Genomic prediction of symbiotic interactions between two Endozoicomonas clades and their coral host, Acropora loripes.

IF 4.4 Q1 MICROBIOLOGY

Animal microbiome Pub Date : 2025-09-25 DOI:10.1186/s42523-025-00455-3

Cecilie R Gotze, Kshitij Tandon, Gayle K Philip, Ashley M Dungan, Justin Maire, Lone Høj, Linda L Blackall, Madeleine J H van Oppen

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Abstract

Background: The bacterial genus Endozoicomonas is a predominant member of the coral microbiome, widely recognised for its ubiquity and ability to form high-density aggregates within coral tissues. Hence, investigating its metabolic interplay with coral hosts offers critical insights into its ecological roles and contributions to coral health and resilience.

Results: Using long- and short-read whole-genome sequencing of 11 Endozoicomonas strains from Acropora loripes, genome sizes were found to range between 5.8 and 7.1 Mbp. Phylogenomic analysis identified two distinct clades within the family Endozoicomonadaceae. Metabolic reconstruction uncovered clade-specific pathways, including the degradation of holobiont-derived carbon and lipids (e.g., galactose, starch, triacylglycerol, D-glucuronate), the latter of which suggests involvement of Endozoicomonas in host 'sex-type' steroid hormone metabolism. A clade-specific type 6 Secretion System (T6SS) and predicted effector molecules were identified, potentially facilitating coral-bacterium symbiosis. Additionally, genomic analyses revealed diverse phosphorus acquisition strategies, implicating Endozoicomonas in holobiont phosphorus cycling and stress responses.

Conclusions: This study reveals clade-specific genomic signatures of Endozoicomonas supporting its mutualistic lifestyle within corals. Findings suggests possible roles in nutrient cycling, reproductive health, and stress resilience, offering novel insights into coral holobiont functioning.

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两个内生单胞菌枝和它们的珊瑚宿主Acropora loripes之间共生相互作用的基因组预测。

背景：细菌属内生单胞菌是珊瑚微生物组的主要成员，因其普遍存在和在珊瑚组织内形成高密度聚集体的能力而被广泛认可。因此，研究其与珊瑚宿主的代谢相互作用为其生态作用和对珊瑚健康和恢复力的贡献提供了重要的见解。结果：对11株洛氏Acropora looripes内生单胞菌进行长、短读全基因组测序，发现基因组大小在5.8 ~ 7.1 Mbp之间。系统基因组学分析鉴定了内生单胞菌科中两个不同的分支。代谢重建揭示了进化枝特异性途径，包括全胞菌衍生的碳和脂质（如半乳糖、淀粉、甘油三酯、d -葡萄糖酸盐）的降解，后者表明内生单胞菌参与了宿主“性别型”类固醇激素代谢。鉴定出一种分支特异性的6型分泌系统（T6SS）和预测的效应分子，可能促进珊瑚-细菌的共生。此外，基因组分析揭示了不同的磷获取策略，暗示内生单胞菌参与全生物磷循环和胁迫响应。结论：本研究揭示了珊瑚内内生单胞菌支持其共生生活方式的进化支特异性基因组特征。研究结果表明可能在营养循环、生殖健康和应激恢复中起作用，为珊瑚全息生物的功能提供了新的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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