Exosome Cell Origin Affects In Vitro Markers of Tendon Repair in Ovine Macrophages and Tenocytes.

Tendon injuries and disease are resistant to surgical repair; thus, adjunct therapies are widely investigated, especially mesenchymal stromal cells (MSCs) and, more recently, their extracellular vesicles (MSCdEVs), for example, exosomes. Thought to act on resident and infiltrating immune cells, the role of MSCdEVs in paracrine signaling is of great interest. This study investigated how MSCdEVs differ from analogs derived from resident (tenocyte) populations (TdEV). As macrophages play a significant role in tendon maintenance and repair, macrophage signaling was compared by cytokine quantification using a multiplexed immunoassay and tenocyte migration by in vitro scratch-wound analysis. TdEV-treated macrophages decreased IL-1 and increased MIP-1 and CXCL8 expression. In addition, macrophage signaling favored collagen synthesis and tenocyte bioactivity, while reducing proangiogenic signaling when TdEVs were used in place of MSCdEVs. These in vitro data demonstrate a differential influence of exosomes on macrophage signaling, according to cell source, supporting that local cell-derived exosomes may preferentially drive healing by different means with possible different outcomes compared to MSCdEVs. Impact Statement Adipose-derived mesenchymal stromal cell (AdMSC) exosomes (EVs) can improve tendon mechanical resilience, tissue organization, and M2 macrophage phenotype predominance in response to tendon injury. This active area of investigation drives great interest in the function of these exosomes as adjunct therapies for tendon disease, particularly rotator cuff tendinopathy. However, little is known about the effects of EVs as a function of cell source, nor regarding their efficacy in preclinical translational ovine models. Herein we demonstrate a differential effect of exosomes as a function of cell source, tenocyte compared to AdMSCs, on macrophage signaling and tenocyte migration of ovine cells.

Evaluation of growth, viability, and structural integrity of equine endometrial organoids following cryopreservation.

Reproductive diseases in mares are a significant cause of subfertility and profound economic loss in the equine industry. Utilizing a 3D in vitro cell culture system that recapitulates the in vivo physiology will reduce time, cost, and welfare concerns associated with in vivo reproductive research in mares. If this 3D model is combined with effective cryopreservation, reproductive research on mares can occur year-round, which is not currently possible in this seasonal species. Endometrial organoids, 3D in vitro cell clusters that exhibit in vivo uterine physiology, have been established in mice, women, and mares. Here we report the first comprehensive assessment of cryopreservation of endometrial organoids in the domestic mare. Organoid growth rate was not affected by the type of freezing media. However, growth rate varied among non-cryopreserved controls, organoids cryopreserved at passage 0 (P0), and organoids cryopreserved at passage 3 (P3). Additionally, there was no difference in organoid viability among freezing media or freezing timepoint (passages). Furthermore, fresh and frozen-thawed organoids displayed positive immunohistochemical staining for ZO-1, which is a marker for intercellular tight junctions, and for periodic acid-Schiff staining as marker for organoid function through mucin production. Results demonstrate that equine endometrial organoids can be cryopreserved with 10% dimethyl sulfoxide with minimal detrimental effects while maintaining intercellular tight junctions (ZO-1) and secretory function. Availability of cryopreserved endometrial organoids may permit expanded research on uterine pathologies that negatively affect mare fertility and improve efficiency, reduce cost, and minimize animal welfare concerns associated with in vivo research in the domestic mare.