Maintenance of immunological memory has been proposed to rely on stem-cell-like lymphocytes. However, data supporting this hypothesis are focused on the developmental potential of lymphocyte populations and are thus insufficient to establish the functional hallmarks of stemness. Here, we investigated self-renewal capacity and multipotency of individual memory lymphocytes by in vivo fate mapping of CD8(+) T cells and their descendants across three generations of serial single-cell adoptive transfer and infection-driven re-expansion. We found that immune responses derived from single naive T (Tn) cells, single primary, and single secondary central memory T (Tcm) cells reached similar size and phenotypic diversity, were subjected to comparable stochastic variation, and could ultimately reconstitute immunocompetence against an otherwise lethal infection with the bacterial pathogen Listeria monocytogenes. These observations establish that adult tissue stem cells reside within the CD62L(+) Tcm cell compartment and highlight the promising therapeutic potential of this immune cell subset.
The acquisition of pathogen-derived antigen by dendritic cells (DCs) is a key event in the generation of cytotoxic CD8(+) T cell responses. In mice, the intracellular bacterium Listeria monocytogenes is directed from the blood to splenic CD8α(+) DCs. We report that L. monocytogenes rapidly associated with platelets in the bloodstream in a manner dependent on GPIb and complement C3. Platelet association targeted a small but immunologically important portion of L. monocytogenes to splenic CD8α(+) DCs, diverting bacteria from swift clearance by other, less immunogenic phagocytes. Thus, an effective balance is established between maintaining sterility of the circulation and induction of antibacterial immunity by DCs. Other gram-positive bacteria also were rapidly tagged by platelets, revealing a broadly active shuttling mechanism for systemic bacteria.
Key Points• Lowest numbers of ex vivo-selected CD8 1 memory T cells can reconstitute pathogen-specific immunity in immunocompromised hosts.Patients undergoing allogeneic hematopoietic stem cell transplantation (allo-HSCT) are threatened by potentially lethal viral manifestations like cytomegalovirus (CMV) reactivation. Because the success of today's virostatic treatment is limited by side effects and resistance development, adoptive transfer of virus-specific memory T cells derived from the stem cell donor has been proposed as an alternative therapeutic strategy. In this context, dose minimization of adoptively transferred T cells might be warranted for the avoidance of graft-versus-host disease (GVHD), in particular in prophylactic settings after T-cell-depleting allo-HSCT protocols. To establish a lower limit for successful adoptive T-cell therapy, we conducted low-dose CD8 1 T-cell transfers in the well-established murine Listeria monocytogenes (L.m.) infection model. Major histocompatibility complex-Streptamer-enriched antigen-specific CD62L hi but not CD62L lo CD8 1 memory T cells proliferated, differentiated, and protected against L.m. infections after prophylactic application. Even progenies derived from a single CD62L hi L.m.-specific CD8 1 T cell could be protective against bacterial challenge. In analogy, low-dose transfers of Streptamerenriched human CMV-specific CD8 1 T cells into allo-HSCT recipients led to strong pathogen-specific T-cell expansion in a compassionate-use setting. In summary, low-dose adoptive T-cell transfer (ACT) could be a promising strategy, particularly for prophylactic treatment of infectious complications after allo-HSCT. (Blood. 2014;124(4):628-637)
T cell activation is a cornerstone in manufacturing of T cell-based therapies, and precise control over T cell activation is important in the development of the next generation T-cell based therapeutics. This need cannot be fulfilled by currently available methods for T cell stimulation, in particular not in a time dependent manner. Here, we describe a modular activation reagent called Expamers, which addresses these limitations. Expamers are versatile stimuli that are intended for research and clinical use. They are readily soluble and can be rapidly bound and removed from the cell surface, allowing nearly instantaneous initiation and termination of activation signal, respectively. Hence, Expamers enable precise regulation of T cell stimulation duration and provide promise of control over T cell profiles in future products. Expamers can be easily adopted to different T cell production formats and have the potential to increase efficacy of T cell immunotherapeutics.
No abstract
Adoptive cell therapy using gene-modified T cells has demonstrated promising clinical outcomes in hematologic malignancies. Production of gene-modified T cells involves the selection of patient T cells, activation via stimulation through the endogenous T cell receptor (TCR) complex and a costimulatory domain, followed by introduction of a tumor antigen-specific TCR or chimeric antigen receptor (CAR) through gene modification. Here we characterize a soluble T cell stimulation reagent, known as an ExpamerTM reagent, in the production of therapeutic CAR T cells. The Expamer reagent used in these studies is designed to be a late-stage clinical and commercial manufacturing ancillary material with two important attributes that make it highly attractive from a manufacturing and regulatory standpoint; it is a soluble and dissociable reagent. These attributes increase the ease of both introduction and removal from the manufacturing process, giving products manufactured with this reagent consistent product quality and purity. This reagent activates T cells through the simultaneous engagement of the TCR-CD3 complex and the costimulatory receptor CD28 and is compatible with manufacturing of both current and next-generation therapeutics. Purified healthy donor T cells cultured in the presence of the Expamer reagent rapidly fluxed Ca2+, demonstrating the capacity to induce early TCR signaling. Activation through this reagent additionally promotes upregulation of the cell surface activation marker CD25 and proliferation as measured by CFSE dilution. Following stimulation with this reagent, T cells are readily transduced with a CD19-specific CAR construct. The function of CAR T cells generated with this reagent was measured by effector cytokine production, proliferation, and cytolytic activity in the presence of CD19 expressing and control target cells in vitro. CAR T cells robustly produced IFN-ɣ and IL-2 after activation with a CAR specific antigen. In addition, proliferation in the presence of CD19 expressing target cells was observed as measured by CFSE dilution. Finally, significant cytolytic activity against CD19-expressing target cells was observed. Collectively, these data provide evidence that functional engineered T cells can be manufactured using the Expamer reagent and support implementation into the production of both current and next-generation therapeutic gene-modified T cells. The first two authors contributed equally to this work. Disclosures Bashour: Juno Therapeutics: Employment. Larson:Juno Therapeutics: Employment. Graef:Juno Therapeutics: Employment. Stemberger:Juno Therapeutics: Employment. Lothar:Juno Therapeutics: Employment. Odegard:Juno Therapeutics: Employment. Ramsborg:Juno Therapeutics: Employment.
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