People with dry eye disease are more likely than those with healthy eyes to suffer injuries to their corneas. Now, researchers at the Washington University School of Medicine in St. Louis, working with mice, have found that proteins made by stem cells that regenerate the cornea may be new targets for treating and preventing such injuries. Their study “Dry eye disease in mice activates adaptive corneal epithelial regeneration distinct from constitutive renewal in homeostasis” appears in PNAS.

Dry eye disease occurs when the eye can’t provide adequate lubrication with natural tears. People with the common disorder use various types of drops to replace missing natural tears and keep the eyes lubricated, but when eyes are dry, the cornea is more susceptible to injury.

“We have drugs, but they only work well in about 10% to 15% of patients,” said senior investigator Rajendra S. Apte, MD, PhD, the Paul A. Cibis Distinguished Professor in the John F. Hardesty, MD, department of ophthalmology and visual sciences. “In this study involving genes that are key to eye health, we identified potential targets for treatment that appear different in dry eyes than in healthy eyes. Tens of millions of people around the world—with an estimated 15 million in the United States alone—endure eye pain and blurred vision as a result of complications and injury associated with dry eye disease, and by targeting these proteins, we may be able to more successfully treat or even prevent those injuries.”

Gene expression analysis

The researchers analyzed genes expressed by the cornea in several mouse models—not only of dry eye disease, but also of diabetes and other conditions. They found that in mice with dry eye disease, the cornea activated expression of the gene SPARC. They also found that higher levels of SPARC protein were associated with better healing.

“We conducted single-cell RNA sequencing to identify genes important to maintaining the health of the cornea, and we believe that a few of them, particularly SPARC, may provide potential therapeutic targets for treating dry eye disease and corneal injury,” said first author Joseph B. Lin, an MD/PhD student in Apte’s lab.

“These stem cells are important and resilient, and a key reason corneal transplantation works so well,” added Apte. “If the proteins we’ve identified don’t pan out as therapies to activate these cells in people with dry eye syndrome, we may even be able to transplant engineered limbal stem cells to prevent corneal injury in patients with dry eyes.

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