Your search keyword '"Grover, Renaud"' showing total 25 results

1. Nutrient starvation and nitrate pollution impairs the assimilation of dissolved organic phosphorus in coral-Symbiodiniaceae symbiosis.

Author

Blanckaert, Alice C.A., Grover, Renaud, Marcus, Maria-Isabelle, and Ferrier-Pagès, Christine

Published

2023

2. Uptake of dissolved free amino acids by four cold-water coral species from the Mediterranean Sea.

Author

Gori, Andrea, Grover, Renaud, Orejas, Covadonga, Sikorski, Séverine, and Ferrier-Pagès, Christine

Subjects

*DEEP-sea corals, *AMINO acids, *SPECIES, *DISSOLVED organic matter, *NITROGEN in water, *RESPIRATION

Abstract

Dissolved organic matter, which contains many compounds such as lipids, sugars and amino acids, is an important source of carbon and nitrogen for several symbiotic and asymbiotic tropical coral species. However, there is still no information on its possible uptake by cold-water coral species. In this study, we demonstrated that dissolved organic matter, in the form of dissolved free amino acids (DFAA), is actively absorbed by four cold-water coral species from the Mediterranean Sea. Although the uptake rates observed with 3 µM DFAA concentration were one order of magnitude lower than those observed in tropical species, they corresponded to 12-50% of the daily excreted-nitrogen, and 16-89% of the daily respired-carbon of the cold-water corals. Consequently, DFAA, even at in situ concentrations lower than those tested in this study, can supply a significant amount of carbon and nitrogen to the corals, especially during periods when particulate food is scarce. [ABSTRACT FROM AUTHOR]

Published

2014

3. Species-Specific Response of Corals to Imbalanced Ratios of Inorganic Nutrients.

Author

Blanckaert, Alice C. A., Biscéré, Tom, Grover, Renaud, and Ferrier-Pagès, Christine

Subjects

*CORALS, *SCLERACTINIA, *ALCYONACEA, *TISSUE physiology, *NUTRIENT uptake, *SEAWATER

Abstract

Dissolved inorganic phosphorus (DIP) is a limiting nutrient in the physiology of scleractinian corals. Anthropogenic addition of dissolved inorganic nitrogen (DIN) to coastal reefs increases the seawater DIN:DIP ratio and further increases P limitation, which is detrimental to coral health. The effects of imbalanced DIN:DIP ratios on coral physiology require further investigation in coral species other than the most studied branching corals. Here we investigated the nutrient uptake rates, elemental tissue composition and physiology of a foliose stony coral, Turbinaria reniformis, and a soft coral, Sarcophyton glaucum, exposed to four different DIN: DIP ratios (0.5:0.2, 0.5:1, 3:0.2, 3:1). The results show that T. reniformis had high uptake rates of DIN and DIP, proportional to the seawater nutrient concentrations. DIN enrichment alone led to an increase in tissue N content, shifting the tissue N:P ratio towards P limitation. However, S. glaucum had 5 times lower uptake rates and only took up DIN when the seawater was simultaneously enriched with DIP. This double uptake of N and P did not alter tissue stoichiometry. This study allows us to better understand the susceptibility of corals to changes in the DIN:DIP ratio and predict how coral species will respond under eutrophic conditions in the reef. [ABSTRACT FROM AUTHOR]

Published

2023

4. Autotrophic carbon budget in coral tissue: a new 13C-based model of photosynthate translocation.

Author

Tremblay, Pascale, Grover, Renaud, Maguer, Jean François, Legendre, Louis, and Ferrier-Pagès, Christine

Subjects

*BIOLOGY experiments, *CORALS, *DINOFLAGELLATES, *PHOTOSYNTHATES, *CARBON, *GASES from plants, *SALINE waters

Abstract

Corals live in symbiosis with dinoflagellates of the genus Symbiodinum. These dinoflagellates translocate a large part of the photosynthetically fixed carbon to the host, which in turn uses it for its own needs. Assessing the carbon budget in coral tissue is a central question in reef studies that still vexes ecophysiologists. The amount of carbon fixed by the symbiotic association can be determined by measuring the rate of photosynthesis, but the amount of carbon translocated by the symbionts to the host and the fate of this carbon are more difficult to assess. In the present study, we propose a novel approach to calculate the budget of autotrophic carbon in the tissue of scleractinian corals, based on a new model and measurements made with the stable isotope 13C. Colonies of the scleractinian coral Stylophora pistillata were incubated in H13CO -3-enriched seawater, after which the fate of 13C was followed in the symbionts, the coral tissue and the released particulate organic carbon (i.e. mucus). Results obtained showed that after 15 min, ca. 60% of the carbon fixed was already translocated to the host, and after 48 h, this value reached 78%. However, ca. 48% of the photosynthetically fixed carbon was respired by the symbiotic association, and 28% was released as dissolved organic carbon. This is different from other coral species, where <1% of the total organic carbon released is from newly fixed carbon. Only 23% of the initially fixed carbon was retained in the symbionts and coral tissue after 48 h. Results show that our 13C-based model could successfully trace the carbon flow from the symbionts to the host, and the photosynthetically acquired carbon lost from the symbiotic association. [ABSTRACT FROM AUTHOR]

