整合单细胞测序与空间定量系统药理学模型spQSP用于个性化预测三阴性乳腺癌免疫治疗反应

Shuming Zhang , Chang Gong , Alvaro Ruiz-Martinez , Hanwen Wang , Emily Davis-Marcisak , Atul Deshpande , Aleksander S. Popel , Elana J. Fertig
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引用次数: 17

摘要

对癌症免疫疗法的反应取决于T细胞识别和杀死癌细胞之间复杂和动态的相互作用,这些相互作用通过肿瘤微环境中的免疫抑制途径被抵消。因此,虽然肿瘤突变负担等测量方法为选择免疫治疗患者提供了生物标志物,但它们既不能普遍预测患者的反应,也不能暗示免疫治疗耐药的机制。单细胞RNA测序技术的最新进展是测量单个肿瘤细胞内的细胞异质性,但尚未实现预测肿瘤学的承诺。除数据外,还开发了机械多尺度计算模型来预测治疗反应。结合来自肿瘤的单细胞数据来参数化这些计算模型,为预测个体患者的临床结果提供了更深入的见解。在这里,我们整合了来自三阴性乳腺癌患者的全外显子组测序和scRNA-seq数据,以模拟肿瘤细胞中的新抗原负荷,作为空间定量系统药理学模型的输入。该模型包括一个代表整个患者的四室定量系统药理学子模型和一个代表细胞尺度肿瘤体积的基于空间主体的子模型。我们使用高通量单细胞数据来模拟抗原负担和肿瘤微环境组成的异质性对预测免疫治疗反应的作用。我们展示了这种综合建模和单细胞分析框架如何用于将新抗原异质性与免疫治疗结果联系起来。我们的研究结果证明了在多尺度计算模型(如spQSP)中合并单细胞数据来初始化细胞状态的可行性,用于个性化预测免疫治疗的临床结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Integrating single cell sequencing with a spatial quantitative systems pharmacology model spQSP for personalized prediction of triple-negative breast cancer immunotherapy response

Integrating single cell sequencing with a spatial quantitative systems pharmacology model spQSP for personalized prediction of triple-negative breast cancer immunotherapy response

Response to cancer immunotherapies depends on the complex and dynamic interactions between T cell recognition and killing of cancer cells that are counteracted through immunosuppressive pathways in the tumor microenvironment. Therefore, while measurements such as tumor mutational burden provide biomarkers to select patients for immunotherapy, they neither universally predict patient response nor implicate the mechanisms that underlie immunotherapy resistance. Recent advances in single-cell RNA sequencing technology measure cellular heterogeneity within cells of an individual tumor but have yet to realize the promise of predictive oncology. In addition to data, mechanistic multiscale computational models are developed to predict treatment response. Incorporating single-cell data from tumors to parameterize these computational models provides deeper insights into prediction of clinical outcome in individual patients. Here, we integrate whole-exome sequencing and scRNA-seq data from Triple-Negative Breast Cancer patients to model neoantigen burden in tumor cells as input to a spatial Quantitative System Pharmacology model. The model comprises a four-compartmental Quantitative System Pharmacology sub-model to represent a whole patient and a spatial agent-based sub-model to represent tumor volumes at the cellular scale. We use the high-throughput single-cell data to model the role of antigen burden and heterogeneity relative to the tumor microenvironment composition on predicted immunotherapy response. We demonstrate how this integrated modeling and single-cell analysis framework can be used to relate neoantigen heterogeneity to immunotherapy treatment outcomes. Our results demonstrate feasibility of merging single-cell data to initialize cell states in multiscale computational models such as the spQSP for personalized prediction of clinical outcomes to immunotherapy.

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Immunoinformatics (Amsterdam, Netherlands)
Immunoinformatics (Amsterdam, Netherlands) Immunology, Computer Science Applications
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