Anoxic seagrass leaf environments as potential hotspots for toxin production and N2O emission

IF 5.3 3区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES

Marine pollution bulletin Pub Date : 2024-10-17 DOI:10.1016/j.marpolbul.2024.117113

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引用次数: 0

Abstract

Epiphytes on seagrass leaves can render parts of the leaf phyllosphere anoxic in darkness owing to leaf/epiphyte respiration and O₂ diffusion constraints. In such anoxic microenvironments, anaerobic microbes can potentially produce phytotoxins and greenhouse gases, but the actual occurrence of such processes in seagrass epiphytic biofilms remain uncertain.

We used microsensors to measure O₂, NO, N₂O and H₂S concentration gradients, as well as NO and O₂ dynamics within epiphytic biofilms on seagrass (Zostera marina) leaves under changing environmental conditions. The bacterial community composition of epiphytic biofilms was analyzed with 16S rRNA gene amplicon sequencing.

Flavobacteriaceae and Rhodobacteraceae were dominant bacterial community members accounting for ˃50 % of the relative abundance, and sulfate-reducing bacteria (Desulfobacterota) were omnipresent in the epiphytic biofilms. We found pronounced production of NO, N₂O and H₂S in anoxic parts of the seagrass phyllosphere, with NO and H₂S reaching maximal concentrations of 1.0 and 4.4 μmol L⁻¹, respectively, under slow flow and hypoxic seawater conditions, while the highest N₂O concentration in the epiphytic biofilms reached 5.9 μmol L⁻¹ in hypoxic, nitrate-rich seawater. Part of the phytotoxic NO and H₂S diffused into the seagrass leaves, while no NO escaped the biofilm. In contrast, N₂O emission from the biofilm in hypoxic and eutrophic seawater reached 9.6 μmol N₂O m⁻² day⁻¹. Such release of the potent greenhouse gas N₂O from seagrass leaves with epiphytic biofilms under eutrophic conditions could potentially offset the carbon burial capacity of seagrass meadows.

Ocean eutrophication can thus stimulate denitrification and sulfate reduction within anoxic leaf microenvironments, negatively impacting seagrass fitness and ecological function.

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缺氧的海草叶片环境是毒素产生和一氧化二氮排放的潜在热点

由于叶片/附生生物的呼吸作用和氧气扩散限制，海草叶片上的附生生物会使部分叶片植物层在黑暗中缺氧。在这种缺氧的微环境中，厌氧微生物有可能产生植物毒素和温室气体，但这种过程在海草附生生物膜中的实际发生情况仍不确定。我们使用微型传感器测量了环境条件变化下海草（Zostera marina）叶片上附生生物膜内的 O2、NO、N2O 和 H2S 浓度梯度，以及 NO 和 O2 的动态变化。黄杆菌科（Flavobacteriaceae）和罗杆菌科（Rhodobacteraceae）是细菌群落的优势成员，占相对丰度的 50%，硫酸盐还原菌（Desulfobacterota）在附生生物膜中无处不在。我们发现在海草叶球缺氧的部分有明显的 NO、N2O 和 H2S 生成，在慢流和缺氧的海水条件下，NO 和 H2S 的最高浓度分别达到 1.0 和 4.4 μmol L-1，而在缺氧、富含硝酸盐的海水条件下，附生生物膜中 N2O 的最高浓度达到 5.9 μmol L-1。部分具有植物毒性的 NO 和 H2S 扩散到海草叶片中，而没有 NO 从生物膜中逸出。相反，生物膜在缺氧和富营养化海水中的 N2O 排放量达到 9.6 μmol N2O m-2 day-1。因此，海洋富营养化会刺激缺氧叶片微环境中的反硝化作用和硫酸盐还原作用，从而对海草的适应性和生态功能产生负面影响。

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来源期刊

Marine pollution bulletin 环境科学-海洋与淡水生物学

CiteScore

10.20

自引率

15.50%

发文量

1077

审稿时长

68 days

期刊介绍： Marine Pollution Bulletin is concerned with the rational use of maritime and marine resources in estuaries, the seas and oceans, as well as with documenting marine pollution and introducing new forms of measurement and analysis. A wide range of topics are discussed as news, comment, reviews and research reports, not only on effluent disposal and pollution control, but also on the management, economic aspects and protection of the marine environment in general.