功能多样性支持珊瑚礁生物多样性。
Functional versatility supports coral reef biodiversity.
作者信息
Bellwood D R, Wainwright P C, Fulton C J, Hoey A S
机构信息
Department of Marine Biology, Centre for Coral Reef Biodiversity, James Cook University, Townsville, Qld 4811, Australia.
出版信息
Proc Biol Sci. 2006 Jan 7;273(1582):101-7. doi: 10.1098/rspb.2005.3276.
Abstract
We explore the role of specialization in supporting species coexistence in high-diversity ecosystems. Using a novel ordination-based method to quantify specialist and generalist feeding structures and diets we examined the relationship between morphology and diet in 120 wrasses and parrotfishes from the Great Barrier Reef. We find that wrasses, despite their morphological diversity, exhibit weak links between morphology and diet and that specialist morphologies do not necessarily equate to specialized diets. The dominant pattern shows extensive overlap in morphology (functional morphospace occupation) among trophic groups; fish with a given morphology may have a number of feeding modes. Such trophic versatility may lay the foundation for both the origins and maintenance of high biodiversity on coral reefs.
摘要
我们探讨了特化在支持高多样性生态系统中物种共存方面的作用。我们使用一种基于新的排序方法来量化特化和泛化的摄食结构及食性,研究了大堡礁120种隆头鱼和鹦嘴鱼的形态与食性之间的关系。我们发现,尽管隆头鱼形态多样,但它们的形态与食性之间的联系较弱,而且特化的形态并不一定等同于特化的食性。主要模式显示,营养级组之间在形态(功能形态空间占据)上有广泛重叠;具有特定形态的鱼类可能有多种摄食模式。这种营养多样性可能为珊瑚礁上高生物多样性的起源和维持奠定基础。
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