SAN FRANCISCO, CA—February 6, 2014—A cure for type 1 diabetes has long eluded even the top experts. Not because they do not know what must be done—but because the tools did not exist to do it. But now scientists at the Gladstone Institutes, harnessing the power of regenerative medicine, have developed a technique in animal models that could replenish the very cells destroyed by the disease. The team's findings, published online today in the journal Cell Stem Cell, are an important step towards freeing an entire generation of patients from the life-long injections that characterize this devastating disease.
Type 1 diabetes, which usually manifests during childhood, is caused by the destruction of ß-cells, a type of cell that normally resides in the pancreas and produces a hormone called insulin. Without insulin, the body's organs have difficulty absorbing sugars, such as glucose, from the blood. Once a death sentence, the disease can now be managed with regular glucose monitoring and insulin injections. A more permanent solution, however, would be to replace the missing ß-cells. But these cells are hard to come by, so researchers have looked towards stem cell technology as a way to make them.
"The power of regenerative medicine is that it can potentially provide an unlimited source of functional, insulin-producing ß-cells that can then be transplanted into the patient," said Dr. Ding, who is also a professor at the University of California, San Francisco (UCSF), with which Gladstone is affiliated. "But previous attempts to produce large quantities of healthy ß-cells—and to develop a workable delivery system—have not been entirely successful. So we took a somewhat different approach."
One of the major challenges to generating large quantities of ß-cells is that these cells have limited regenerative ability; once they mature it's difficult to make more. So the team decided to go one step backwards in the life cycle of the cell.
The team first collected skin cells, called fibroblasts, from laboratory mice. Then, by treating the fibroblasts with a unique 'cocktail' of molecules and reprogramming factors, they transformed the cells into endoderm-like cells. Endoderm cells are a type of cell found in the early embryo, and which eventually mature into the body's major organs—including the pancreas.
"Using another chemical cocktail, we then transformed these endoderm-like cells into cells that mimicked early pancreas-like cells, which we called PPLC's," said Gladstone Postdoctoral Scholar Ke Li, PhD, the paper's lead author. "Our initial goal was to see whether we could coax these PPLC's to mature into cells that, like ß-cells, respond to the correct chemical signals and—most importantly—secrete insulin. And our initial experiments, performed in a petri dish, revealed that they did."
The research team then wanted to see whether the same would occur in live animal models. So they transplanted PPLC's into mice modified to have hyperglycemia (high glucose levels), a key indicator of diabetes.
"Importantly, just one week post-transplant, the animals' glucose levels started to decrease gradually approaching normal levels," continued Dr. Li. "And when we removed the transplanted cells, we saw an immediate glucose spike, revealing a direct link between the transplantation of the PPLC's and reduced hyperglycemia."
But it was when the team tested the mice eight weeks post-transplant that they saw more dramatic changes: the PPLC's had given rise to fully functional, insulin-secreting ß-cells.
"These results not only highlight the power of small molecules in cellular reprogramming, they are proof-of-principle that could one day be used as a personalized therapeutic approach in patients," explained Dr. Ding.
"I am particularly excited about the prospect of translating these findings to the human system," said Matthias Hebrok, PhD, one of the study's authors and director of the UCSF Diabetes Center. "Most immediately, this technology in human cells could significantly advance our understanding of how inherent defects in ß-cells result in diabetes, bringing us notably closer to a much-needed cure."
Saiyong Zhu, PhD, Shaohua Xu, PhD, Tao Xu, PhD, Yu Zhang, PhD, and Tianhua Ma, PhD also participated in this research at Gladstone, which was supported by the Roddenberry Foundation, the Eunice Kennedy Shriver National Institute of Child Health and Human Development, the National Energy Institute, the National Heart, Lung and Blood Institute, the National Institute of Mental Health/National Institutes of Health, the California Institute for Regenerative Medicine, the United States Department of Defense and the William K. Bowes, Jr. Foundation.
About the Gladstone Institutes
Gladstone is an independent and nonprofit biomedical-research organization dedicated to accelerating the pace of scientific discovery and innovation to prevent, treat and cure cardiovascular, viral and neurological diseases. Gladstone is affiliated with the University of California, San Francisco.
Journal
Cell Stem Cell