Conserved Transcription Factors Promote Cell Fate Stability and Restrict Reprogramming Potential in Differentiated Cells

Overview

Journal Nat Commun

Specialty Biology

Date 2023 Mar 27

PMID 36973293

Authors

Maria A Missinato

Sean Murphy

Michaela Lynott

Michael S Yu

Anais Kervadec

Yu-Ling Chang

Suraj Kannan

Mafalda Loreti

Christopher Lee

Prashila Amatya

Hiroshi Tanaka

Chun-Teng Huang

Pier Lorenzo Puri

Chulan Kwon

Peter D Adams

Li Qian

Alessandra Sacco

Peter Andersen

Alexandre R Colas

Affiliations

Soon will be listed here.

Abstract

Defining the mechanisms safeguarding cell fate identity in differentiated cells is crucial to improve 1) - our understanding of how differentiation is maintained in healthy tissues or altered in a disease state, and 2) - our ability to use cell fate reprogramming for regenerative purposes. Here, using a genome-wide transcription factor screen followed by validation steps in a variety of reprogramming assays (cardiac, neural and iPSC in fibroblasts and endothelial cells), we identified a set of four transcription factors (ATF7IP, JUNB, SP7, and ZNF207 [AJSZ]) that robustly opposes cell fate reprogramming in both lineage and cell type independent manners. Mechanistically, our integrated multi-omics approach (ChIP, ATAC and RNA-seq) revealed that AJSZ oppose cell fate reprogramming by 1) - maintaining chromatin enriched for reprogramming TF motifs in a closed state and 2) - downregulating genes required for reprogramming. Finally, KD of AJSZ in combination with MGT overexpression, significantly reduced scar size and improved heart function by 50%, as compared to MGT alone post-myocardial infarction. Collectively, our study suggests that inhibition of barrier to reprogramming mechanisms represents a promising therapeutic avenue to improve adult organ function post-injury.

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