New UCLA research could help explain the link between a high-cholesterol diet and an elevated risk for colon cancer.
In a study of mice, scientists from the David Geffen School of Medicine at UCLA discovered that boosting the animals’ cholesterol levels spurred intestinal stem cells to divide more quickly, enabling tumors to form significantly faster. Published online in Cell Stem Cell, the study identifies a new target for colon cancer treatment.
“We were excited to find that cholesterol influences the growth of stem cells in the intestines, which in turn accelerates the rate of tumor formation by more than 100-fold,” said Dr. Peter Tontonoz, the medical school’s Frances and Albert Piansky Professor of Pathology and Laboratory Medicine. “While the connection between dietary cholesterol and colon cancer is well established, no one has previously explained the mechanism behind it.”
The scientists increased cholesterol in the intestinal stem cells in some of the mice by introducing more of the substance into their diets. In others, the researchers altered a gene that regulates phospholipids, the primary type of fat in cell membranes, which spurred the cells to produce more cholesterol on their own.
The stem cells’ ability to multiply increased in both groups.
As the animals’ cholesterol levels rose, their cells divided more rapidly, causing the tissue lining their guts to expand and their intestines to lengthen. These changes significantly sped up the rate of tumor formation in their colons.
The UCLA team will explore whether the phospholipid-cholesterol interaction they discovered plays a similar role in accelerating the growth of other cancers.
The three-year study was funded by the National Heart, Lung and Blood Institute and the National Institute of Diabetes and Digestive and Kidney Diseases.
Tontonoz’s coauthors were first author Bo Wang, Xin Rong, Elisa Palladino, Dr. Alan Fogelman and Dr. Martin Martin, all of UCLA; Waddah Alrefai of the University of Illinois at Chicago; and David Ford of St. Louis University.
Source : UCLA