Coral high molecular weight carbohydrates support opportunistic microbes in bacterioplankton from an algae-dominated reef.

IF 5 2区 生物学 Q1 MICROBIOLOGY mSystems Pub Date : 2024-10-22 DOI:10.1128/msystems.00832-24
Bianca M Thobor, Andreas F Haas, Christian Wild, Craig E Nelson, Linda Wegley Kelly, Jan-Hendrik Hehemann, Milou G I Arts, Meine Boer, Hagen Buck-Wiese, Nguyen P Nguyen, Inga Hellige, Benjamin Mueller
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Abstract

High molecular weight (HMW; >1 kDa) carbohydrates are a major component of dissolved organic matter (DOM) released by benthic primary producers. Despite shifts from coral to algae dominance on many reefs, little is known about the effects of exuded carbohydrates on bacterioplankton communities in reef waters. We compared the monosaccharide composition of HMW carbohydrates exuded by hard corals and brown macroalgae and investigated the response of the bacterioplankton community of an algae-dominated Caribbean reef to the respective HMW fractions. HMW coral exudates were compositionally distinct from the ambient, algae-dominated reef waters and similar to coral mucus (high in arabinose). They further selected for opportunistic bacterioplankton taxa commonly associated with coral stress (i.e., Rhodobacteraceae, Phycisphaeraceae, Vibrionaceae, and Flavobacteriales) and significantly increased the predicted energy-, amino acid-, and carbohydrate-metabolism by 28%, 44%, and 111%, respectively. In contrast, HMW carbohydrates exuded by algae were similar to those in algae tissue extracts and reef water (high in fucose) and did not significantly alter the composition and predicted metabolism of the bacterioplankton community. These results confirm earlier findings of coral exudates supporting efficient trophic transfer, while algae exudates may have stimulated microbial respiration instead of biomass production, thereby supporting the microbialization of reefs. In contrast to previous studies, HMW coral and not algal exudates selected for opportunistic microbes, suggesting that a shift in the prevalent DOM composition and not the exudate type (i.e., coral vs algae) per se, may induce the rise of opportunistic microbial taxa.

Importance: Dissolved organic matter (DOM) released by benthic primary producers fuels coral reef food webs. Anthropogenic stressors cause shifts from coral to algae dominance on many reefs, and resulting alterations in the DOM pool can promote opportunistic microbes and potential coral pathogens in reef water. To better understand these DOM-induced effects on bacterioplankton communities, we compared the carbohydrate composition of coral- and macroalgae-DOM and analyzed the response of bacterioplankton from an algae-dominated reef to these DOM types. In line with the proposed microbialization of reefs, coral-DOM was efficiently utilized, promoting energy transfer to higher trophic levels, whereas macroalgae-DOM likely stimulated microbial respiration over biomass production. Contrary to earlier findings, coral- and not algal-DOM selected for opportunistic microbial taxa, indicating that a change in the prevalent DOM composition, and not DOM type, may promote the rise of opportunistic microbes. Presented results may also apply to other coastal marine ecosystems undergoing benthic community shifts.

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珊瑚高分子量碳水化合物支持藻类为主的珊瑚礁浮游细菌中的机会微生物。
高分子量(HMW;>1 kDa)碳水化合物是底栖初级生产者释放的溶解有机物(DOM)的主要成分。尽管许多珊瑚礁已从珊瑚为主转变为藻类为主,但人们对排出的碳水化合物对珊瑚礁水域浮游细菌群落的影响知之甚少。我们比较了硬珊瑚和褐巨藻渗出的高分子量碳水化合物的单糖组成,并研究了以藻类为主的加勒比海珊瑚礁中的浮游细菌群落对各自的高分子量组分的反应。高分子量珊瑚渗出物的成分与环境中藻类占主导地位的珊瑚礁水不同,与珊瑚粘液(阿拉伯糖含量高)相似。它们进一步选择了通常与珊瑚应激有关的机会性浮游细菌类群(即罗杆菌科、藻类、纤毛虫科和黄杆菌科),并使预测的能量代谢、氨基酸代谢和碳水化合物代谢分别显著增加了 28%、44% 和 111%。相比之下,藻类渗出的高分子量碳水化合物与藻类组织提取物和珊瑚礁水中的碳水化合物相似(富含岩藻糖),并没有明显改变浮游细菌群落的组成和预测代谢。这些结果证实了之前的研究结果,即珊瑚的渗出物支持有效的营养传递,而藻类的渗出物可能刺激了微生物的呼吸作用,而不是生物量的产生,从而支持了珊瑚礁的微生物化。与以往研究不同的是,高分子量珊瑚而非藻类渗出物选择了机会性微生物,这表明普遍存在的溶解有机物(DOM)成分的变化,而非渗出物类型(即珊瑚与藻类)本身,可能会诱发机会性微生物类群的增加:重要性:底栖初级生产者释放的溶解有机物(DOM)为珊瑚礁食物网提供了燃料。人为压力因素导致许多珊瑚礁从珊瑚为主转变为藻类为主,由此引起的溶解有机物库的变化会促进珊瑚礁水中机会性微生物和潜在珊瑚病原体的繁殖。为了更好地了解这些 DOM 对浮游细菌群落的影响,我们比较了珊瑚和大型藻类 DOM 的碳水化合物组成,并分析了以藻类为主的珊瑚礁中的浮游细菌对这些 DOM 类型的反应。与所提出的珊瑚礁微生物化的观点一致,珊瑚-DOM 被有效利用,促进了能量向更高营养级的转移,而大型藻类-DOM 很可能刺激了微生物的呼吸作用,而不是生物量的产生。与之前的研究结果相反,珊瑚-而非藻类-DOM 选择了机会微生物类群,这表明主要 DOM 成分的变化,而非 DOM 类型的变化,可能会促进机会微生物的崛起。这些结果可能也适用于正在经历底栖生物群落变化的其他沿海海洋生态系统。
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来源期刊
mSystems
mSystems Biochemistry, Genetics and Molecular Biology-Biochemistry
CiteScore
10.50
自引率
3.10%
发文量
308
审稿时长
13 weeks
期刊介绍: mSystems™ will publish preeminent work that stems from applying technologies for high-throughput analyses to achieve insights into the metabolic and regulatory systems at the scale of both the single cell and microbial communities. The scope of mSystems™ encompasses all important biological and biochemical findings drawn from analyses of large data sets, as well as new computational approaches for deriving these insights. mSystems™ will welcome submissions from researchers who focus on the microbiome, genomics, metagenomics, transcriptomics, metabolomics, proteomics, glycomics, bioinformatics, and computational microbiology. mSystems™ will provide streamlined decisions, while carrying on ASM''s tradition of rigorous peer review.
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