多模态数据的马尔可夫场网络模型可预测免疫系统扰动对猕猴静脉注射卡介苗的影响。

Cell systems Pub Date : 2024-12-18 Epub Date: 2024-11-05 DOI:10.1016/j.cels.2024.10.001
Shu Wang, Amy J Myers, Edward B Irvine, Chuangqi Wang, Pauline Maiello, Mark A Rodgers, Jaime Tomko, Kara Kracinovsky, H Jacob Borish, Michael C Chao, Douaa Mugahid, Patricia A Darrah, Robert A Seder, Mario Roederer, Charles A Scanga, Philana Ling Lin, Galit Alter, Sarah M Fortune, JoAnne L Flynn, Douglas A Lauffenburger
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引用次数: 0

摘要

对多模式数据集的分析可以确定生物系统底层的多尺度相互作用,但由于间接影响通过未绘制的生物网络传播,可能会受到虚假连接的困扰。例如,对猕猴的研究表明,通过静脉途径接种卡介苗(BCG)可预防结核病,这与各种免疫数据模式的变化相关。为了消除虚假相关性并识别接种过疫苗的猕猴的公共多模式数据集(系统血清学、细胞因子和细胞测定法)中的关键免疫相互作用,我们应用了马尔可夫场(MFs),这是一种数据驱动方法,可通过多变量网络路径解释疫苗功效和免疫相关性,而不需要相对于多变量特征的大量样本(即猕猴)。我们发现,用 MF 整合多种数据模式有助于去除虚假连接。最后,我们利用 MF 预测了各种免疫节点的扰动结果,包括经过实验验证的 B 细胞耗竭,这种耗竭会诱发整个网络的变化,但不会降低疫苗保护能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Markov field network model of multi-modal data predicts effects of immune system perturbations on intravenous BCG vaccination in macaques.

Analysis of multi-modal datasets can identify multi-scale interactions underlying biological systems but can be beset by spurious connections due to indirect impacts propagating through an unmapped biological network. For example, studies in macaques have shown that Bacillus Calmette-Guerin (BCG) vaccination by an intravenous route protects against tuberculosis, correlating with changes across various immune data modes. To eliminate spurious correlations and identify critical immune interactions in a public multi-modal dataset (systems serology, cytokines, and cytometry) of vaccinated macaques, we applied Markov fields (MFs), a data-driven approach that explains vaccine efficacy and immune correlations via multivariate network paths, without requiring large numbers of samples (i.e., macaques) relative to multivariate features. We find that integrating multiple data modes with MFs helps remove spurious connections. Finally, we used the MF to predict outcomes of perturbations at various immune nodes, including an experimentally validated B cell depletion that induced network-wide shifts without reducing vaccine protection.

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