PO.IM01.03 · 免疫学

Preclinical potential of gammadelta T cells in novel virus-like particle vaccines for triple-negative breast cancer

海报缩略图:Preclinical potential of gammadelta T cells in novel virus-like particle vaccines for triple-negative breast cancer
编号 4371 展板 11 时间 4/21 09:00–12:00 区域 Section 10 主讲 Arnau Solé Casaramona, BS;MS
分会场 Vaccine Platforms and Target Identification
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作者与单位

Arnau Solé Casaramona1, Anish Ghimire1, Romano Josi1, Sanjana Marar1, Anita Ogriņa-Komarova2, Simone De Brot1, Chang Wang1, David Wiggins3, Wendao Liu3, Sarat Kumar Kottarath3, Martin F. Bachmann1, Eva M. Sevick3, Mona O. Mohsen1

1University of Bern, Bern, Switzerland,2Latvian Biomedical Research, Riga, Latvia,3University of Texas at Houston, Houston, TX

摘要 Abstract

Triple-negative breast cancer (TNBC) is an aggressive subtype with limited treatment options, high recurrence rates and poor outcomes. The conventional treatment among the standard of care strategies fail to elicit a long-term benefit for these patients. Personalized cancer vaccines using virus-like particles (VLPs), represent a promising strategy with the potential to induce durable immune responses. Recent research has highlighted the innate and adaptive properties of gammadelta T cells, underscoring their potential in cancer immunotherapy. However, how VLPs interact with gammadelta T cells, and their clinical efficacy to enhance their antitumor activity remains poorly understood and requires further investigation. We designed and developed novel next-generation VLPs engineered to incorporate cell-adjuvanted innate ligands and present tumor-neoantigens on their surface from a preclinical model of TNBC. We validated them by Cryo-EM and biochemical assays. We evaluated the interaction of VLPs with gammadelta T cells in wildtype and transgenic mice by transmission imaging techniques. Tumor in vivo experimentation was carried out in the 4T1 TNBC model. We compared three subcutaneous (s.c.) administration routes: systemic, targeting tumor-draining lymph nodes (tdLNs), and targeting non-tdLNs. Survival was assessed under different dosing and immune checkpoint inhibitor co-treatment. CD4, CD8, and gammadelta T cells were depleted to determine their contributions. We performed immunohistochemistry, flow cytometry, and RNA-seq analysis to evaluate the immune response. Our results show that gammadelta T cells efficiently engulfed VLPs in wild-type mice while this interaction is hindered in transgenic mice lacking key components of innate immune sensing pathways. Our novel VLPs expanded gammadelta T cells in tdLNs, promoting antitumor subsets and phenotypes. Subtype analysis revealed distinct activation profiles of gammadelta T cells subsets Vgamma-1 and Vgamma-4. Evaluation of tdLNs and tumors revealed early expansion of gammadelta T cells, highlighting innate properties. Depletion of gammadelta T cells abolished antitumor efficacy of the immunotherapy, suggesting adaptive properties. Furthermore, our personalized vaccine enhanced tumor infiltration of CD4, CD8 and gammadelta T cells, increased cytotoxic markers, reduced recurrence and metastasis, and improved survival despite low tumor mutational burden. Our findings reveal novel innate and adaptive properties of gammadelta T cells in response to our next-generation VLPs loaded with diverse innate immune stimuli and presenting tumor-neoantigens from 4T1 cells. These findings have the potential to reshape the field of cancer vaccines by harnessing gammadelta T cells as key players in anti-tumor immunity. ( AI tools were used only to improve the clarity of the text in this abstract. All content was reviewed and verified by the authors. )
利益披露 Disclosure
A. Solé Casaramona, None.. A. Ghimire, None.. R. Josi, None. S. Marar, DeepVax Employment. A. Ogriņa-Komarova, None.. S. De Brot, None.. C. Wang, None.. D. Wiggins, None.. W. Liu, None.. S. Kumar Kottarath, None. M. F. Bachmann, DeepVax Other Business Ownership. M. O. Mohsen, DeepVax Other Business Ownership.

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