Researchers at Washington University School of Medicine in St. Louis
have identified a potential target for treating diabetes and obesity.
Studying mice, they found that when the target protein was disabled,
the animals became more sensitive to insulin and were less likely to get
fat even when they ate a high-fat diet that caused their littermates to
become obese.
The findings are published online in the journal Cell Metabolism.
The researchers studied how the body manufactures fat from dietary
sources such as carbohydrates. That process requires an enzyme called
fatty acid synthase (FAS). Mice engineered so that they don't make FAS
in their fat cells can eat a high-fat diet without becoming obese.
"Mice without FAS were significantly more resistant to obesity than
their wild-type littermates," says first author Irfan J. Lodhi, PhD.
"And it wasn't because they ate less. The mice ate just as much fatty
food, but they metabolized more of the fat and released it as heat."
To understand why that happened, Lodhi, a research instructor in
medicine, analyzed their fat cells. Mice have two types of fat: white
fat and brown fat. White fat stores excess calories and contributes to
obesity. Brown fat helps burn calories and protects against obesity.
In mice genetically blocked from making fatty acid synthase in fat
cells, Lodhi and his colleagues noticed that the animals' white fat was
transformed into tissue that resembled brown fat.
"These cells are 'brite' cells, brown fat found where white fat cells
should be," Lodhi says. "They had the genetic signature of brown fat
cells and acted like brown fat cells. Because the mice were resistant to
obesity, it appears that fatty acid synthase may control a switch
between white fat and brown fat. When we removed FAS from the equation,
white fat transformed into brite cells that burned more energy."
Determining whether humans also have brown fat has been somewhat
controversial throughout the years, but recent studies elsewhere have
confirmed that people have it.
"It definitely exists, and perhaps the next strategy we'll use for
treating people with diabetes and obesity will be to try to reverse
their problems by activating these brown fat cells," says senior
investigator Clay F. Semenkovich, MD.
Semenkovich, the Herbert S. Gasser Professor of Medicine, professor
of cell biology and physiology and director of the Division of
Endocrinology, Metabolism and Lipid Research, says the new work is
exciting because FAS provides a target that may be able to activate
brown fat cells to treat obesity and diabetes. But even better, he says
it may be possible to target a protein downstream from FAS to lower the
risk for potential side effects from the therapy.
That is possible because the scientists learned that the FAS pathway
involves a family of proteins known as the PPARs (peroxisome
proliferator-activated receptors). PPARs are important in lipid
metabolism. One of them, PPAR-alpha, helps burn fat, but the related
protein, PPAR-gamma manufactures fat and helps store it.
Lodhi and Semenkovich noticed that in mice without FAS in their fat
cells, activity of PPAR-alpha (the fat burner) was increased, while
PPAR-gamma (the fat builder) activity decreased.
A protein called PexRAP (Peroxisomal Reductase Activating PPAR-gamma)
turned out to be a downstream mediator of the effects of FAS and a key
regulator of the PPAR-gamma, fat-storing pathway. When the researchers
blocked PexRAP in fat cells in mice, they also interfered with the
manufacture and buildup of fat.
"There was decreased fat when we blocked PexRAP," Lodhi says. "Those
mice also had improved glucose metabolism, so we think that inhibiting
either fatty acid synthase or PexRAP might be good strategies for
treating obesity and diabetes."
Several pharmaceutical companies are working on FAS inhibitors.
Meanwhile, the discovery that inhibiting PexRAP also makes the animals
less obese and less diabetic has convinced the Washington University
researchers to continue those studies.
"Because PexRAP is downstream, it theoretically might cause fewer
side effects, but nobody knows what role the protein might play in
different tissues in the body," Semenkovich says. "We need to conduct
more experiments with the goal that we may be able to move into some
sort of clinical trials relatively soon. It's very important to find new
treatments for obesity and diabetes because these disorders aren't just
an inconvenience, both can be lethal."
Journal Reference:
- Irfan J. Lodhi, Li Yin, Anne P.L. Jensen-Urstad, Katsuhiko Funai, Trey Coleman, John H. Baird, Meral K. El Ramahi, Babak Razani, Haowei Song, Fong Fu-Hsu, John Turk, Clay F. Semenkovich. Inhibiting Adipose Tissue Lipogenesis Reprograms Thermogenesis and PPARĪ³ Activation to Decrease Diet-Induced Obesity. Cell Metabolism, 2012; DOI: 10.1016/j.cmet.2012.06.013
Courtesy: ScienceDaily
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