The Fourth Affiliated Hospital, Department of Environmental Medicine, Zhejiang University School of Medicine, Zhejiang 310058, China.
Institute of Genetics, International School of Medicine, Zhejiang University, Zhejiang 310058, China.
Environ Sci Technol. 2024 Oct 1;58(39):17259-17269. doi: 10.1021/acs.est.4c04373. Epub 2024 Aug 29.
Bisphenol A (BPA) is a commonly used plastic additive. Since BPA has been banned in maternal and infant food containers in many countries, BPA substitutes have been widely introduced to replace it. By systematically assessing the potential developmental toxicity of BPA substitutes, we observed that the 41-150 nM BPC exposure (around the reported concentration detected in infant urine: 6-186 nM) induced cardiac defects in zebrafish. Mechanistically, BPC disrupted mA homeostasis by downregulation of the key mA methyltransferase, Mettl3, thereby causing the mA reader, Igf2bp2b, to fail in recognizing and stabilizing the inefficiently mA-modified and mRNA. Then, downregulation of Acox1 (a regulator in cardiac fatty acid metabolism) and Tnnt2d (a component of cardiac troponin for muscle contraction) led to cardiac defects. Indeed, the dual cardiac functional axes regulated by the same mA reader in response to BPC provided new insight into the regulatory mechanisms of epitranscriptomics and cardiac development. Collectively, our study not only presented evidence showing that the internal exposure levels of BPC in humans could lead to cardiac developmental defects but also demonstrated the underlying mechanism of BPC-mediated defects by disrupting the Mettl3-mA-Igf2bp2b-Acox1/Tnnt2d pathways, which provided potential molecular markers associated with BPC exposure.
双酚 A(BPA)是一种常用的塑料添加剂。由于 BPA 已在许多国家被禁止用于母婴食品容器,因此已广泛引入 BPA 替代品来替代它。通过系统评估 BPA 替代品的潜在发育毒性,我们观察到 41-150 nM 的 BPC 暴露(约为报告的婴儿尿液中检测到的浓度:6-186 nM)诱导斑马鱼出现心脏缺陷。在机制上,BPC 通过下调关键的 mA 甲基转移酶 Mettl3 破坏 mA 稳态,从而导致 mA 阅读器 Igf2bp2b 无法识别和稳定修饰效率低下的 mA 和 mRNA。然后,Acox1(心脏脂肪酸代谢调节剂)和 Tnnt2d(心肌收缩的肌钙蛋白组件)的下调导致心脏缺陷。事实上,同一 mA 阅读器响应 BPC 调节的双重心脏功能轴提供了对表观转录组学和心脏发育调控机制的新见解。总的来说,我们的研究不仅提供了证据表明人类体内的 BPC 内暴露水平可能导致心脏发育缺陷,还通过破坏 Mettl3-mA-Igf2bp2b-Acox1/Tnnt2d 途径证明了 BPC 介导的缺陷的潜在机制,为与 BPC 暴露相关的潜在分子标记提供了依据。
