Consumer isoscapes reveal heterogeneous food webs in deep-sea submarine canyons and adjacent slopes

IF 3.8 3区 地球科学 Q1 OCEANOGRAPHY
Amanda W.J. Demopoulos , Brian J. Smith , Jill R. Bourque , Jason D. Chaytor , Jennifer McClain-Counts , Nancy Prouty , Steve W. Ross , Sandra Brooke , Gerard Duineveld , Furu Mienis
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引用次数: 0

Abstract

The deep sea is the largest biome on earth, but one of the least studied despite its critical role in global carbon cycling and climate buffering. Deep-sea organisms largely rely on particulate organic matter from the surface ocean for energy – these organisms in turn play critical roles in energy transport, transformation, storage, and sequestration of carbon. Within the deep sea, submarine canyons are amongst the most complex and dynamic environments in our oceans, where varied morphology, powerful currents, and variable nutrient conditions influence the distribution of species and transport of organic material throughout the water column and the seafloor. Significant habitat heterogeneity provides ideal substrates for cold-water corals, making submarine canyons of interest to conservation and management. However, how these and other topographic features in the deep ocean influence energy flow and trophic pathways is poorly known. Thus, submarine canyons serve as model systems to track variability in organic material flux and consequential utilization and assimilation by the benthos. In this study, we used an extensive stable isotope dataset to examine food-web structure in Baltimore and Norfolk submarine canyons and compared them to their adjacent slopes located along the U.S. Atlantic margin. Linear models were used to construct geospatially-explicit consumer isoscapes that predicted variation in carbon and nitrogen isotopes across the canyon-slope seascape, providing a predictive map from which to test hypotheses on the distribution and flow of energy resources, relevant to understanding whole community function. Communities were composed of isotopically diverse feeding groups with photosynthetically-derived organic carbon providing the basal food resource. Canyon communities were distinct from the slope, with canyon consumers significantly 13C-depleted, indicating a greater supply and/or utilization of fresh organic matter compared to the slope. Isoscapes for benthic and suspension feeders were distinct, possibly due to the consumption of different quality organic matter sources (fresh = suspension feeders, old = benthic feeders), each with distinct isotope composition. To our knowledge, our modeled isoscapes represent the first spatially extensive isotopic maps of deep-sea consumers, providing insights into regional-scale variation in stable carbon and nitrogen isotopes for different consumer groups. They provide a baseline for tracking climate-change induced fluctuations in the quality and availability of surface primary production and the consequential impact to benthic communities, which play critical roles in carbon cycling in our world’s oceans.

消费者等距景观揭示了深海海底峡谷和邻近斜坡的异质食物网
深海是地球上最大的生物群落,但却是研究最少的生物群落之一,尽管它在全球碳循环和气候缓冲方面发挥着至关重要的作用。深海生物主要依靠来自表层海洋的微粒有机物获取能量--这些生物反过来又在能量传输、转化、储存和固碳方面发挥着关键作用。在深海中,海底峡谷是海洋中最复杂、最具活力的环境之一,这里形态各异、洋流强劲、营养条件多变,影响着整个水柱和海底的物种分布和有机物质的运输。栖息地的显著异质性为冷水珊瑚提供了理想的基质,使海底峡谷成为保护和管理的重点。然而,人们对深海中的这些地形特征和其他地形特征如何影响能量流和营养途径还知之甚少。因此,海底峡谷可作为跟踪有机物质通量变化及底栖动物利用和同化情况的模型系统。在这项研究中,我们利用广泛的稳定同位素数据集研究了巴尔的摩和诺福克海底峡谷的食物网结构,并将它们与邻近的斜坡进行了比较。利用线性模型构建了地理空间上明确的消费者等景观,预测了整个峡谷-斜坡海景中碳和氮同位素的变化,提供了一个预测图,据此检验了与了解整个群落功能有关的能量资源分布和流动假设。群落由同位素不同的摄食群组成,光合作用产生的有机碳提供了基本的食物资源。峡谷生物群落与斜坡生物群落不同,峡谷生物群落的摄食者明显缺碳,这表明与斜坡生物群落相比,峡谷生物群落对新鲜有机物的供应和/或利用更多。底栖动物和悬浮取食动物的等位景观各不相同,这可能是由于它们消耗了不同质量的有机质(新鲜有机质=悬浮取食动物,陈旧有机质=底栖取食动物),每种有机质的同位素组成也各不相同。据我们所知,我们的模型等位景观代表了第一张深海消费者的空间广泛同位素图,为不同消费者群体的稳定碳和氮同位素的区域尺度变化提供了见解。它们为跟踪气候变化引起的表层初级生产的质量和可用性波动及其对底栖生物群落的影响提供了基线,而底栖生物群落在世界海洋的碳循环中发挥着至关重要的作用。
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来源期刊
Progress in Oceanography
Progress in Oceanography 地学-海洋学
CiteScore
7.20
自引率
4.90%
发文量
138
审稿时长
3 months
期刊介绍: Progress in Oceanography publishes the longer, more comprehensive papers that most oceanographers feel are necessary, on occasion, to do justice to their work. Contributions are generally either a review of an aspect of oceanography or a treatise on an expanding oceanographic subject. The articles cover the entire spectrum of disciplines within the science of oceanography. Occasionally volumes are devoted to collections of papers and conference proceedings of exceptional interest. Essential reading for all oceanographers.
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