Lenka V. Hurton

Membrane-bound IL-21 promotes sustained Ex Vivo proliferation of human natural killer cells

NK cells have therapeutic potential for a wide variety of human malignancies. However, because NK cells expand poorly in vitro, have limited life spans in vivo, and represent a small fraction of peripheral white blood cells, obtaining sufficient cell numbers is the major obstacle for NK-cell immunotherapy. Genetically-engineered artificial antigen-presenting cells (aAPCs) expressing membrane-bound IL-15 (mbIL15) have been used to propagate clinical-grade NK cells for human trials of adoptive immunotherapy, but ex vivo proliferation has been limited by telomere shortening. We developed K562-based aAPCs with membrane-bound IL-21 (mbIL21) and assessed their ability to support human NK-cell proliferation. In contrast to mbIL15, mbIL21-expressing aAPCs promoted log-phase NK cell expansion without evidence of senescence for up to 6 weeks of culture. By day 21, parallel expansion of NK cells from 22 donors demonstrated a mean 47,967-fold expansion (median 31,747) when co-cultured with aAPCs expressing mbIL21 compared to 825-fold expansion (median 325) with mbIL15. Despite the significant increase in proliferation, mbIL21-expanded NK cells also showed a significant increase in telomere length compared to freshly obtained NK cells, suggesting a possible mechanism for their sustained proliferation. NK cells expanded with mbIL21 were similar in phenotype and cytotoxicity to those expanded with mbIL15, with retained donor KIR repertoires and high expression of NCRs, CD16, and NKG2D, but had superior cytokine secretion. The mbIL21-expanded NK cells showed increased transcription of the activating receptor CD160, but otherwise had remarkably similar mRNA expression profiles of the 96 genes assessed. mbIL21-expanded NK cells had significant cytotoxicity against all tumor cell lines tested, retained responsiveness to inhibitory KIR ligands, and demonstrated enhanced killing via antibody-dependent cell cytotoxicity. Thus, aAPCs expressing mbIL21 promote improved proliferation of human NK cells with longer telomeres and less senescence, supporting their clinical use in propagating NK cells for adoptive immunotherapy.

Activating and Propagating Polyclonal Gamma Delta T Cells with Broad Specificity for Malignancies

Purpose: To activate and propagate populations of γδ T cells expressing polyclonal repertoire of γ and δ T-cell receptor (TCR) chains for adoptive immunotherapy of cancer, which has yet to be achieved. Experimental Design: Clinical-grade artificial antigen-presenting cells (aAPC) derived from K562 tumor cells were used as irradiated feeders to activate and expand human γδ T cells to clinical scale. These cells were tested for proliferation, TCR expression, memory phenotype, cytokine secretion, and tumor killing. Results: γδ T-cell proliferation was dependent upon CD137L expression on aAPC and addition of exogenous IL2 and IL21. Propagated γδ T cells were polyclonal as they expressed TRDV1, TRDV2-2, TRDV3, TRDV5, TRDV7, and TRDV8 with TRGV2, TRGV3F, TRGV7, TRGV8, TRGV9*A1, TRGV10*A1, and TRGV11 TCR chains. IFNγ production by Vδ1, Vδ2, and Vδ1negVδ2neg subsets was inhibited by pan-TCRγδ antibody when added to cocultures of polyclonal γδ T cells and tumor cell lines. Polyclonal γδ T cells killed acute and chronic leukemia, colon, pancreatic, and ovarian cancer cell lines, but not healthy autologous or allogeneic normal B cells. Blocking antibodies demonstrated that polyclonal γδ T cells mediated tumor cell lysis through combination of DNAM1, NKG2D, and TCRγδ. The adoptive transfer of activated and propagated γδ T cells expressing polyclonal versus defined Vδ TCR chains imparted a hierarchy (polyclonal>Vδ1>Vδ1negVδ2neg>Vδ2) of survival of mice with ovarian cancer xenografts. Conclusions: Polyclonal γδ T cells can be activated and propagated with clinical-grade aAPCs and demonstrate broad antitumor activities, which will facilitate the implementation of γδ T-cell cancer immunotherapies in humans. Clin Cancer Res; 20(22); 5708–19. ©2014 AACR.

Tethered IL-15 augments antitumor activity and promotes a stem-cell memory subset in tumor-specific T cells

Significance We describe an approach based on cytokine therapeutics to enhance the persistence and effectiveness of T-cell–based immunotherapies using chimeric antigen receptors (CARs). This strategy is effective without the use of high-dose exogenous cytokines that are typically associated with toxicities. Moreover, we report that the persistence of the least differentiated memory T cell, the T-memory stem cell, was promoted by signaling induced by a membrane-bound chimeric IL-15 cytokine-fusion molecule. These findings may contribute to improving the safety and therapeutic efficacy of CAR-based immunotherapies of patients with advanced cancer. Adoptive immunotherapy retargeting T cells to CD19 via a chimeric antigen receptor (CAR) is an investigational treatment capable of inducing complete tumor regression of B-cell malignancies when there is sustained survival of infused cells. T-memory stem cells (TSCM) retain superior potential for long-lived persistence, but challenges exist in manufacturing this T-cell subset because they are rare among circulating lymphocytes. We report a clinically relevant approach to generating CAR+ T cells with preserved TSCM potential using the Sleeping Beauty platform. Because IL-15 is fundamental to T-cell memory, we incorporated its costimulatory properties by coexpressing CAR with a membrane-bound chimeric IL-15 (mbIL15). The mbIL15-CAR T cells signaled through signal transducer and activator of transcription 5 to yield improved T-cell persistence independent of CAR signaling, without apparent autonomous growth or transformation, and achieved potent rejection of CD19+ leukemia. Long-lived T cells were CD45ROnegCCR7+CD95+, phenotypically most similar to TSCM, and possessed a memory-like transcriptional profile. Overall, these results demonstrate that CAR+ T cells can develop long-term persistence with a memory stem-cell phenotype sustained by signaling through mbIL15. This observation warrants evaluation in clinical trials.

