Upregulation of MiR‑6747‑3p Affects Red Blood Cell Lineage Development and Induces Fetal Hemoglobin Expression by Targeting BCL11A in β‑thalassemia

Overview

Journal Mol Med Rep

Specialty Molecular Biology

Date 2024 Oct 25

PMID 39450557

Authors

Aixiang Lv

Meihuan Chen

Siwen Zhang

Wantong Zhao

Jingmin Li

Siyang Lin

Yanping Zheng

Na Lin

Liangpu Xu

Hailong Huang

Affiliations

Soon will be listed here.

Abstract

In β‑thalassemia, excessive α‑globin chain impedes the normal development of red blood cells resulting in anemia. Numerous miRNAs, including miR‑6747‑3p, are aberrantly expressed in β‑thalassemia major (β‑TM), but there are no reports on the mechanism of miR‑6747‑3p in regulating red blood cell lineage development and fetal hemoglobin (HbF) expression. In the present study, RT‑qPCR was utilized to confirm miR‑6747‑3p expression in patients with β‑TM and the healthy controls. Electrotransfection was employed to introduce the miR‑6747‑3p mimic and inhibitor in both HUDEP‑2 and K562 cells, and red blood cell lineage development was evaluated by CCK‑8 assay, flow cytometry, Wright‑Giemsa staining and Benzidine blue staining. B‑cell lymphoma/leukemia 11A (BCL11A) was selected as a candidate target gene of miR‑6747‑3p for further validation through FISH assay, dual luciferase assay and Western blotting. The results indicated that miR‑6747‑3p expression was notably higher in patients with β‑TM compared with healthy controls and was positively related to HbF levels. Functionally, miR‑6747‑3p overexpression resulted in the hindrance of cell proliferation, promotion of cell apoptosis, facilitation of cellular erythroid differentiation and γ‑globin expression in HUDEP‑2 and K562 cells. Mechanistically, miR‑6747‑3p could specifically bind to the 546‑552 loci of BCL11A 3'‑UTR and induce γ‑globin expression. These data indicate that upregulation of miR‑6747‑3p affects red blood cell lineage development and induces HbF expression by targeting BCL11A in β‑thalassemia, highlighting miR‑6747‑3p as a potential molecular target for β‑thalassemia therapy.

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