Browsing by Author "Schuh, Christina"

Now showing 1 - 2 of 2
  • Thumbnail Image
    Item
    Extracellular Vesicles derived from Apis mellifera Royal Jelly promote wound healing by modulating inflammation and cellular responses
    (2022) Álvarez, Simón; Contreras Kallens, Pamina; Aguayo Paul, Sebastián; Ramírez, Orlando; Vallejos, Catalina; Ruiz, Jorge; Carrasco Gallardo, Eva; Troncoso Vera, Stephanie; Morales, Bernardo; Schuh, Christina
    Apis mellifera Royal Jelly (RJ) is a well-known remedy in traditional medicine around the world and its versatile effects range from antibacterial to anti-inflammatory properties and pro-regenerative properties. Several active compounds have been identified, however, the mechanisms of action still remain widely unknown. As a glandular product, RJ has been shown to contain a substantial number of extracellular vesicles (EVs) and in this study, we aimed to investigate the extent of involvement of RJEVs in wound healing associated effects. Molecular analysis of RJEVs verified the presence of important conserved exosomal markers such as CD63 and syntenin, as well as cargo molecules MRJP1, defensin-1 and jellein-3. RJEV internalization analysis demonstrated the involvement of membrane fusion as well as macropinocytosis or clathrin-dependent endocytosis into mammalian cells. Furthermore, RJEVs have demonstrated to modulate MSCs differentiation and secretome, as well as decrease LPS-induced inflammation in RAW 264.7 macrophages by blocking the MAPK pathway. In vivo studies confirmed anti-bacterial effects of RJEVs, and demonstrated an acceleration of wound healing in a splinted mouse model. Summarizing, this study suggests that RJEVs of potentially exosomal origin play a crucial role in the known effects of RJ by modulating the inflammatory phase and cellular response in wound healing.
  • No Thumbnail Available
    Item
    Royal Jelly Derived Extracellular Vesicles Modulate Microglial Nanomechanics and Inflammatory Responses
    (2025) Zavala, Gabriela; Berríos, Pablo; Sandoval, Felipe; Bravo, Graciela; Barrera, Nelson P.; Alarcón Moyano, Jéssica; Díaz Calderón, Paulo; Aguayo, Sebastián; Schuh, Christina
    BACKGROUND Microglia, the braińs resident immune cells, undergo profound mechanical and functional changes upon activation contributing to neuroinflammation, a pathological signature of many neurological diseases. Thus, new anti-inflammatory treatment options are needed that tackle these mechanobiological alterations in microglia, which remain strongly understudied. In this context, extracellular vesicles (EVs) are crucial mediators of intercellular and interkingdom communication, yet their influence on the mechanobiological properties of recipient cells remains largely unknown. Honeybee-derived Royal Jelly EVs (RJEVs) have demonstrated remarkable anti-inflammatory properties, but their impact on microglial cellular nanomechanics and uptake mechanisms remains unclear. RESULTS In this study, we used a multi-disciplinary approach to analyze the resulting biological and nanomechanical changes following the activation of human microglia and the potential effect of RJEV treatment on these mechanobiological parameters. We observed that LPS treatment was associated with decreased cellular Young’s modulus, increased membrane fluidity, and enhanced motility of microglia, indicating a more migratory and pro-inflammatory phenotype. Additionally, LPS exposure altered cellular EV uptake mechanisms by shifting preference from an equilibrium of four mechanisms to the predominance of macropinocytosis and clathrin-dependent endocytosis. Remarkably, RJEV treatment counteracted these mechanobiological changes by, in turn, increasing microglial stiffness, reducing motility, and decreasing secretion of pro-inflammatory cytokines. CONCLUSION This is the first study to demonstrate that microglial activation state dictates EV uptake mechanisms and to establish a direct link between inflammation, cellular and membrane mechanics, and EV-mediated modulation. Our findings highlight RJEVs as promising candidates for regulating neuroinflammation by targeting microglial mechanobiology as well as opening new strategies for EV-based therapeutics