Advanced single-cell and spatial analysis with high-multiplex characterization of circulating tumor cells and tumor tissue in prostate cancer: Unveiling resistance mechanisms with the CoDuCo in situ assay.

IF 9.5 2区医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL

Biomarker Research Pub Date : 2024-11-16 DOI:10.1186/s40364-024-00680-z

Lilli Bonstingl, Margret Zinnegger, Katja Sallinger, Karin Pankratz, Christin-Therese Müller, Elisabeth Pritz, Corinna Odar, Christina Skofler, Christine Ulz, Lisa Oberauner-Wappis, Anatol Borrás-Cherrier, Višnja Somođi, Ellen Heitzer, Thomas Kroneis, Thomas Bauernhofer, Amin El-Heliebi

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引用次数: 0

Abstract

Background: Metastatic prostate cancer is a highly heterogeneous and dynamic disease and practicable tools for patient stratification and resistance monitoring are urgently needed. Liquid biopsy analysis of circulating tumor cells (CTCs) and circulating tumor DNA are promising, however, comprehensive testing is essential due to diverse mechanisms of resistance. Previously, we demonstrated the utility of mRNA-based in situ padlock probe hybridization for characterizing CTCs.

Methods: We have developed a novel combinatorial dual-color (CoDuCo) assay for in situ mRNA detection, with enhanced multiplexing capacity, enabling the simultaneous analysis of up to 15 distinct markers. This approach was applied to CTCs, corresponding tumor tissue, cancer cell lines, and peripheral blood mononuclear cells for single-cell and spatial gene expression analysis. Using supervised machine learning, we trained a random forest classifier to identify CTCs. Image analysis and visualization of results was performed using open-source Python libraries, CellProfiler, and TissUUmaps.

Results: Our study presents data from multiple prostate cancer patients, demonstrating the CoDuCo assay's ability to visualize diverse resistance mechanisms, such as neuroendocrine differentiation markers (SYP, CHGA, NCAM1) and AR-V7 expression. In addition, druggable targets and predictive markers (PSMA, DLL3, SLFN11) were detected in CTCs and formalin-fixed, paraffin-embedded tissue. The machine learning-based CTC classification achieved high performance, with a recall of 0.76 and a specificity of 0.99.

Conclusions: The combination of high multiplex capacity and microscopy-based single-cell analysis is a unique and powerful feature of the CoDuCo in situ assay. This synergy enables the simultaneous identification and characterization of CTCs with epithelial, epithelial-mesenchymal, and neuroendocrine phenotypes, the detection of CTC clusters, the visualization of CTC heterogeneity, as well as the spatial investigation of tumor tissue. This assay holds significant potential as a tool for monitoring dynamic molecular changes associated with drug response and resistance in prostate cancer.

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对前列腺癌循环肿瘤细胞和肿瘤组织进行先进的单细胞和空间分析及高倍表征：利用 CoDuCo 原位测定揭示抗药性机制。

背景：转移性前列腺癌是一种高度异质性和动态的疾病，迫切需要实用的工具对患者进行分层和耐药性监测。循环肿瘤细胞（CTCs）和循环肿瘤DNA的液体活检分析很有前景，但由于耐药机制多种多样，因此必须进行全面检测。在此之前，我们已经证明了基于 mRNA 的原位挂锁探针杂交技术在表征 CTCs 方面的实用性：方法：我们开发了一种新颖的组合双色（CoDuCo）检测方法，用于 mRNA 的原位检测，具有更强的复用能力，可同时分析多达 15 个不同的标记物。我们将这种方法应用于 CTC、相应的肿瘤组织、癌细胞系和外周血单核细胞，进行单细胞和空间基因表达分析。利用监督机器学习，我们训练了一个随机森林分类器来识别 CTC。我们使用开源 Python 库、CellProfiler 和 TissUUmaps 对结果进行了图像分析和可视化：我们的研究展示了来自多名前列腺癌患者的数据，证明了CoDuCo检测法能够直观地显示多种耐药机制，如神经内分泌分化标志物（SYP、CHGA、NCAM1）和AR-V7的表达。此外，还在 CTC 和福尔马林固定、石蜡包埋组织中检测到了可药物靶点和预测标记物（PSMA、DLL3、SLFN11）。基于机器学习的 CTC 分类取得了很好的效果，召回率为 0.76，特异性为 0.99：CoDuCo原位检测法将高复用能力和基于显微镜的单细胞分析相结合，是其独特而强大的功能。这种协同作用可同时鉴定上皮、上皮-间质和神经内分泌表型的 CTC 并确定其特征，检测 CTC 簇，观察 CTC 的异质性，以及对肿瘤组织进行空间研究。这种检测方法作为一种监测与前列腺癌药物反应和耐药性相关的动态分子变化的工具，具有巨大的潜力。

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来源期刊

Biomarker Research Biochemistry, Genetics and Molecular Biology-Molecular Medicine

CiteScore

15.80

自引率

1.80%

发文量

审稿时长

10 weeks

期刊介绍： Biomarker Research, an open-access, peer-reviewed journal, covers all aspects of biomarker investigation. It seeks to publish original discoveries, novel concepts, commentaries, and reviews across various biomedical disciplines. The field of biomarker research has progressed significantly with the rise of personalized medicine and individual health. Biomarkers play a crucial role in drug discovery and development, as well as in disease diagnosis, treatment, prognosis, and prevention, particularly in the genome era.