Reduced Mechanical Stimulation in Aged Bone Marrow Contributes to Cell Dysfunction
Cells react to physical forces placed upon them, and changes in the character of those forces will tend to result in altered cell behavior. Cells in a three dimensional extracellular matrix do not behave in the same way as cells in a petri dish. Further, the extracellular matrix in aged tissues differs from that in young tissues in ways that can meaningfully affect its material properties, and thus the forces placed on cells within that matrix. Researchers here demonstrate that some fraction of the undesirable changes occurring in cells within bone tissue are the result of reduced mechanical stimulation. Vibration to induce that mechanical stimulation can restore some of the lost function in aged mice.
Emerging evidence highlights a critical role for mechanical signaling in modulating transcriptional and epigenetic processes. Bone marrow mesenchymal stem/stromal cells (BMSCs) are embedded in a dynamic microenvironment where they continuously perceive and respond to mechanical cues, affecting cellular traction force and directing cell behavior. Aging significantly alters the physical properties of the bone microenvironment, disrupting the mechanical signals transmitted to cells.
In this work, we show that aging reduces intracellular traction forces in BMSCs and aged bone tissue, a deficiency that can be reversed in vitro and in vivo through appropriate mechanical stimulation to restore the cell mechanics. Mechanistically, the restoration of cellular traction force enhances chromatin accessibility, leading to the activation of FOXO1 expression. Importantly, FOXO1 knockdown abolished the mechanically rejuvenating effects, underscoring its critical role in mediating cellular responses to mechanical forces.
Beyond bone recovery, mechanical interventions (vibrational loading) in aged mice improved locomotor activity, alleviated physical frailty, and reduced systemic inflammation. These findings highlight both local and systemic benefits of mechanical stimulation, offering a straightforward approach with significant translational potential for combating age-related tissue decline.