When the researchers fed mice a diet high in saturated milk fats, microglia, a type of immune cell, underwent a population explosion in the brain region called the hypothalamus, which is responsible for feeding behavior.
The researchers used an experimental drug and, alternatively, a genetic approach to knock out these microglia, and both strategies resulted in a complete loss of microglia-driven inflammation in the hypothalamus. Remarkably, doing so also resulted in the mice eating less food each day than did their untreated counterparts, without any apparent ill effects.
UCSF postdoctoral fellow Martin Valdearcos Contreras, PhD, first author on the paper, published in the December 11, 2014 issue of Cell Reports, discovered that when mice consumed large amounts of saturated fats, the fat entered their brains and accumulated in the hypothalamus.
According to the senior scientist for the study, Suneil Koliwad, MD, PhD, an assistant professor of medicine at the UCSF Diabetes Center, the microglia senses the saturated fat and sends instructions to brain circuits in the hypothalamus. These instructions are important drivers of food intake, he said.
Microglia are primarily known for causing inflammation in the brain in response to infection or injury, but the new study indicates that they also play a key role in shaping the brain's response to diet, according to Koliwad.
Outside the brain, in fat tissue, the liver, muscles and other immune cells, called macrophages, trigger inflammation in response to "diet-induced obesity," Koliwad said. This inflammation is implicated in triggering insulin resistance, a late stage event on the road to type 2 diabetes.
However, overeating causes microglia to accumulate much more quickly in the hypothalamus than macrophages accumulate in peripheral tissues, Koliwad said. But until now, the effects of this microglial build-up were unknown.
"As opposed to classically defined inflammation, in which immune cells build up in tissues where environmental insults have created disarray, microglial activation in the brain may be a part of a normal physiological process to remodel brain function in response to changes in the composition of food intake," Koliwad said.
"When the intake of saturated fats is chronically high, this microglial sensory network may be hijacked and this has the potential to mediate increased food consumption and promote more rapid weight gain."
"Targeting microglia may therefore be a novel way to control food intake in the face of consumption of a fat-rich diet, something that is quite common in today's world," he said.
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