Abstract B62: Evaluation of systemic RNA-based cancer vaccine induced T-cell responses via mouse T-cell receptor (TCR) profiling

Abstract

Abstract Identification of biomarkers is pivotal towards the proper development of cancer immunotherapies, in particular for designing the most effective regimens and identifying patient subgroups most likely to benefit from a given treatment. T-cell receptor (TCR) repertoire emerged as a promising biomarker in this respect, as it allows measurement of the dynamics of the T cell response both in time and in different compartments. In this work, we developed and evaluated an NGS-based mouse TCR profiling method (TCR alpha and TCR beta) for discovery and validation of biomarkers related to the antitumoral T-cell response in different compartments upon systemic administration of an RNA-based cancer vaccine (RNA-lipoplex). The in-house established mouse TCR profiling protocol was able to detect blood-spiked known-TCR sequences down to a frequency of 0,001% spiked cells for both TCR alpha and TCR beta chains and the relative frequencies of detected TCRs in the tumor correlated well with the degree of T-cell infiltration into the same tumors assessed by flow cytometry. Comparative analysis of changes in the TCR repertoire between blood and tumor upon repetitive vaccination with RNA-lipoplexes encoding immunodominant epitope of chicken ovalbumin (OVA257-264) revealed that richness as well as diversity of endogenous TCRs were generally lower in B16-OVA tumors compared to blood and decreased with further vaccination. Interestingly, top clones overlapped increasingly in blood and tumor until after the second vaccination, but drifted apart after the third vaccination, with the TCR repertoire in the tumor narrowing down. This overlap was less evident when mice were inoculated with B16-F10 tumors. Top clones within the same compartment were found to be highly variable between individual animals, complicating comparative analyses. Monitoring intra-individual TCR repertoire changes in the blood of a given mouse over time, however, indicated a tendency for decreasing richness and diversity following a single RNA vaccination, which may be pointing at repertoire adaptation and antigen focus. Supporting this notion, tumors isolated at late time-points exhibited a lower diversity than those investigated at earlier time-points and at baseline. In contrast to RNA vaccination, richness and diversity were reduced in response to treatment with an agonistic anti-CD40 antibody in blood and spleen but were similar among tumors. Consequently, richness and diversity in the periphery may not necessarily be predictive of corresponding repertoire changes in the tumor microenvironment. Citation Format: Lena Mareen Kranz, Barbara Schrörs, Thomas Bukur, Christian Albrecht, Lorieta Leppin, Martin Suchan, Marta Faryna, Eileen Powalsky, Rainer Hipfel, Özlem Türeci, Ugur Sahin, Mustafa Diken. Evaluation of systemic RNA-based cancer vaccine induced T-cell responses via mouse T-cell receptor (TCR) profiling [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2018 Nov 27-30; Miami Beach, FL. Philadelphia (PA): AACR; Cancer Immunol Res 2020;8(4 Suppl):Abstract nr B62.