Phytoplankton photoacclimation and photoadaptation in response to environmental gradients in a shelf sea

Moore, C. Mark; Suggett, David J.; Hickman, Anna E.; Kim, Young Nam; Tweddle, Jacqueline F.; Sharples, Jonathan; Geider, Richard J.; Holligan, Patrick M.

doi:10.4319/lo.2006.51.2.0936

Cited by 197 publications

(237 citation statements)

References 41 publications

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“…Differences in photoacclimation strategy are due to the heterogeneity in photosynthetic structure and accessory pigment composition between species, influencing the rate and quantity of photons received by the photosystem (Wilhelm, 1990). Some species acclimate by changing the size of the light harvesting antenna of the individual reaction centre, while others increase the total number of reaction centres, keeping antenna size constant (Falkowski and LaRoche, 1991;Moore et al, 2006). As with temperate diatoms (Ruban et al, 2004;Dimier et al, 2007;Lavaud et al, 2007), SO-and sea ice diatoms are highly plastic to fluctuations in light with a strong dependence on rapid and reversible xanthophyll cycling (Moisan et al, 1998;Moisan and Mitchell, 1999;Kropuenske et al, 2009;Petrou et al, 2011a,c), however, not all species utilise the same strategies, nor have the same level of physiological plasticity (Kropuenske et al, 2009;Mills et al, 2010;Petrou et al, 2011a).…”

Section: Lightmentioning

confidence: 99%

Southern Ocean phytoplankton physiology in a changing climate

Petrou

Kranz

Trimborn

et al. 2016

Journal of Plant Physiology

119

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Please cite this article in press as: Petrou, K., et al., Southern Ocean phytoplankton physiology in a changing climate. J Plant Physiol (2016), http://dx.doi.org/10.1016/j.jplph.2016.05.004 ARTICLE IN PRESS a b s t r a c tThe Southern Ocean (SO) is a major sink for anthropogenic atmospheric carbon dioxide (CO 2 ), potentially harbouring even greater potential for additional sequestration of CO 2 through enhanced phytoplankton productivity. In the SO, primary productivity is primarily driven by bottom up processes (physical and chemical conditions) which are spatially and temporally heterogeneous. Due to a paucity of trace metals (such as iron) and high variability in light, much of the SO is characterised by an ecological paradox of high macronutrient concentrations yet uncharacteristically low chlorophyll concentrations. It is expected that with increased anthropogenic CO 2 emissions and the coincident warming, the major physical and chemical process that govern the SO will alter, influencing the biological capacity and functioning of the ecosystem. This review focuses on the SO primary producers and the bottom up processes that underpin their health and productivity. It looks at the major physico-chemical drivers of change in the SO, and based on current physiological knowledge, explores how these changes will likely manifest in phytoplankton, specifically, what are the physiological changes and floristic shifts that are likely to ensue and how this may translate into changes in the carbon sink capacity, net primary productivity and functionality of the SO.

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Section: Lightmentioning

confidence: 99%

Southern Ocean phytoplankton physiology in a changing climate

Petrou

Kranz

Trimborn

et al. 2016

Journal of Plant Physiology

119

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“…Dark-adapted measurements of the effective absorption cross section, s PSII , are affected by both physiological (phenotypic) and taxonomic (genotypic) signatures of the phytoplankton community (Suggett et al, 2004;Moore et al 2005Moore et al , 2006. Specifically, smaller s PSII values are indicative of large eukaryotes or cyanobacteria but may also indicate a down-regulation in light harvesting for photochemistry; higher s PSII values are indicative of smaller eukaryotes but also an up-regulation of light harvesting for photochemistry (Suggett et al, 2004).…”

Section: Variability Of Psii Light Absorptionmentioning

confidence: 99%

“…However, these approximations of non-photochemical quenching assume that the dark-adapted effective absorption cross-section remains constant throughout the water column. Recent evidence from both the laboratory (Suggett et al, 2004) and field (Moore et al, 2005(Moore et al, , 2006) has demonstrated that s PSII,478 can be highly variable both between taxa and with photoacclimatory state. This would imply that the dark-adapted effective absorption cross-section is not constant with depth where distinct phytoplankton populations occur at different depths within the water column, as frequently occurs within tropical and subtropical Atlantic provinces (Zubkov et al, 2000;Barlow et al, 2002).…”

