Heterozygous Variants in GATA2 Contribute to DCML Deficiency in Mice by Disrupting Tandem Protein Binding

Overview

Journal Commun Biol

Specialty Biology

Date 2022 Apr 20

PMID 35440757

Authors

Atsushi Hasegawa

Yuki Hayasaka

Masanobu Morita

Yuta Takenaka

Yuna Hosaka

Ikuo Hirano

Masayuki Yamamoto

Ritsuko Shimizu

Affiliations

Soon will be listed here.

Abstract

Accumulating lines of clinical evidence support the emerging hypothesis that loss-of-function mutations of GATA2 cause inherited hematopoietic diseases, including Emberger syndrome; dendritic cell, monocyte B and NK lymphoid (DCML) deficiency; and MonoMAC syndrome. Here, we show that mice heterozygous for an arginine-to-tryptophan substitution mutation in GATA2 (G2), which was found in a patient with DCML deficiency, substantially phenocopy human DCML deficiency. Mice heterozygous for the GATA2-null mutation (G2) do not show such phenotypes. The G2 protein possesses a decreased DNA-binding affinity but obstructs the function of coexpressed wild-type GATA2 through specific cis-regulatory regions, which contain two GATA motifs in direct-repeat arrangements. In contrast, G2 is innocuous in mice containing single GATA motifs. We conclude that the dominant-negative effect of mutant GATA2 on wild-type GATA2 through specific enhancer/silencer of GATA2 target genes perturbs the GATA2 transcriptional network, leading to the development of the DCML-like phenotype. The present mouse model provides an avenue for the understanding of molecular mechanisms underlying the pathogenesis of GATA2-related hematopoietic diseases.

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