Litcius/Paper detail

Phytoplankton exudates and lysates support distinct microbial consortia with specialized metabolic and ecophysiological traits

Brandon Kieft, Li Zhou, Samuel Bryson, Robert L. Hettich, Chongle Pan, Xavier Mayali, Ryan Mueller

2021Proceedings of the National Academy of Sciences87 citationsDOIOpen Access PDF

Abstract

C-labeled exudate or lysate from a diatom or a picocyanobacterium was preferentially assimilated by different heterotrophic taxa with specialized metabolic and physiological adaptations. Bacteroidetes populations, with their unique high-molecular-weight transporters, were superior competitors for DOM derived from diatom cell lysis, rapidly increasing growth rates and ribosomal protein expression to produce new relatively high C:N biomass. Proteobacteria responses varied, with relatively low levels of assimilation by Gammaproteobacteria populations, while copiotrophic Alphaproteobacteria such as the Roseobacter clade, with their diverse array of ABC- and TRAP-type transporters to scavenge monomers and nitrogen-rich metabolites, accounted for nearly all cyanobacteria exudate assimilation and produced new relatively low C:N biomass. Carbon assimilation rates calculated from SIP data show that exudate and lysate from two common marine phytoplankton are being used by taxonomically distinct sets of heterotrophic populations with unique metabolic adaptations, providing a deeper mechanistic understanding of consumer succession and carbon use during marine bloom events.

Topics & Concepts

PhytoplanktonBiologyBotanyEcologyNutrientMicrobial Community Ecology and PhysiologyIsotope Analysis in EcologyMarine and coastal ecosystems