Paediatrics (RCH) - Research Publications

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Author: Trapani, Joseph × Author: Darcy, Phillip ×

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    TSTEM-like CAR-T cells exhibit improved persistence and tumor control compared with conventional CAR-T cells in preclinical models
    Meyran, D ; Zhu, JJ ; Butler, J ; Tantalo, D ; MacDonald, S ; Nguyen, TN ; Wang, M ; Thio, N ; D'Souza, C ; Qin, VM ; Slaney, C ; Harrison, A ; Sek, K ; Petrone, P ; Thia, K ; Giuffrida, L ; Scott, AM ; Terry, RL ; Tran, B ; Desai, J ; Prince, HM ; Harrison, SJ ; Beavis, PA ; Kershaw, MH ; Solomon, B ; Ekert, PG ; Trapani, JA ; Darcy, PK ; Neeson, PJ (AMER ASSOC ADVANCEMENT SCIENCE, 2023-04-05)
    Patients who receive chimeric antigen receptor (CAR)-T cells that are enriched in memory T cells exhibit better disease control as a result of increased expansion and persistence of the CAR-T cells. Human memory T cells include stem-like CD8+ memory T cell progenitors that can become either functional stem-like T (TSTEM) cells or dysfunctional T progenitor exhausted (TPEX) cells. To that end, we demonstrated that TSTEM cells were less abundant in infused CAR-T cell products in a phase 1 clinical trial testing Lewis Y-CAR-T cells (NCT03851146), and the infused CAR-T cells displayed poor persistence in patients. To address this issue, we developed a production protocol to generate TSTEM-like CAR-T cells enriched for expression of genes in cell replication pathways. Compared with conventional CAR-T cells, TSTEM-like CAR-T cells had enhanced proliferative capacity and increased cytokine secretion after CAR stimulation, including after chronic CAR stimulation in vitro. These responses were dependent on the presence of CD4+ T cells during TSTEM-like CAR-T cell production. Adoptive transfer of TSTEM-like CAR-T cells induced better control of established tumors and resistance to tumor rechallenge in preclinical models. These more favorable outcomes were associated with increased persistence of TSTEM-like CAR-T cells and an increased memory T cell pool. Last, TSTEM-like CAR-T cells and anti-programmed cell death protein 1 (PD-1) treatment eradicated established tumors, and this was associated with increased tumor-infiltrating CD8+CAR+ T cells producing interferon-γ. In conclusion, our CAR-T cell protocol generated TSTEM-like CAR-T cells with enhanced therapeutic efficacy, resulting in increased proliferative capacity and persistence in vivo.
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    Chimeric Antigen Receptor T cell Therapy and the Immunosuppressive Tumor Microenvironment in Pediatric Sarcoma
    Terry, RL ; Meyran, D ; Fleuren, EDG ; Mayoh, C ; Zhu, J ; Omer, N ; Ziegler, DS ; Haber, M ; Darcy, PK ; Trapani, JA ; Neeson, PJ ; Ekert, PG (MDPI, 2021-09)
    Sarcomas are a diverse group of bone and soft tissue tumors that account for over 10% of childhood cancers. Outcomes are particularly poor for children with refractory, relapsed, or metastatic disease. Chimeric antigen receptor T (CAR T) cells are an exciting form of adoptive cell therapy that potentially offers new hope for these children. In early trials, promising outcomes have been achieved in some pediatric patients with sarcoma. However, many children do not derive benefit despite significant expression of the targeted tumor antigen. The success of CAR T cell therapy in sarcomas and other solid tumors is limited by the immunosuppressive tumor microenvironment (TME). In this review, we provide an update of the CAR T cell therapies that are currently being tested in pediatric sarcoma clinical trials, including those targeting tumors that express HER2, NY-ESO, GD2, EGFR, GPC3, B7-H3, and MAGE-A4. We also outline promising new CAR T cells that are in pre-clinical development. Finally, we discuss strategies that are being used to overcome tumor-mediated immunosuppression in solid tumors; these strategies have the potential to improve clinical outcomes of CAR T cell therapy for children with sarcoma.
