Maya S deVries, Nhi Ly, Chase Ebner, Ryan Hallisey
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引用次数: 0
Abstract
A central question in ecology is to what extent do trophic interactions govern the structure and function of communities? This question is becoming more pressing as trophic interactions shift with rapid climate change. Sea urchins and abalone are key invertebrates in the habitats where they reside. Sea urchins are critical members of exemplar trophic cascades in kelp forests due to their impact on kelp establishment and maintenance; yet their populations are controlled by predators, such as sea otters and sunflower sea stars. Abalone compete with urchins for macroalgal food resources and therefore can help regulate urchin populations in kelp forests. Given that both urchin tests and abalone shells used for predator defense are comprised of calcium carbonate, much research has been conducted on the impacts of ocean acidification (OA) on these calcified structures. A growing body of literature has shown that urchin tests are less calcified and break with less force under OA conditions. Less is known about abalone, but their shells also appear to respond negatively to OA. Using kelp forest communities as exemplar ecosystems, we discuss the morphological, biomechanical, and physiological responses to OA in urchins and abalone and consider how these individual level responses scale to trophic interactions and ultimately whole ecosystem processes. Although the impacts of OA on the calcified structures used for defense have been well studied, calcified mechanisms for food consumption, such as the Aristotle's lantern of urchins, are much less understood. Thus, examining both the feeding and defense sides of trophic interactions would greatly improve our understanding of OA responses across individual to ecosystem scales. More generally, measurements of morphological, biomechanical, and physiological responses to OA can be made in individuals to help predict higher level ecological responses, which would greatly contribute to broader predictions of whole ecosystem responses to OA.
生态学的一个核心问题是:营养相互作用在多大程度上支配着群落的结构和功能?随着气候的快速变化,营养相互作用也发生了变化,这个问题变得越来越紧迫。海胆和鲍鱼是其栖息地的关键无脊椎动物。海胆对海藻的生长和维护具有重要影响,因此是海藻林中示范性营养级联的关键成员;然而它们的数量却受到海獭和向日葵海星等捕食者的控制。鲍鱼与海胆竞争大型藻类食物资源,因此有助于调节海藻林中的海胆数量。由于海胆试验和鲍鱼用于防御捕食者的外壳都是由碳酸钙组成的,因此人们对海洋酸化(OA)对这些钙化结构的影响进行了大量研究。越来越多的文献表明,在OA条件下,海胆的钙化程度较低,断裂的力量也较小。人们对鲍鱼的了解较少,但它们的外壳似乎也对OA有负面影响。我们以海藻森林群落为示例生态系统,讨论了海胆和鲍鱼对 OA 的形态、生物力学和生理反应,并考虑了这些个体水平的反应如何扩展到营养相互作用,并最终扩展到整个生态系统过程。尽管 OA 对用于防御的钙化结构的影响已得到深入研究,但对食物消耗的钙化机制(如海胆的亚里士多德灯笼)的了解却少得多。因此,对营养相互作用的摄食和防御两方面进行研究,将大大提高我们对从个体到生态系统尺度的 OA 反应的理解。更广泛地说,测量个体对 OA 的形态、生物力学和生理反应,有助于预测更高层次的生态反应,这将大大有助于更广泛地预测整个生态系统对 OA 的反应。
期刊介绍:
Integrative and Comparative Biology ( ICB ), formerly American Zoologist , is one of the most highly respected and cited journals in the field of biology. The journal''s primary focus is to integrate the varying disciplines in this broad field, while maintaining the highest scientific quality. ICB''s peer-reviewed symposia provide first class syntheses of the top research in a field. ICB also publishes book reviews, reports, and special bulletins.
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