The Senescence‐associated Secretome of Fat Cells Drives Inflammation and Insulin Resistance and Inhibits the Proliferation of Human Skeletal Muscle Cells

Infiltration of fat cells into skeletal muscle is a hallmark of aging that has been associated with insulin resistance and the pathogenesis of type 2 diabetes mellitus (T2DM). The mechanisms by which fat cells affect the health and metabolic state of skeletal muscle are poorly understood. Given the evidence for cross‐talk between these tissues and the secretory phenotype of senescent preadipocytes, we first utilized real time‐PCR to examine the expression of inflammatory cytokines in primary human skeletal muscle‐derived cells (SkMDCs) in response to conditioned medium (CM) from either control human preadipocytes (Normal CM) or from human preadipocytes driven to senescence by irradiation (Senescent CM). Exposure of SkMDCs to either Normal CM or Senescent CM for 24 hours significantly increased their expression of IL‐6 (5.1±1.7‐and 14.1±4.7‐fold, respectively), TNFα (1.3±0.2‐and 2.1±0.67‐fold, respectively) and MCP‐1 (2.9±1.1‐and 6.8±2.3‐fold, respectively). Next, we investigated the effects of CM on insulin signaling in SkMDCs via Western blot analysis. Exposure of SKMDCs to preadipocyte CM significantly blunted insulin‐stimulated phosphorylation of its downstream effectors, including Akt (14–24%, p<0.05). Finally, we examined the effects of CM on the proliferative capacity of undifferentiated SkMDCs. Senescent CM inhibited SkMDC proliferation by more than 30% (p < 0.05). In conclusion, factors secreted by preadipocytes, and in particular, senescent preadipocytes, negatively impact the inflammatory and metabolic phenotype and the proliferative capacity of skeletal muscle cells. Elucidation of the biologic materials that are secreted from fat cells and mediate these effects may lead to novel therapeutic strategies for the treatment of age‐related conditions, including T2DM. The authors acknowledge the support of Mayo Clinic and a generous gift from Robert and Arlene Kogod.