Eye-in-a-Dish Models Reveal Genetic Underpinnings of Macular Degeneration
“Eye-in-a-Dish” retinal cells derived from a patient’s skin cells, via induced pluripotent stem cells, organize in a polygonal shape and take on characteristic pigmentation. Image credit: UC San Diego
Age-related macular degeneration (AMD) is one of the most common causes of vision loss in people over age 65. The exact cause is unknown, but the fact that a family history of AMD increases a person’s risk for the condition suggests genetics play an important role. Using stem cells derived from six people, University of California San Diego School of Medicine researchers recapitulated retinal cells in the lab. This “eye-in-a-dish” model allowed them to look for genetic variants that might contribute to AMD.
The study, published May 9, 2019 by Stem Cell Reports, revealed the importance of a specific genetic variation that affects expression of the VEGFA gene. The product of this gene, the VEGFA protein, is known for supporting new blood vessel growth — a process that goes awry in AMD. Using this new model of AMD, the researchers determined that a specific genetic variation in a region of the genome that regulates expression of the VEGFA gene reduces the amount of VEGFA produced and directly contributes to AMD.
“We didn’t start with the VEGFA gene when we went looking for genetic causes of AMD,” said senior author Kelly A. Frazer, PhD, professor of pediatrics and director of the Institute for Genomic Medicine at UC San Diego School of Medicine and Moores Cancer Center. “But we were surprised to find that, with samples from just six people, this genetic variation clearly emerged as a causal factor.” Frazer led the study with co-first authors Erin N. Smith, PhD, and Agnieszka D'Antonio-Chronowska, PhD, both scientists in her lab.
AMD involves the slow breakdown of cells that make up the macula, which is part of the retina, a region in the back of the eye that sends information to the brain. The most common treatment for AMD is injections of a drug that inhibits VEGF. This therapy blocks the formation of new blood vessels and leakage from abnormal vessels.
“Since current AMD therapies work by inhibiting VEGF, we knew VEGF was involved in AMD,” D'Antonio-Chronowska said. “But we were surprised that the causal variant results in decreased VEGFA expression prior to AMD onset, and this finding could potentially be relevant for the treatment of AMD using anti-VEGF therapeutics.”
The “eye-in-a-dish” model was generated from induced pluripotent stem cells (iPSCs). Researchers first obtained skin samples from participants, then converted skin cells into iPSCs as an intermediary. Like all stem cells, iPSCs can both self-renew, making more iPSCs, and differentiate into a specialized cell type. With the right cocktail of molecules and growth factors, the researchers specifically coaxed iPSCs into becoming retinal cells. The resulting “eye-in-a-dish” model took on physiological and molecular characteristics similar to native retinal cells, including a polygonal shape and pigmentation.
Next, the team collected molecular data, including RNA transcripts and epigenetic information, from the retinal models. They integrated this new data with complementary published data from 18 adults with and without AMD. The genetic variant most closely associated with AMD was rs943080, a specific genetic variation that affects expression of the VEGFA gene by altering activity of a distant region of the genome. Five of the six participants had one copy of rs943080 and one person had two copies of the gene variant.
The team made all of their data publicly available, giving researchers around the world the opportunity to further study the molecular features of these iPSC-derived retinal cells. They plan to develop this retinal model for more people, and use it to investigate other genes involved in AMD.
This article has been republished from materials provided by UC San Diego. Note: material may have been edited for length and content. For further information, please contact the cited source.
Smith, E., et al. (2019). Human iPSC-Derived Retinal Pigment Epithelium: A Model System for Prioritizing and Functionally Characterizing Causal Variants at AMD Risk Loci. Stem Cell Reports DOI:https://doi.org/10.1016/j.stemcr.2019.04.012