Single-cell analysis identifies MKI67+ microglia as drivers of neovascularization in proliferative diabetic retinopathy
Keyi Zou, Xue Li, Bibo Ren, Fu Cheng, Jian Ye, Zhishuo Ou
Abstract
BACKGROUND: Proliferative diabetic retinopathy (PDR) is among the primary causes of blindness in individuals with diabetes. Elevated lactate levels have been identified as a critical biomarker associated with the prognosis of PDR. While significant lactate accumulation has been observed in the vitreous fluid of PDR patients, the detailed pathways through which lactate impacts pathological neovascularization remain insufficiently elucidated. METHODS: The study employed single-cell RNA sequencing (scRNA-seq) to identify and characterize lactate-associated cell type in PDR patients. Key gene expression profiles and molecular pathways associated with lactate metabolism were analyzed. In vitro experiments were conducted using microglial cell cultures treated with high-glucose conditions (50 mM) to assess the induction of lactate metabolism-related genes. Additionally, an oxygen-induced retinopathy (OIR) mouse model was used to evaluate the impact of abemaciclib, an FDA-approved proliferation inhibitor, on retinal neovascularization. RESULTS: microglia, distinguished by robust upregulation of genes implicated in lactate metabolic processes and proliferation, such as MKI67, PARK7 and LDHA, as well as a pronounced enrichment of glycolysis-associated molecular pathways. This unique cell type promotes angiogenesis by interacting with endothelial cells via secreted phosphoprotein 1 (SPP1)-Integrin alpha 4 (ITGA4) signaling. In vitro experiments have shown the use of 50 mM high glucose to simulate microglia in PDR environment and observe its promotion of vascular proliferation. In the in vivo OIR model, treatment with abemaciclib, a FDA-approved proliferation inhibitor, significantly reduced neovascularization. CONCLUSION: microglia as a cell type strongly associated with lactate metabolism provides a novel perspective on the mechanisms underlying PDR onset. These findings expand our understanding of the cellular and metabolic dynamics in PDR, emphasizing potential implications for targeted therapeutic interventions.