Purpose: HumanTcells targeted to the B cell^specific CD19 antigen through retroviral-mediated transfer of a chimeric antigen receptor (CAR), termed 19z1, have shown significant but partial in vivo antitumor efficacy in a severe combined immunodeficient (SCID)-Beige systemic human acute lymphoblastic leukemia (NALM-6) tumor model. Here, we investigate the etiologies of treatment failure in this model and design approaches to enhance the efficacy of this adoptive strategy. Experimental Design: A panel of modified CD19-targeted CARs designed to deliver combined activating and costimulatory signals to theT cell was generated and tested in vitro to identify an optimal second-generation CAR. Antitumor efficacy of Tcells expressing this optimal costimulatory CAR, 19-28z, was analyzed in mice bearing systemic costimulatory ligand-deficient NALM-6 tumors. Results: Expression of the 19-28z CAR, containing the signaling domain of the CD28 receptor, enhanced systemic T-cell antitumor activity when compared with 19z1 in treated mice. A treatment schedule of 4 weekly T-cell injections, designed to prolong in vivo T-cell function, further improved long-term survival. Bioluminescent imaging of tumor in treated mice failed to identify a conserved site of tumor relapse, consistent with successful homing by tumor-specific T cells to systemic sites of tumor involvement. Conclusions: Both in vivo costimulation and repeated administration enhance eradication of systemic tumor by genetically targeted T cells. The finding that modifications in CAR design as well asT-cell dosing allowed for the complete eradication of systemic disease affects the design of clinical trials using this treatment strategy.
Adoptive cell therapy with genetically modified T cells expressing a chimeric antigen receptor (CAR) is a promising therapy for patients with B-cell acute lymphoblastic leukemia. However, CAR-modified T cells (CAR T cells) have mostly failed in patients with solid tumors or low-grade B-cell malignancies including chronic lymphocytic leukemia with bulky lymph node involvement. Herein, we enhance the antitumor efficacy of CAR T cells through the constitutive expression of CD40 ligand (CD40L, CD154). T cells genetically modified to constitutively express CD40L (CD40L-modified T cells) demonstrated increased proliferation and secretion of proinflammatory TH1 cytokines. Further, CD40L-modified T cells augmented the immunogenicity of CD40(+) tumor cells by the upregulated surface expression of costimulatory molecules (CD80 and CD86), adhesion molecules (CD54, CD58, and CD70), human leukocyte antigen (HLA) molecules (Class I and HLA-DR), and the Fas-death receptor (CD95). Additionally, CD40L-modified T cells induced maturation and secretion of the proinflammatory cytokine interleukin-12 by monocyte-derived dendritic cells. Finally, tumor-targeted CD19-specific CAR/CD40L T cells exhibited increased cytotoxicity against CD40(+) tumors and extended the survival of tumor-bearing mice in a xenotransplant model of CD19(+) systemic lymphoma. This preclinical data supports the clinical application of CAR T cells additionally modified to constitutively express CD40L with anticipated enhanced antitumor efficacy.
Purpose: Most patients diagnosed with ovarian cancer will ultimately die from their disease. For this reason, novel approaches to the treatment of this malignancy are needed. Adoptive transfer of a patient's own T cells, genetically modified ex vivo through the introduction of a gene encoding a chimeric antigen receptor (CAR) targeted to a tumor-associated antigen, is a novel approach to the treatment of ovarian cancer. Experimental Design: We have generated several CARs targeted to the retained extracellular domain of MUC16, termed MUC-CD, an antigen expressed on most ovarian carcinomas. We investigate the in vitro biology of human T cells retrovirally transduced to express these CARs by coculture assays on artificial antigen-presenting cells as well as by cytotoxicity and cytokine release assays using the human MUC-CD+ ovarian tumor cell lines and primary patient tumor cells. Further, we assess the in vivo antitumor efficacy of MUC-CD–targeted T cells in SCID-Beige mice bearing peritoneal human MUC-CD+ tumor cell lines. Results: CAR-modified, MUC-CD–targeted T cells exhibited efficient MUC-CD–specific cytolytic activity against both human ovarian cell and primary ovarian carcinoma cells in vitro. Furthermore, expanded MUC-CD–targeted T cells infused through either i.p. injection or i.v. infusion into SCID-Beige mice bearing orthotopic human MUC-CD+ ovarian carcinoma tumors either delayed progression or fully eradicated disease. Conclusion: These promising preclinical studies justify further investigation of MUC-CD–targeted T cells as a potential therapeutic approach for patients with high-risk MUC16+ ovarian carcinomas. Clin Cancer Res; 16(14); 3594–606. ©2010 AACR.
We developed a novel approach to bioluminescent T cell imaging (BLI) using a membrane-anchored form of the Gaussia luciferase (GLuc) enzyme, termed extGLuc, which we could stably express in both mouse and human primary T cells. In vitro, extGLuc+ cells emitted significantly higher bioluminescent signal when compared to cells expressing GLuc, Renilla luciferase (RLuc), and membrane-anchored RLuc (extRLuc). In vivo, mouse extGLuc+ T cells exhibited higher bioluminescent signal when compared to GLuc+ and RLuc+ T cells. Application of this imaging approach to human T cells genetically modified to express tumor-specific chimeric antigen receptors (CARs) enabled us to demonstrate in vivo CAR-mediated T cell accumulation in tumor, T cell persistence over time, and concomitant imaging of T cells and tumor cells modified to express firefly luciferase (FFLuc). This sensitive imaging technology has application to many in vivo cell based studies in a wide array of mouse models.
The ability to genetically modify human T cells to target tumor antigens through retroviral gene transfer constitutes a potentially powerful approach to cancer immunotherapy. However, low transduction efficiencies may hamper the efficacy of such therapeutic strategies in the clinical setting. Most commonly, gammaretroviral gene transfer into T cells is conducted through spinoculation, that is, centrifugation of retroviral particles and T cells on RetroNectin-coated non-tissue culture vessels. Here we present data investigating the impact of temperature, speed, and frequency of spinoculation on T cell transduction efficiencies. We found that all three variables independently impacted gene transfer, with increasing temperature, speed, and frequency of spinoculation all enhancing the transduction of T cells. These improved conditions were additive, with the greatest proportion of transduced T cells being generated at the highest tested temperature and speed, after daily spinoculation for 2 to 3 days. Under these conditions, enhanced gene transfer was observed in T cells derived from healthy donors, using research-grade vector stocks. Whereas both RetroNectin and spinoculation were critical to optimal gene transduction, preloading of gammaretroviral particles before spinoculation did not enhance gene transfer. Significantly, application of these enhanced transduction conditions to T cells derived from previously treated patients with chronic lymphocytic leukemia allowed for adequate gene transfer under both small-scale and large-scale clinically applicable conditions using either preclinical or current Good Manufacturing Practice-grade gammaretroviral vector stocks.
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