Intermittent Cobalt (II, III) Oxide Exposure Exacerbates Inflammatory Injury through Tumor Necrosis Factor-Alpha-Dependent Bone Marrow-Mediated Trained Immunity
Hongyan Yu, Yidi Chen, Zhe Kou, Jingxu Zhang, Chen Wang, Yijiao Li, Duxing Li, Yubin Zhang, Yuxin Zheng, Xiaoting Jin
Journal:ACS Nano
IF:17.3
DOI:10.1021/acsnano.6c03750
PMID:42133975
Published:2026-05-14
research field:免疫学炎症研究造血生物学环境毒理学纳米医学
Abstract
Environmental nanoparticle exposure in real-world scenarios is often intermittent rather than continuous, yet its associated risks and mechanisms remain poorly understood. This study investigates whether such intermittent exposure induces maladaptive trained immunity within the bone marrow (BM) to drive inflammatory injury. We establish a physiologically relevant “prime-rest-rechallenge” mouse model of intermittent inhalation to cobalt (II, III) oxide (Co3O4) nanoparticles, a representative environmental stressor. Using this model, we provide in vivo evidence that intermittent Co3O4 exposure establishes a lasting, maladaptive immune memory in the BM─termed BM-mediated trained immunity. Primary Co3O4 exposure induces hematopoietic reprogramming toward a myeloid-biased phenotype, a state that is restored following a rest period. Upon secondary challenge, this reprogrammed state drives an augmented myelopoietic response, characterized by a 1.5-fold expansion of myeloid progenitors and a sustained output of mature myeloid cells. Integrated bioinformatics analysis and functional validation identify tumor necrosis factor-alpha (TNF-α), the highest-degree node (degree = 17) in the interaction network, as the central mediator orchestrating this BM-mediated trained immunity. In vivo TNF-α neutralization abrogates this trained myelopoietic phenotype. Furthermore, this Co3O4-induced, TNF-α-dependent trained immunity exacerbates inflammatory injury in distant organs, including the heart and brain. Our work establishes intermittent exposure as a critical yet overlooked risk paradigm, reveals trained immunity as a mechanistic link between nanoparticles and inflammatory disorders, and positions TNF-α as a potential therapeutic target to mitigate pollution-related risks.
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