PO.CL01.01 · 临床研究

Longitudinal peripheral blood TCR tracking predicts response to immune checkpoint inhibitors

海报缩略图:Longitudinal peripheral blood TCR tracking predicts response to immune checkpoint inhibitors
编号 1018 展板 12 时间 4/19 02:00–05:00 区域 Section 40 主讲 Dingyuan Wang, MBBS;MS
分会场 Biomarkers Predictive of Therapeutic Benefit 1
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作者与单位

Dingyuan Wang1, Kaiyan Xu2, Parker J. Li3, David J. H. Shih3, Matthew K. L. Chiu1, Jason W. H. Wong3, Wei Dai1, Aya El Helali1

1Department of Clinical Oncology, School of Clinical Medicine, LKS Faculty of Medicine, The University of Hong Kong, Hong Kong, Hong Kong,2Centre for Oncology and Immunology, Hong Kong Science Park, Hong Kong, Hong Kong,3School of Biomedical Science, The University of Hong Kong, Hong Kong, Hong Kong

摘要 Abstract

Background: While immune checkpoint inhibitor (ICI) therapy has revolutionized oncology, reliable biomarkers to predict clinical response are critically needed. Static, single-time-point analysis of the T-cell receptor (TCR) repertoire has proven inadequate. We hypothesized that the longitudinal tracking of TCR clonal dynamics would provide a more powerful and predictive biomarker of clinical outcome. Methods: To test this hypothesis, we employed a two-stage strategy. First, we performed an exploratory analysis on the public longitudinal TCR-seq dataset GSE212217 to investigate whether dynamic changes in TCR clones could distinguish responders from non-responders. Based on the observed temporal expansion patterns, we developed a novel classification model that categorizes TCR clones algorithmically by quantifying the direction and magnitude of change in their relative abundance over time. Clones are assigned to distinct behavioral types, Response, Super-response, Transient, and Quiescent, based on specific, quantitative criteria applied to their longitudinal trajectories. Second, we validated this model in an independent, prospective pilot cohort of advanced melanoma patients using TCR sequencing from serial blood samples. Results: Analysis of the public dataset confirmed that baseline TCR diversity metrics were unable to differentiate between clinical responders and non-responders. In contrast, our longitudinal model identified distinct clonal expansion trajectories. This novel response score was significantly elevated in responders compared to non-responders in the discovery cohort (Wilcoxon test, P = 0.011). Critically, patients with a high score exhibited a marked survival advantage (Log-rank P = 0.040), confirming the clinical prognostic value of our dynamic metric. Validation in our independent melanoma cohort confirmed the clinical utility of our model. Strikingly, the patient with disease progression exhibited a low proportion of active, expanding clones (5.5%), whereas the patient achieving a deep clinical response demonstrated a markedly higher proportion of active, expanding clones (10.5%). Conclusion: We have developed and validated a novel biomarker based on the dynamic expansion of T-cell clones that effectively predicts ICI response and survival. This work definitively moves beyond the limitations of static TCR metrics, establishing longitudinal clonal tracking as a crucial strategy for liquid biopsy. This approach provides a critical tool for real-time response monitoring and precision stratification of cancer immunotherapy.
利益披露 Disclosure
D. Wang, None.. K. Xu, None.. P. J. Li, None.. D. J. H. Shih, None.. M. K. L. Chiu, None.. J. W. H. Wong, None.. W. Dai, None.. A. El Helali, None.

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