The Transcriptome and Proteome of the Diatom Thalassiosira Pseudonana Reveal a Diverse Phosphorus Stress Response

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2012 Apr 6

PMID 22479440

Citations 104

Authors

Sonya T Dyhrman

Bethany D Jenkins

Tatiana A Rynearson

Mak A Saito

Melissa L Mercier

Harriet Alexander

LeAnn P Whitney

Andrea Drzewianowski

Vladimir V Bulygin

Erin M Bertrand

Zhijin Wu

Claudia Benitez-Nelson

Abigail Heithoff

Affiliations

Soon will be listed here.

Abstract

Phosphorus (P) is a critical driver of phytoplankton growth and ecosystem function in the ocean. Diatoms are an abundant class of marine phytoplankton that are responsible for significant amounts of primary production. With the control they exert on the oceanic carbon cycle, there have been a number of studies focused on how diatoms respond to limiting macro and micronutrients such as iron and nitrogen. However, diatom physiological responses to P deficiency are poorly understood. Here, we couple deep sequencing of transcript tags and quantitative proteomics to analyze the diatom Thalassiosira pseudonana grown under P-replete and P-deficient conditions. A total of 318 transcripts were differentially regulated with a false discovery rate of <0.05, and a total of 136 proteins were differentially abundant (p<0.05). Significant changes in the abundance of transcripts and proteins were observed and coordinated for multiple biochemical pathways, including glycolysis and translation. Patterns in transcript and protein abundance were also linked to physiological changes in cellular P distributions, and enzyme activities. These data demonstrate that diatom P deficiency results in changes in cellular P allocation through polyphosphate production, increased P transport, a switch to utilization of dissolved organic P through increased production of metalloenzymes, and a remodeling of the cell surface through production of sulfolipids. Together, these findings reveal that T. pseudonana has evolved a sophisticated response to P deficiency involving multiple biochemical strategies that are likely critical to its ability to respond to variations in environmental P availability.

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