Published

2012

5. High phosphate uptake requirements of the scleractinian coral Stylophora pistillata.

Author

Godinot, Claire, Grover, Renaud, Allemand, Denis, and Ferrier-Pagès, Christine

Subjects

*NUTRIENT uptake, *PHOSPHATES, *INORGANIC compounds, *SCLERACTINIA, *CORALS

Abstract

Several untested aspects of the regulation of inorganic nutrient uptake were examined using nutrient depletion experiments with the symbiotic coral Stylophora pistillata. The total inhibition of phosphate uptake in artificial seawater lacking sodium indicates the involvement of a sodium/phosphate symporter for the uptake of phosphate across host membranes. Addition of ammonium or nitrate (up to 6.0 μmol l-1) did not enhance saturated phosphate uptake rates, thus indicating that corals, or their symbiotic algae, were not, or not sufficiently, nitrogen limited to modify their phosphate needs. Conversely, the saturated uptake rate of ammonium increased by 2.5-fold in the presence of 3.0 μmol l-1 of phosphate, thus indicating that the corals or their symbionts were lacking intracellular phosphate to take advantage of the inorganic nitrogen compounds dissolved in their surrounding medium. Overall, these results highlight some greater limitation in phosphate rather than in nitrogen. Finally, the rate of phosphate uptake decreased with particulate feeding of the host (organic phosphate source). Indeed, corals that were fed 1 and 3 days before the uptake experiment took up phosphate 42 and 19% slower, respectively, than corals that were fed 21 days before. This result provides additional evidence of phosphate limitation in S. pistillata. This study therefore brings new insights into the relationships between nutrients and symbiotic corals, and may provide a rapid and effective tool to investigate which nutrient is the most limiting for coral metabolism. [ABSTRACT FROM AUTHOR]

Published

2011

6. Uptake of dissolved free amino acids by the scleractinian coral Stylophora pistillata.

Author

Grover, Renaud, Maguer, Jean-François, Allemand, Denis, and Ferrier-Pagès, Christine

Subjects

*STYLOPHORA, *NITROGEN excretion, *METABOLISM, *URINALYSIS, *NITROGEN compounds, *DEVELOPMENTAL biology

Abstract

This study was designed to assess the importance of dissolved free amino acids (DFAA) as a nitrogen source for the scieractinian coral Stylophora pistillata. For this purpose, experiments were performed using 15N-enriched DFAAs, and %15N enrichment was measured both in animal tissue and zooxanthellae at different DFAA concentrations, incubation time and light levels. As previously observed for urea, which is another source of organic nitrogen, DFAA uptake exhibited a biphasic mode consisting of an active carrier-mediated transport for concentrations below 3 μmol-1 and a linear uptake for higher concentrations. The value of the carrier affinity (Km=1.23 μmol l-1 DFAA) indicated good adaptation of the corals to the low levels of DFAA concentrations measured in most oligotrophic waters. DFAA uptake was also correlated with light. The DFAA contribution to the nitrogen requirements for tissue growth was compared to the contribution of ammonia, nitrate and urea, for which uptake was also measured in S. pistillata. Inorganic sources (NH4+ and NO3-) contributed 75% of the daily nitrogen needs against 24% for organic sources. Taken altogether, dissolved organic and inorganic nitrogen can supply almost 100% of the nitrogen needs for tissue growth. [ABSTRACT FROM AUTHOR]

Published

2008

7. Urea uptake by the scleractinian coral Stylophora pistillata

Author

Grover, Renaud, Maguer, Jean-François, Allemand, Denis, and Ferrier-Pagès, Christine

Subjects

*NITROGEN excretion, *METABOLISM, *URINE, *NITROGEN

Abstract

Abstract: Urea can be one of the major sources of nitrogen for phytoplankton, but little is known about its importance for corals. Experiments were therefore designed to assess the uptake rates of urea by the scleractinian coral Stylophora pistillata; 15N-urea was used to follow the incorporation of nitrogen into the zooxanthellae and animal tissue. The uptake kinetics of urea in the tissue of S. pistillata showed that there is a concentration-dependent uptake of urea. The transport of urea was composed of a linear component (diffusion) at concentrations higher than 6 μmol N-urea l−1 and an active carrier-mediated component, at lower concentrations. The value of the carrier affinity (K m =1.05 μmol urea l−1) indicates a good adaptation of the corals to low levels of urea in seawater. At the in situ concentration of ca. 0.2 μmol N-urea l−1, the uptake rate was equal to 0.1 nmol N h−1 cm−2. Urea uptake was at least four times higher in the animal than in the algal fraction, and five times higher when corals were incubated in the light than in the dark. These results could be explained by the involvement of urea in the calcification process, which is also enhanced by light. Comparison of urea uptake rates with nitrate or ammonium uptake rates for the same S. pistillata species, at in situ concentrations, showed that urea is preferred to nitrate and may therefore be an important source of nitrogen for scleractinian corals. [Copyright &y& Elsevier]

Published

2006

8. Nitrate uptake in the scleractinian coral Stylophora pistillata.

Author

Grover, Renaud, Maguer, Jean-François, Allemand, Denis, and Ferrier-Pagès, Christine

