后代
氧化应激
生物
硒
转录组
抗氧化剂
内分泌系统
生理学
内分泌学
睾酮(贴片)
锌
氧化损伤
代谢组学
内科学
二羟基化合物
生殖毒性
激素
繁殖
生殖系统
内分泌干扰物
男性生殖系统
超氧化物歧化酶
机制(生物学)
疾病
双酚A
缺锌(植物性疾病)
细胞凋亡
平衡
生殖生物学
表观遗传学
葡萄糖稳态
怀孕
男科
氧化磷酸化
金属硫蛋白
作者
Jing Ma,Yuanjing Li,Yuejia Li,Jiajie Bi,Junsheng Liu,Junling Li,Fanshun Meng,Lei Yan,Jianan Wen,Xueting Wang,Jian G. Qin,Shusong Wang,Rong Du
标识
DOI:10.1016/j.envint.2025.109975
摘要
Bisphenol A (BPA), a common environmental endocrine disruptor, has been shown to adversely affect male reproductive function. However, the mechanisms of reproductive impairment in both BPA-exposed males (F0) and their unexposed offspring (F1) remain unclear. Furthermore, there are currently no reports on that paternal Zinc (Zn) and/or Selenium (Se) supplementation ameliorate BPA-induced and transgenerational reproductive damage in F0 and F1, respectively. This study aimed to address these scientific issues by integrating transcriptomics and metabolomics. Our results revealed that BPA induced reproductive damage of F0 by altering the transport and homeostasis of Zn and Se, disrupting the synthesis and transformation balances of testosterone (T) and estradiol (E2), and increasing the oxidative stress and apoptosis levels. Furthermore, most of the changes of F0 was transmitted to F1 generation, causing reproductive damage to the male offspring. In contrast, supplementing with Zn and/or Se for F0 could alleviate these impacts of BPA on F0 and F1. Notably, the combination of Zn and Se was generally more effective compared to individual supplementation. The transcriptomics and metabolomics analyses revealed the overall mechanisms of Zn and/or Se alleviating BPA-induced testicular damage in F0 and F1 male mice. The reason why Zn and Se combined is superior to Zn or Se alone is related to their unique or additive regulatory roles on the oxidative phosphorylation pathway and antioxidant functions, which exhibits the characteristic of intergenerational transmission in male mice.
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