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A platform for parallel TCR cloning and testing enables anti-neoantigen tumor immunotherapy
Alexander M. Rowe, Smriti Chaurasia, Wenzhong Wei, Laura García-Diéguez, Katherine Tempro, Johnathon G. Schiebel, Christy Smolak, Alexander Muralles, Daniel Wikenheiser, Kevin Quann, Collin Pirner, Kentin Codispot, Mark J. Shlomchik, Warren D. Shlomchik
Alexander M. Rowe, Smriti Chaurasia, Wenzhong Wei, Laura García-Diéguez, Katherine Tempro, Johnathon G. Schiebel, Christy Smolak, Alexander Muralles, Daniel Wikenheiser, Kevin Quann, Collin Pirner, Kentin Codispot, Mark J. Shlomchik, Warren D. Shlomchik
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Research Article Immunology Oncology

A platform for parallel TCR cloning and testing enables anti-neoantigen tumor immunotherapy

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Abstract

Tumor-infiltrating CD8 cells recognize neoantigens created by tumor-specific mutations. Nonetheless, even after checkpoint inhibitor therapy, most patients’ tumors progress. A deeper understanding of antitumor responses could facilitate development of better therapies. To enable such studies, we applied TCXpress, a high throughput platform that clones fully expressible TCRs from single cells into retroviral or lentiviral vectors without sequencing or gene synthesis, to study TCRs from CD8 cells infiltrating mouse MC38 tumors. We expressed cloned TCRs in reporter cells and interrogated TCR specificity by coculturing them with B6WT3 cells transduced with tandem minigenes encoding predicted neoantigens. We isolated TCRs reactive against epitopes from mutant Rpl18, Adpgk, Psmd2, and Zc3h7b along with self-reactive TCRs that recognized normal B6 and MC38 cells. Importantly, we successfully treated MC38-bearing mice with T cells transduced with anti-Rpl18 TCRs. These results establish a system that could be used to study many types of T cell responses and validate a therapeutic approach that could be tested in the clinic.

Authors

Alexander M. Rowe, Smriti Chaurasia, Wenzhong Wei, Laura García-Diéguez, Katherine Tempro, Johnathon G. Schiebel, Christy Smolak, Alexander Muralles, Daniel Wikenheiser, Kevin Quann, Collin Pirner, Kentin Codispot, Mark J. Shlomchik, Warren D. Shlomchik

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Figure 2

Identification of neoantigen-reactive TCRs.

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Identification of neoantigen-reactive TCRs.
(A) TMGs encoding putative n...
(A) TMGs encoding putative neoantigens flanked by epitopes from OVA (SIINFEKL) and H60 (LTFNYRNL) were cloned into retroviral vectors; see also Supplemental Figure 2A. (B) Pools of 5 Jurkat lines (quintets), each expressing a TCR cloned from a single cell, were cocultured with B6WT3 cells transduced with TMG retroviruses. The percentage of CD69+ cells in each culture was determined by flow cytometry and plotted as a heatmap. (C) Representative flow plots from quintet 1 showing reactivities against B6WT3 cells expressing TMGs 3.0, 3.4, 3.6, 3.22, 3.36 or an empty vector (EV) negative control. (D) Putative neoantigens encoded by TMGs 3.0, 3.4, 3.5, 3.6, 3.22, and 3.26. The individual resource lines from quintet 1 were separately cocultured with TMGs 3.0, 3.4, 3.6, 3.22, and 3.26. (E) TCR A09 reacted with TMGs 3.0, 3.4, and 3.22, which shared expression of Rpl18, whereas TCR A10 reacted with TMGs 3.0, 3.6, and 3.26, which shared expression of ADPGK. (F and G) Quintet 22 reacted with TMGs 3.9 and 3.23, which only shared expression of PSMD2. (H) The single lines from quintet 22 were individually cultured with TMG-APCs 3.9 and 3.23, revealing TCR G13 to be reactive against PSMD2.

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