Researchers at Bar-Ilan University have successfully restored youthful patterns of DNA organization in the livers of old mice, reversing key molecular features associated with aging. The study, published in Nature Communications, identifies the protein SIRT6 as a powerful protector against age-related breakdown in chromatin, the complex system that packages DNA and controls how genes are switched on and off.

The findings suggest that aging is not simply a passive process of wear and tear, but may be driven in part by reversible changes in the way DNA is organized inside cells.

DNA inside cells is tightly folded and packaged into chromatin, a structure that acts like a biological control system for gene activity. Using advanced tools to study DNA organization and gene activity, the researchers examined multiple molecular changes in the livers of young and old mice. What they discovered was dramatic: aging disrupts chromatin architecture in the liver, causing inflammatory pathways to become overactive while weakening the metabolic programs that define healthy liver tissue.

Emerging evidence suggests that organs age at different rates. This study identifies a mechanism by which the naturally hypoxic intervertebral disc ages relatively slowly, via selective autophagy of HIF-1α, and designs a small molecule to export this mechanism across tissues.

Losing muscle strength is a natural part of aging. At the core of this decline is a drop in the number of muscle stem cells (MuSCs), the specialized cells responsible for maintaining and regenerating muscle tissue throughout our lives. Loss of muscle strength can severely affect mobility, increasing the risk of falls, fractures and, most importantly, the loss of independence.

Published in Nature Aging, a recent study took a crucial first step toward restoring stem cell function in aging muscles—gaining a clearer understanding of how metabolism changes when stem cells are activated and how these critical processes weaken with age.

The researchers’ investigation led them to glutamine metabolism, the process by which cells use the amino acid glutamine to support essential functions. They found that for MuSCs, glutamine is more than just a nutrient. It provides the raw material needed to produce fatty acids that help cells grow, divide, and repair damaged muscles.