Abstract
Glaucoma is the leading cause of irreversible blindness with trabecular meshwork (TM) dysfunction resulting in elevated intraocular pressure and retinal ganglion cell (RGC) damage leading to vision loss. In this study, we discovered that secretome, derived from human TM stem cells, via minimal invasive periocular injection, can reduce intraocular pressure, restore TM homeostasis, protect RGC, and restore RGC function in both steroid-induced and genetic myocilin mutant mouse models of glaucoma. The secretome upregulated the COX2-PGE2 axis via mitochondrial TMEM177 and led to activation of endogenous stem cells and TM regeneration. Inhibition of COX2 abolished the protective effect of secretome on TM cells. Secretome treatment also enhanced RGC survival and function. Proteomic analysis revealed that the secretome is enriched with proteins involved in extracellular matrix modulation leading to the remodeling of TM to restore homeostasis. This study highlights the feasibility of stem cell-free therapy for glaucoma with minimal invasive administration and the involvement of multiple novel pathways for a cumulative regenerative effect on the TM to protect RGC.
Brief summary This study describes a cell-free treatment using stem cell secretome in two animal models of glaucoma and explores the potential mechanisms
Competing Interest Statement
University of Pittsburgh has a competing interest with a patent trabecular meshwork stem cells with Yiqin Du and Joel S. Schuman as inventors. University of Pittsburgh has filed provisional patent compositions and methods for treating ocular disorders with Yiqin Du and Ajay Kumar as inventors. All other authors declare no competing interests.