Low nutrient availability reduces high‐irradiance‐induced viability loss in oceanic phytoplankton

Kulk, Gemma; Poll, Willem H. van de; Visser, Ronald J. W.; Buma, Anita G. J.

doi:10.4319/lo.2013.58.5.1747

Cited by 17 publications

(11 citation statements)

References 68 publications

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“…The pigment's qualitative composition did not vary but total pigment content per cell showed significant differences between growing conditions according to initial nitrogen availability (Table 4), and cells growing in the M882 condition had the highest pigment concentration. This is consistent with previous studies where pigment content and pigment ratio were used as indicators of the diatom physiological status (Geider et al, 1993;Kulk et al, 2013;Van Leeuwe et al, 2008) and where nitrogen availability affected total chlorophyll a cellular content. However, in our study, the light-harvesting pigment ratio Chl c + fucoxanthin/Chl a was unaffected by nitrogen limitation (Table 4).…”

Section: Biochemical Compositionsupporting

confidence: 57%

Growth and biochemical composition of a microphytobenthic diatom (Entomoneis paludosa) exposed to shorebird (Calidris alpina) droppings

Jauffrais

Drouet

Turpin

et al. 2015

Journal of Experimental Marine Biology and Ecology

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Section: Biochemical Compositionsupporting

confidence: 57%

Growth and biochemical composition of a microphytobenthic diatom (Entomoneis paludosa) exposed to shorebird (Calidris alpina) droppings

Jauffrais

Drouet

Turpin

et al. 2015

Journal of Experimental Marine Biology and Ecology

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“…Samples used for the incubations were unfiltered and therefore included all grazers present in the natural seawater samples ( see Van de Poll et al in press). In the experimental setup, 20 μ mol photons m −2 s −1 was provided continuously (no dark period) by a 250 W MHNTD lamp (Philips), which closely matched the diurnal cycle in Kongsfjorden in June (Kirk ) and a natural PAR spectrum (Kulk et al ). Photoacclimation to the relatively lower irradiance intensity in the experimental setup (Table ) was thereby established within 24 h (as measured by fast repetition rate fluorometry [FRRf]).…”

Section: Methodsmentioning

confidence: 99%

“…Detailed laboratory studies with single phytoplankton species have revealed that both nutrient starvation and limitation may have considerable effects on phytoplankton photophysiology. Generally, the light harvesting capacity is reduced during nutrient starvation by a reduction in the cellular chlorophyll a (Chl a ) concentration and quantum yield of photosystem II (PSII) ( F v / F m ), as well as an increase in the relative amount of photoprotective carotenoids per Chl a (XC/Chl a ) and subsequent nonphotochemical quenching processes (NPQ NSV ) (Geider et al , ; Berges et al ; Kulk et al ). However, Chl a specific absorption and the absorption cross section of the remaining PSII ( σ PSII ) may increase during nutrient starvation (Kolber et al ; Geider et al ; Berges et al ), partially counteracting the reduced light harvesting capacity.…”

mentioning

confidence: 99%

Photophysiology of nitrate limited phytoplankton communities in Kongsfjorden, Spitsbergen

Kulk

Poll

Buma

2018

Limnology & Oceanography

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In Arctic coastal regions, the phytoplankton bloom is often initiated by meltwater induced stratification in spring, while subsequent nutrient depletion is believed to drive phytoplankton succession in summer. The associated changes in photophysiology are difficult to identify, because these can be governed by acclimation to light and nutrient availability as well as variations in phytoplankton biomass and taxonomic composition. In the present study, the consequences of nutrient limitation for photophysiology and growth were assessed in natural phytoplankton communities from Kongsfjorden, Spitsbergen. A series of nutrient addition experiments demonstrated N-limitation from mid-June onwards and possible co-limitation with P later in summer. The onset of N-limitation was associated with a pronounced change in taxonomic composition from a dictyochophytes to a haptophytes dominated community. Fast Repetition Rate fluorometry measurements of photosystem II (PSII) photophysiology showed that the dictyochophytes dominated community was characterized by high PSII efficiency and electron transport rates which were efficiently used for growth. Marked changes in PSII photophysiology were observed later in summer, with decreasing efficiencies, lower connectivity between reaction centers, and slower turnover rates. Simultaneously, alternative electron requirements downstream of PSII became more important and energy was likely allocated to the uptake of nutrients rather than carbon fixation and growth. Relief of nutrient limitation during the nutrient addition experiments did not lead to pronounced changes in PSII photophysiology. It is, therefore, concluded that PSII photophysiology of the phytoplankton community in Kongsfjorden is associated with changes in species composition rather than a direct effect of nutrient availability or nutrient limitation.

