Macrophage memory emerges from coordinated transcription factor and chromatin dynamics.

Cell systems Pub Date : 2025-02-19 Epub Date: 2025-02-11 DOI:10.1016/j.cels.2025.101171

Andrew G Wang, Minjun Son, Aleksandr Gorin, Emma Kenna, Abinash Padhi, Bijentimala Keisham, Adam Schauer, Alexander Hoffmann, Savaş Tay

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Abstract

Cells of the immune system operate in dynamic microenvironments where the timing, concentration, and order of signaling molecules constantly change. Despite this complexity, immune cells manage to communicate accurately and control inflammation and infection. It is unclear how these dynamic signals are encoded and decoded and if individual cells retain the memory of past exposure to inflammatory molecules. Here, we use live-cell analysis, ATAC sequencing, and an in vivo model of sepsis to show that sequential inflammatory signals induce memory in individual macrophages through reprogramming the nuclear factor κB (NF-κB) network and the chromatin accessibility landscape. We use transcriptomic profiling and deep learning to show that transcription factor and chromatin dynamics coordinate fine-tuned macrophage responses to new inflammatory signals. This work demonstrates how macrophages retain the memory of previous signals despite single-cell variability and elucidates the mechanisms of signal-induced memory in dynamic inflammatory conditions like sepsis.

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巨噬细胞记忆源于转录因子和染色质动力学的协调。

免疫系统的细胞在动态微环境中运作，信号分子的时间、浓度和顺序不断变化。尽管如此复杂，免疫细胞还是能够准确地沟通并控制炎症和感染。目前尚不清楚这些动态信号是如何被编码和解码的，以及单个细胞是否保留了过去暴露于炎症分子的记忆。在这里，我们使用活细胞分析、ATAC测序和脓毒症的体内模型来表明，顺序的炎症信号通过重编程核因子κB （NF-κB）网络和染色质可及性来诱导个体巨噬细胞的记忆。我们使用转录组学分析和深度学习来显示转录因子和染色质动力学协调微调巨噬细胞对新的炎症信号的反应。这项工作证明了巨噬细胞如何在单细胞变异的情况下保留先前信号的记忆，并阐明了信号诱导记忆在脓毒症等动态炎症条件下的机制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Cell systems

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