November 23, 2024

Brighton Journal

Complete News World

The unexpected benefits of aging “zombie” cells

The unexpected benefits of aging “zombie” cells

The salamander species studied by Yoon’s group: Red-spotted salamander Notophthalmus viridescens. By studying salamanders, which have remarkable regenerative abilities, researchers have discovered that the presence of senescent cells speeds up the process of limb regeneration. The cells secrete factors that signal mature muscle fibers to transform into former muscle cells, which promotes regeneration. This finding could help researchers understand why humans have limited regeneration capabilities and possibly develop new treatments for age-related diseases. Credit: Maximina Yun

Scientists have shown that so-called senescent cells, that is, cells that have permanently stopped dividing, promote the production of new muscle cells to promote the regeneration of lost limbs in salamanders.

Senescent cells, associated with aging and disease, may have regenerative properties. Studying salamanders, researchers found that senescent cells accelerate limb regeneration by signaling muscle fibers to de-differentiate, which could lead to new treatments for age-related diseases.

Senescent cells are cells that have permanently stopped dividing in response to cellular stress but have not died. As organisms age, the number of senescent cells in the body increases. This buildup is currently considered a hallmark of aging and has been linked to a variety of diseases, including cancer. However, the true nature of these cells may be more complex and context dependent.

A growing body of evidence suggests that senescent cells may also have beneficial effects, such as healing wounds or preventing tissue scarring. “A few years ago, our group found that senescent cells were present at key stages of salamander limb regeneration. Interestingly, other groups have subsequently found these cells in other regeneration contexts, including in mammals. Therefore, we wanted to see if these cells contribute to In any way it can renew itself,” explains Dr. Maximina Yon, research group leader at the Center for Regenerative Therapies Dresden (CRTD) and the Physics of Excellence (PoL) group at TU Dresden and the Max Planck Institute in[{” attribute=””>Molecular Cell Biology and Genetics (MPI-CBG).

Senescent Cells Promote Regeneration

The researchers in Yun’s group study salamanders. These animals have unique regeneration abilities and are able to re-grow many organs of their bodies, including lost limbs. “Salamander limb regeneration is a fascinating process. In a matter of weeks, they re-grow a fully functional limb,” explains Dr. Yun.

To check if the presence of senescent cells influences the limb regeneration process, researchers in the Yun group found a way to modulate the number of senescent cells in the wound. The team observed that the presence of senescent cells enhanced the regeneration process.

“When more senescent cells were present in the wound, the animals developed a larger regeneration bud, or – as we call it – blastema. This is a collection of cells that are going to form all the needed tissues in the new limb. The larger the blastema, the more cells are there to regrow the limb and the quicker the regeneration process. The presence of senescent cells seemed to ‘fuel’ the regeneration process,” Dr. Yun says.

“Zombie” Signaling Promotes New Muscle Cells

Looking more closely at the blastema with and without the influence of the senescent cells, the Yun team uncovered a new mechanism that enhances the regeneration process and found that the presence of senescent cells increased the number of regenerating muscle cells. They showed that senescent cells secrete factors that stimulate nearby muscle tissue to take a developmental step back and produce new muscle.

“Our results show that senescent cells use cell-cell communication to influence the regeneration process. They secrete molecules that signal to mature muscle fibers to dedifferentiate into muscle progenitor cells. These cells can multiply themselves as well as differentiate into new muscle cells, thereby enhancing the regeneration process. This signaling appears to be an important part of promoting regeneration,” says Dr. Yun.

For now, the group focused on muscle, one of the most important tissues in the regenerating limb. However, the team is already investigating whether senescent cell signaling also contributes to the regeneration of other tissues.

Lessons From the Salamanders

Yun’s group is working with salamanders to study regeneration and aging processes. “Salamanders are one of the few animal species that seem to defy the natural aging process. They do not develop typical signs of aging and do not accumulate age-related diseases such as cancer. They also have extraordinary healing abilities,” says Dr. Yun. The animals can regenerate almost any organ in their body.

Studying salamanders is helping Dr. Yun and her colleagues at the CRTD understand the principles of the regeneration process and, in the long run, may help solve the puzzle of why humans have very limited regenerative abilities.

Reference: “Senescent cells enhance newt limb regeneration by promoting muscle dedifferentiation” by Hannah E. Walters, Konstantin E. Troyanovskiy, Alwin M. Graf and Maximina H. Yun, 6 April 2023, Aging Cell.
DOI: 10.1111/acel.13826

See also  The antidote to aging? Critical role of HKDC1 in maintaining cell youth