Nuclear receptor Rev-erbα role in fine-tuning erythropoietin gene expression.
Sumit KumarRashmi AroraShalini GuptaNancy AhujaElla BhagyarajRavikanth NanduriRashi KalraAsheesh Kumar KhareSaumyata KumawatVipashu KaushalMahathi SharmaPawan GuptaPublished in: Blood advances (2024)
The regulation of red blood cell (RBC) homeostasis by erythropoietin (EPO) is critical for O2 transport and maintaining the adequate number of RBCs in vertebrates. Therefore, dysregulation in EPO synthesis results in disease conditions such as polycythemia in the case of excessive EPO production and anemia, which occurs when EPO is inadequately produced. EPO plays a crucial role in treating anemic patients; however, its overproduction can increase blood viscosity, potentially leading to fatal heart failure. Consequently, the identification of druggable transcription factors and their associated ligands capable of regulating EPO offers a promising therapeutic approach to address EPO-related disorders. This study unveils a novel regulatory mechanism involving 2 pivotal nuclear receptors (NRs), Rev-ERBA (Rev-erbα, is a truncation of reverse c-erbAa) and RAR-related orphan receptor A (RORα), in the control of EPO gene expression. Rev-erbα acts as a cell-intrinsic negative regulator, playing a vital role in maintaining erythropoiesis at the correct level. It accomplishes this by directly binding to newly identified response elements within the human and mouse EPO gene promoter, thereby repressing EPO production. These findings are further supported by the discovery that a Rev-erbα agonist (SR9011) effectively suppresses hypoxia-induced EPO expression in mice. In contrast, RORα functions as a positive regulator of EPO gene expression, also binding to the same response elements in the promoter to induce EPO production. Finally, the results of this study revealed that the 2 NRs, Rev-erbα and RORα, influence EPO synthesis in a negative and positive manner, respectively, suggesting that the modulating activity of these 2 NRs could provide a method to target disorders linked with EPO dysregulation.
Keyphrases
- gene expression
- transcription factor
- heart failure
- dna methylation
- type diabetes
- magnetic resonance
- poor prognosis
- magnetic resonance imaging
- air pollution
- computed tomography
- bone marrow
- mesenchymal stem cells
- skeletal muscle
- adipose tissue
- stem cells
- prognostic factors
- left ventricular
- atrial fibrillation
- genome wide
- long non coding rna
- cell therapy
- dna binding
- patient reported outcomes
- weight loss