Photosynthetic energy conversion under extreme conditions—II: the significance of lipids under light limited growth in Antarctic sea ice diatoms

Möck, Thomas; Kroon, Bernd M. A.

doi:10.1016/s0031-9422(02)00215-7

Cited by 103 publications

(83 citation statements)

References 25 publications

(19 reference statements)

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“…This might be due to the mixotrophic lifestyle of this alga (Tranvik et al, 1989) and associated differences in the adaptation response to changing environmental conditions as compared with exclusively phototrophic species. In order to sustain high photosynthetic rates, phototrophic organisms have to maintain a certain fluidity of chloroplast membranes, which ensures electron flow between the electron acceptors of photosystem II (Horva´th et al, 1987;Mock & Kroon, 2002). Although thylakoid membranes presumably do not contain sterols (Havaux, 1998), chloroplast envelope membranes contain low but significant amounts of sterols (Douce & Joyard, 1990).…”

Section: Discussionmentioning

confidence: 99%

Phytoplankton sterol contents vary with temperature, phosphorus and silicate supply: a study on three freshwater species

Piepho

Martin‐Creuzburg

Wacker

2012

European Journal of Phycology

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The understanding of environmentally induced changes in the biochemical composition of phytoplankton species is of great importance in both physiological studies and ecological food web research. In extensive laboratory experiments we tested the influence of two different temperatures (10 C and 25 C) and a phosphorus supply gradient on the sterol concentrations of the three freshwater phytoplankton species Scenedesmus quadricauda, Cryptomonas ovata and Cyclotella meneghiniana. The diatom C. meneghiniana was additionally exposed to a silicate gradient. In two separate experiments we analysed (1) possible interactive effects of temperature and phosphorus supply and (2) the effect of four phosphorus levels and three silicate levels on algal sterol concentrations. We observed that sterol concentrations were higher at 25 C than at 10 C in S. quadricauda and C. meneghiniana, but were not affected by temperature in C. ovata. Interactive effects of temperature and phosphorus supply on sterol concentrations were found in C. meneghiniana. This presumably was due to the bioconversion of one sterol (24-methylenecholesterol) into another (22-dihydrobrassicasterol). Increasing phosphorus supply resulted in species-specific effects on sterol concentrations, viz. an optimum curve response in S. quadricauda, a saturation curve response in C. meneghiniana and no change in sterol concentration in C. ovata. Effects of silicate supply on the sterols of C. meneghiniana equalled the effects of phosphorus supply. Albeit we did not observe a general trend in the three phytoplankton species tested, we conclude that sterol concentrations of phytoplankton are strongly affected by temperature and nutrient supply. Interactive effects point out the importance of taking into account more than just one environmental factor when assessing the effects of environmentally induced changes on phytoplankton sterol concentrations.

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Section: Discussionmentioning

confidence: 99%

Phytoplankton sterol contents vary with temperature, phosphorus and silicate supply: a study on three freshwater species

Piepho

Martin‐Creuzburg

Wacker

2012

European Journal of Phycology

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“…The ability to rapidly acclimate via phenotypic plasticity is essential for cells to satisfy physiological requirements and maximize fitness in variable environments. Antarctic diatoms have been shown to adjust their photophysiology to maximize photosynthesis for growth (Ralph et al, 2007; and vary their macromolecular pools to changing environmental conditions, increasing lipid concentrations for maintaining membrane structure and for energy storage (Mock and Kroon, 2002) or altering protein concentrations in response to osmoregulation and cryoprotection (Krell et al, 2008). Although speciesspecific data are scarce, increasing evidence suggests that phenotypic responses are highly variable within and between taxonomic groups Sackett et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…In variable environments, such as those in the Southern Ocean, the caloric value of food can be of critical importance, in particular in winter when sunlight and food are scarce. For example, lipids, which are the most energy-rich macromolecule, are known to vary under different environmental conditions (Mock and Kroon, 2002); therefore, changes in macromolecular composition and energy partitioning in the cell will determine the nutritional value of the food and productivity of the entire food web (Diekmann et al, 2009). Quantifying a species' capacity for phenotypic variation can inform predictions of its ability to survive environmental change (Charmantier et al, 2008) and may provide insight into which species could dominate under future environmental conditions in the Southern Ocean, such as a reduction in sea-ice thickness, duration and extent.…”