Sleeping Beauty transposition of chimeric antigen receptors targeting receptor tyrosine kinase-like orphan receptor-1 (ROR1) into diverse memory T-cell populations

T cells modified with chimeric antigen receptors (CARs) targeting CD19 demonstrated clinical activity against some B-cell malignancies. However, this is often accompanied by a loss of normal CD19+ B cells and humoral immunity. Receptor tyrosine kinase-like orphan receptor-1 (ROR1) is expressed on sub-populations of B-cell malignancies and solid tumors, but not by healthy B cells or normal post-partum tissues. Thus, adoptive transfer of T cells specific for ROR1 has potential to eliminate tumor cells and spare healthy tissues. To test this hypothesis, we developed CARs targeting ROR1 in order to generate T cells specific for malignant cells. Two Sleeping Beauty transposons were constructed with 2nd generation ROR1-specific CARs signaling through CD3ζ and either CD28 (designated ROR1RCD28) or CD137 (designated ROR1RCD137) and were introduced into T cells. We selected for T cells expressing CAR through co-culture with γ-irradiated activating and propagating cells (AaPC), which co-expressed ROR1 and co-stimulatory molecules. Numeric expansion over one month of co-culture on AaPC in presence of soluble interleukin (IL)-2 and IL-21 occurred and resulted in a diverse memory phenotype of CAR+ T cells as measured by non-enzymatic digital array (NanoString) and multi-panel flow cytometry. Such T cells produced interferon-γ and had specific cytotoxic activity against ROR1+ tumors. Moreover, such cells could eliminate ROR1+ tumor xenografts, especially T cells expressing ROR1RCD137. Clinical trials will investigate the ability of ROR1-specific CAR+ T cells to specifically eliminate tumor cells while maintaining normal B-cell repertoire.

278. Next-Generation Non-Viral Gene Transfer to Redirect T-Cell Specificity

Non-viral gene transfer using the Sleeping Beauty (SB) transposon/transposase system has been successfully tested in humans to express a chimeric antigen receptor (CAR) to redirect T-cell specificity to CD19. This system has been modified to (i) improve the design of the CD19-specific CAR and (ii) reduce the time in culture to 14 days. Our previous clinical trials infused T cells expressing a 2nd generation CAR (designated CD19RCD28) with an IgG4-Fc stalk that activated via chimeric CD28 and CD3ζ. To evaluate the length of extracellular domain on function, we tested four CD19-specific CARs with two long [IgG4-Fc (CD19RCD28) and EQ (L235E and N297Q) mutant IgG4-Fc (CD19R*CD28)], medium (CD8α hinge, CD19RCD8CD28) and short (12aa IgG1 hinge, CD19R12aaCD28) stalks which all signaled through chimeric CD28 and CD3ζ endodomains. Generation of our T cells is based on electro-transfer of CARs coded by the SB system and antigen-specific stimulation through activating and K562-derived propagating cells (AaPC) in the presence of exogenous cytokines. After electro-transfer of SB-derived DNA plasmids, T cells were selectively propagated with either a new two-weekly (2x) or standard four-weekly (4x) additions of AaPC. All genetically modified T cells were capable of specific lysis of CD19+ tumor targets and producing IFN-γ in response to CD19+ stimulator cells. Serial killing was tested using massively parallel microscopy to observe single T cells and we observed that CDl9RCD8CD28+ T cells exhibited superior ability to partake in multiple killing events. CAR+ T cells were further tested in vivo for their ability to control CD19+ leukemia in a mouse model of minimal residual disease as well as established disease (Figure A and BFigure A and B). We found that T cells expressing modified CARs (CD19R*CD28, CD19RCD8CD28, CD19R12aaCD28) with reduced ability to bind to Fc gamma receptors (FcγR) were able to control leukemia more efficiently in mice compared to T cells expressing CD19RCD28. The CD19RCD8CD28 CAR was superior in controlling disease in the model of minimal residual disease compared with the CAR design evaluated in our prior clinical trials. T cells expressing CD19R*CD28 and CD19RCD8CD28 were then evaluated in 2x stimulation cycle. Both the 4x CAR+ T cells had similar CAR expression (>70%) whereas the 2x CAR+ T cells exhibited reduced CAR expression (~40%). The 2x CAR+ T cells expressed markers associated with less differentiated state of naive-like and memory T cells when compared to 4x CAR+ T cells, which was supported by measurement of mRNA species using bar-coded probes. The efficacy of the CAR+ T cells was tested in mice bearing established CD19+ leukemia and we observed superior survival in mice receiving the 2x CAR+ T cells compared with the 4x CAR+ T cells (Figure CFigure C). These data depict that length of extracellular domain and its associated binding to FcγR improves T-cell effector functions and that decreasing the time in culture can improve control of leukemia in vivo. These data support the use of cDl9RCD8CD28 testing in a next-generation clinical trial (IND# 16474).View Large Image | Download PowerPoint Slide