Washington: A previously unknown biological mechanism involved in the regulation of pancreatic islet beta cells, whose role is to produce and release insulin, has been identified by researchers at the University of California, San Diego School of Medicine.
The discovery suggests a new therapeutic target for treating dysfunctional beta cells and type 2 diabetes, a disease affecting more than 25 million Americans.
Jerrold M. Olefsky, MD, associate dean for scientific affairs and distinguished professor of medicine, and colleagues said that a transmembrane binding protein called fractalkine, which typically mediates cell-to-cell adhesion though its receptor, CX3CR1, can also be released from cells to circulate in the blood and stimulate insulin secretion.
"Our discovery of fractalkine`s role in beta cells is novel and has never been talked about in prior literature," said Olefsky.
More importantly, the research highlights fractalkine`s apparently vital role in normal, healthy beta cell function. In mouse models and in cultured human islets, the researchers found administering the protein stimulated insulin secretion and improved glucose tolerance, both key factors in diabetes. In contrast, fractalkine had no effect in mice or islets when the fractalkine receptor was deleted.
"Whether or not decreased fractalkine or impaired fractalkine signaling are causes of decreased beta cell function in diabetes is unknown," said Olefsky.
"What we do know, without doubt, is that administration of fractalkine improves or restores insulin secretion in all of the mouse models we have examined, as well as in human islet cells," he added.
Olefsky said fractalkine or a protein analog could prove "a potential treatment to improve insulin secretion in type 2 diabetic patients. It might also improve beta cell function or beta cell health, beyond simply increasing insulin secretion, since fractalkine prevents beta cell apoptosis (cell death) and promotes the beta cell differentiation program.
"If successfully developed, this could be an important new complement to the therapeutic arsenal we use in type 2 diabetes. It is not likely to `cure` diabetes, but it would certainly do a good job at providing glycemic control," Olefsky added.
The finding was reported in the April 11, 2013 issue of Cell.
The discovery suggests a new therapeutic target for treating dysfunctional beta cells and type 2 diabetes, a disease affecting more than 25 million Americans.
Jerrold M. Olefsky, MD, associate dean for scientific affairs and distinguished professor of medicine, and colleagues said that a transmembrane binding protein called fractalkine, which typically mediates cell-to-cell adhesion though its receptor, CX3CR1, can also be released from cells to circulate in the blood and stimulate insulin secretion.
"Our discovery of fractalkine`s role in beta cells is novel and has never been talked about in prior literature," said Olefsky.
More importantly, the research highlights fractalkine`s apparently vital role in normal, healthy beta cell function. In mouse models and in cultured human islets, the researchers found administering the protein stimulated insulin secretion and improved glucose tolerance, both key factors in diabetes. In contrast, fractalkine had no effect in mice or islets when the fractalkine receptor was deleted.
"Whether or not decreased fractalkine or impaired fractalkine signaling are causes of decreased beta cell function in diabetes is unknown," said Olefsky.
"What we do know, without doubt, is that administration of fractalkine improves or restores insulin secretion in all of the mouse models we have examined, as well as in human islet cells," he added.
Olefsky said fractalkine or a protein analog could prove "a potential treatment to improve insulin secretion in type 2 diabetic patients. It might also improve beta cell function or beta cell health, beyond simply increasing insulin secretion, since fractalkine prevents beta cell apoptosis (cell death) and promotes the beta cell differentiation program.
"If successfully developed, this could be an important new complement to the therapeutic arsenal we use in type 2 diabetes. It is not likely to `cure` diabetes, but it would certainly do a good job at providing glycemic control," Olefsky added.
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