Your search keyword '"Vittorio, Orazio"' showing total 2 results

1. Additional file 1 of A novel transcriptional signature identifies T-cell infiltration in high-risk paediatric cancer

Author

Mayoh, Chelsea, Gifford, Andrew J., Terry, Rachael, Lau, Loretta M. S., Wong, Marie, Rao, Padmashree, Shai-Hee, Tyler, Saletta, Federica, Khuong-Quang, Dong-Anh, Qin, Vicky, Mateos, Marion K., Meyran, Deborah, Miller, Katherine E., Yuksel, Aysen, Mould, Emily V. A., Bowen-James, Rachel, Govender, Dinisha, Senapati, Akanksha, Zhukova, Nataliya, Omer, Natacha, Dholaria, Hetal, Alvaro, Frank, Tapp, Heather, Diamond, Yonatan, Pozza, Luciano Dalla, Moore, Andrew S., Nicholls, Wayne, Gottardo, Nicholas G., McCowage, Geoffrey, Hansford, Jordan R., Khaw, Seong-Lin, Wood, Paul J., Catchpoole, Daniel, Cottrell, Catherine E., Mardis, Elaine R., Marshall, Glenn M., Tyrrell, Vanessa, Haber, Michelle, Ziegler, David S., Vittorio, Orazio, Trapani, Joseph A., Cowley, Mark J., Neeson, Paul J., and Ekert, Paul G.

Abstract

Additional file 1: Table S1. Immune checkpoint and regulatory genes. Fig. S1. PRISM clinical trial study schema. Fig. S2. Cohort overview. Fig. S3. Deconvolution algorithms exhibit high concordance and an abundance of M2 macrophages in paediatric cancer. Fig. S4. Immunohistochemistry identifies paediatric patients with T-cell infiltrated tumours. Fig. S5. Prior treatment and steroid administration do not significantly affect T-cell infiltration. Fig. S6. Distribution of IPASS and T-cell clones are heterogenous across histologies. Fig. S7. IPASS correlations with additional markers of immune infiltration.

Published

2023

2. GD2-targeting CAR-T cells enhanced by transgenic IL-15 expression are an effective and clinically feasible therapy for glioblastoma

Author

Tessa Gargett, Lisa M Ebert, Nga T H Truong, Paris M Kollis, Kristyna Sedivakova, Wenbo Yu, Erica C F Yeo, Nicole L Wittwer, Briony L Gliddon, Melinda N Tea, Rebecca Ormsby, Santosh Poonnoose, Jake Nowicki, Orazio Vittorio, David S Ziegler, Stuart M Pitson, Michael P Brown, Gargett, Tessa, Ebert, Lisa M, Truong, Nga TH, Kollis, Paris M, Sedivakova, Kristyna, Yu, Wenbo, Yeo, Erica CF, Wittwer, Nicole L, Gliddon, Briony L, Tea, Melinda N, Ormsby, Rebecca, Poonnoose, Santosh, Nowicki, Jake, Vittorio, Orazio, Ziegler, David S, Pitson, Stuart M, and Brown, Michael P

Subjects

Interleukin-15, Pharmacology, brain neoplasms, Cancer Research, Receptors, Chimeric Antigen, Brain Neoplasms, T-Lymphocytes, Immunology, receptors, Glioma, adoptive, Xenograft Model Antitumor Assays, Oncology, chimeric antigen, Gangliosides, Humans, Molecular Medicine, Immunology and Allergy, immunotherapy, Glioblastoma, Immune Checkpoint Inhibitors

Abstract

BackgroundAggressive primary brain tumors such as glioblastoma are uniquely challenging to treat. The intracranial location poses barriers to therapy, and the potential for severe toxicity. Effective treatments for primary brain tumors are limited, and 5-year survival rates remain poor. Immune checkpoint inhibitor therapy has transformed treatment of some other cancers but has yet to significantly benefit patients with glioblastoma. Early phase trials of CAR-T cell therapy have demonstrated that this approach is safe and feasible, but with limited evidence of its effectiveness. The choices of appropriate target antigens for CAR-T cell therapy also remain limited.MethodsWe profiled an extensive biobank of patients’ biopsy tissues and patient-derived early passage glioma neural stem cell lines for GD2 expression using immunomicroscopy and flow cytometry. We then employed an approved clinical manufacturing process to make CAR-T cells from peripheral blood of glioblastoma and diffuse midline glioma patients and characterized their phenotype and function in vitro. Finally, we tested intravenously administered CAR-T cells in an aggressive intracranial xenograft model of glioblastoma and used multicolor flow cytometry, multicolor whole-tissue immunofluorescence and next-generation RNA sequencing to uncover markers associated with effective tumor control.ResultsHere we show that the tumor-associated antigen GD2 is highly and consistently expressed in primary glioblastoma tissue removed at surgery. Moreover, despite glioblastoma patients having perturbations in their immune system, highly functional GD2-specific CAR-T cells can be produced from their peripheral T cells using an approved clinical manufacturing process. Finally, after intravenous administration, GD2-CAR-T cells effectively infiltrated the brain and controlled tumor growth in an aggressive orthotopic xenograft model of glioblastoma. Tumor control was further improved using CAR-T cells manufactured with a clinical retroviral vector encoding an IL-15 transgene alongside the GD2-specific CAR. These CAR-T cells achieved a striking 50% complete response rate by bioluminescence imaging in established intracranial tumors. Markers associated with tumor control included those related to T-cell homing, infiltration, and cytotoxicity.ConclusionsTargeting GD2 using a clinically deployed CAR-T therapy has a sound scientific and clinical rationale as a treatment for glioblastoma and other aggressive primary brain tumors.What is already known on this topicGD2 is a tumor antigen of significant interest for targeting immunotherapy. A single preclinical study has shown the effectiveness of GD2-CAR-T cell therapy in an orthotopic xenograft model of diffuse midline glioma. Similarly, there is one previous preclinical study of GD2-CAR-T therapy in a orthotopic glioblastoma xenograft model but tumor control was achieved only following intracranial injection of CAR-T cells. Given that GD2-CAR-T therapy is already being evaluated clinically for other tumor indications, it is important to establish whether there is an acceptable rationale for its use in brain tumors.What this study addsThis is the first description of a GD2-targeted CAR-T cell therapy that shows antitumor effectiveness in a preclinical model of human glioblastoma following intravenous administration. It is also the first study to investigate the potential effects that the immune profile of glioblastoma patients may have on the feasibility of CAR-T cell manufacturing.How this study might affect research, practice, or policyThe results of this study have led to the initiation of an Australian phase 1 clinical trial program aiming to test GD2-specific CAR-T cells for the treatment of childhood and adult primary brain tumors. The study provides valuable insights into the microenvironmental factors that influence the effectiveness of CAR-T cell therapy for this type of tumor, paving the way for further optimization of CAR-T cell technology for treatment of aggressive primary brain tumors such as glioblastoma.

Published

2022