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    EARLY-PHENOTYPE LEWIS Y CAR-T CELLS PERSIST BETTER IN VIVO AND INDUCE SOLID TUMOR REGRESSION IN COMBINATION WITH ANTI-PD1
    Meyran, D ; Zhu, J ; Butler, J ; Macdonald, S ; Tantalo, D ; Thio, N ; Sek, K ; Ekert, P ; Kershaw, M ; Trapani, J ; Darcy, P ; Neeson, P (BMJ PUBLISHING GROUP, 2020-11)
    Background Chimeric antigen receptor (CAR-T) cells are a promising new therapy for patients with cancer. However, in contrast to their success in B cell malignancies, CAR-T cells targeting solid cancers have had limited success so far due to their poor proliferation and poor long-term persistence in vivo. To address this issue, we used naïve T cells to generate second-generation CAR-T cells recognizing the tumor antigen Lewis Y (LeY), termed ‘early’ CAR-T cells. Methods Purified naïve T cells were activated by CD3/CD28 soluble tetrameric antibody complex, retrovirally transduced (LeY scFv-CD3z-CD28 CAR) and expanded in IL-7/IL-15. The early LeY CAR-T cell function was tested in vitro for cytotoxicity (Cr-release and degranulation), proliferation, and cytokine secretion by CBA, either de novo or following chronic stimulation for 1 month. Finally, early CAR-T cell persistence and anti-tumor efficacy was assessed in the OVCAR3-NSG model, in the presence or absence of anti-PD-1. Results The early-CAR-T cells comprised stem cell memory-like (CD95+, CD62L+, CD45RA+) and central memory phenotype (CD95+, CD62L+, CD45RA-) T cells with increased expression of ICOS, Ki67, TCF7 and CD27 (Figure 1). The early-CAR-T cells retained potent antigen-specific cytotoxicity, and secreted significantly higher levels of cytokines (IFN-?, TNF-a and IL-2) and increased proliferation compared to conventional CAR-T cells. Importantly, early-CAR-T cells had a significantly higher proliferative capacity after long-term chronic stimulation compared to conventional CAR-T cells (figure 2), and CD4+ CAR-T cells were critical for effective early CD8+ CAR-T cell proliferation capacity in vitro (figure 3). Early CAR-T cells had significantly better in vivo tumor control compared to conventional CAR-T cells (Figure 4), this was associated with increased CAR-T cell persistence. Because chronically stimulated early-LeY-CAR-T cells expressed PD-1 (figure 2), and OVCAR-3 cells expressed PD-L1 when co-cultured with LeY-CAR-T cells (figure 5), we combined early LeY-CAR-T cells with anti-PD-1 therapy and observed complete tumour regression in these mice. Interestingly, early LeY-CAR-T cell plus anti-PD-1 treatment also enhanced the percentage of circulating stem-cell memory like CAR-T cells in vivo (figure 5). Abstract 126 Figure 1Early-CAR-T protocol, including Naïve-T cells purification and expansion in IL-7 and IL-15 promotes the maintenance of a TSCM and TCM phenotype. A) Scheme of the 7-day production protocol for Early-CAR-T cells. B) Phenotype by FACs of the conventional CAR-T cells and the Early-CAR-T cells. Pooled data in triplicate for 6 donors. C) Phenotype by Mass cytometry comparing the Conventional-CAR-T cells vs Early-CAR-T cells vs Early-CD8-CAR-T cells. Data for one donor representative of 3 different donors Abstract 126 Figure 2Early-CAR-T cells are comparable in vitro to conventional CAR-T cells in terms of killing but have a better proliferation capacity that persists after chronic stimulation. The long-term stimulated early- CAR-T cells maintain their memory phenotype and upregulated PD-1. A) Chromium release assay against the LeY+ cell line (OVCAR3), data for one donor representative of 3 other donors. B) Cytokine secretion evaluated by CBA after coculture with the LeY+ cell line (OVCAR3) or with the LeY- cell line (MDA-MB435). C) Division index of CAR-T cells quantified with CTV. D) Evaluation of the differentiation, proliferation and cytotoxicity of the CAR-T cells after chronic stimulation Abstract 126 Figure 3Early-CD4+- CAR-T cells are critical for the proliferation capacity of the Early-CD8+-CAR-T cells. A) Scheme of the CD4-depletion protocol to compare Early-CD8-CAR-T proliferation with or without CD4-T cells. B) Division index of CD4-depleted Early-CAR-T cells, CD8-T cells from bulk Early-CAR-T cells, and from CD4+ T cells from bulk Early-CAR-T-cells quantified with CTV Abstract 126 Figure 4Early-CAR-T cells show in vivo a better persistence and a better proliferation capacity associated with a better tumoral control. A) Design of the in vivo experiment (n=7 mice per group) B) T-cell persistence in peripheral blood was measured by FACS. C) Speakman correlation (Day 13) between Tumor size and% CAR-T- cells. D) Tumor kinetic and Kaplan-Meier analysis of survival of OVCAR-bearing NSG mice treated with Conventional CAR-T cells, or Early-CAR-T cells or Low-dose of Early-CAR-T cells Abstract 126 Figure 5Anti-PD1 treatment enhance the efficacy of the Early-CAR-T cells. A) Upregulation of PD-L1 on OVCAR3 when expanded in the supernatant from co-culture of OVCAR3 with LeY-CAR-T cells. B) Design of the in vivo experiment (n=7 mice per group). C) T-cell persistence, phenotype and anti-human IgG4 in peripheral blood were measured by FACS. D) Tumor kinetic of OVCAR-bearing NSG mice treated with Early-CAR-T cells or Early-CAR-T cells + Nivolumab Conclusions Our early CAR-T cells have better cytokine secretion and proliferation than conventional CAR-T cells. Early CAR-T cells also have superior anti-tumor efficacy in vivo, they have better persistence and maintain the circulating T cell memory pool. Importantly, low dose early-LeY-CAR-T cells combined with anti-PD1-treatment leads to complete clearance of LeY+ solid tumors in vivo. The early CAR-T cell production protocol is directly translatable for improving CAR-T cell efficacy in clinical trials for patients with solid tumors.