气道
产前暴露
医学
怀孕
生物
遗传学
妊娠期
麻醉
作者
Xin Hu,Boris Minasenko,Dongxue Wang,John Chan,ViLinh Thi Ly,Theresa W. Gauthier,Carmen J. Marsit,Dean P. Jones,Young‐Mi Go,Cherry Wongtrakool,Chang Su
出处
期刊:Research Square - Research Square
日期:2024-11-06
标识
DOI:10.21203/rs.3.rs-5389961/v1
摘要
Abstract Prenatal exposure to environmental hazards such as cadmium (Cd) and arsenic (As) can severely impair fetal lung development, leading to lifelong adverse effects. As two of the most common and toxic heavy metals, Cd and As pose significant risks to pregnant women in many communities through food and water consumption. We have shown that prenatal co-exposure to Cd and As at levels relevant to human intake inhibits branching morphogenesis, yet cell type-specific mechanisms remain elusive. In this study, we examined early embryonic lungs (E12) from mice exposed prenatally to either 0 (control) or 250 (treated) ppb of both Cd and As. Through single-cell multiome sequencing (scATAC-seq + scRNA-seq) and high-resolution metabolomics, we present a multifaceted landscape of Cd and As-induced molecular and cellular disruption. We identified 19 cell states exhibiting state-specific changes in gene expression related to cell proliferation and differentiation. Velocity analysis integrating RNA splicing and chromatin kinetics showed profound disruptions in cell fate, particularly affecting differentiation of Sox2+ proximal progenitors and Wnt2+ mesenchymal progenitors. Gene regulatory network analysis pinpointed the diminished function of Gata6 and Gli2 as central to these disruptions, which was further confirmed by their reduced protein expression in exposed E12, E14.5 and E17 lungs. Additionally, metabolomic alterations in polyamine, tyrosine and fatty acid biosynthesis correlated with changes in gene expression of catalytic enzymes. These findings demonstrate that Cd and As at levels relevant to human exposure impair early airway formation across multiple regulatory levels, including chromatin accessibility, transcription and cell metabolism, and provide insights into the factors governing cell resilience during this critical, vulnerable stage of lung development.
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