Abstract
β-thalassemia is a hematologic disease that may be associated with significant morbidity and mortality. Increased expression of HBG1/2 can ameliorate the severity of β-thalassemia. Compared to the unaffected population, some β-thalassemia patients display elevated HBG1/2 expression levels in their red blood cells. However, the magnitude of up-regulation does not reach the threshold of self-healing, and thus, the molecular mechanism underlying HBG1/2 expression in the context of HBB-deficiency requires further elucidation. Here, we performed a multi-omics study examining chromatin accessibility, transcriptome, proteome, and phosphorylation patterns in the HBB homozygous knockout of the HUDEP2 cell line (HBB-KO). We found that up-regulation of HBG1/2 in HBB-KO cells was not induced by the H3K4me3-mediated genetic compensation response. Deletion of HBB in human erythroid progenitor cells resulted in increased ROS levels and production of oxidative stress, which led to an increased rate of apoptosis. Furthermore, in response to oxidative stress, slower cell cycle progression and proliferation were observed. In addition, stress erythropoiesis was initiated leading to increased intracellular HBG1/2 expression. This molecular model was also validated in the single-cell transcriptome of hematopoietic stem cells from β-hemoglobinopathy patients. These findings further the understanding of HBG1/2 gene regulatory networks and provide novel clinical insights into β-thalassemia phenotypic diversity.
Highlights
Introductionred blood cells (RBCs) circulate in the blood for approximately 120 days to deliver oxygen to tissues via a tetrameric hemoglobin protein [1]
The human body generates approximately two million red blood cells (RBCs) every second through a process called erythropoiesis, which usually occurs in the bone marrow.RBCs circulate in the blood for approximately 120 days to deliver oxygen to tissues via a tetrameric hemoglobin protein [1]
We generated a human umbilical cord blood-derived erythroid progenitor (HUDEP2) cell line with homozygous knockout of HBB to elucidate the molecular mechanisms underlying the up-regulation of HBG1/2 expression induced by HBB deletion
Summary
RBCs circulate in the blood for approximately 120 days to deliver oxygen to tissues via a tetrameric hemoglobin protein [1]. Fetal hemoglobin (HbF, α2 γ2 ) is comprised of two copies of γ-globin (HBG1/2) and two copies of α-globin (HBA), while adult hemoglobin (HbA, α2 β2 ) is comprised of two copies of α-globin (HBA) and two copies of β-globin (HBB) [2,3]. The HBG1/2 gene is primarily expressed during development, but silenced soon after birth and replaced by HBB expression [2,4]. Β-thalassemia is a hereditary hematological disease caused by over 300 mutations in the HBB gene [5]. Among β-thalassemia patients, there is a sub-population who simultaneously exhibit the hereditary persistence of fetal hemoglobin (HPFH) [2,6]. HPFH-related mutations in the HBB gene cluster or point mutations in the HBG1/2 gene lead to excessive
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