Subjects

*NITRATES, *STYLOPHORA, *CORALS, *SEAWATER, *AMMONIUM

Abstract

We assessed the uptake rates of nitrate by the scleractinian coral Stylophora pistillata by following [sup15]N from seawater into the coral tissue. Two sets of corals were first prepared, with "nitrate-enriched" corals grown in 5 µmol L[sup-1] NO[sup-, sub3] and control corals grown in ≤ 1 µmol L[sup-1] NO[sup-, sub3]. Uptake rates at 0.3 and 3 µmol L[sup-1][[sup15]N]NO[sup-, sub3] were then measured. Most of the %[sup15]N enrichment occurred in the zooxanthellae fraction. Uptake rates were not significantly different between nitrate-enriched and control corals, suggesting that they were not dependent on a nitrate acclimation. These rates increased with the in situ nitrate concentration and varied from 1.2 ± 0.2 ng h[sup-1] cm[sup-2] N to 6.1 ± 1.1 ng h[sup-1] cm[sup-2] N in the algal fraction at 0.3 and 3 µmol L[sup-1] [[sup15]N]NO[sup-, sub3], respectively. In a second experiment, two sets of corals were prepared, with "ammonium-enriched" corals grown in 5 µmol L[sup-1] NH[sup+, sub4] and control corals grown in < 1 µmol L[sup-1] NH[sup+, sub4]. Uptake rates at 3 µmol L[sup-1] [[sup15]N]NO[sup-, sub3] were measured. These rates were significantly lower with high NH[sup+, sub4] concentrations in seawater. In the algal fraction, they ranged from 0.1 to 0.6 ng h[sup-1] cm[sup-2] N in NH[sup+, sub4]-enriched corals and from 2.2 to 4.5 ng h[sup-1] cm[sup-2] N in control corals. Nitrate can therefore be considered as an important source of nitrogen for corals, at least when ammonium concentrations are low in seawater. [ABSTRACT FROM AUTHOR]

Published

2003

9. Elevated ammonium delays the impairment of the coral-dinoflagellate symbiosis during labile carbon pollution.

Author

Bednarz, Vanessa N., Grover, Renaud, and Ferrier-Pagès, Christine

Subjects

*SYMBIODINIUM, *CORAL reef ecology, *SYMBIOSIS, *DISSOLVED organic matter, *ECOLOGICAL integrity, *CORAL bleaching, *CORAL reefs & islands

Abstract

• Labile carbon pollution de-stabilizes the symbiotic functioning of corals. • Both, coral host and symbiotic algae physiology are affected. • The photosynthetic efficiency and activity of symbiotic algae are largely reduced. • Labile carbon assimilation partially replaces reduced photosynthate translocation. • Excess ammonium supply sustains photosynthesis and delays symbiosis breakdown. Labile dissolved organic carbon (DOC) is a major pollutant in coastal marine environments affected by anthropogenic impacts, and may significantly contribute to coral bleaching and subsequent mortality on coastal reefs. DOC can cause bleaching indirectly through the rapid proliferation of copiotrophic and pathogenic bacteria. Here we demonstrate that labile DOC compounds can also impair the coral-dinoflagellate symbiosis by directly affecting coral physiology on both the host and algal symbiont level. In a controlled aquarium experiment, we monitored over several weeks key physiological parameters of the tropical coral Stylophora pistillata exposed to ambient and elevated labile DOC levels (0.1 and 1.0 mM) in combination with low and high nitrogen (i.e. ammonium) conditions (0.2 and 4.0 μM). At the symbiont level, DOC exposure under low ammonium availability decreased the photosynthetic efficiency accompanied by ∼75 % Chl a and ∼50 % symbiont cell reduction. The photosynthetic functioning of the symbionts recovered once the DOC enrichment ceased indicating a reversible shift between autotrophic and heterotrophic metabolism. At the host level, the assimilation of exogenous DOC sustained the tissue carbon reserves, but induced a depletion of the nitrogen reserves, indicated by ∼35 % decreased protein levels. This suggests an imbalanced exogenous carbon to nitrogen supply with nitrogen potentially limiting host metabolism on the long-term. We also demonstrate that increased ammonium availability delayed DOC-induced bleaching likely by keeping symbionts in a photosynthetically competent state, which is crucial for symbiosis maintenance and coral survival. Overall, the present study provides further insights into how coastal pollution can de-stabilize the coral-algal symbiosis and cause coral bleaching. Therefore, reducing coastal pollution and sustaining ecological integrity are critical to strengthen the resilience of coral reefs facing climate change. [ABSTRACT FROM AUTHOR]

Published

2020

10. Symbiotic stony and soft corals: Is their host‐algae relationship really mutualistic at lower mesophotic reefs?

Author

Ferrier‐Pagès, Christine, Bednarz, Vanessa, Grover, Renaud, Benayahu, Yehuda, Maguer, Jean‐François, Rottier, Cecile, Wiedenmann, Joerg, and Fine, Maoz

