PO.CL05.02 · 临床研究

High-throughput ex vivo TCR-T cells screening identifies aggrephagy-driven, therapy-resistant clones in KRAS-mutant PDAC

海报缩略图:High-throughput ex vivo TCR-T cells screening identifies aggrephagy-driven, therapy-resistant clones in KRAS-mutant PDAC
编号 5183 展板 1 时间 4/21 09:00–12:00 区域 Section 40 主讲 Masoumeh Eshaghi, PhD
分会场 Adoptive Cell Therapy 2
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作者与单位

Masoumeh Eshaghi1, Fei Miao1, Ali Abdollahzadeh2, Sixing Chen3, Jacopo Chiaro4, Elahe Kamali G1, Joshua Glover5, Vineeth Koneru1, Michael C. Milone6, Miren L Baroja1, Gerald P. Linette7, Beatriz M. Carreno7, Emma E. Furth8, Vincenzo Cerullo4, Joseph Fraietta9, Carl H. June10, Friederike Herbst-Nowrouzi1

1Center for Cellular Immunotherapies, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA,2A.I. Virtanen Institute for Molecular Sciences, University of Eastern Finland, Philadelphia, Finland,3Department of Genetics, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA,4Helsinki Institute of Life Science (HiLIFE), University of Helsinki, Helsinki, Finland,5The Stem Cell & Xenograft Core (SCXC), Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA,6Department of Pathology and Laboratory Medicine, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA,7University of Pennsylvania, Philadelphia, PA,8Hospital of the University of Pennsylvania, Philadelphia, PA,9Department of Microbiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA,10Program Director of Translational Research, Abramson Family Cancer Research Inst, University of Pennsylvania, Philadelphia, PA

摘要 Abstract

Background: Pancreatic ductal adenocarcinoma (PDAC) is characterized by frequent KRAS‑G12 oncogenic mutations, low immune cell infiltration, and early metastatic spread, leading to poor outcomes. Selective pressure from systemic therapies promotes the emergence of resistant clones and relapse. Patient-derived models that capture tumor heterogeneity are needed to optimize T cell receptor-engineered T cell (TCR‑T) strategies and anticipate mechanisms of resistance. Methods: We developed a high-throughput ex vivo screening platform to test cell-based immunotherapies in patient-derived PDAC spheroids. KRAS‑G12V-specific CD8⁺ TCR‑T cells were co-cultured with KRAS-mutant 3D tumor spheroids under graded levels of cytotoxic pressure and monitored using automated image cytometry. Microcavity plates enabled parallel tracking of thousands of spheroids across two sequential TCR‑T challenges. Surviving cells were profiled by single-cell RNA sequencing (scRNA‑seq), followed by 2D regrowth assays and orthotopic transplantation into NSG mice to assess tumor-initiating capacity. Results: High-throughput resistance screening of over 33,000 microcavities revealed that 6.6% of 3D-PDAC spheroids remained viable after repeated TCR-T cell challenge, enriching for rare resistant subclones. After the first challenge, most cells exhibited an antiviral-like inflammatory response, characterized by increased levels of MX1, MX2, RIG-I, and interferon-stimulated gene expression. scRNA-seq after re-challenge revealed proliferating cells with upregulation of MHC II molecules and TUBA1B-associated aggrephagy pathways, implicating aggrephagy in immune escape. Resistant cells retained tumor-initiating potential and generated distant metastases in orthotopic NSG models ( n = 10). In vitro , paclitaxel, a microtubule disassembly inhibitor, reduced colony formation by TCR‑T-escaped clones, supporting a rationale for combination therapy. Conclusions: High-throughput ex vivo cytotoxicity screening of patient-derived PDAC models reveals aggrephagy-enriched, therapy-resistant clones and nominates rational combination partners such as paclitaxel. This platform may help anticipate patient-specific resistance to KRAS‑targeted TCR‑T therapy and guide the design of preventative combination strategies.
利益披露 Disclosure
M. Eshaghi, None.. F. Miao, None.. A. Abdollahzadeh, None.. S. Chen, None.. J. Chiaro, None.. E. Kamali G, None.. J. Glover, None.. V. Koneru, None. M. C. Milone, Verismo Therapeutics Founder, stockholder, and scientific advisor. Cabaletta Bio Other, Founder, stockholder, and scientific advisor. Novartis AG Other, M.C.M. is an inventor of CAR-T cell technology, including designs described in this review, which are owned by the University of Pennsylvania and licensed to Novartis AG. Tmunity M.C.M. is an inventor of CAR-T cell technology, including designs described in this review, which are owned by the University of Pennsylvania and licensed to Tmunity. Verismo Therapeutics M.C.M. is an inventor of CAR-T cell technology, including designs described in this review, which are owned by the University of Pennsylvania and licensed to Verismo Therapeutics. Cabaletta Bio M.C.M. is an inventor of CAR-T cell technology, including designs described in this review, which are owned by the University of Pennsylvania and licensed to Cabaletta Bio. M. Baroja, None.. E. E. Furth, None. V. Cerullo, VALO Therapeutics Other, co-founder and shareholder. J. Fraietta, Danaher Corporation ). Tmunity Therapeutics ). Retro Biosciences Other, Consultancy. Cartography Bio Other, Scientific advisory board memberships. Shennon Biotechnologies Inc Scientific advisory board memberships. CellFe Biotech Scientific advisory board memberships. OverT Bio Scientific advisory board memberships. Tceleron Therapeutics, Inc Scientific advisory board memberships. F. Herbst-Nowrouzi, Kite ). Danaher ).

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