University of Pennsylvania, Philadelphia, Pennsylvania, USA.
Center for Quantitative Medicine, University of Connecticut Health Centergrid.208078.5, Farmington, Connecticut, USA.
mSphere. 2022 Aug 31;7(4):e0007422. doi: 10.1128/msphere.00074-22. Epub 2022 Jul 12.
Iron is essential to the virulence of Aspergillus species, and restricting iron availability is a critical mechanism of antimicrobial host defense. Macrophages recruited to the site of infection are at the crux of this process, employing multiple intersecting mechanisms to orchestrate iron sequestration from pathogens. To gain an integrated understanding of how this is achieved in aspergillosis, we generated a transcriptomic time series of the response of human monocyte-derived macrophages to Aspergillus and used this and the available literature to construct a mechanistic computational model of iron handling of macrophages during this infection. We found an overwhelming macrophage response beginning 2 to 4 h after exposure to the fungus, which included upregulated transcription of iron import proteins transferrin receptor-1, divalent metal transporter-1, and ZIP family transporters, and downregulated transcription of the iron exporter ferroportin. The computational model, based on a discrete dynamical systems framework, consisted of 21 3-state nodes, and was validated with additional experimental data that were not used in model generation. The model accurately captures the steady state and the trajectories of most of the quantitatively measured nodes. In the experimental data, we surprisingly found that transferrin receptor-1 upregulation preceded the induction of inflammatory cytokines, a feature that deviated from model predictions. Model simulations suggested that direct induction of transferrin receptor-1 (TfR1) after fungal recognition, independent of the iron regulatory protein-labile iron pool (IRP-LIP) system, explains this finding. We anticipate that this model will contribute to a quantitative understanding of iron regulation as a fundamental host defense mechanism during aspergillosis. Invasive pulmonary aspergillosis is a major cause of death among immunosuppressed individuals despite the best available therapy. Depriving the pathogen of iron is an essential component of host defense in this infection, but the mechanisms by which the host achieves this are complex. To understand how recruited macrophages mediate iron deprivation during the infection, we developed and validated a mechanistic computational model that integrates the available information in the field. The insights provided by this approach can help in designing iron modulation therapies as anti-fungal treatments.
铁元素是曲霉属物种毒力所必需的,限制铁的可用性是抗菌宿主防御的关键机制。募集到感染部位的巨噬细胞是这一过程的关键,它们采用多种相互交织的机制从病原体中协调铁的螯合。为了全面了解曲霉病中是如何实现这一点的,我们生成了人类单核细胞衍生的巨噬细胞对曲霉属反应的转录组时间序列,并使用该时间序列和可用的文献构建了一个在这种感染过程中巨噬细胞铁处理的机制计算模型。我们发现,在接触真菌后 2 到 4 小时,巨噬细胞就会产生强烈的反应,包括铁摄取蛋白转铁蛋白受体-1、二价金属转运蛋白-1 和 ZIP 家族转运蛋白的转录上调,以及铁输出蛋白亚铁蛋白的转录下调。该计算模型基于离散动力系统框架,由 21 个 3 态节点组成,并使用未用于模型生成的额外实验数据进行了验证。该模型准确地捕捉到了大多数定量测量节点的稳态和轨迹。在实验数据中,我们惊讶地发现转铁蛋白受体-1 的上调先于炎症细胞因子的诱导,这一特征偏离了模型预测。模型模拟表明,真菌识别后转铁蛋白受体-1(TfR1)的直接诱导,独立于铁调节蛋白-不稳定铁池(IRP-LIP)系统,解释了这一发现。我们预计,该模型将有助于深入了解铁调节作为曲霉病中一种基本的宿主防御机制。侵袭性肺曲霉病是免疫抑制个体死亡的主要原因,尽管有最好的治疗方法。剥夺病原体的铁是宿主防御的一个重要组成部分,但宿主实现这一目标的机制很复杂。为了了解招募的巨噬细胞如何在感染过程中介导铁剥夺,我们开发并验证了一个机制计算模型,该模型整合了该领域的现有信息。这种方法提供的见解有助于设计铁调节疗法作为抗真菌治疗。