Subjects

*ALCYONACEA, *SCLERACTINIA, *REEFS, *CORALS, *SYMBIODINIUM, *PHOTOSYNTHETIC rates, *SPECIES

Abstract

Mesophotic coral ecosystems (30–150 m depth) present a high oceanic biodiversity, but remain one of the most understudied reef habitats, especially below 60 m depth. Here, we have assessed the rates of photosynthesis and dissolved inorganic carbon (DIC) and nitrogen (DIN) assimilation by Symbiodiniaceae associated with four soft coral species of the genus Sinularia and two stony coral species of the genus Leptoseris collected respectively at 65 and 80–90 m depth in the Gulf of Eilat. Our study demonstrates that both Leptoseris and Sinularia species have limited autotrophic capacities at mid‐lower mesophotic depths. DIC and DIN assimilation rates were overall ~ 10 times lower compared to shallow corals from 10 m depth in the same reef. While Leptoseris symbionts transferred at least 50% of the acquired nitrogen to their host after 8‐h incubation, most of the nitrogen was retained in the symbionts of Sinularia. In addition, the host tissue of Sinularia species presented a very high structural carbon to nitrogen ratio (C : N) compared to Leptoseris or to the shallow coral species, suggesting nitrogen limitation in these mesophotic soft corals. The limited capacity of soft coral symbionts to acquire DIN and transfer it to the coral animal, as well as the high C : N ratios, might explain the scarcity of symbiotic soft corals at mid‐lower mesophotic depths compared to their prevalence in the shallower reef. Overall, this study highlights the significance of DIN for the distribution of the Cnidarian‐ Symbiodiniaceae association at mesophotic depth. [ABSTRACT FROM AUTHOR]

Published

2022

11. Nitrogen fixation in the mucus of Red Sea corals.

Author

Grover, Renaud, Ferrier-Pagès, Christine, Maguer, Jean-François, Ezzat, Leila, and Fine, Maoz

Subjects

*NITROGEN fixation, *SCLERACTINIA, *NITROGEN-fixing bacteria, *DINOFLAGELLATES, *PLANT-bacterial symbiosis

Abstract

Scleractinian corals are essential constituents of tropical reef ecological diversity. They live in close association with diazotrophs [dinitrogen (N2)-fixing microbes], which can fix high rates of N2. Whether corals benefit from this extrinsic nitrogen source is still under debate. Until now, N2 fixation rates have been indirectly estimated using the acetylene reduction assay, which does not permit assessment of the amount of nitrogen incorporated into the different compartments of the coral holobiont. In the present study, the 15N2 technique was applied for the first time on three Red Sea coral species. Significant 15N enrichment was measured in particles released by corals to the surrounding seawater. N2 fixation rates were species specific and as high as 1.6-2 ng N day-1 l-1. However, no significant enrichment was measured in the symbiotic dinoflagellates or the coral host tissues, suggesting that corals do not benefit from diazotrophic N2 fixation. [ABSTRACT FROM AUTHOR]

Published

2014

12. Nutrient starvation impairs the trophic plasticity of reef‐building corals under ocean warming.

Author

Ezzat, Leïla, Maguer, Jean‐François, Grover, Renaud, Rottier, Cécile, Tremblay, Pascale, Ferrier‐Pagès, Christine, and Field, Katie

Subjects

*CORAL bleaching, *CORALS, *OCEAN acidification, *STARVATION, *THERMAL stresses, *NUTRIENT uptake, *MATERIAL plasticity

Abstract

Global warming of the world's oceans is driving reef‐building corals towards their upper thermal limit, inducing bleaching, nutrient starvation and mortality. In addition, corals are predicted to experience large fluctuations in seawater nutrient concentrations, following water column stratification or eutrophication problems, which can further alter their nutritional capacities and ultimately their resilience to global change.We investigated the effect of thermal stress and dissolved inorganic nutrient (DINUT) availability on the auto‐ and heterotrophic nutritional capacities of corals. In particular, we assessed the effect of nitrogen enrichment or DINUT depletion (both in nitrogen and in phosphorus) on the assimilation of heterotrophic nutrients and on the heat‐stress tolerance of the reef‐building coral Stylophora pistillata.Here, we show that DINUT depletion enhanced coral bleaching under thermal stress and more importantly, significantly impaired rates of heterotrophic nutrient assimilation, inducing coral starvation. In contrast, corals grown under nitrogen enrichment maintained high rates of heterotrophic nutrient assimilation and avoided bleaching, although nutrient uptake rates were lowered. We therefore observed a positive coupling between auto‐ and heterotrophy within the coral–dinoflagellate symbiosis, indicating that heterotrophic processes require a minimum of autotrophically acquired nutrients to be functional.These findings show that the trophic plasticity of corals directly depends on the availability of dissolved inorganic nutrients in seawater. The lack of a shift towards greater heterotrophy under DINUT depletion may lead to substantial modifications of the role that feeding plays in the response of reef‐building corals to climate change. A plain language summary is available for this article. Plain Language Summary [ABSTRACT FROM AUTHOR]

Published

2019

13. Trophic dynamics of scleractinian corals: stable isotope evidence.

Author

Tremblay, Pascale, Maguer, Jean François, Grover, Renaud, and Ferrier-Pagès, Christine

Subjects

*SCLERACTINIA, *STABLE isotope analysis, *SYMBIOSIS, *DINOFLAGELLATES, *CNIDARIA, *FOOD

