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

Dyhrman, Sonya T.; Jenkins, Bethany D.; Rynearson, Tatiana A.; Saito, Mak A.; Mercier, Melissa L.; Alexander, Harriet; Whitney, LeAnn P.; Drzewianowski, Andrea; Bulygin, Vladimir V.; Bertrand, Erin M.; Wu, Zhijin; Benitez-Nelson, Claudia R.; Heithoff, Abigail

doi:10.1371/journal.pone.0033768

Cited by 280 publications

(362 citation statements)

References 70 publications

(105 reference statements)

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“…Thus, both field and culture observations from Synechococcus appear to discount a polyP overplus response. The modest net polyP breakdown upon P-stress might mask substantial intracellular recycling: cells have multiple polyP pools with distinct physiological functions and dynamics (33,34), and enzymes to synthesize and degrade polyP are both up-regulated in P-stressed cultures (31). Moreover, P-stressed Trichodesmium cultures have polyP:TPP ratios indistinguishable from those of natural Sargasso Sea Trichodesmium populations (30), which is consistent with our Synechococcus observations.…”

Section: Physiological Shifts In Polyp:tpp In Field and Cultured Popusupporting

confidence: 87%

Accumulation and enhanced cycling of polyphosphate by Sargasso Sea plankton in response to low phosphorus

Martin¹,

Dyhrman

Lomas

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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154

183

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Phytoplankton alter their biochemical composition according to nutrient availability, such that their bulk elemental composition varies across oceanic provinces. However, the links between plankton biochemical composition and variation in biogeochemical cycling of nutrients remain largely unknown. In a survey of phytoplankton phosphorus stress in the western North Atlantic, we found that phytoplankton in the phosphorus-depleted subtropical Sargasso Sea were enriched in the biochemical polyphosphate (polyP) compared with nutrient-rich temperate waters, contradicting the canonical oceanographic view of polyP as a luxury phosphorus storage molecule. The enrichment in polyP coincided with enhanced alkaline phosphatase activity and substitution of sulfolipids for phospholipids, which are both indicators of phosphorus stress. Further, polyP appeared to be liberated preferentially over bulk phosphorus from sinking particles in the Sargasso Sea, thereby retaining phosphorus in shallow waters. Thus, polyP cycling may form a feedback loop that attenuates the export of phosphorus when it becomes scarce, contributes bioavailable P for primary production, and supports the export of carbon and nitrogen via sinking particles. nutrient limitation | phosphorus cycling | marine phytoplankton | lipids P hosphorus (P) is an essential element for all living organisms.However, P can be extremely scarce in open-ocean surface waters such as in the subtropical western North Atlantic (the Sargasso Sea), where soluble reactive P (SRP) concentrations are routinely <10 nmol·L −1 and turnover rates are on the order of hours (1). Despite this scarcity, primary production by phytoplankton in the Sargasso Sea does not appear to be limited primarily by P (2, 3), reflecting the intensity of P recycling by the microbial community (4, 5) and the exquisite adaptations of marine phytoplankton to low P conditions, which remain to be fully characterized.Phytoplankton respond to low P by producing enzymes such as alkaline phosphatase to hydrolyze extracellular dissolved organic P molecules (4, 6, 7), increasing the affinity and rate of P uptake (8, 9) and reducing their inventory of P-containing biochemicals (1, 10). In contrast, when P is abundant, phytoplankton take up excess P and store it as a luxury reserve that is generally thought to be composed of polyphosphate (polyP) (10-12). This modulation of P-containing biochemicals results in basin-scale relationships between P availability and biomass carbon-to-phosphorus (C:P) ratios (13). Presently, the only class of molecules known to consistently contribute to these gradients in cellular P are lipids because P stress in phytoplankton triggers substitution of non-P-membrane lipids for phospholipids, such as the sulfolipid sulfoquinovosyldiacylglycerol (SQDG) for the phospholipid phosphatidylglycerol (PG) (1, 14). However, lipid substitution alone probably cannot account for the full range of C:P observed in the ocean, and yet an understanding of other biochemical drivers of the C:P gradient remains el...

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Section: Physiological Shifts In Polyp:tpp In Field and Cultured Popusupporting

confidence: 87%

Accumulation and enhanced cycling of polyphosphate by Sargasso Sea plankton in response to low phosphorus

Martin¹,

Dyhrman

Lomas

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

154

183

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“…Such genes or their protein products are frequently used as proxies to identify limitation in the field (39). In E1 and E2, there was a decrease in diatom-associated glycerophosphoryl phosphodiesterase (22) and adenosylhomocysteinase (40), indicative of phosphorus and vitamin limitation, respectively (Fig. 3).…”

Section: Resultsmentioning

confidence: 99%

“…Molecular-level tools that can track transcripts, proteins, or even metabolites and biochemicals in a taxon-specific way are increasingly being used in cultures and field populations to track metabolic capacity and physiological responses (16)(17)(18)(19)(20)(21)(22)(23). Molecular assessment of physiology for eukaryotic populations is most tractable in coastal systems with high biomass (17,18); thus, in oligotrophic ocean regions, molecular studies of physiology have typically been limited to the numerically abundant members of the microbial community: picoplankton (cyanobacteria, heterotrophic bacteria, and small picoeukaryotes).…”