Section: Frr Fluorescence and Fluorescence Quenchingmentioning

confidence: 99%

“…This latter phenomenon is equivalent to the maximum achievable turnover rate of electrons, ETR max , that is, in turn, determined by acclimative and adaptive constraints on both light harvesting and processing electrons 'downstream' of PSII (Moore et al, 2006). Least-squares non-linear regression was used to fit Eq.…”

Section: Maximum Electron Turnovermentioning

confidence: 99%

“…Direct in situ FRR measurements of s PSII 0 are weighted to the LED spectrum of the FRR fluorometer (termed s PSII 0 ,478 , Moore et al, 2006, and references therein). Accurate application of Eq.…”

Section: Frr Fluorescence and Determination Of Electron Transport Ratesmentioning

confidence: 99%

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Photosynthetic electron turnover in the tropical and subtropical Atlantic Ocean

Suggett

Moore

Marañón

et al. 2006

Deep Sea Research Part II: Topical Studies in Oceanography

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Photosynthetic electron transport directly generates the energy required for carbon fixation and thus underlies the aerobic metabolism of aquatic systems. We determined photosynthetic electron turnover rates, ETRs, from ca. 100 FRR fluorescence water-column profiles throughout the subtropical and tropical Atlantic during six Atlantic Meridional Transect cruises (AMT 6, May-June 1998, to AMT 11, September-October 2000. Each FRR fluorescence profile yielded a water-column ETR-light response from which the maximum electron turnover rate ðETR max RCII Þ, effective absorption (s PSII ) and light saturation parameter (E k ) specific to the concentration of photosystem II reaction centres (RCIIs) were calculated. ETR max RCII and E k increased whilst s PSII decreased with mixed-layer depth and the daily integrated photosynthetically active photon flux when all provinces were considered together. These trends suggested that variability in maximum ETR can be partly attributed to changes in effective absorption. Independent bio-optical measurements taken during AMT 11 demonstrated that s PSII variability reflects taxonomic and physiological differences in the phytoplankton communities. ETR max RCII and E k , but not s PSII , remained correlated with mixed-layer depth and daily integrated photosynthetically active photon flux when data from each oceanic province were considered separately, indicating a decoupling of electron turnover and carbon fixation rates within each province. Comparison of maximum ETRs with 14 C-based measurements of P max further suggests that light absorption and C fixation are coupled to differing extents for the various oligotrophic Atlantic provinces. We explore the importance of quantifying RCII concentration for determination of ETRs and interpretation of ETR-C fixation coupling. r

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Phytoplankton competition and resilience under fluctuating temperature

Siegel

Baker

Low‐Décarie

et al. 2023

Ecology and Evolution

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Environmental variability is an inherent feature of natural systems which complicates predictions of species interactions. Primarily, the complexity in predicting the response of organisms to environmental fluctuations is in part because species' responses to abiotic factors are non-linear, even in stable conditions. Temperature exerts a major control over phytoplankton growth and physiology, yet the influence of thermal fluctuations on growth and competition dynamics is largely unknown. To investigate the limits of coexistence in variable environments, stable mixed cultures with constant species abundance ratios of the marine diatoms, Phaeodactylum tricornutum and Thalassiosira pseudonana, were exposed to different temperature fluctuation regimes (n = 17) under high and low nitrogen (N) conditions. Here we demonstrate that phytoplankton exhibit substantial resilience to temperature variability. The time required to observe a shift in the species abundance ratio decreased with increasing fluctuations, but coexistence of the two model species under high N conditions was disrupted only when amplitudes of temperature fluctuation were high (±8.2°C). N limitation caused the thermal amplitude for disruption of species coexistence to become lower (±5.9°C). Furthermore, once stable conditions were reinstated, the two species differed in their ability to recover from temperature fluctuations. Our findings suggest that despite the expectation of unequal effect of fluctuations on different competitors, cycles in environmental conditions may reduce the rate of species replacement when amplitudes remain below a certain threshold. Beyond these thresholds, competitive exclusion could, however, be accelerated, suggesting that aquatic heatwaves and N availability status are likely to lead to abrupt and unpredictable restructuring of phytoplankton community composition.

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Phytoplankton photoacclimation and photoadaptation in response to environmental gradients in a shelf sea

Cited by 197 publications

References 41 publications

Southern Ocean phytoplankton physiology in a changing climate

Southern Ocean phytoplankton physiology in a changing climate

Photosynthetic electron turnover in the tropical and subtropical Atlantic Ocean

Phytoplankton competition and resilience under fluctuating temperature

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