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对卵形鲳鲹早期生命阶段微生物群的机制性见解。

Mechanistic insights into the early life stage microbiota of silver pompano ().

作者信息

Sumithra T G, Sharma S R Krupesha, Suresh Gayathri, Gop Ambarish P, Surya S, Gomathi P, Anil M K, Sajina K A, Reshma K J, Ebeneezar Sanal, Narasimapallavan Iyyapparaja, Gopalakrishnan A

机构信息

Marine Biotechnology, Fish Nutrition, and Health Division, ICAR-Central Marine Fisheries Research Institute (CMFRI), Kochi, India.

Cochin University of Science and Technology, Kochi, Kerala, India.

出版信息

Front Microbiol. 2024 Apr 17;15:1356828. doi: 10.3389/fmicb.2024.1356828. eCollection 2024.

DOI:10.3389/fmicb.2024.1356828
PMID:38694807
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11061439/
Abstract

INTRODUCTION

Deep investigations of host-associated microbiota can illuminate microbe-based solutions to improve production in an unprecedented manner. The poor larval survival represents the critical bottleneck in sustainable marine aquaculture practices. However, little is known about the microbiota profiles and their governing eco-evolutionary processes of the early life stages of marine teleost, impeding the development of suitable beneficial microbial management strategies. The study provides first-hand mechanistic insights into microbiota and its governing eco-evolutionary processes in early life stages of a tropical marine teleost model, .

METHODS

The microbiota profiles and their dynamics from the first day of hatching till the end of metamorphosis and that of fingerling's gut during the routine hatchery production were studied using 16S rRNA amplicon-based high-throughput sequencing. Further, the relative contributions of various external factors (rearing water, live feed, microalgae, and formulated feed) to the microbiota profiles at different ontogenies was also analyzed.

RESULTS

A less diverse but abundant core microbial community (~58% and 54% in the whole microbiota and gut microbiota, respectively) was observed throughout the early life stages, supporting 'core microbiota' hypothesis. Surprisingly, there were two well-differentiated clusters in the whole microbiota profiles, ≤10 DPH (days post-hatching) and > 10 DPH samples. The levels of microbial taxonomic signatures of stress indicated increased stress in the early stages, a possible explanation for increased mortality during early life stages. Further, the results suggested an adaptive mechanism for establishing beneficial strains along the ontogenetic progression. Moreover, the highly transient microbiota in the early life stages became stable along the ontogenetic progression, hypothesizing that the earlier life stages will be the best window to influence the microbiota. The egg microbiota also crucially affected the microbial community. Noteworthily, both water and the feed microbiota significantly contributed to the early microbiota, with the feed microbiota having a more significant contribution to fish microbiota. The results illustrated that rotifer enrichment would be the optimal medium for the early larval microbiota manipulations.

CONCLUSION

The present study highlighted the crucial foundations for the microbial ecology of during early life stages with implications to develop suitable beneficial microbial management strategies for sustainable mariculture production.

摘要

引言

对宿主相关微生物群的深入研究能够以前所未有的方式揭示基于微生物的解决方案,从而提高产量。幼体存活率低是可持续海水养殖实践中的关键瓶颈。然而,对于硬骨鱼类早期生命阶段的微生物群概况及其主导的生态进化过程知之甚少,这阻碍了合适的有益微生物管理策略的发展。本研究为热带硬骨鱼类模型早期生命阶段的微生物群及其主导的生态进化过程提供了第一手的机制性见解。

方法

使用基于16S rRNA扩增子的高通量测序技术,研究了从孵化第一天到变态结束期间的微生物群概况及其动态变化,以及常规孵化场生产过程中幼鱼肠道的微生物群概况。此外,还分析了不同个体发育阶段各种外部因素(养殖用水、活饵、微藻和配合饲料)对微生物群概况的相对贡献。

结果

在整个早期生命阶段观察到一个多样性较低但丰富的核心微生物群落(分别占整个微生物群和肠道微生物群的约58%和54%),支持“核心微生物群”假说。令人惊讶的是,在整个微生物群概况中,存在两个明显分化的聚类,即孵化后≤10天(DPH)和>10 DPH的样本。应激的微生物分类特征水平表明早期阶段应激增加,这可能是早期生命阶段死亡率增加的一个解释。此外,结果表明在个体发育过程中建立有益菌株的一种适应机制。而且,早期生命阶段高度 transient 的微生物群在个体发育过程中变得稳定,推测早期生命阶段将是影响微生物群的最佳窗口。鱼卵微生物群也对微生物群落有至关重要的影响。值得注意的是,水和饲料微生物群对早期微生物群都有显著贡献,其中饲料微生物群对鱼类微生物群的贡献更为显著。结果表明,轮虫强化将是早期幼体微生物群操纵的最佳媒介。

结论

本研究突出了 早期生命阶段微生物生态学的关键基础,对为可持续海水养殖生产制定合适的有益微生物管理策略具有启示意义。

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