Department of Plant Biology, University of Illinois at Urbana-Champaign, Urbana, Illinois, 61801, USA.
Department of Biological Sciences, Eastern Illinois University, Charleston, Illinois, 61920, USA.
Ecology. 2020 Sep;101(9):e03097. doi: 10.1002/ecy.3097. Epub 2020 Aug 19.
Wood is a major carbon input into aquatic ecosystems and is thought to decay slowly, yet surprisingly little terrestrial carbon accumulates in marine sediments. A better mechanistic understanding of how habitat conditions and decomposer communities influence wood decay processes along the river-estuary-ocean continuum can address this seeming paradox. We measured mass loss, wood element, and polymer concentrations, quantified invertebrate-induced decay, and sequenced fungal communities associated with replicate sections of Guazuma branch wood submerged in freshwater, estuarine, and near-shore marine habitats and placed on the soil surface in nearby terrestrial habitats in three watersheds in the tropical eastern Pacific. Over 15 months, we found that wood decayed at similar rates in estuarine, marine, and terrestrial sites, reflecting the combined activity of invertebrate and microbial decomposers. In contrast, in the absence of shipworms (Teredinidae), which accounted for ~40% of wood mass loss in the estuarine habitats, decay proceeded more slowly in freshwater. Over the experiment, wood element chemistry diverged among freshwater, estuarine, and marine habitats, due to differences in both nutrient losses (e.g., potassium and phosphorus) and gains (e.g., calcium and aluminum) through decay. Similarly, we observed changes in wood polymer content, with the highest losses of cellulose, hemicellulose, and lignin moieties in the marine habitat. Aquatic fungal communities were strongly dominated by ascomycetes (88-99% of taxa), compared to terrestrial communities (55% ascomycetes). Large differences in fungal diversity were also observed across habitats with threefold higher richness in terrestrial than freshwater habitats and twofold higher diversity in freshwater than estuarine/marine habitats. Divergent decay trajectories across habitats were associated with widespread order-level differences in fungal composition, with distinct communities found in freshwater, estuarine and marine habitats. However, few individual taxa that were significantly associated with mass loss were broadly distributed, suggesting a high level of functional redundancy. The rapid processing of wood entering tropical rivers by microbes and invertebrates, comparable to that on land, indicates that estuaries and coastal oceans are hotspots not just for the processing of particulate and dissolved organic carbon, but also for woody debris and for the breakdown of lignin, the most recalcitrant polymer in plant tissue.
木材是水生生态系统中主要的碳输入源,通常被认为会缓慢腐烂,但令人惊讶的是,海洋沉积物中积累的陆地碳却很少。更好地了解栖息地条件和分解者群落如何影响河流-河口-海洋连续体中的木材腐烂过程,可以解决这一看似矛盾的问题。我们测量了在热带东太平洋三个流域的淡水、河口和近岸海洋栖息地中浸没的瓜祖马树枝的质量损失、木材元素和聚合物浓度,量化了无脊椎动物诱导的腐烂,并对附着在附近陆地栖息地土壤表面的重复样本的真菌群落进行了测序。在 15 个月的时间里,我们发现木材在河口、海洋和陆地栖息地的腐烂速度相似,这反映了无脊椎动物和微生物分解者的综合活动。相比之下,在没有占河口栖息地木材损失约 40%的船蛆(Teredinidae)的情况下,淡水环境中的腐烂速度较慢。在整个实验过程中,由于营养物质损失(如钾和磷)和通过腐烂获得的营养物质(如钙和铝)的差异,淡水、河口和海洋栖息地之间的木材元素化学性质存在差异。同样,我们观察到木材聚合物含量的变化,其中海洋栖息地的纤维素、半纤维素和木质素部分损失最大。与陆地群落(55%的子囊菌)相比,水生真菌群落主要由子囊菌(88-99%的分类群)组成。不同栖息地之间的真菌多样性也存在很大差异,陆地栖息地的丰富度比淡水栖息地高三倍,淡水栖息地的多样性比河口/海洋栖息地高两倍。栖息地之间不同的腐烂轨迹与真菌组成的广泛属级差异有关,在淡水、河口和海洋栖息地中都发现了独特的群落。然而,与质量损失显著相关的少数个别类群分布广泛,表明功能冗余程度较高。微生物和无脊椎动物对进入热带河流的木材的快速处理,与陆地的处理速度相当,这表明河口和沿海海洋不仅是处理颗粒态和溶解态有机碳的热点,也是木质碎屑和木质素分解的热点,木质素是植物组织中最顽固的聚合物。
