gert J Hulselmans

Maxime De Waegeneer

Xiaojiang Quan

Duygu Koldere

Mardelle Atkins

Georg Halder

Mirka Uhlirova

Anne-Kathrin Classen

Stein Aerts

Affiliations

Soon will be listed here.

Abstract

Wound response programs are often activated during neoplastic growth in tumors. In both wound repair and tumor growth, cells respond to acute stress and balance the activation of multiple programs, including apoptosis, proliferation, and cell migration. Central to those responses are the activation of the JNK/MAPK and JAK/STAT signaling pathways. Yet, to what extent these signaling cascades interact at the -regulatory level and how they orchestrate different regulatory and phenotypic responses is still unclear. Here, we aim to characterize the regulatory states that emerge and cooperate in the wound response, using the wing disc as a model system, and compare these with cancer cell states induced by in the eye disc. We used single-cell multiome profiling to derive enhancer gene regulatory networks (eGRNs) by integrating chromatin accessibility and gene expression signals. We identify a 'proliferative' eGRN, active in the majority of wounded cells and controlled by AP-1 and STAT. In a smaller, but distinct population of wound cells, a 'senescent' eGRN is activated and driven by C/EBP-like transcription factors (Irbp18, Xrp1, Slow border, and Vrille) and Scalloped. These two eGRN signatures are found to be active in tumor cells at both gene expression and chromatin accessibility levels. Our single-cell multiome and eGRNs resource offers an in-depth characterization of the senescence markers, together with a new perspective on the shared gene regulatory programs acting during wound response and oncogenesis.

Citing Articles

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