Institute of Bioscience and Biotechnology, National Taiwan Ocean University, Keelung, Taiwan.
Neurotoxicol Teratol. 2013 Jul-Aug;38:92-103. doi: 10.1016/j.ntt.2013.05.006. Epub 2013 May 25.
Alcohol exposure during embryogenesis results in a variety of developmental disorders. Here, we demonstrate that continuous exposure to 1.5% ethanol causes substantial apoptosis and abrogated retinal and CNS development in zebrafish embryos. Chronic exposure to ethanol for 24h before hatching also induces apoptosis and retinal disorder. After the 2-day post-fertilization (dpf) stage, chronic exposure to ethanol continued to induce apoptosis, but did not block retinal differentiation. Although continuous ethanol exposure induces substantial accumulation of reactive oxygen species (ROS) and increases p53 expression, depletion of p53 did not eliminate ethanol-induced apoptosis. On the other hand, sequestering ROS with the antioxidant reagent N-acetylcysteine (NAC) successfully inhibited ethanol-associated apoptosis, suggesting that the ethanol-induced cell death primarily results from ROS accumulation. Continuous ethanol treatment of embryos reduced expression of the mature neural and photoreceptor markers elavl3/huC, rho, and crx; in addition, expression of the neural and retinal progenitor markers ascl1b and pax6b was maintained at the undifferentiated stage, indicating that retinal and CNS neural progenitor cells failed to undergo further differentiation. Moreover, ethanol treatment enhanced BrdU incorporation, histone H3 phosphorylation, and pcna expression in neural progenitor cells, thereby maintaining a high rate of proliferation. Ethanol treatment also resulted in sustained transcription of ccnd1/cyclin D1 and ccne/cyclin E throughout development in neural progenitor cells, without an appropriate increase of cdkn1b/p27 and cdkn1c/p57 expression, suggesting that these cells failed to exit from the cell cycle. Although NAC was able to mitigate ethanol-mediated apoptosis, it was unable to ameliorate the defects in visual and CNS neural differentiation, suggesting that abrogated neural development in ethanol-exposed embryos is unlikely to arise from excessive apoptosis. In conclusion, we demonstrate that the pathological effect of ethanol on zebrafish embryos is partially attributable to cell death and inhibition of visual and CNS neuron differentiation. Excessive apoptosis largely results from the accumulation of ROS, whereas abrogated neural development is caused by failure of cell cycle arrest, which in turn prevents a successful transition from proliferation to differentiation.
胚胎发育期接触酒精会导致多种发育障碍。在这里,我们证明持续暴露于 1.5%乙醇会导致斑马鱼胚胎大量凋亡,并破坏视网膜和中枢神经系统的发育。孵化前 24 小时慢性接触乙醇也会诱导凋亡和视网膜紊乱。在受精后 2 天(dpf)阶段后,慢性接触乙醇继续诱导凋亡,但不阻止视网膜分化。尽管持续的乙醇暴露会导致大量活性氧(ROS)的积累并增加 p53 的表达,但耗尽 p53 并不能消除乙醇诱导的凋亡。另一方面,用抗氧化剂 N-乙酰半胱氨酸(NAC)隔离 ROS 成功抑制了与乙醇相关的凋亡,表明乙醇诱导的细胞死亡主要是由 ROS 积累引起的。胚胎的连续乙醇处理降低了成熟的神经和光感受器标记物 elavl3/huC、rho 和 crx 的表达;此外,神经和视网膜祖细胞标记物 ascl1b 和 pax6b 的表达保持在未分化阶段,表明视网膜和中枢神经系统神经祖细胞未能进一步分化。此外,乙醇处理增强了神经祖细胞中 BrdU 的掺入、组蛋白 H3 的磷酸化和 pcna 的表达,从而保持了较高的增殖率。乙醇处理还导致 ccnd1/cyclin D1 和 ccne/cyclin E 在神经祖细胞中的转录持续存在,而没有适当增加 cdkn1b/p27 和 cdkn1c/p57 的表达,表明这些细胞未能从细胞周期中退出。尽管 NAC 能够减轻乙醇介导的凋亡,但它不能改善视觉和中枢神经系统神经分化的缺陷,这表明暴露于乙醇的胚胎中神经发育的中断不太可能是由于过度凋亡引起的。总之,我们证明乙醇对斑马鱼胚胎的病理影响部分归因于细胞死亡和视觉及中枢神经系统神经元分化的抑制。过量的凋亡主要是由于 ROS 的积累,而神经发育的中断是由于细胞周期停滞失败,从而阻止了从增殖到分化的成功转变。
