Exercise has the ability to imitate the molecular profile of muscles that have been subjected to Yamanaka factors, resulting in a molecular expression similar to that of younger cells.
Evidence suggests that exercise creates a molecular profile in muscle that is consistent with the expression of youthful-promoting Yamanaka factors.
A recent study published in the Journal of Physiology has further supported the idea that exercise can help maintain youthful qualities in aging organisms. This research builds upon earlier experiments with lab mice who were near the end of their lifespan and had access to a weighted exercise wheel.
The lead author of the paper is Kevin Murach, an assistant professor at the University of Arkansas in the Department of Health, Human Performance and Recreation. The first author is Ronald G. Jones III, who is a Ph.D. student in Murach’s Molecular Muscle Mass Regulation Laboratory.
For this paper, the researchers compared aging mice that had access to a weighted exercise wheel with mice that had undergone epigenetic reprogramming via the expression of Yamanaka factors.
Kevin Murach. Credit: University of Arkansas
The Yamanaka factors are four protein transcription factors (identified as Oct3/4, Sox2, Klf4, and c-Myc, often abbreviated to OKSM) that can revert highly specified cells (such as a skin cell) back to a stem cell, which is a younger and more adaptable state. The Nobel Prize in Physiology or Medicine was awarded to Dr. Shinya Yamanaka for this discovery in 2012. In the correct dosages, inducing the Yamanaka factors throughout the body in rodents can ameliorate the hallmarks of aging by mimicking the adaptability that is common to more youthful cells.
Of the four factors, Myc is induced by exercising skeletal muscle. Myc may serve as a naturally induced reprogramming stimulus in muscle, making it a useful point of comparison between cells that have been reprogrammed via over-expression of the Yamanaka factors and cells that have been reprogrammed through exercise — “reprogramming” in the latter case reflecting how an environmental stimulus can alter the accessibility and expression of genes.
The researchers compared the skeletal muscle of mice who had been allowed to exercise late in life to the skeletal muscle of mice that overexpressed OKSM in their muscles, as well as to genetically modified mice limited to the overexpression of just Myc in their muscles.
Ultimately, the team determined that exercise promotes a molecular profile consistent with epigenetic partial programming. That is to say: exercise can mimic aspects of the molecular profile of muscles that have been exposed to Yamanaka factors (thus displaying molecular characteristics of more youthful cells). This beneficial effect of exercise may in part be attributed to the specific actions of Myc in muscle.
While it would be easy to hypothesize that someday we might be able to manipulate Myc in muscle to achieve the effects of exercise, thus sparing us the actual hard work, Murach cautions that would be the wrong conclusion to draw.
First, Myc would never be able to replicate all the downstream effects exercise has throughout the body. It is also the cause of tumors and cancers, so there are inherent dangers to manipulating its expression. Instead, Murach thinks manipulating Myc might best be employed as an experimental strategy to understand how to restore exercise adaptation to old muscles showing declining responsiveness. Possibly it could also be a means of supercharging the exercise response of astronauts in zero gravity or people confined to bed rest who only have a limited capacity for exercise. Myc has many effects, both good and bad, so defining the beneficial ones could lead to a safe therapeutic that could be effective for humans down the road.
Murach sees their research as further validation of exercise as a polypill. “Exercise is the most powerful drug we have,” he says, and should be considered a health-enhancing — and potentially life-extending — treatment along with medications and a healthy diet.
Reference: “A molecular signature defining exercise adaptation with ageing and in vivo partial reprogramming in skeletal muscle” by Ronald G. Jones III, Andrea Dimet-Wiley, Amin Haghani, Francielly Morena da Silva, Camille R. Brightwell, Seongkyun Lim, Sabin Khadgi, Yuan Wen, Cory M. Dungan, Robert T. Brooke, Nicholas P. Greene, Charlotte A. Peterson, John J. McCarthy, Steve Horvath, Stanley J. Watowich, Christopher S. Fry and Kevin A. Murach, 19 December 2022, The Journal of Physiology.
DOI: 10.1113/JP283836
The study was funded by the National Institute of Health.
Source: SciTechDaily
