揭示了海参Apostichopus japonicus的早期生命核心微生物群和促进生长的亚硫酸盐杆菌的意外丰度。

IF 4.9 Q1 MICROBIOLOGY Animal microbiome Pub Date : 2023-10-24 DOI:10.1186/s42523-023-00276-2
Juanwen Yu, Chunqi Jiang, Ryota Yamano, Shotaro Koike, Yuichi Sakai, Sayaka Mino, Tomoo Sawabe
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引用次数: 0

摘要

背景:生命早期的微生物组对宿主的免疫和生理发育有长期影响,已知其紊乱会引发宿主动物的各种疾病。刺参是亚洲最有价值的海洋无脊椎动物之一,也是再生研究的模式动物。为了了解影响宿主发育和全生物维持的因素,在过去十年中,人们积极研究了宿主微生物组的关联。然而,我们目前缺乏对早期生命核心微生物组在个体发生过程中的知识,以及它如何有益于宿主的生长。结果:我们分析了来自实验室养殖系统的28个海参样本中的微生物群落,该系统旨在复制水产养殖环境,在三年的时间里,跨越六个发育阶段(受精卵到幼年期),以检查微生物组的动态和稳定性。在每种情况下,海参幼虫个体发生过程中都会发生微生物组的变化。应用最复杂的核心微生物组提取方法,这是一种具有丰度占用核心微生物组分析的混合方法(总读数的前75%和> 70%的职业)和核心指数计算,首次揭示了由Alteromonadae和Rhodobacteria组成的早期生活核心微生物组,以及由a.japonicus中的先驱核心微生物Pseudoalteromonadeae组成的阶段核心微生物组。更有趣的是,四个隶属于Alteromonadae和Rhodobacteriae的ASV被提取为早期生命的核心微生物组。其中一种ASV(ASV0007)隶属于Sulfitobactor菌株BL28(红细菌科),该菌株是从2019年的一批中分离出来的。出乎意料的是,生物测定显示BL28菌株保留了宿主生长促进能力。进一步的宏基因组学方法显示,BL28基因组读数在宏基因组序列库中丰富,特别是在日本血吸虫早期肠道发育后的序列库中。结论:利用实验室水产养殖复制养殖环境和混合核心微生物组提取方法对日本A.japonicus进行反复饲养,首次揭示了属于Alteromonadae和Rhodobacteriae的特定ASV是日本A.jabonicus早期生活的核心微生物组。进一步的生物测定揭示了核心微生物之一,即被鉴定为ASV0007的硫杆菌菌株BL28对寄主海参的生长促进能力。在刺参肠道发育后,BL28的基因组读数丰富,这使我们考虑将这些核心微生物组有效地用于海参资源的生产和保护。该研究还强调了核心微生物组在影响海洋无脊椎动物早期生命阶段方面的重要性。了解这些动态可以为提高海洋无脊椎动物的生长、免疫力和抗病能力提供途径。
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Unveiling the early life core microbiome of the sea cucumber Apostichopus japonicus and the unexpected abundance of the growth-promoting Sulfitobacter.

Background: Microbiome in early life has long-term effects on the host's immunological and physiological development and its disturbance is known to trigger various diseases in host Deuterostome animals. The sea cucumber Apostichopus japonicus is one of the most valuable marine Deuterostome invertebrates in Asia and a model animal in regeneration studies. To understand factors that impact on host development and holobiont maintenance, host-microbiome association has been actively studied in the last decade. However, we currently lack knowledge of early life core microbiome during its ontogenesis and how it benefits the host's growth.

Results: We analyzed the microbial community in 28 sea cucumber samples from a laboratory breeding system, designed to replicate aquaculture environments, across six developmental stages (fertilized eggs to the juvenile stage) over a three years-period to examine the microbiomes' dynamics and stability. Microbiome shifts occurred during sea cucumber larval ontogenesis in every case. Application of the most sophisticated core microbiome extraction methodology, a hybrid approach with abundance-occupancy core microbiome analyses (top 75% of total reads and > 70% occupation) and core index calculation, first revealed early life core microbiome consisted of Alteromonadaceae and Rhodobacteraceae, as well as a stage core microbiome consisting of pioneer core microbe Pseudoalteromonadaceae in A. japonicus, suggesting a stepwise establishment of microbiome related to ontogenesis and feeding behavior in A. japonicus. More interestingly, four ASVs affiliated to Alteromonadaceae and Rhodobacteraceae were extracted as early life core microbiome. One of the ASV (ASV0007) was affiliated to the Sulfitobactor strain BL28 (Rhodobacteraceae), isolated from blastula larvae in the 2019 raring batch. Unexpectedly, a bioassay revealed the BL28 strain retains a host growth-promoting ability. Further meta-pangenomics approach revealed the BL28 genome reads were abundant in the metagenomic sequence pool, in particular, in that of post-gut development in early life stages of A. japonicus.

Conclusion: Repeated rearing efforts of A. japonicus using laboratory aquaculture replicating aquaculture environments and hybrid core microbiome extraction approach first revealed particular ASVs affiliated to Alteromonadaceae and Rhodobacteraceae as the A. japonicus early life core microbiome. Further bioassay revealed the growth promoting ability to the host sea cucumber in one of the core microbes, the Sulfitobactor strain BL28 identified as ASV0007. Genome reads of the BL28 were abundant in post-gut development of A. japonicus, which makes us consider effective probiotic uses of those core microbiome for sea cucumber resource production and conservation. The study also emphasizes the importance of the core microbiome in influencing early life stages in marine invertebrates. Understanding these dynamics could offer pathways to improve growth, immunity, and disease resistance in marine invertebrates.

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