From discovermagazine.comHibernation might sound like an extreme way of life: Animals gain a lot of weight quickly, then drastically slow their metabolism to survive off stored energy through long, cold months.
But for all its intensity, hibernation is surprisingly healthy, so much so that researchers are now exploring whether humans carry dormant versions of the same genetic switches that allow bears, ground squirrels, and other hibernators to cycle through extreme physiological changes without damaging their health.
In two companion studies published in Science, a research team from University of Utah Health uncovered molecular pathways that could help make humans more like hibernators — at least in the ways that matter most for health and disease prevention
In the first study, the team investigated a genetic cluster associated with hibernation and how its regulation affects metabolism. They focused on a region known as the fat mass and obesity (FTO) locus, which also exists in humans. Notably, this region is our strongest genetic risk factor for obesity, explained senior author Chris Gregg, a professor at University of Utah Health, in a press release.
The researchers discovered hibernator-specific DNA regions that regulate the FTO locus, tuning nearby genes up or down, likely to support rapid weight gain before hibernation, followed by long periods of fasting.
To test their theory, they edited these hibernator-specific DNA regions in mice (which don’t naturally hibernate). The result: changes in metabolism and behavior resembling that of hibernators, including altered weight regulation, body temperature control, and foraging instincts.
“When you knock out one of these elements — this one tiny, seemingly insignificant DNA region — the activity of hundreds of genes changes,” said co-author Susan Steinwand in the press statement. “It’s pretty amazing.”
Hibernator Gene Switches
In the second study, the researchers explored how hibernators regulate these genetic responses in the brain. They focused on the hypothalamus, a brain region that plays a central role in metabolism.
By analyzing gene expression in fasting and fed mice, and comparing it with the genetic profile of hibernating species, they identified key genes that act as coordinators of fasting responses.
The team theorizes, that over evolutionary time, these genes became genetic "switches," turned on or off depending on whether hibernation was advantageous. In theory, these same switches could one day be targeted in humans for therapeutic benefit.
So kind of like editing a line in a config file, or in the source code
