Genes involved in carbon, nitrogen, and sulfur cycling in an important estuarine ecosystem show coherent shifts in response to changes in environmental conditions

IF 3.8 1区 地球科学 Q1 LIMNOLOGY Limnology and Oceanography Pub Date : 2024-11-18 DOI:10.1002/lno.12731
Sarah Pacocha Preheim, Shaina Morris, Yue Zhang, Chris Holder, Keith Arora‐Williams, Paul Gensbigler, Amanda Hinton, Rui Jin, Marie‐Aude Pradal, Morgan Buchanan, Anand Gnanadesikan
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Abstract

While metagenomics can provide insight into microbial community metabolic potential, understanding factors that influence gene abundance is necessary to maximize the information gained from this analysis. Gene abundances are influenced by chemical or physical conditions along with other factors, such as copy number variation between taxa, methodological biases, or issues associated with identification and classification. Here, we identify major drivers of spatiotemporal shifts in microbial gene relative abundance from multiple months, sites, and depths within Chesapeake Bay in 2017 using shotgun metagenomics. We compared changes in relative abundance of key genes for bacterial photosynthesis, nitrogen, and sulfur metabolism with each other and measured environmental variables. Major drivers of differences in key metabolic gene abundances are associated with environmental variables that largely change with depth and season (e.g., temperature, oxygen, phosphate). For sulfur oxidation, bacterial photosynthesis, and denitrification, genes within each process are generally significantly correlated with each other and with several environmental variables. For other processes, such as nitrification, nitrogen fixation, and dissimilatory nitrate reduction to ammonium, genes that encode enzymes within the same pathway are not well correlated. The lack of correlation typically results from differences in identified taxa carrying these genes, suggesting modular pathway structure, methodological errors, or discrepancies in gene copy number between taxonomic groups. To be suitable indicators of biogeochemical processes for models, genes or pathways should be strongly correlated with environmental variables and specific to and inclusive of all taxa mediating the associated process.
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在一个重要的河口生态系统中,参与碳、氮和硫循环的基因随着环境条件的变化而发生一致的变化
虽然元基因组学可以让人们深入了解微生物群落的代谢潜力,但要想最大限度地利用这一分析所获得的信息,就必须了解影响基因丰度的因素。基因丰度受到化学或物理条件以及其他因素的影响,例如类群之间的拷贝数差异、方法偏差或与鉴定和分类相关的问题。在此,我们利用霰弹枪元基因组学确定了 2017 年切萨皮克湾内多个月份、地点和深度的微生物基因相对丰度时空变化的主要驱动因素。我们比较了细菌光合作用、氮和硫代谢关键基因相对丰度的变化,并测量了环境变量。关键代谢基因丰度差异的主要驱动因素与环境变量有关,而环境变量主要随深度和季节(如温度、氧气、磷酸盐)而变化。在硫氧化、细菌光合作用和反硝化过程中,每个过程中的基因之间以及与几个环境变量之间一般都有显著的相关性。至于其他过程,如硝化、固氮和将硝酸盐还原成氨的异氨作用,同一途径中编码酶的基因之间的相关性不强。缺乏相关性的典型原因是携带这些基因的已识别类群存在差异,这表明存在模块化途径结构、方法错误或类群间基因拷贝数的差异。要成为生物地球化学过程模型的合适指标,基因或通路应与环境变量密切相关,并对所有介导相关过程的类群具有特异性和包容性。
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来源期刊
Limnology and Oceanography
Limnology and Oceanography 地学-海洋学
CiteScore
8.80
自引率
6.70%
发文量
254
审稿时长
3 months
期刊介绍: Limnology and Oceanography (L&O; print ISSN 0024-3590, online ISSN 1939-5590) publishes original articles, including scholarly reviews, about all aspects of limnology and oceanography. The journal''s unifying theme is the understanding of aquatic systems. Submissions are judged on the originality of their data, interpretations, and ideas, and on the degree to which they can be generalized beyond the particular aquatic system examined. Laboratory and modeling studies must demonstrate relevance to field environments; typically this means that they are bolstered by substantial "real-world" data. Few purely theoretical or purely empirical papers are accepted for review.
期刊最新文献
Advancing an integrated understanding of land–ocean connections in shaping the marine ecosystems of coastal temperate rainforest ecoregions Life in turbulent waters: unsteady biota–flow interactions across scales Genes involved in carbon, nitrogen, and sulfur cycling in an important estuarine ecosystem show coherent shifts in response to changes in environmental conditions Diel dissolved organic matter patterns reflect spatiotemporally varying sources and transformations along an intermittent stream Differential impacts of temperature increase on prokaryotes across temperature regimes in subtropical coastal waters: insights from field experiments
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