Genetically modified cells encapsulated in alginate-poly-L-lysine-alginate (APA) are being developed to deliver therapeutic products to treat a variety of diseases. The characterization of the encapsulated cells thus becomes paramount. This study reports a novel method to assess the viability, granularity and proliferation of encapsulated cells based on flow cytometry. The in vitro viability of encapsulated G8 murine myoblasts secreting canine FVIII (cFVIII) measured by flow cytometry was comparable to the traditional trypan blue exclusion method and both correlated with cFVIII secretion levels. In contrast, after implantation into mice, only viability measured by flow cytometry correlated with cFVIII secretion. Further, flow cytometry analysis of encapsulated cells maintained in vitro and in vivo revealed a greater fraction of granular cells compared to free cells, suggesting that encapsulation influences the morphology (cytoplasmic composition) of cells within APA microcapsules. Interestingly, the proliferation study showed that encapsulated cells proliferate faster, on average, and were more heterogeneous in vivo compared to in vitro culture conditions, suggesting that encapsulated cell proliferation is complex and environment-dependent. In conclusion, we show that flow cytometry analysis allows for a more consistent and comprehensive examination of encapsulated cells to aid in the development of cell therapy protocols.
The immune response to allogeneic cells in tissue-engineered constructs is a major barrier to their successful application in the treatment of many human diseases. Specifically, the T cell-mediated immune response, initiated through the recognition of cell surface MHCI molecules, is the primary cause of acute cellular allograft rejection. In this study, we altered expression of MHCI through viral immunomodulatory mechanisms to examine whether allogeneic cells could be made to 'mimic' viral evasion of a host CTL response. We demonstrate the successful application of a retroviral vector in vitro to overexpress the Kaposi's sarcoma-associated herpesvirus immunomodulatory protein, MIR2, in human monocyte-like myeloid progenitor cells. This approach led to differential downregulation of cell surface MHCI, ICAM-1 and B7-2 molecules. We also demonstrate that downregulation of immunoactive molecules has the functional effect of significantly reducing T cell-mediated cytotoxicity without altering NK-mediated cytotoxicity in vitro. These results provide proof-of-concept that viral immune evasion strategies allow cell-based tissue-engineered constructs to delay or even prevent acute cellular immune rejection in vivo. Importantly, this methodology could facilitate the development of universal donor cells for tissue engineering applications.
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