Fetal Hepatocytes Protect the HSPC Genome Via Fetuin-A

Overview

Journal Nature

Specialty Science

Date 2024 Dec 5

PMID 39633051

Authors

Xiao-Lin Guo

Yi-Ding Wang

Yan-Jun Liu

Lei Chu

Hua Zhu

Ye Hu

Ren-Yan Wu

Hong-Yu Xie

Juan Yu

Shui-Ping Li

Zhao-Yang Xiong

Chao-Yang Xiong

Ruo-Yan Li

Fang Ke

Lei Chen

Guo-Qiang Chen

Liang Chen

Fan Bai

Tariq Enver

Guo-Hong Li

Huai-Fang Li

Deng-Li Hong

Affiliations

Soon will be listed here.

Abstract

The maintenance of genomic integrity in rapidly proliferating cells is a substantial challenge during embryonic development. Although numerous cell-intrinsic mechanisms have been revealed, little is known about genome-protective effects and influences of developmental tissue microenvironments on tissue-forming cells. Here we show that fetal liver hepatocytes provide protection to haematopoietic stem and progenitor cell (HSPC) genomes. Lineage tracing and depletion in mice demonstrated that delayed hepatocyte development in early fetal livers increased the chromosomal instability of newly colonizing HSPCs. In addition, HSPCs developed tolerance to genotoxins in hepatocyte-conditioned medium, suggesting that hepatocytes protect the HSPC genome in a paracrine manner. Proteomic analyses demonstrated the enrichment of fetuin-A in hepatocyte-conditioned medium but not in early fetal livers. Fetuin-A activates a Toll-like receptor pathway to prevent pathogenic R-loop accumulation in HSPCs undergoing DNA replication and gene transcription in the fetal liver. Numerous haematopoietic regulatory genes frequently involved in leukaemogenic mutations are associated with R-loop-enriched regions. In Fetua-knockout mice, HSPCs showed increased genome instability and susceptibility to malignancy induction. Moreover, low concentrations of fetuin-A correlated with the oncogenesis of childhood leukaemia. Therefore, we uncover a mechanism operating in developmental tissues that offers tissue-forming cell genome protection and is implicated in developmental-related diseases.

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