PHOTO CREDIT: Paulo Temblador

A superhero, powered by acylcarnitines (AC), combats the bitter cold. Claudio Villanueva chose this image as an inspiration to minorities and women in science. “We can’t afford to lose more superheroes,” he says.

When grandpa nudges the settings on the thermostat, there’s likely a good reason. Humans, like other animals, become more sensitive to cold with age. Now, scientists from University of Utah Health report that delivering a single dose of a nutritional supplement called L-carnitine to older mice restores a youthful ability to adapt to the cold. After treatment, they tolerate chilly conditions that would ordinarily trigger hypothermia.

“We uncovered a well-controlled process for mobilizing energy to the tissues that need it,” explains senior author Claudio Villanueva, assistant professor of biochemistry at U of U Health. Expanding on these findings could lead to a therapy for cold sensitivity.

As reported online in Cell Metabolism on Sept. 5, the supplement works by boosting levels of a newly discovered fuel source for brown fat, a “good fat” that generates body heat in response to the cold.

In a commentary “Inclusive Science Empowers the Superhero Within Us All”  published in the same issue, Villanueva explains the inspiration for the accompanying graphic (top of this page) depicting a female minority scientist who has unleashed the power within.

Lighting the fire within

While humans have only small amounts of brown fat, it is far more prevalent in mice that must adapt to the cold in order to survive. Unlike white fat that stores calories, this active fat burns energy to maintain the body’s core temperature.

Villanueva and his team clued into a different outlook on cold adaptation after determining that circulating levels of a waxy lipid called acylcarnitines fluctuated in response to the cold. Levels shot up in young mice as they adapted to the change in temperature. In contrast, acylcarnitines didn’t change as much in older mice that could not keep their core temperature from drifting dangerously low.

PHOTO CREDIT: University of Utah Health

Judith Simcox (standing, left), James Cox (seated), and Claudio Villanueva (standing, right).

“It was surprising to see acylcarnitines in the bloodstream,” remarks lead author and postdoctoral fellow Judith Simcox. “The dogma was that once cells generated them, they used them right away.”

Scientists had seen circulating acylcarnitines before but it was always considered to be a sign of trouble. In infants, high levels of the lipid indicate they have a metabolic disease. The molecules also mount in the bloodstream during exercise, considered a flag for muscles under stress. The context in which Villanueva and Simcox saw acylcarnitines accumulate hinted that the buildup could also be part of a healthy process.

To see what the lipids were doing, Simcox traced their migration as originating from the liver, the first time the organ has been implicated in cold adaptation. The lipids traveled through the bloodstream, ending up in a small number of energy-intensive tissues including brown fat. Once there, the fatty tissue broke down the lipids and metabolized them, indicating that they had become fuel for the main function of these specialized cells: to generate heat.

Cementing the idea, depleting the lipid from circulation caused even young mice to lose their ability to adequately warm up in the cold.

“This work is putting a new face on an old character,” says Simcox. “We’re changing how we think about cold-induced thermogenesis.”

Energy well spent

One reason it might be so difficult for aging animals to shirk off the cold is that doing so is costly from an energy standpoint. Simcox says that what is considered a disadvantage evolutionarily could be turned into an advantage for people.

She explains that because of brown fat’s ability to burn calories, jump-starting the cold adaptation process may not just be useful for fixing cold sensitivity but could also become a way to fight obesity. Now, with an activator of brown fat in hand, scientists have a handle on manipulating brown fat’s power.

“The idea is to increase fuel utilization to drive the energy demanding process of adapting to the cold,” says Villanueva. “If we can find a way to tell the body to expend more energy than it is taking in, the calories lost can lead to weight loss.”

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Funding was provided by the National Institutes of Health and the Margolis Research Foundation

Global analysis of plasma lipids identifies liver-derived acylcarnitines as a fuel source for brown fat thermogenesis” appears online in Cell Metabolism on Sept. 5

In addition to University of Utah Health, collaborating institutions include University of Texas Southwestern Medical Center, University of Kansas Medical Center, University of Pittsburgh, VA Salt Lake City Health System, and University of Graz, Austria. See the publication for the full list of authors.

Media Contacts

Julie Kieferassociate director, science communications, University of Utah Health
Office: 801-587-1293


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