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Trophic strategies explain the ocean niches of small eukaryotic phytoplankton

Kyle F. Edwards, Qian Li, Kelsey A. McBeain, Christopher R. Schvarcz, Grieg F. Steward

2023Proceedings of the Royal Society B Biological Sciences27 citationsDOIOpen Access PDF

Abstract

A large fraction of marine primary production is performed by diverse small protists, and many of these phytoplankton are phagotrophic mixotrophs that vary widely in their capacity to consume bacterial prey. Prior analyses suggest that mixotrophic protists as a group vary in importance across ocean environments, but the mechanisms leading to broad functional diversity among mixotrophs, and the biogeochemical consequences of this, are less clear. Here we use isolates from seven major taxa to demonstrate a tradeoff between phototrophic performance (growth in the absence of prey) and phagotrophic performance (clearance rate when consuming Prochlorococcus ). We then show that trophic strategy along the autotrophy-mixotrophy spectrum correlates strongly with global niche differences, across depths and across gradients of stratification and chlorophyll a . A model of competition shows that community shifts can be explained by greater fitness of faster-grazing mixotrophs when nutrients are scarce and light is plentiful. Our results illustrate how basic physiological constraints and principles of resource competition can organize complexity in the surface ocean ecosystem.

Topics & Concepts

Trophic levelEcologyProchlorococcusMixotrophBiologyPhototrophPhytoplanktonCompetition (biology)PicoplanktonAutotrophEcosystemProtistNiche differentiationPlanktonNicheIntraguild predationEcological nicheBiogeochemical cycleHeterotrophPredationHabitatNutrientPredatorPhotosynthesisCyanobacteriaGeneticsBacteriaSynechococcusGeneBiochemistryBotanyMarine and coastal ecosystemsMicrobial Community Ecology and PhysiologyMarine Biology and Ecology Research
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