Erythropoiesis-Inosine Metabolic Axis Failure Underlying Retinal Neurodegeneration in Glaucoma: Novel Diagnoses and Therapies

Authors

Yuyu Chou
Wuping Liu
Yanxiu Li
Changhan Chen
Cheng Luo
Shiping Shen
Piaoyu Dai
Lemeng Feng
Wenhao Xiao
Yiyan Wang
Juncheng Wang
Linlin Wan
Zhiyu Yang
Tingting Xie
Yujin Zhang
Rodney E Kellems
Weitao Song
Xiaobo Xia
Yang Xia

Language

English

Publication Date

2-13-2026

Journal

Experimental & Molecular Medicine

DOI

10.1038/s12276-026-01654-x

PMID

41688739

Abstract

Glaucoma, long considered an ocular-limited, age-dependent and hypoxia-driven neurodegeneration, is here reframed as a systemic erythroid-inosine axis failure that originates in the bone marrow yet culminates in retinal ganglion cell (RGC) death. By mining UK Biobank datasets (n = 127,028) and validating our findings in an independent clinical cohort (n = 178), we reveal that glaucoma is preceded by dyserythropoiesis and a compensatory, AMPK-driven metabolic rewiring of mature erythrocytes that hypercatabolizes inosine to enhance oxygen unloading. This adaptation collapses when accelerated erythrocyte inosine metabolism drains systemic pools, starving high-energy demand hematopoietic progenitors, driving retinal microenvironment hypoxia and accelerating RGC loss. Genetic ablation of murine erythroid equilibrative nucleoside transporter 1 (ENT1) recapitulates the hallmark features of patients with glaucoma, including impaired erythropoiesis, reduced oxygen delivery, retinal hypoxia and RGC apoptosis in both age and intraocular pressure-induced glaucoma models. Conversely, inosine repletion reconstitutes erythroid output, restores oxygen delivery from mature erythrocytes and halts neurodegeneration in inducible glaucoma models. A ten-metabolite erythrocyte signature centered on inosine metabolism offers diagnostic potential. Altogether, our work redefines glaucoma as the first treatable systemic erythroid-driven hypoxic syndrome, positioning inosine as a pleiotropic metabolic rescue factor for neurodegeneration and a powerful biomarker for intercepting hypoxia-driven pathologies across organs.

Published Open-Access

yes

Recommended Citation

Chou, Yuyu; Liu, Wuping; Li, Yanxiu; et al., "Erythropoiesis-Inosine Metabolic Axis Failure Underlying Retinal Neurodegeneration in Glaucoma: Novel Diagnoses and Therapies" (2026). Faculty, Staff and Student Publications. 5963.
https://digitalcommons.library.tmc.edu/uthgsbs_docs/5963