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“…These light conditions are ecologically relevant for the surface waters of the North Sea and Wadden Sea, whereby ML represents a daily average for the spring period (Dring et al, 2001;Ly et al, 2014). We used a 10-fold difference between LL and HL, which is a natural range experienced by phytoplankton in temperate waters (Kulk et al, 2013), and whereby LL represents a level at which the maximum growth rate of natural phytoplankton populations is halved (Cloern, 1999) and HL shows significant inhibiting effects on the photosynthetic efficiency (Fv/Fm) of our model species under P replete conditions. Triplicate 50 ml cultures were grown semi-continuously under P-replete and P-limiting conditions with daily dilution 3 h into the light period.…”

Section: Culturing and Experimental Set-upmentioning

confidence: 99%

“…Irradiance can either limit phytoplankton growth and production by a reduced availability (turbidity, season, water depth or mixing to deep waters; see Huisman et al, 2002) or by an excess of it, causing photoinhibition (mixing to shallow waters, stratification; Long et al, 1994). The effects of these growth-controling factors can even be cumulative (Cloern, 1999;Colijn and Cadée, 2003;van de Poll et al, 2005;Kulk et al, 2013;Arteaga et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Combined Phosphorus Limitation and Light Stress Prevent Viral Proliferation in the Phytoplankton Species Phaeocystis globosa, but Not in Micromonas pusilla

2016

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Under natural conditions phytoplankton are often simultaneously subjected to phosphorus (P) limitation and suboptimal light levels. Potential interacting effects of P-limitation and light availability on phytoplankton virus-host interactions have thus far not been reported. We studied the influence of three environmentally relevant light levels (low; 25, medium; 100, and high; 250 µmol quanta m −2 s −1 ) in combination with P-limitation (vs. P-replete conditions) on virus proliferation in the key phytoplankton species Micromonas pusilla and Phaeocystis globosa. Cultures were acclimated to balanced P-limited growth at 3 light levels by semi-continuous culturing, before one-step infection experiments were carried out in batch mode. Under optimal conditions (medium light, P-replete), the latent period (time until first release of progeny viruses) was 6-9 and 9-12 h, and the burst size (number of viruses released per lysed host cell) was 241 ± 5 and 690 ± 28 for M. pusilla virus MpV and P. globosa virus PgV, respectively. Low light intensity under P-replete conditions prolonged the latent period of PgV (with maximally 3 h). The PgV burst size was 2.8-fold reduced under low light and 2.2-fold reduced under high light. The 10-fold range in light intensity did not affect viral latent period or burst size in P-replete M. pusilla. However, P-limitation (under optimal light) also led to elongated latent periods (with maximally 3 h compared to P-replete) and the viral burst sizes decreased by 2.7-fold for MpV and 3.5-fold for PgV. Finally, infectivity assays showed that PgV progeny from the P-limited high and low light cultures largely lost their infectivity, reducing their infective burst sizes to only 2-4 infective viruses per lysed host cell. Our study demonstrates that the effects of specific light and P-availability on virus-phytoplankton interaction are not only species specific, but can also strengthen each other's effects. Relatively small differences in environmental conditions with depth, geography or time have the potential to drastically affect viral infection of phytoplankton, with consequent effects on host species composition and biogeochemical fluxes.

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Low nutrient availability reduces high‐irradiance‐induced viability loss in oceanic phytoplankton

Cited by 17 publications

References 68 publications

Growth and biochemical composition of a microphytobenthic diatom (Entomoneis paludosa) exposed to shorebird (Calidris alpina) droppings

Growth and biochemical composition of a microphytobenthic diatom (Entomoneis paludosa) exposed to shorebird (Calidris alpina) droppings

Photophysiology of nitrate limited phytoplankton communities in Kongsfjorden, Spitsbergen

Combined Phosphorus Limitation and Light Stress Prevent Viral Proliferation in the Phytoplankton Species Phaeocystis globosa, but Not in Micromonas pusilla

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