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J. Villena-Vargas
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ORAL 28 - T Cell Therapy for Lung Cancer (ID 132)
- Event: WCLC 2015
- Type: Oral Session
- Track: Biology, Pathology, and Molecular Testing
- Presentations: 2
- Moderators:P.S. Adusumilli, E. Smit
- Coordinates: 9/08/2015, 16:45 - 18:15, Four Seasons Ballroom F1+F2
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ORAL28.02 - Mesothelin-Targeted CAR T-Cell Therapy for the Treatment of Heterogeneous Antigen-Expressing Lung Adenocarcinoma (ID 3172)
16:45 - 18:15 | Author(s): J. Villena-Vargas
- Abstract
Background:
Adoptive T-cell therapy using chimeric antigen receptors (CAR) is an emerging strategy by redirecting T-cell effector functions against a cancer cell-surface antigen. To target lung adenocarcinoma (ADC) by CAR T-cell therapy, our laboratory has identified mesothelin (MSLN), a cell-surface antigen based on our published observation that MSLN is expressed in 60% of primary and metastatic lung ADC and is associated with tumor aggressiveness. Unlike hematological malignancies where CAR T-cell therapy has been successful targeting CD19, a cell-surface antigen that is uniformly expressed on B cells, MSLN expression intensity and distribution among lung ADC tumors is heterogeneous. The efficacy of CAR T-cell therapy in a heterogeneous antigen microenvironment is unknown. We hypothesized that the MSLN-targeted CAR T cells will be effective against high-antigen expressing lung ADC cells and the presence of even a small proportion of high MSLN expressing cells can enhance CAR T-cell cytotoxicity against low-antigen expressing lung ADC cells.
Methods:
Human peripheral blood T cells were retrovirally transduced with a 2[nd] generation of CAR targeting MSLN and bearing CD28 and CD3zeta activation domains. In vitro, we analyzed CAR T-cell cytotoxicity ([51]Cr release assay), effector cytokine secretion (Luminex assay), and proliferation (cell-counting assay) against lung ADC cell lines expressing variable levels of MSLN. In vivo, antitumor efficacy was evaluated by median survival and tumor bioluminescence (BLI) in mice bearing established homogeneous or heterogeneous lung ADC tumors.
Results:
In in vitro assays utilizing lung ADC cells with variable level of MSLN expression [low-antigen expression (EKVX or A549) or high-antigen expression (A549M and H1299M), control lung fibroblast (MRC5) or mesothelial cells (MET5A)], CAR T cells exhibit antigen-specific cytolytic activity, effector cytokine secretion and proliferation in proportion to the MSLN expression on cancer cells. In vivo, a single low dose of CAR T cells eradicates primary and metastatic established tumor expressing high-level of MSLN and prolongs tumor free survival (41 days vs not reached, p<0.0001). We next evaluated CAR T-cell efficacy in heterogeneous antigen microenvironment by mixing low and high antigen-expressing cells (A549 expressing firefly luciferase/A549M) and assessed the A549 tumor burden only by bioluminescence imaging. In the presence of A549M cells, CAR T cells are able to prolong progression-free survival of A549 tumor burden (22 days vs 0 days in absence of A549M cells). Further mechanistic studies demonstrated that CAR T cells lysed an additional 5%-15% A549 or EKVX cells in the presence of H1299M or A549M cells (p<0.05) without off-target cytotoxicity. Antigen-activated CAR T cells were effective against low-antigen expressing lung ADC cells without the need for high-antigen expressing cells in the coculture.
Conclusion:
Our results provide scientific rationale to translate MSLN-targeted CAR T-cell therapy for the treatment of the primary and metastatic lung ADC. A phase I clinical trial (NCT02414269) that includes lung ADC patients is initiated at our center.
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ORAL28.04 - Tumor-Targeted Radiation Therapy Helps Overcome the Solid Tumor T-Cell Infiltration Barrier and Promotes Mesothelin CAR T-Cell Therapy (ID 3142)
16:45 - 18:15 | Author(s): J. Villena-Vargas
- Abstract
Background:
Translating recent chimeric antigen receptor (CAR) T-cell therapy successes in hematologic malignancies to solid cancers requires overcoming barriers unique to solid tumors such as inadequate tumor infiltration, proliferation, and persistence. Our laboratory has published the rationale to target mesothelin (MSLN), a cell-surface antigen expressed in the majority of thoracic malignancies. We hypothesized that the immune modulating effects of low-dose radiation therapy (RT) would enhance the infiltration and proliferation of mesothelin-targeted CAR T-cell therapy for thoracic cancers, thereby achieving long-term tumor eradication.
Methods:
Using human T cells retrovirally transduced to express mesothelin-targeted CARs, we evaluated T-cell cytotoxicity by chromium release assay, proliferation by cell count assay, cytokine-release by multiplex ELISA, phenotype by flow cytometry, and chemokine receptor profiles by PCR against MSLN-expressing mesothelioma and lung cancer cell lines with and without localized RT. In clinically relevant mouse models (NOD/SCID gamma mice) with established MSLN-expressing tumors, we monitored therapy response, T-cell kinetics and anti-tumor efficacy by utilizing bioluminescent imaging (BLI), and conducted flow cytometric analysis of splenic/peripheral blood T cells for characterization of CAR T-cell effector phenotype.
Results:
RT did not enhance CAR T-cell cytotoxicity. In vitro, RT enhanced CAR T-cell migration in chemotactic assays, and correlatively induced the secretion of chemokines by tumor cells (Fig.1A). In vivo, RT resulted in dose dependent chemokine secretion with robust early intratumoral CAR T-cell accumulation (p<0.05, Fig.1B) as demonstrated by T-cell BLI. Ex vivo tumor analysis by flow cytometry on day 7 post T-cell administration confirmed that RT increased early infiltration and proliferation (p<0.05). Also, single low-dose RT potentiated the efficacy of systemically administered CAR T cells (median survival 30d vs. 79d, p= 0.02) with at least 50% tumor eradication up to 100 days even with a 30-fold decreased dose (Fig.1C&D). Furthermore, in mice with tumor eradication, harvested spleen T-cell analysis at day 56 demonstrated a greater number of persisting CAR T cells in mice treated with RT (p=0.02, Fig.1E).Figure 1
Conclusion:
Our data provides the rationale to use localized RT as a preconditioning regimen prior to CAR T-cell administration in a clinical trial for thoracic malignancies. Furthermore, our mechanistic observation of RT-induced, chemokine-mediated, enhanced T-cell infiltration may also assist the trafficking of endogenous anti-tumor T cells, thereby shifting the balance towards a cohesive anti-tumor immune microenvironment.
