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microRNA‐320a prevent Müller cells from hypoxia injury by targeting aquaporin‐4

Zhen Chen, Zhengrong Yang, Xiaoliang Li, He Wang, Yonggang Wang, Chao Ding, Jingying Yang, Ninghua Ni, Mei Yan, Shiwen Zhang

2020Journal of Cellular Biochemistry16 citationsDOI

Abstract

Müller cells are closely related to diabetic retinopathy (DR). Aquaporin-4 (AQP4) can effectively promote the diffusion of water across cellular membranes. However, the dynamic balance of water plays key role in many diseases, such as cerebral edema. Meanwhile, the unusual expression and distribution of AQP4 in the retina are the significant causes of ocular hypertension and reperfusion injury. To explore the functional significance between microRNA-320a (miR-320a) and AQP4 in pathological hypoxia-induced DR related retinal edema, we hypothesized that miR-320a regulates AQP4 expression and internalization to relieve the edema of Müller cells under the pathological retinal hypoxia stress by targeting AQP4, thereby attenuate the damage of Müller cells. Results demonstrated that miR-320a mimics inhibited the expressions of AQP4 in Müller cells. Furthermore, overexpression miR-320a protected Müller cells by suppressing superoxide anion. In addition, overexpression miR-320a markedly attenuated hypoxia-induced injury, significantly increased the cell viability, and promoted the internalization of AQP4. Furthermore, miR-320a can also regulate the stable anchoring of AQP4 on the cell membrane. Our study indicated that miR-320a may be a potential modulator which can mediate AQP4 expression and attenuate the hypoxia damage of Müller cells. In conclusion, miR-320a may be a potential target for DR therapy by targeting AQP4.

Topics & Concepts

Aquaporin 4InternalizationHypoxia (environmental)Cell biologyEdemaAquaporin 1HomeostasismicroRNACell damageDownregulation and upregulationGene knockdownCellMedicineChemistryBiologyPathologyInternal medicineApoptosisBiochemistryWater channelMechanical engineeringOxygenOrganic chemistryGeneEngineeringInletIon Transport and Channel RegulationMicroRNA in disease regulationSphingolipid Metabolism and Signaling