Abstract

Reef-building corals form symbioses with dinoflagellates from the diverse genus Symbiodinium. This symbiotic association has developed adaptations to acquire and share nutrients, which are essential for its survival and growth in nutrient-poor tropical waters. The host is thus able to prey on a wide range of organic food sources (heterotrophic nutrition) whereas the symbionts acquire most of the inorganic nutrients (autotrophic nutrition). However, nutrient fluxes between the two partners remain unclear, especially concerning heterotrophically acquired carbon and nitrogen. We combined physiological measurements and pulse-chase isotopic labeling of heterotrophic carbon and nitrogen, as well as autotrophic carbon to track nutrient fluxes in two coral species, Stylophora pistillata and Turbinana reniformis, in symbiosis with Symbiodinium clades A, and C, D respectively. We showed a rapid acquisition, exchange and a longterm retention of heterotrophic nutrients within the symbiosis, whereas autotrophic nutrients were rapidly used to meet immediate metabolic needs. In addition, there was a higher retention of heterotrophic nitrogen compared with carbon, in agreement with the idea that tropical corals are nitrogen-limited. Finally, a coupling between auto- and heterotrophy was observed in the species S. pistillata, with a higher acquisition and retention of heterotrophic nutrients under low irradiance to compensate for a 50% reduction in autotrophic nutrient acquisition and translocation. Conversely, T. reniformis conserved an equivalent heterotrophic nutrient acquisition at both light levels because this coral species did not significantly reduce its rates of gross photosynthesis and autotrophic carbon acquisition between the two irradiances. These experiments advance the current understanding of the nutrient exchanges between the two partners of a symbiotic association, providing evidence of the complexity of the host-symbiont relationship. [ABSTRACT FROM AUTHOR]

Published

2015

14. Desert dust deposition supplies essential bioelements to Red Sea corals.

Author

Blanckaert, Alice C. A., Omanović, Dario, Fine, Maoz, Grover, Renaud, and Ferrier‐Pagès, Christine

Subjects

*CORAL bleaching, *CORALS, *OCEAN temperature, *PHOTOSYNTHETIC rates, *DUST storms, *IRON, *DUST

Abstract

Climate change‐related increase in seawater temperature has become a leading cause of coral bleaching and mortality. However, corals from the northern Red Sea show high thermal tolerance and no recorded massive bleaching event. This specific region is frequently subjected to intense dust storms, coming from the surrounding arid deserts, which are expected to increase in frequency and intensity in the future. The aerial dust deposition supplies essential bioelements to the water column. Here, we investigated the effect of dust deposition on the physiology of a Red Sea coral, Stylophora pistillata. We measured the modifications in coral and Symbiodiniaceae metallome (cellular metal content), as well as the changes in photosynthesis and oxidative stress status of colonies exposed during few weeks to dust deposition. Our results show that 1 mg L−1 of dust supplied nanomolar amounts of nitrate and other essential bioelements, such as iron, manganese, zinc and copper, rapidly assimilated by the symbionts. At 25°C, metal bioaccumulation enhanced the chlorophyll concentration and photosynthesis of dust‐exposed corals compared to control corals. These results suggest that primary production was limited by metal availability in seawater. A 5°C increase in seawater temperature enhanced iron assimilation in both control and dust‐enriched corals. Temperature rise increased the photosynthesis of control corals only, dust‐exposed ones having already reached maximal photosynthesis rates at 25°C. Finally, we observed a combined effect of temperature and bioelement concentration on the assimilation of molybdenum, cadmium, manganese and copper, which were in higher concentrations in symbionts of dust‐exposed corals maintained at 30°C. All together these observations highlight the importance of dust deposition in the supply of essential bioelements, such as iron, to corals and its role in sustaining coral productivity in Red Sea reefs. [ABSTRACT FROM AUTHOR]

Published

2022

15. Coral Uptake of Inorganic Phosphorus and Nitrogen Negatively Affected by Simultaneous Changes in Temperature and pH.

Author

Godinot, Claire, Houlbrèque, Fanny, Grover, Renaud, and Ferrier-Pagès, Christine

Subjects

*SCLERACTINIA, *PHOSPHORUS metabolism, *PHOTOSYNTHESIS, *INORGANIC compounds, *TEMPERATURE effect, *PH effect, *NITROGEN metabolism, *ACIDIFICATION

Abstract

The effects of ocean acidification and elevated seawater temperature on coral calcification and photosynthesis have been extensively investigated over the last two decades, whereas they are still unknown on nutrient uptake, despite their importance for coral energetics. We therefore studied the separate and combined impacts of increases in temperature and pCO2 on phosphate, ammonium, and nitrate uptake rates by the scleractinian coral S. pistillata. Three experiments were performed, during 10 days i) at three pHT conditions (8.1, 7.8, and 7.5) and normal temperature (26°C), ii) at three temperature conditions (26°, 29°C, and 33°C) and normal pHT (8.1), and iii) at three pHT conditions (8.1, 7.8, and 7.5) and elevated temperature (33°C). After 10 days of incubation, corals had not bleached, as protein, chlorophyll, and zooxanthellae contents were the same in all treatments. However, photosynthetic rates significantly decreased at 33°C, and were further reduced for the pHT 7.5. The photosynthetic efficiency of PSII was only decreased by elevated temperature. Nutrient uptake rates were not affected by a change in pH alone. Conversely, elevated temperature (33°C) alone induced an increase in phosphate uptake but a severe decrease in nitrate and ammonium uptake rates, even leading to a release of nitrogen into seawater. Combination of high temperature (33°C) and low pHT (7.5) resulted in a significant decrease in phosphate and nitrate uptake rates compared to control corals (26°C, pHT = 8.1). These results indicate that both inorganic nitrogen and phosphorus metabolism may be negatively affected by the cumulative effects of ocean warming and acidification. [ABSTRACT FROM AUTHOR]