Section: Significancementioning

confidence: 99%

Functional group-specific traits drive phytoplankton dynamics in the oligotrophic ocean

Alexander

Rouco

Haley

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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109

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A diverse microbial assemblage in the ocean is responsible for nearly half of global primary production. It has been hypothesized and experimentally demonstrated that nutrient loading can stimulate blooms of large eukaryotic phytoplankton in oligotrophic systems. Although central to balancing biogeochemical models, knowledge of the metabolic traits that govern the dynamics of these bloom-forming phytoplankton is limited. We used eukaryotic metatranscriptomic techniques to identify the metabolic basis of functional group-specific traits that may drive the shift between net heterotrophy and autotrophy in the oligotrophic ocean. Replicated blooms were simulated by deep seawater (DSW) addition to mimic nutrient loading in the North Pacific Subtropical Gyre, and the transcriptional responses of phytoplankton functional groups were assayed. Responses of the diatom, haptophyte, and dinoflagellate functional groups in simulated blooms were unique, with diatoms and haptophytes significantly (95% confidence) shifting their quantitative metabolic fingerprint from the in situ condition, whereas dinoflagellates showed little response. Significantly differentially abundant genes identified the importance of colimitation by nutrients, metals, and vitamins in eukaryotic phytoplankton metabolism and bloom formation in this system. The variable transcript allocation ratio, used to quantify transcript reallocation following DSW amendment, differed for diatoms and haptophytes, reflecting the longstanding paradigm of phytoplankton r-and K-type growth strategies. Although the underlying metabolic potential of the large eukaryotic phytoplankton was consistently present, the lack of a bloom during the study period suggests a crucial dependence on physical and biogeochemical forcing, which are susceptible to alteration with changing climate. metatranscriptomics | phytoplankton | ecological traits |

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“…For example, does P limitation limit the ability of phytoplankton to repair their cell membranes, resulting in significant leakage? Dyhrman et al (2012) showed that Thalassiosira pseudonana changes the composition of its lipids in response to P limitation, though they did not investigate whether these changes affected DOM release by the diatom.…”

Section: Physiology Of Phytoplankton Dom Releasementioning

confidence: 99%

“…A new understanding of the diatom genome has led to research on gene expression in stressed diatoms using transcriptomic and proteomic approaches. For example, recent work with T. pseudonana has shown that it has a sophisticated suite of biochemical strategies to deal with phosphorus deficiency (Dyhrman et al, 2012) and putative death-related genes play a role in acclimation to low iron conditions (Thamatrakoln et al, 2012). Similar approaches could be used to investigate gene expression associated with metabolic pathways and transport proteins associated with exudation and leakage.…”

Section: Physiology Of Phytoplankton Dom Releasementioning

confidence: 99%

Dissolved organic matter (DOM) release by phytoplankton in the contemporary and future ocean

Thornton

2014

European Journal of Phycology

327

308

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The partitioning of organic matter (OM) between dissolved and particulate phases is an important factor in determining the fate of organic carbon in the ocean. Dissolved organic matter (DOM) release by phytoplankton is a ubiquitous process, resulting in 2-50% of the carbon fixed by photosynthesis leaving the cell. This loss can be divided into two components: passive leakage by diffusion across the cell membrane and the active exudation of DOM into the surrounding environment. At present there is no method to distinguish whether DOM is released via leakage or exudation. Most explanations for exudation remain hypothetical; as while DOM release has been measured extensively, there has been relatively little work to determine why DOM is released. Further research is needed to determine the composition of the DOM released by phytoplankton and to link composition to phytoplankton physiological status and environmental conditions. For example, the causes and physiology of phytoplankton cell death are poorly understood, though cell death increases membrane permeability and presumably DOM release. Recent work has shown that phytoplankton interactions with bacteria are important in determining both the amount and composition of the DOM released. In response to increasing CO 2 in the atmosphere, climate change is creating increasingly stressful conditions for phytoplankton in the surface ocean, including relatively warm water, low pH, low nutrient supply and high light. As ocean physics and chemistry change, it is hypothesized that a greater proportion of primary production will be released directly by phytoplankton into the water as DOM. Changes in the partitioning of primary production between the dissolved and particulate phases will have bottom-up effects on ecosystem structure and function. There is a need for research to determine how these changes affect the fate of organic matter in the ocean, particularly the efficiency of the biological carbon pump.

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

Cited by 280 publications

References 70 publications

Accumulation and enhanced cycling of polyphosphate by Sargasso Sea plankton in response to low phosphorus

Accumulation and enhanced cycling of polyphosphate by Sargasso Sea plankton in response to low phosphorus

Functional group-specific traits drive phytoplankton dynamics in the oligotrophic ocean

Dissolved organic matter (DOM) release by phytoplankton in the contemporary and future ocean

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