Evidence that dimethyl sulfide facilitates a tritrophic mutualism between marine primary producers and top predators

Tritrophic mutualistic interactions have been best studied in plant-insect systems. During these interactions, plants release volatiles in response to herbivore damage, which, in turn, facilitates predation on primary consumers or benefits the primary producer by providing nutrients. Here we explore...

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Bibliographic Details
Main Authors: Savoca, Matthew S, Nevitt, Gabrielle A
Format: Article in Journal/Newspaper
Language:unknown
Published: eScholarship, University of California 2014
Subjects:
Biological Sciences
Ecology
Life Below Water
Analysis of Variance
Animals
Birds
Cues
Diet
Feces
Food Chain
Iron
Marine Biology
Models
Biological
Oceans and Seas
Phylogeny
Phytoplankton
Species Specificity
Sulfides
Symbiosis
Southern Ocean
Online Access:https://escholarship.org/uc/item/1qm041mf
Description
Summary:Tritrophic mutualistic interactions have been best studied in plant-insect systems. During these interactions, plants release volatiles in response to herbivore damage, which, in turn, facilitates predation on primary consumers or benefits the primary producer by providing nutrients. Here we explore a similar interaction in the Southern Ocean food web, where soluble iron limits primary productivity. Dimethyl sulfide has been studied in the context of global climate regulation and is an established foraging cue for marine top predators. We present evidence that procellariiform seabird species that use dimethyl sulfide as a foraging cue selectively forage on phytoplankton grazers. Their contribution of beneficial iron recycled to marine phytoplankton via excretion suggests a chemically mediated link between marine top predators and oceanic primary production.

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