Key Laboratory of East China Sea Fishery Resources Exploitation, Ministry of Agriculture and Rural Affairs, East China Sea Fisheries Research Institute, Chinese Academy of Fishery Sciences, No.300 Jungong Road, Yangpu Area, Shanghai, 200090, People's Republic of China.
College of Fisheries and Life Science, Shanghai Ocean University, Pudong New Area, Shanghai, People's Republic of China.
Mar Biotechnol (NY). 2024 Dec;26(6):1246-1259. doi: 10.1007/s10126-024-10369-x. Epub 2024 Sep 9.
As a prerequisite for the success of embryo development, embryonic genome activation (EGA) is an important biological event in which zygotic gene products in the embryo are activated to replace maternal-derived transcripts. Although EGA has been extensively studied in a large number of vertebrates and invertebrates, there is a lack of information regarding this event in crustacean crab. In this study, the timing of EGA was confirmed by examining a transcriptomic dataset of early embryonic development, including mature oocytes and embryos through six early developmental stages, and signaling pathways associated with EGA were identified in the mud crab, S. paramamosain. The comprehensive transcriptomic data identified a total of 53,915 transcripts from these sequencing samples. Notable transcriptomic change was evident at the 1-cell stage, indicated by a 36% transcript number shift and a reduction in transcript fragment length, compared to those present in the mature oocytes. Concurrently, a substantial increase in the expression of newly transcribed transcripts was observed, with gene counts reaching 3485 at the 1-cell stage, indicative of the onset of EGA. GO functional enrichment revealed key biological processes initiated at the 1-cell stage, such as protein complex formation, protein metabolism, and various biosynthetic processes. KEGG analysis identified several critical signaling pathways activated during EGA, including the "cell cycle," "spliceosome," "RNA degradation", and "RNA polymerase", pathways. Furthermore, transcription factor families, including zinc finger, T-box, Nrf1, and Tub were predominantly enriched at the 1-cell stage, suggesting their pivotal roles in regulating embryonic development through the targeting of specific DNA sequences during the EGA process. This groundbreaking study not only addresses a significant knowledge gap regarding the developmental biology of S. paramamosain, especially for the understanding of the mechanism underlying EGA, but also provides scientific data crucial for the research on the individual synchronization of seed breeding within S. paramamosain aquaculture. Additionally, it serves as a reference basis for the study of early embryonic development in other crustacean species.
作为胚胎发育成功的前提条件,胚胎基因组激活(EGA)是一个重要的生物学事件,在此过程中,胚胎中的合子基因产物被激活以取代母体来源的转录本。尽管在大量的脊椎动物和无脊椎动物中对 EGA 进行了广泛的研究,但在甲壳类蟹中,关于这一事件的信息却很缺乏。在这项研究中,通过检查早期胚胎发育的转录组数据集,包括成熟卵母细胞和六个早期发育阶段的胚胎,证实了 EGA 的时间,同时在泥蟹 Scylla paramamosain 中确定了与 EGA 相关的信号通路。从这些测序样本中总共鉴定出了 53915 个转录本。在 1 细胞阶段,转录组发生了显著变化,表现为转录本数量变化了 36%,转录本片段长度减少,与成熟卵母细胞中的转录本相比。同时,新转录本的表达大量增加,在 1 细胞阶段达到 3485 个基因计数,表明 EGA 的开始。GO 功能富集揭示了在 1 细胞阶段开始的关键生物学过程,如蛋白质复合物形成、蛋白质代谢和各种生物合成过程。KEGG 分析确定了在 EGA 过程中激活的几个关键信号通路,包括“细胞周期”、“剪接体”、“RNA 降解”和“RNA 聚合酶”通路。此外,转录因子家族,包括锌指、T 盒、Nrf1 和 Tub,在 1 细胞阶段主要富集,表明它们在通过靶向 EGA 过程中的特定 DNA 序列来调节胚胎发育方面发挥着关键作用。这项开创性的研究不仅填补了关于 Scylla paramamosain 发育生物学的重大知识空白,特别是对 EGA 机制的理解,而且还为 Scylla paramamosain 水产养殖中个体同步种子繁殖的研究提供了重要的科学数据。此外,它还为其他甲壳类动物早期胚胎发育的研究提供了参考基础。
