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丰富且活跃的群落成员对温泉光合生物膜中的昼夜循环做出反应。

Abundant and active community members respond to diel cycles in hot spring phototrophic mats.

作者信息

Shelton Amanda N, Yu Feiqiao B, Grossman Arthur R, Bhaya Devaki

机构信息

Division of Biosphere Sciences and Engineering, Carnegie Science, Stanford, CA 94305, United States.

MultiOmics Tech Center, Arc Institute, Palo Alto, CA 94304, United States.

出版信息

ISME J. 2025 Jan 2;19(1). doi: 10.1093/ismejo/wraf001.

DOI:10.1093/ismejo/wraf001
PMID:39777507
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11788075/
Abstract

Photosynthetic microbial mats in hot springs can provide insights into the diel behaviors of communities in extreme environments. In this habitat, photosynthesis dominates during the day, leading to super-oxic conditions, with a rapid transition to fermentation and anoxia at night. Multiple samples were collected from two springs over several years to generate metagenomic and metatranscriptomic datasets. Metagenome-assembled genomes comprised 71 taxa (in 19 different phyla), of which 12 core taxa were present at high abundance in both springs. The eight most active taxa identified by metatranscriptomics were an oxygenic cyanobacterium (Synechococcus sp.), five anoxygenic phototrophs from three different phyla, and two understudied heterotrophs from phylum Armatimonadota. In all eight taxa, a significant fraction of genes exhibited a diel expression pattern, although peak timing varied considerably. The two abundant heterotrophs exhibit starkly different peak timing of expression, which we propose is shaped by their metabolic and genomic potential to use carbon sources that become differentially available during the diel cycle. Network analysis revealed pathway expression patterns that had not previously been linked to diel cycles, including ribosome biogenesis and chaperones. This provides a framework for analyzing metabolically coupled communities and the dominant role of the diel cycle.

摘要

温泉中的光合微生物垫能够为极端环境中群落的昼夜行为提供见解。在这个栖息地,光合作用在白天占主导地位,导致超氧环境,而在夜间迅速转变为发酵和缺氧状态。多年来从两个温泉中采集了多个样本,以生成宏基因组和宏转录组数据集。宏基因组组装的基因组包含71个分类单元(分属于19个不同的门),其中12个核心分类单元在两个温泉中均以高丰度存在。通过宏转录组学鉴定出的八个最活跃的分类单元分别是一种产氧蓝细菌(聚球藻属)、来自三个不同门的五种不产氧光合生物,以及来自装甲菌门的两种研究较少的异养生物。在所有八个分类单元中,尽管峰值时间差异很大,但相当一部分基因呈现出昼夜表达模式。这两种丰富的异养生物表现出截然不同的表达峰值时间,我们认为这是由它们利用在昼夜循环中差异可用的碳源的代谢和基因组潜力所塑造的。网络分析揭示了以前未与昼夜循环相关联的途径表达模式,包括核糖体生物合成和伴侣蛋白。这为分析代谢耦合群落以及昼夜循环的主导作用提供了一个框架。

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