Section: Introductionmentioning

confidence: 99%

Snapshot prediction of carbon productivity, carbon and protein content in a Southern Ocean diatom using FTIR spectroscopy

et al. 2015

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Diatoms, an important group of phytoplankton, bloom annually in the Southern Ocean, covering thousands of square kilometers and dominating the region's phytoplankton communities. In their role as the major food source to marine grazers, diatoms supply carbon, nutrients and energy to the Southern Ocean food web. Prevailing environmental conditions influence diatom phenotypic traits (for example, photophysiology, macromolecular composition and morphology), which in turn affect the transfer of energy, carbon and nutrients to grazers and higher trophic levels, as well as oceanic biogeochemical cycles. The paucity of phenotypic data on Southern Ocean phytoplankton limits our understanding of the ecosystem and how it may respond to future environmental change. Here we used a novel approach to create a 'snapshot' of cell phenotype. Using mass spectrometry, we measured nitrogen (a proxy for protein), total carbon and carbon-13 enrichment (carbon productivity), then used this data to build spectroscopy-based predictive models. The models were used to provide phenotypic data for samples from a third sample set. Importantly, this approach enabled the first ever rate determination of carbon productivity from a single time point, circumventing the need for timeseries measurements. This study showed that Chaetoceros simplex was less productive and had lower protein and carbon content during short-term periods of high salinity. Applying this new phenomics approach to natural phytoplankton samples could provide valuable insight into understanding phytoplankton productivity and function in the marine system.

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“…An increase in polyunsaturated fatty acids (PUFAs) is important for maintaining membrane fluidity at freezing temperatures (MorganKiss et al, 2006). Furthermore, increases in PUFA composition within the thylakoid membrane enables increased electron flow under light limitation (Mock and Kroon, 2002b), compensates for pigment and protein loss under nitrogen limitation (Mock and Kroon, 2002a), and has been shown to confer salinity tolerance in the freshwater cyanobacterium, Synechocystis (Allakhverdiev et al, 1999). Polar diatoms also produce ice-binding proteins that serve as cryoprotectants via their ability to prevent ice recrystallization (Janech et al, 2006).…”

mentioning

confidence: 99%

Proteomic Analysis of a Sea-Ice Diatom: Salinity Acclimation Provides New Insight into the Dimethylsulfoniopropionate Production Pathway

et al. 2011

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Dimethylsulfoniopropionate (DMSP) plays important roles in oceanic carbon and sulfur cycling and may significantly impact climate. It is a biomolecule synthesized from the methionine (Met) pathway and proposed to serve various physiological functions to aid in environmental stress adaptation through its compatible solute, cryoprotectant, and antioxidant properties. Yet, the enzymes and mechanisms regulating DMSP production are poorly understood. This study utilized a proteomics approach to investigate protein changes associated with salinity-induced DMSP increases in the model sea-ice diatom Fragilariopsis cylindrus (CCMP 1102). We hypothesized proteins associated with the Met-DMSP biosynthesis pathway would increase in relative abundance when challenged with elevated salinity. To test this hypothesis axenic log-phase cultures initially grown at a salinity of 35 were gradually shifted to a final salinity of 70 over a 24-h period. Intracellular DMSP was measured and two-dimensional gel electrophoresis was used to identify protein changes at 48 h after the shift. Intracellular DMSP increased by approximately 85% in the hypersaline cultures. One-third of the proteins increased under high salinity were associated with amino acid pathways. Three protein isoforms of S-adenosylhomo-cysteine hydrolase, which synthesizes a Met precursor, increased 1.8-to 2.1-fold, two isoforms of S-adenosyl Met synthetase increased 1.9-to 2.5-fold, and S-adenosyl Met methyltransferase increased by 2.8-fold, suggesting active methyl cycle proteins are recruited in the synthesis of DMSP. Proteins from the four enzyme classes of the proposed algal Met transaminase DMSP pathway were among the elevated proteins, supporting our hypothesis and providing candidate genes for future characterization studies.

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Photosynthetic energy conversion under extreme conditions—II: the significance of lipids under light limited growth in Antarctic sea ice diatoms

Cited by 103 publications

References 25 publications

Phytoplankton sterol contents vary with temperature, phosphorus and silicate supply: a study on three freshwater species

Phytoplankton sterol contents vary with temperature, phosphorus and silicate supply: a study on three freshwater species

Snapshot prediction of carbon productivity, carbon and protein content in a Southern Ocean diatom using FTIR spectroscopy

Proteomic Analysis of a Sea-Ice Diatom: Salinity Acclimation Provides New Insight into the Dimethylsulfoniopropionate Production Pathway

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