Han He, Ji Mengzhi, Li Yan, Gong Xiaofan, Song Wen, Zhou Jiayin, Ma Kai, Zhou Yuqi, Liu Xia, Wang Mengqi, Li Yueyue, Tu Qichao
Institute of Marine Science and Technology, Shandong University, Qingdao, Shandong, China.
Qingdao Key Laboratory of Ocean Carbon Sequestration and Negative Emission Technology, Shandong University, Qingdao, Shandong, China.
mSystems. 2025 Jul 22;10(7):e0041325. doi: 10.1128/msystems.00413-25. Epub 2025 Jun 12.
Eukaryotes, both micro- and macro-, constitute the dominant component of Earth's biosphere visible to the naked eye. Although relatively big in organismal size, tracing eukaryotic diversity in complex environments is not easy. For example, they may actively escape from sampling and be physically absent from the collected samples. In this study, we strived to recover non-fungal eukaryotic DNA sequences from typical shotgun metagenomes in the complex mudflat intertidal zones. Multiple recently developed approaches for identifying eukaryotic sequences from shotgun metagenomes were comparatively assessed. Considering the low overlap among different approaches, an integrative workflow was proposed. The integrative workflow was then used to recover the eukaryotic communities in complex intertidal sediments. The temporal dynamics of intertidal eukaryotic communities were investigated through a time-series sampling effort. Thirty-four non-fungal eukaryotic phyla were detected from 36 shotgun metagenomes. Clear temporal variation in relative abundance was observed for eukaryotic genera such as and . Strong temporal turnover of intertidal eukaryotic communities was observed. By comparing to 18S rRNA gene amplicon sequencing, dramatically different community profiles were observed between these two approaches. However, the temporal patterns for intertidal eukaryotic communities recovered by both approaches were generally comparable. This study provides valuable technical insights into the recovery of non-fungal eukaryotic information from complex environments and demonstrates an alternative route for reusing the massive metagenomic data sets generated in the past and future.IMPORTANCEEukaryotes represent the dominant component visible to the naked eye and contribute to the primary biomass in the Earth's biosphere. Yet, tracing the eukaryotic diversity in complex environments remains difficult, as they can actively move around and escape from sampling. Here, using the intertidal sediments as an example, we strived to retrieve non-fungal eukaryotic sequences from typical shotgun metagenomes. Compared to 18S rRNA gene amplicon sequencing, the shotgun metagenome-based approach resolved dramatically different eukaryotic community profiles, though comparable ecological patterns could be observed. This study paves an alternative way for utilizing shotgun metagenomic data to recover non-fungal eukaryotic information in complex environments, demonstrating significant potential for environmental monitoring and biodiversity investigations.
真核生物,无论微观还是宏观的,都是肉眼可见的地球生物圈的主要组成部分。尽管生物体尺寸相对较大,但在复杂环境中追踪真核生物多样性并非易事。例如,它们可能会主动避开采样,导致采集的样本中实际不存在。在本研究中,我们致力于从复杂潮间带泥滩的典型鸟枪法宏基因组中恢复非真菌真核生物的DNA序列。我们对多种最近开发的从鸟枪法宏基因组中识别真核生物序列的方法进行了比较评估。考虑到不同方法之间重叠性较低,我们提出了一种综合流程。然后使用该综合流程来恢复复杂潮间带沉积物中的真核生物群落。通过时间序列采样研究了潮间带真核生物群落的时间动态。从36个鸟枪法宏基因组中检测到34个非真菌真核生物门。观察到真核生物属(如 和 )的相对丰度存在明显的时间变化。观察到潮间带真核生物群落有强烈的时间更替。与18S rRNA基因扩增子测序相比,这两种方法观察到的群落概况有显著差异。然而,两种方法恢复的潮间带真核生物群落的时间模式总体上具有可比性。本研究为从复杂环境中恢复非真菌真核生物信息提供了有价值的技术见解,并展示了一条重新利用过去和未来产生的大量宏基因组数据集的替代途径。
重要性
真核生物是肉眼可见的主要组成部分,对地球生物圈的初级生物量有贡献。然而,在复杂环境中追踪真核生物多样性仍然困难,因为它们可以四处移动并避开采样。在这里,以潮间带沉积物为例,我们致力于从典型的鸟枪法宏基因组中检索非真菌真核生物序列。与18S rRNA基因扩增子测序相比,基于鸟枪法宏基因组的方法解析出了截然不同的真核生物群落概况,尽管可以观察到可比的生态模式。本研究为利用鸟枪法宏基因组数据在复杂环境中恢复非真菌真核生物信息铺平了一条替代道路,显示出在环境监测和生物多样性调查方面的巨大潜力。
