Hibernating Bear Blood Prevents Human Muscle Atrophy
Author: Hiroshima University
Published: 2022/07/16 - Updated: 2026/02/14
Publication Details: Peer-Reviewed, Research, Study, Analysis
Category Topic: Medical Research - Related Publications
Page Content: Synopsis - Introduction - Main - Insights, Updates
Synopsis: This peer-reviewed research, published in the journal PLOS ONE, details how scientists from Hiroshima University and Hokkaido University discovered that blood serum drawn from hibernating Japanese black bears can suppress muscle protein degradation in cultured human skeletal muscle cells. The study found that hibernating bear serum weakened the destruction mechanism responsible for breaking down unused muscle by suppressing MuRF1, the protein that triggers the shredding of inactive muscles, while also activating the Akt/FOXO3a signaling pathway associated with protein synthesis. The findings are significant for people with disabilities, seniors, and anyone facing prolonged periods of immobility or bed rest, as muscle atrophy from disuse remains a serious clinical problem linked to obesity, diabetes, and early death. While the specific protective factor in the serum has not yet been identified, the researchers believe that isolating it could eventually lead to better rehabilitation strategies and new ways to prevent muscle wasting in humans who are unable to maintain physical activity - Disabled World (DW).
- Definition: Hibernation
Hibernation is a way animals conserve energy to survive adverse weather conditions or lack of food. Hibernation is a state of minimal activity and metabolic depression undergone by some animal species. Hibernation is a seasonal heterothermy characterized by low body temperature, slow breathing and heart rate, and low metabolic rate. It most commonly occurs during the winter months. Hibernating bears can recycle their proteins and urine, allowing them to stop urinating for months and avoid muscle atrophy. They stay hydrated with the metabolic fat produced in sufficient quantities to satisfy the water needs of the bear. They also do not eat or drink while hibernating but live off their stored fat. Despite long-term inactivity and lack of food intake, hibernating bears are believed to maintain their bone mass and do not suffer from osteoporosis. They also increase the availability of certain essential amino acids in the muscle and regulate the transcription of a suite of genes that limit muscle wasting.
Introduction
Bear Blood Protects Against Human Muscle Breakdown
Japanese scientists observed "muscle gain" in cultured human skeletal muscle cells infused with serum from hibernating black bears, confirming that unique factors activated in these creatures' blood during winter trigger their remarkable ability to prevent muscular atrophy despite months of inactivity. Hibernating bears can lie still for 5-7 months a year inside their dens without eating or drinking. In humans, three weeks of inactivity is enough to lose muscle mass. Prolonging it could lead to sedentary lifestyle-related diseases like obesity and diabetes - and even early death. Bears survive hibernation with limited muscle loss, minimal metabolic dysfunction, and unharmed physical functions.
"The 'use it or lose it' phenomenon is a well-accepted physiological principle for the skeletal muscle, which is highly plastic in response to functional demands. Disuse typically leads to skeletal muscle loss and metabolic dysfunction in many animal species, including humans," study first-author Mitsunori Miyazaki, associate professor at Hiroshima University's Graduate School of Biomedical and Health Sciences, explained.
"In contrast, hibernating animals are likely better described to be under the 'no use, but no lose' phenomenon, in that there is potential resistance to muscle atrophy during continued disuse conditions."
Main Content
The study jointly conducted with researchers from Hokkaido University found that the serum drawn from the blood of hibernating Japanese black bears weakened the "destruction mechanism" controlling muscular degradation. Their findings were published in the journal PLOS ONE.
Muscle mass is generally determined by the dynamic balance between the "synthesis" and "degradation" of proteins. But since the hibernating bears' serum disrupts this balance, the cultured muscle cells showed significant protein growth following 24 hours of treatment. This notable increase in protein was not seen in cultured muscle cells infused with serum collected during the bears' active summer season.
The researchers attributed the diminished capacity of the muscles' "destruction mechanism" to the suppressed expression of MuRF1 (Muscle RING-finger protein-1), the switch triggering the shredding of unused muscles. According to them, it is likely that suppression of MuRF1 expression was mediated by the activation of the Akt/FOXO3a (protein kinase B/Forkhead box class O 3a) axis responsible for the elevation of protein synthesis.
They also observed increased levels of the growth factor hormone IGF-1 (insulin-like growth factor-1) in the hibernating bear serum. The researchers identified it as a candidate upstream factor that induces activation of the Akt/FOXO3a axis. Previous studies have reported seasonal variations of IGF-1 concentrations in bear serum. These studies found that IGF-1 concentrations were highest during the active summer period, lowest in early hibernation and then increased again near the end.
But Miyazaki and his co-researchers later redirected their attention elsewhere after correcting their calculations on IGF-1 concentration levels in the hibernating bear serum. They said it is a possibility that the higher IGF-1 concentrations observed in the study were simply due to a decrease in the serum's water content brought about by other causes, such as dehydration.
"We have indicated that 'some factor' present in hibernating bear serum may regulate protein metabolism in cultured human skeletal muscle cells and contribute to the maintenance of muscle mass. However, the identification of this 'factor' has not yet been achieved," Miyazaki said.
Originally a physical therapist, the associate professor said he wondered why it is not possible to build muscles that do not weaken in the first place rather than restore deteriorated muscles.
"I wanted to do research that would lead to the development of effective rehabilitation and training methods," Miyazaki said, adding that this is the reason he got interested in exploring hibernation's secrets.
"By identifying this 'factor' in hibernating bear serum and clarifying the unexplored mechanism behind 'muscles that do not weaken even without use' in hibernating animals, it is possible to develop effective rehabilitation strategies in humans and prevent becoming bedridden in the future."
Sources:
Hiroshima University: Bears got hibernation power in their blood, but the identity of 'superhero' components still a mystery (published: 07/15/2022).
Mitsunori Miyazaki, Michito Shimozuru, Toshio Tsubota, et al.: Supplementing cultured human myotubes with hibernating bear serum results in increased protein content by modulating Akt/FOXO3a signaling; in PLOS ONE (2022).
Insights, Analysis, and Developments
Editorial Note: There is something genuinely striking about the idea that an animal capable of lying motionless for up to seven months without eating, drinking, or losing significant muscle mass could hold a biological key to one of the most persistent problems in human health. Muscle atrophy from prolonged inactivity affects millions of people worldwide - from patients recovering after surgery or spinal cord injury to elderly individuals who become bedridden and never fully recover. What this Hiroshima University team demonstrated is that something in the blood of hibernating bears actively protects against the protein breakdown that humans experience after just three weeks of disuse. The mystery factor has not been pinpointed yet, and the IGF-1 lead turned out to be less straightforward than initially hoped. But the underlying science is sound, the peer-reviewed results are measurable, and the potential applications for rehabilitation medicine and disability care are hard to overstate. If researchers can eventually isolate and replicate whatever is keeping those bear muscles intact, it could fundamentally change how we approach immobility-related muscle loss in humans - Disabled World (DW).Attribution/Source(s): This peer reviewed publication was selected for publishing by the editors of Disabled World (DW) due to its relevance to the disability community. Originally authored by Hiroshima University and published on 2022/07/16, this content may have been edited for style, clarity, or brevity.