|Title||Gradients in primary production predict trophic strategies of mixotrophic corals across spatial scales|
|Publication Type||Journal Article|
|Year of Publication||2018|
|Authors||Fox M.D, Williams GJ, Johnson M.D, Radice V.Z, Zgliczynski B.J, Kelly E.LA, Rohwer F.L, Sandin SA, Smith JE|
|Type of Article||Article|
|Keywords||Biochemistry & Molecular Biology; bleached corals; Cell Biology; central equatorial pacific; coral; heterotrophy; reef corals; scleractinian corals; skeletal growth; stylophora-pistillata; symbiotic; tissue; zooxanthellae|
Mixotrophy is among the most successful nutritional strategies in terrestrial and marine ecosystems. The ability of organisms to supplement primary nutritional modes along continua of autotrophy and heterotrophy fosters trophic flexibility that can sustain metabolic demands under variable or stressful conditions. Symbiotic, reef-building corals are among the most broadly distributed and ecologically important mixotrophs, yet we lack a basic understanding of how they modify their use of autotrophy and heterotrophy across gradients of food availability. Here, we evaluate how one coral species, Pocillopora meandrina, supplements autotrophic nutrition through heterotrophy within an archipelago and test whether this pattern holds across species globally. Using stable isotope analysis (delta C-13) and satellite-derived estimates of nearshore primary production (chlorophylla, as a proxy for food availability), we show that P. meandrina incorporates a greater proportion of carbon via heterotrophy when more food is available across five central Pacific islands. We then show that this pattern is consistent globally using data from 15 coral species across 16 locations spanning the Caribbean Sea and the Indian and Pacific Oceans. Globally, surface chlorophyll-a explains 77% of the variation in coral heterotrophic nutrition, 86% for one genus across 10 islands, and 94% when controlling for coral taxonomy within archipelagos. These results demonstrate, for the first time, that satellite-derived estimates of nearshore primary production provide a globally relevant proxy for resource availability that can explain variation in coral trophic ecology. Thus, our model provides a pivotal step toward resolving the biophysical couplings between mixotrophic organisms and spatial patterns of resource availability in the coastal oceans.
|Short Title||Curr. Biol.|