Today's open access review looks over the evidence for senescent cells to contribute to the age-related loss of muscle mass and strength, leading to sarcopenia and frailty. Regular readers will know that the research community has found many mechanisms that are arguably important contribution to the characteristic weakness of old age. This part of the field is rife with competing evidence for processes ranging from the comparatively mundane, such as an inadequate dietary intake of protein in older people, to the highly complex, such as the biochemical disarray that causes loss of neuromuscular junctions, and the interactions between those junctions and mechanisms of muscle tissue maintenance. The most compelling evidence points to stem cell dysfunction as the primary cause of loss of muscle and strength with age. But then we might well ask which of the fundamental causes of aging produces that stem cell dysfunction?

The review here argues for cellular senescence to be an important cause. Senescent cells accumulate over time, a tiny fraction of the countless cells that become senescent every day managing to linger rather than self-destruct. The immune system clears out near all of those, but the immune system falters with age. Cancer is an age-related disease in large part because of this loss of capability in the portions of the immune system responsible for destroying errant cells, and the accumulation of senescent cells is no doubt in the same boat. Yet even in very old tissues, only a small percentage of cells are senescent. The harm they cause is not direct, but rather results from the potent mix of signals that they generate. Those signals produce chronic inflammation, destructively remodel tissue structure, and change the behavior of surrounding cells for the worse.

Just looking at chronic inflammation, it is known that this state can disrupt the normal processes of tissue maintenance and regeneration. But there are many other mechanisms worth surveying when it comes to the ways in which cellular senescence might be acting to suppress the activity of stem cell populations, thus leading to atrophy and loss of function in tissues such as skeletal muscle. What if these senescent cells could be removed, however? Might we expect some degree of rejuvenation of stem cell activity? That doesn't seem an unreasonable goal, based on the evidence to date. Senolytic therapies capable of clearing a fraction of senescent cells already exist, albeit not packaged up for the mass market, and not yet run through rigorous human trials. More effective therapies are entering the regulatory pipeline, under development in a number of young companies, and will arrive in the clinic over the years ahead.

Musculoskeletal senescence: a moving target ready to be eliminated