State Key Laboratory for Marine Environmental Science, Collage of Ocean and Earth Sciences, Xiamen University, Xiamen, 361102, People's Republic of China.
Institute of Marine Microbes and Ecospheres, Xiamen University, Xiamen, 361102, People's Republic of China.
Environ Microbiol. 2019 Jul;21(7):2533-2543. doi: 10.1111/1462-2920.14646. Epub 2019 May 31.
In this study, we investigated the microbially mediated transformation of labile Synechococcus-derived DOM to RDOM using a 60-day experimental incubation system. Three phases of TOC degradation activity (I, II and III) were observed following the addition of Synechococcus-derived DOM. The phases were characterized by organic carbon consumption rates of 8.77, 1.26 and 0.16 μmol L day , respectively. Excitation emission matrix analysis revealed the presence of three FDOM components including tyrosine-like, fulvic acid-like, and humic-like molecules. The three components also exhibited differing biological availabilities that could be considered as labile DOM (LDOM), semi-labile DOM (SLDOM) and RDOM, respectively. DOM molecular composition was also evaluated using FT-ICR MS. Based on differing biological turnover rates and normalized intensity values, a total of 1704 formulas were identified as candidate LDOM, SLDOM and RDOM molecules. Microbial transformation of LDOM to RDOM tended to proceed from high to low molecular weight, as well as from molecules with high to low double bond equivalent (DBE) values. Relatively higher aromaticity was observed in the formulas of RDOM molecules relative to those of LDOM molecules. FDOM components provide valuable proxy information to investigate variation in the bioavailability of DOM. These results suggest that coordinating fluorescence spectroscopy and FT-ICR MS of DOM, as conducted here, is an effective strategy to identify and characterize LDOM, SLDOM and RDOM molecules in incubation experiments emulating natural systems. The results described here provide greater insight into the metabolism of phytoplankton photosynthate by heterotrophic bacteria in marine environments.
在这项研究中,我们使用为期 60 天的实验培养系统,研究了不稳定的聚球藻衍生 DOM 被微生物转化为 RDOM 的过程。添加聚球藻衍生 DOM 后,观察到 TOC 降解活性的三个阶段(I、II 和 III)。这三个阶段的有机碳消耗率分别为 8.77、1.26 和 0.16 μmol L 天。激发发射矩阵分析显示存在三种 FDOM 成分,包括酪氨酸样、富里酸样和腐殖酸样分子。这三种成分也表现出不同的生物可利用性,可以分别视为易降解 DOM(LDOM)、半易降解 DOM(SLDOM)和 RDOM。还使用 FT-ICR MS 评估 DOM 的分子组成。基于不同的生物周转率和归一化强度值,共鉴定出 1704 个公式作为候选的 LDOM、SLDOM 和 RDOM 分子。LDOM 向 RDOM 的微生物转化倾向于从高分子量到低分子量,以及从高双烯当量(DBE)值的分子到低双烯当量值的分子。与 LDOM 分子相比,RDOM 分子的公式中观察到相对较高的芳香度。FDOM 成分提供了有价值的代理信息,可用于研究 DOM 生物利用度的变化。这些结果表明,在这里进行的 DOM 的荧光光谱学和 FT-ICR MS 的协调是一种有效的策略,可以在模拟自然系统的孵育实验中识别和表征 LDOM、SLDOM 和 RDOM 分子。这里描述的结果提供了对海洋环境中异养细菌对浮游植物光合作用产物代谢的更深入了解。
