Hibernating for better health: harnessing the genetic mechanisms underlying hibernation


Original story from the University of Utah Health (UT, USA).

Hibernating animals’ superpowers could lie hidden in our own DNA, opening the door to developing treatments that could reverse neurodegeneration and diabetes.

Animals that hibernate are incredibly resilient. They can spend months without food or water while their muscles refuse to atrophy, their body temperature dropping to near freezing as their metabolism and brain activity slow to a crawl. When they emerge from hibernation, they recover from dangerous health changes similar to those seen in type 2 diabetes, Alzheimer’s disease and stroke.

The genetics of metabolism and obesity

A research team at the University of Utah Health (UT, USA) have found that a gene cluster called the ‘fat mass and obesity (FTO) locus’ plays an important role in hibernators’ abilities. Intriguingly, humans have these genes too. “What’s striking about this region is that it is the strongest genetic risk factor for human obesity,” commented Chris Gregg, professor in neurobiology and human genetics at University of Utah Health and senior author on the studies [1, 2]. However, hibernators seem able to use genes in the FTO locus in new ways to their advantage.

The team identified hibernator-specific DNA regions near the FTO locus that regulate the activity of neighboring genes, tuning them up or down. The researchers speculate that adjusting the activity of neighboring genes, including those in or near the FTO locus, allows hibernators to pack on the pounds before settling in for the winter, then slowly use their fat reserves for energy throughout hibernation.

Indeed, the hibernator-specific regulatory regions outside of the FTO locus seem crucial for tweaking metabolism. When the researchers mutated those hibernator-specific regions in mice, they saw changes in mice weight and metabolism. Some mutations sped up or slowed down weight gain under specific dietary conditions, others affected the ability to recover body temperature after a hibernation-like state or tuned overall metabolic rate up or down.

Intriguingly, the hibernator-specific DNA regions the researchers identified weren’t genes themselves. Instead, the regions were DNA sequences that contact nearby genes and turn their expression up or down. This means that mutating a single hibernator-specific region has wide-ranging effects extending far beyond the FTO locus, explained Susan Steinwand, research scientist in neurobiology and first author on one of the studies [2].  “When you knock out one of these elements – this one tiny, seemingly insignificant DNA region – the activity of hundreds of genes changes,” she commented. “It’s pretty amazing.”

Understanding hibernators’ metabolic flexibility could lead to better treatments for human metabolic disorders like type 2 diabetes, the researchers say. “If we could regulate our genes a bit more like hibernators, maybe we could overcome type 2 diabetes the same way that a hibernator returns from hibernation back to a normal metabolic state,” explained Elliott Ferris, bioinformatician and first author on the other study [1].


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Uncovering the regulation of hibernation

Finding the genetic regions that may enable hibernation is a problem akin to excavating needles from a massive DNA haystack. To narrow down the regions involved, the researchers used multiple independent whole-genome technologies to ask which regions might be relevant for hibernation. Then, they started looking for overlap between the results from each technique.

First, they looked for sequences of DNA that most mammals share but that had recently changed in hibernators. “If a region doesn’t change much from species to species for over 100 million years but then changes rapidly and dramatically in two hibernating mammals, then we think it points us to something that is important for hibernation, specifically,” Ferris shared.

To understand the biological processes that underlie hibernation, the researchers tested for and identified genes that turn up or down during fasting in mice, which triggers metabolic changes similar to hibernation. Next, they found the genes that act as central coordinators, or ‘hubs,’ of these fasting-induced changes to gene activity.

Many of the DNA regions that had recently changed in hibernators also appeared to interact with these central coordinating hub genes. Because of this, the researchers expect that the evolution of hibernation requires specific changes to the controls of the hub genes. These controls comprise a shortlist of DNA elements that are avenues for future investigation.

Awakening human potential

Most of the hibernator-associated changes in the genome appeared to ‘break’ the function of specific pieces of DNA, rather than confer a new function. This hints that hibernators may have lost constraints that would otherwise prevent extreme flexibility in the ability to control metabolism. In other words, it’s possible that the human ‘thermostat’ is locked to a narrow range of continuous energy consumption. For hibernators, that lock may be gone.

Hibernators can reverse neurodegeneration, avoid muscle atrophy, stay healthy despite massive weight fluctuations, and show improved aging and longevity. The researchers think their findings show that humans may already have the needed genetic code to have similar hibernator-like superpowers – if we can bypass some of our metabolic switches.

“Humans already have the genetic framework,” Steinwand remarked. “We just need to identify the control switches for these hibernator traits.” By learning how, researchers could help confer similar resilience to humans.

“There’s potentially an opportunity – by understanding these hibernation-linked mechanisms in the genome – to find strategies to intervene and help with age-related diseases,” Gregg concluded. “If that’s hidden in the genome that we’ve already got, we could learn from hibernators to improve our own health.”


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