PNNL

Abstract

Marine algae perform approximately half of global carbon fixation, but their growth is often limited by availability of phosphate or other nutrients1,2. As oceans warm, the area of phosphate-limited surface waters is predicted to increase, resulting in ocean desertification3,4. Understanding the responses of key eukaryotic phytoplankton to nutrient limitation is therefore critical5,6. We used advanced photo-bioreactors to investigate how the widespread green alga Micromonas commoda grows under transitions from replete nutrients to chronic phosphate limitation and subsequent relief, analyzing photosystem changes and broad cellular responses using proteomics, transcriptomics and biophysical measurements. We find that physiological and protein expression responses previously attributed to stress are critical to supporting stable exponential growth when phosphate is limiting. Unexpectedly, the abundance of most proteins involved in light-harvesting does not change, but an ancient light-harvesting related protein, LHCSR, is induced and dissipates damaging excess absorbed light as heat during P-limitation. Concurrently, a suite of uncharacterized proteins with narrow phylogenetic distributions increase multifold. Notably, of the proteins that exhibit significant changes, 70% are not differentially expressed at the mRNA transcript level, highlighting the importance of post-transcriptional processes in microbial eukaryotes. Nevertheless, transcript-protein pairs with concordant changes were identified that will enable more robust interpretation of eukaryotic phytoplankton responses in the field from metatranscriptomic studies. Our results show P-limited Micromonas responds quickly to a fresh pulse of phosphate by rapidly increasing replication and that the protein network associated with this ability is composed of both conserved and phylogenetically recent proteome systems that promote dynamic phosphate homeostasis. That an ancient mechanism for mitigating light-stress is central to sustaining growth throughout extended periods of phosphate limitation highlights possible interactive effects, arising from multiple stressors under ocean change, which could reduce the efficacy of algal strategies for optimizing marine photosynthesis.