In brown fat, the heat-generating process depends on a protein called UCP1; the protein is also thought to be central in brown fat's ability to prevent diabetes. Researchers are now exploring ways of activating this molecular pathway. But in trying to figure out exactly how fat cells respond to the body being cold, Spiegelman and colleagues discovered that plain old "white" fat cells have a few surprises left. In a study appearing online today in the Proceedings of the National Academy of Sciences, the researchers exposed various kinds of fat cells to cold temperatures directly. "We were a little surprised that no one had tried this before," Spiegelman says.
The researchers cooled several types of lab-grown human fat cells—brown, white and "beige" (white adipose tissue with some brown cells mixed in)—to temperatures between 27˚ and 39˚C for four hours, eight hours, or up to ten days. White fat cells and beige cells responded to cooling in dramatic fashion. In these cells, levels of the UCP1 were doubled by 8 hours after the treatment. The change in UCP1 also proved to be reversible: Its levels returned to normal once the cells' temperature was lowered to 37 degrees. But in brown fat cells, no induction of the protein was observed, indicating that cold temperatures don't mobilize these cells by flipping this particular switch.
The researchers also found that white fat cells obtained from mice lacking receptors for norepinephrine were still able to respond to cooling by turning on UCP1—showing that the heat-generating pathway is both specific to those fat cells and independent of the sympathetic nervous system .
The finding won't lead to an antifat pill any time soon, Spiegelman says, but it does give scientists new avenues to explore. "It's a piece of the basic science, adding to an evolving awareness that fat cells have many lives that we never knew about. Now we know they can sense temperature directly. The next question is, how do they do it, and can that ability be manipulated?"
"The paper is filling in an emerging picture that adipose tissue can be a more flexible, adaptive organ than we once thought," says Sven Enerbäck, a physician and adipose tissue researcher at the University of Gothenburg in Sweden. "The finding raises the question of whether this new pathway has widespread effects on the animal as a whole."
Finding that white fat cells directly detect and react to cold is a surprising development, notes cell biologist Peter Tontonoz of the University of California, Los Angeles, because it shows that the sympathetic nervous system isn't the whole story when it comes to heat generation by adipose tissue. He's curious whether the heat-generating pathway in white fat is a routine part of everyday temperature regulation. "Even if it isn't," he adds, "it could still be targeted by small molecules or other drugs."