Published

2011

16. Unravelling the different causes of nitrate and ammonium effects on coral bleaching.

Author

Fernandes de Barros Marangoni, Laura, Ferrier-Pagès, Christine, Rottier, Cécile, Bianchini, Adalto, and Grover, Renaud

Subjects

*CORAL bleaching, *CORAL reefs & islands, *CORAL reef ecology, *STYLOPHORA pistillata, *OXIDATIVE stress

Abstract

Mass coral bleaching represents one of the greatest threats to coral reefs and has mainly been attributed to seawater warming. However, reduced water quality can also interact with warming to increase coral bleaching, but this interaction depends on nutrient ratios and forms. In particular, nitrate (NO3−) enrichment reduces thermal tolerance while ammonium (NH4+) enrichment tends to benefit coral health. The biochemical mechanisms underpinning the different bleaching responses of corals exposed to DIN enrichment still need to be investigated. Here, we demonstrated that the coral Stylophora pistillata underwent a severe oxidative stress condition and reduced aerobic scope when exposed to NO3− enrichment combined with thermal stress. Such condition resulted in increased bleaching intensity compared to a low-nitrogen condition. On the contrary, NH4+ enrichment was able to amend the deleterious effects of thermal stress by favoring the oxidative status and energy metabolism of the coral holobiont. Overall, our results demonstrate that the opposite effects of nitrate and ammonium enrichment on coral bleaching are related to the effects on corals' energy/redox status. As nitrate loading in coastal waters is predicted to significantly increase in the future due to agriculture and land-based pollution, there is the need for urgent management actions to prevent increases in nitrate levels in seawater. In addition, the maintenance of important fish stocks, which provide corals with recycled nitrogen such as ammonium, should be favoured. [ABSTRACT FROM AUTHOR]

Published

2020

17. Productivity and carbon fluxes depend on species and symbiont density in soft coral symbioses.

Author

Pupier, Chloé A., Fine, Maoz, Bednarz, Vanessa N., Rottier, Cécile, Grover, Renaud, and Ferrier-Pagès, Christine

Subjects

*ALCYONACEA, *CORALS, *CORAL bleaching, *STABLE isotope tracers, *SCLERACTINIA, *CORAL reefs & islands, *ECOLOGICAL disturbances

Abstract

Soft corals often constitute one of the major benthic groups of coral reefs. Although they have been documented to outcompete reef-building corals following environmental disturbances, their physiological performance and thus their functional importance in reefs are still poorly understood. In particular, the acclimatization to depth of soft corals harboring dinoflagellate symbionts and the metabolic interactions between these two partners have received little attention. We performed stable isotope tracer experiments on two soft coral species (Litophyton sp. and Rhytisma fulvum fulvum) from shallow and upper mesophotic Red Sea coral reefs to quantify the acquisition and allocation of autotrophic carbon within the symbiotic association. Carbon acquisition and respiration measurements distinguish Litophyton sp. as mainly autotrophic and Rhytisma fulvum fulvum as rather heterotrophic species. In both species, carbon acquisition was constant at the two investigated depths. This is a major difference from scleractinian corals, whose carbon acquisition decreases with depth. In addition, carbon acquisition and photosynthate translocation to the host decreased with an increase in symbiont density, suggesting that nutrient provision to octocoral symbionts can quickly become a limiting factor of their productivity. These findings improve our understanding of the biology of soft corals at the organism-scale and further highlight the need to investigate how their nutrition will be affected under changing environmental conditions. [ABSTRACT FROM AUTHOR]

Published

2019

18. Diazotrophic community and associated dinitrogen fixation within the temperate coral Oculina patagonica.

Author

Bednarz, Vanessa N., Water, Jeroen A. J. M., Rabouille, Sophie, Maguer, Jean‐François, Grover, Renaud, and Ferrier‐Pagès, Christine

Subjects

*NITROGEN fixation, *CYANOBACTERIA, *NITRIFICATION inhibitors, *NITROGEN-fixing bacteria, *CORALS

