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T antigen–specific CD8+ T cells associate with PD-1 blockade response in virus-positive Merkel cell carcinoma
Ulla Kring Hansen, Candice D. Church, Ana Micaela Carnaz Simões, Marcus Svensson Frej, Amalie Kai Bentzen, Siri A. Tvingsholm, Jürgen C. Becker, Steven P. Fling, Nirasha Ramchurren, Suzanne L. Topalian, Paul T. Nghiem, Sine Reker Hadrup
Ulla Kring Hansen, Candice D. Church, Ana Micaela Carnaz Simões, Marcus Svensson Frej, Amalie Kai Bentzen, Siri A. Tvingsholm, Jürgen C. Becker, Steven P. Fling, Nirasha Ramchurren, Suzanne L. Topalian, Paul T. Nghiem, Sine Reker Hadrup
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Research Article Immunology Oncology

T antigen–specific CD8+ T cells associate with PD-1 blockade response in virus-positive Merkel cell carcinoma

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Abstract

Merkel cell carcinoma (MCC) is a highly immunogenic skin cancer primarily induced by Merkel cell polyomavirus, which is driven by the expression of the oncogenic T antigens (T-Ags). Blockade of the programmed cell death protein-1 (PD-1) pathway has shown remarkable response rates, but evidence for therapy-associated T-Ag–specific immune response and therapeutic strategies for the nonresponding fraction are both limited. We tracked T-Ag–reactive CD8+ T cells in peripheral blood of 26 MCC patients under anti-PD1 therapy, using DNA-barcoded pMHC multimers, displaying all peptides from the predicted HLA ligandome of the oncoproteins, covering 33 class I haplotypes. We observed a broad T cell recognition of T-Ags, including identification of 20 T-Ag–derived epitopes we believe to be novel. Broadening of the T-Ag recognition profile and increased T cell frequencies during therapy were strongly associated with clinical response and prolonged progression-free survival. T-Ag–specific T cells could be further boosted and expanded directly from peripheral blood using artificial antigen-presenting scaffolds, even in patients with no detectable T-Ag–specific T cells. These T cells provided strong tumor-rejection capacity while retaining a favorable phenotype for adoptive cell transfer. These findings demonstrate that T-Ag–specific T cells are associated with the clinical outcome to PD-1 blockade and that Ag-presenting scaffolds can be used to boost such responses.

Authors

Ulla Kring Hansen, Candice D. Church, Ana Micaela Carnaz Simões, Marcus Svensson Frej, Amalie Kai Bentzen, Siri A. Tvingsholm, Jürgen C. Becker, Steven P. Fling, Nirasha Ramchurren, Suzanne L. Topalian, Paul T. Nghiem, Sine Reker Hadrup

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Figure 1

Screening with DNA barcode–labeled pMHC multimers.

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Screening with DNA barcode–labeled pMHC multimers.
(A) Schematic overvie...
(A) Schematic overview of the in silico peptide prediction for selecting the library of MCPyV-derived peptides. Created with BioRender. (B) The distribution of the peptides across the 33 HLA haplotypes, colored based on the protein of origin. (C) Experimental workflow for the detection of multimer-reactive CD8+ T cells. Created with BioRender. (D) Flow plots for the 2 multimer design strategies with either single multimer color for all peptides (PE) (left) or 2 multimer colors separating T-Ag peptides (PE) and VP1+CEF peptides (APC) (right). (E) Representative examples of screening results for patient 4 and 2 non–ICI-treated healthy donors screened in parallel. T cell recognition of a given epitope is defined by significant enrichment of the pMHC-assigned DNA barcode with log-fold change > 2 and FDR < 0.001, indicated by the dotted line. T cell epitopes are colored based on the protein of origin. (F) Combined screening results for all patients divided based on HLA haplotype. Number of patients screened with a given haplotype is indicated above the graph.

Copyright © 2026 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)

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