Dr. Cowan’s lab is using iPS cells to support studies of obesity and metabolic disorders. While the lab can easily obtain fat cells from patients, these cells can’t be cultured over the long term. “We can keep the fat cells alive for a short period of time but that only allows us to do a one-time endpoint assay. It doesn’t allow us to tease out the complexities of what might be going wrong in a patient with a metabolic disorder. The ability to make patient-specific fat cells from iPS cells completely changes the game.”
With iPS cells, the lab can conduct dozens of assays to identify differences in fat cells from a person with a metabolic disorder such as type 2 diabetes versus a person with normal body weight or someone without diabetes. The ability to take a single genotype and potentially make any of the tissues that might be involved in a metabolic disorder such as hypothalamus, pancreatic beta cells, and hepatocytes, could lead to powerful disease models.
In his lab at the University of California, Santa Barbara, Dennis Clegg, Ph.D., is using iPS cells as one tool to study the loss of vision in age-related macular degeneration (AMD). In AMD, the degeneration of retinal pigment epithelial (RPE) cells appears to cause the death of neighboring rods and cones in the macular region of the central retina.
Dr. Clegg’s lab is evaluating the use of iPS-derived RPE cells to treat AMD and using iPS cell lines to create ocular cells, which can be used to study how the eye develops. “The real utility of iPS cells is that you can study human cells and processes in ways you couldn’t do before,” notes Dr. Clegg.