Abstract

Summary: Dinitrogen (N2) fixing bacteria (diazotrophs) are an important source of new nitrogen in oligotrophic environments and represent stable members of the microbiome in tropical corals, while information on corals from temperate oligotrophic regions is lacking. Therefore, this study provides new insights into the diversity and activity of diazotrophs associated with the temperate coral Oculina patagonica from the Mediterranean Sea by combining metabarcoding sequencing of amplicons of both the 16S rRNA and nifH genes and 15N2 stable isotope tracer analysis to assess diazotroph‐derived nitrogen (DDN) assimilation by the coral. Results show that the diazotrophic community of O. patagonica is dominated by autotrophic bacteria (i.e. Cyanobacteria and Chlorobia). The majority of DDN was assimilated into the tissue and skeletal matrix, and DDN assimilation significantly increased in bleached corals. Thus, diazotrophs may constitute an additional nitrogen source for the coral host, when nutrient exchange with Symbiodinium is disrupted (e.g. bleaching) and external food supply is limited (e.g. oligotrophic summer season). Furthermore, we hypothesize that DDN can facilitate the fast proliferation of endolithic algae, which provide an alternative carbon source for bleached O. patagonica. Overall, O. patagonica could serve as a good model for investigating the importance of diazotrophs in coral recovery from bleaching. [ABSTRACT FROM AUTHOR]

Published

2019

19. Biochemical composition of the cold-water coral Dendrophyllia cornigera under contrasting productivity regimes: Insights from lipid biomarkers and compound-specific isotopes.

Author

Gori, Andrea, Tolosa, Imma, Orejas, Covadonga, Rueda, Lucia, Viladrich, Núria, Grinyó, Jordi, Flögel, Sascha, Grover, Renaud, and Ferrier-Pagès, Christine

Subjects

*CORALS, *LIPID analysis, *FATTY alcohols, *PHYTOPLANKTON, *DINOFLAGELLATES

Abstract

Abstract The cold-water coral (CWC) Dendrophyllia cornigera is widely distributed in areas of both high and low productivity, suggesting a significant trophic plasticity of this coral depending on the food available in the environment. In this study, lipid biomarkers and their isotopic signature were compared in colonies of D. cornigera and sediment from the highly productive Cantabrian Sea (Northeast Atlantic Ocean) and the less productive Menorca Channel (Western Mediterranean Sea). Lipid content and composition in coral tissue clearly reflected the contrasting productivity in the two areas. Cantabrian corals presented higher content in fatty acids (FA), fatty alcohols and sterols than Menorca corals. Energy storage (saturated + mono-unsaturated FA) to structural (poly-unsaturated FA) ratio was higher in Cantabrian than in Menorca corals. The high ΣC20:1 content as well as PUFA (n-3) /PUFA (n-6) ratio suggest that Cantabrian corals mainly feed on phytoplankton and herbivorous grazers. This is also supported by the higher mono-unsaturated fatty alcohols (MUOH) and long chain mono-unsaturated fatty alcohols (LCMUOH) content in Cantabrian compared to Menorca corals. Conversely, higher PUFA (n-6) content in Menorca corals, with the dominance of C22:4 (n-6) and C20:4 (n-6) , as well as the dominance of cholesterol and norC 27 Δ5,22 among sterols, point to a higher trophic role of dinoflagellates and invertebrates. The observed geographical variability in trophic ecology supports a high trophic plasticity of D. cornigera , which may favour the wide distribution of this CWC in areas with highly contrasted food availability. Highlights • Higher lipid content in D. cornigera in Cantabrian Sea than in Menorca Channel. • Lipid composition and δ 13C values reflected contrasted food captured by corals. • Feeding on phytoplankton and herbivorous grazers by Cantabrian D. cornigera. • Main trophic role of dinoflagellates and invertebrates for Menorca D. cornigera. • High trophic plasticity of D. cornigera. [ABSTRACT FROM AUTHOR]

Published

2018

20. The c-Jun N-terminal kinase prevents oxidative stress induced by UV and thermal stresses in corals and human cells.

Author

Courtial, Lucile, Picco, Vincent, Grover, Renaud, Cormerais, Yann, Rottier, Cécile, Labbe, Antoine, Pagès, Gilles, and Ferrier-Pagès, Christine

Abstract

Coral reefs are of major ecological and socio-economic interest. They are threatened by global warming and natural pressures such as solar ultraviolet radiation. While great efforts have been made to understand the physiological response of corals to these stresses, the signalling pathways involved in the immediate cellular response exhibited by corals remain largely unknown. Here, we demonstrate that c-Jun N-terminal kinase (JNK) activation is involved in the early response of corals to thermal and UV stress. Furthermore, we found that JNK activity is required to repress stress-induced reactive oxygen species (ROS) accumulation in both the coral Stylophora pistillata and human skin cells. We also show that inhibiting JNK activation under stress conditions leads to ROS accumulation, subsequent coral bleaching and cell death. Taken together, our results suggest that an ancestral response, involving the JNK pathway, is remarkably conserved from corals to human, protecting cells from the adverse environmental effects. [ABSTRACT FROM AUTHOR]

Published

2017

21. Limited phosphorus availability is the Achilles heel of tropical reef corals in a warming ocean.

Author

Ezzat, Leïla, Maguer, Jean-François, Grover, Renaud, and Ferrier-Pagès, Christine

Published

2016

22. Phosphorus metabolism of reef organisms with algal symbionts.

Author

Ferrier‐Pagès, Christine, Godinot, Claire, D'Angelo, Cecilia, Wiedenmann, Jörg, and Grover, Renaud

