Characterization of regulatory T cell expansion for manufacturing cellular immunotherapies.

Regulatory T cells (Tregs) are critical mediators of peripheral immune tolerance. Tregs suppress immune activation against self-antigens and are the focus of cell-based therapies for autoimmune diseases. However, Tregs circulate at a very low frequency in blood, limiting the number of cells that can be isolated by leukapheresis. To effectively expand Tregsex vivo for cell therapy, we report the metabolic modulation of T cells using mono-(6-amino-6-deoxy)-ß-cyclodextrin (ßCD-NH2) encapsulated rapamycin (Rapa). Encapsulating Rapa in ß-cyclodextrin increased its aqueous solubility ∼154-fold and maintained bioactivity for at least 30 days. ßCD-NH2-Rapa complexes (CRCs) enriched the fraction of CD4+CD25+FoxP3+ mouse T (mT) cells and human T (hT) cells up to 6-fold and up to 2-fold respectively and suppressed the overall expansion of effector T cells by 5-fold in both species. Combining CRCs and transforming growth factor beta-1 (TGF-ß1) synergistically promoted the expansion of CD4+CD25+FoxP3+ T cells. CRCs significantly reduced the fraction of pro-inflammatory interferon-gamma (IFN-γ) expressing CD4+ T cells, suppressing this Th1-associated cytokine while enhancing the fraction of IFN-γ- tumor necrosis factor-alpha (TNF-α) expressing CD4+ T cells. We developed a model using kinetic rate equations to describe the influence of the initial fraction of naïve T cells on the enrichment of Tregsin vitro. The model related the differences in the expansion kinetics of mT and hT cells to their susceptibility for immunophenotypic modulation. CRCs may be an effective and potent means for phenotypic modulation of T cells and the enrichment of Tregsin vitro. Our findings contribute to the development of experimental and analytical techniques for manufacturing Treg based immunotherapies.

Applications of molecular engineering in T-cell-based immunotherapies.

Harnessing an individual's immune cells to mediate antitumor and antiviral responses is a life-saving option for some patients with otherwise intractable forms of cancer and infectious disease. In particular, T-cell-based engineered immune cells are a powerful new class of therapeutics with remarkable efficacy. Clinical experience has helped to define some of the major challenges for reliable, safe, and effective deployment of T-cells against a broad range of diseases. While poised to revolutionize immunotherapy, scalable manufacturing, safety, specificity, and the development of resistance are potential roadblocks in their widespread usage. The development of molecular engineering tools to allow for the direct or indirect engineering of T-cells to enable one to troubleshoot delivery issues, amplify immunomodulatory effects, integrate the synergistic effects of different molecules, and home to the target cells in vivo. In this review, we will analyze thus-far developed cell- and material-based tools for enhancing T-cell therapies, including methods to improve safety and specificity, enhancing efficacy, and overcoming limitations in scalable manufacturing. We summarize the potential of T-cells as immune modulating therapies and the potential future directions for enabling their adoption for a broad range of diseases. This article is categorized under: Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease Nanotechnology Approaches to Biology > Cells at the Nanoscale.