Subjects

*CORALS, *EUTROPHICATION, *PHOSPHATES, *PHOSPHORUS, *SYMBIODINIUM, *SYMBIOSIS

Abstract

Phosphorus (P), an essential structural and functional component of all living organisms, is considered to be the ultimate limiting nutrient in marine ecosystems. To optimize its acquisition, marine species such as protozoa, sponges, foraminifera, clams, and reef corals, among others, have entered symbiotic relationships with algae, which recycle waste products of the animal host and transform dissolved inorganic nutrients into organic molecules, making them bioavailable to their host. Such associations provide a competitive edge in an environment where ambient nutrient availability is low. The aim of this review is to summarize the current knowledge on the P sources available to reef organisms with algal symbionts, to discuss the means by which P is taken up and stored within the symbiosis, and to assess the effects of eutrophication-induced phosphate enrichment on the algal and host physiology. Finally, we give an overview of knowledge gaps and open questions that should be addressed to better understand the role of phosphorus in reef symbioses functioning. [ABSTRACT FROM AUTHOR]

Published

2016

23. New insights into carbon acquisition and exchanges within the coral-dinoflagellate symbiosis under NH4+ and NO3- supply.

Author

Ezzat, Leïla, Maguer, Jean-François, Grover, Renaud, and Ferrier-Pagès, Christine

Subjects

*CORAL reef ecology, *DINOFLAGELLATES, *SYMBIOSIS, *AMMONIUM, *CARBON fixation, *NITRATES, *NUTRIENT cycles, *COASTAL ecology

Abstract

Anthropogenic nutrient enrichment affects the biogeochemical cycles and nutrient stoichiometry of coastal ecosystems and is often associated with coral reef decline. However, the mechanisms by which dissolved inorganic nutrients, and especially nitrogen forms (ammonium versus nitrate) can disturb the association between corals and their symbiotic algae are subject to controversial debate. Here, we investigated the coral response to varying N : P ratios, with nitrate or ammonium as a nitrogen source. We showed significant differences in the carbon acquisition by the symbionts and its allocation within the symbiosis according to nutrient abundance, type and stoichiometry. In particular, under low phosphate concentration (0.05 µM), a 3 µM nitrate enrichment induced a significant decrease in carbon fixation rate and low values of carbon translocation, compared with control conditions (N : P = 0.5 : 0.05), while these processes were significantly enhanced when nitrate was replaced by ammonium. A combined enrichment in ammonium and phosphorus (N : P = 3 : 1) induced a shift in nutrient allocation to the symbionts, at the detriment of the host. Altogether, these results shed light into the effect of nutrient enrichment on reef corals. More broadly, they improve our understanding of the consequences of nutrient loading on reef ecosystems, which is urgently required to refine risk management strategies. [ABSTRACT FROM AUTHOR]

Published

2015

24. Controlling Effects of Irradiance and Heterotrophy on Carbon Translocation in the Temperate Coral Cladocora caespitosa.

Author

Tremblay, Pascale, Ferrier-Pagès, Christine, Maguer, Jean François, Rottier, Cécile, Legendre, Louis, Grover, Renaud, and Browman, Howard

Subjects

*SPECTRAL irradiance, *CORALS, *CORAL colonies, *SYMBIOSIS, *HOSTS (Biology), *PHOTOBIOLOGY

Abstract

Temperate symbiotic corals, such as the Mediterranean species Cladocora caespitosa, live in seasonally changing environments, where irradiance can be ten times higher in summer than winter. These corals shift from autotrophy in summer to heterotrophy in winter in response to light limitation of the symbiont's photosynthesis. In this study, we determined the autotrophic carbon budget under different conditions of irradiance (20 and 120 μmol photons m-2 s-1) and feeding (fed three times a week with Artemia salina nauplii, and unfed). Corals were incubated in H13CO3--enriched seawater, and the fate of 13C was followed in the symbionts and the host tissue. The total amount of carbon fixed by photosynthesis and translocated was significantly higher at high than low irradiance (ca. 13 versus 2.5-4.5 μg cm-2 h-1), because the rates of photosynthesis and carbon fixation were also higher. However, the percent of carbon translocation was similar under the two irradiances, and reached more than 70% of the total fixed carbon. Host feeding induced a decrease in the percentage of carbon translocated under low irradiance (from 70 to 53%), and also a decrease in the rates of carbon translocation per symbiont cell under both irradiances. The fate of autotrophic and heterotrophic carbon differed according to irradiance. At low irradiance, autotrophic carbon was mostly respired by the host and the symbionts, and heterotrophic feeding led to an increase in host biomass. Under high irradiance, autotrophic carbon was both respired and released as particulate and dissolved organic carbon, and heterotrophic feeding led to an increase in host biomass and symbiont concentration. Overall, the maintenance of high symbiont concentration and high percentage of carbon translocation under low irradiance allow this coral species to optimize its autotrophic carbon acquisition, when irradiance conditions are not favourable to photosynthesis. [ABSTRACT FROM AUTHOR]

Published

2012

25. On the use of 31P NMR for the quantification of hydrosoluble phosphorus-containing compounds in coral host tissues and cultured zooxanthellae.

Author

Godinot, Claire, Gaysinski, Marc, Thomas, Olivier P., Ferrier-Pagès, Christine, and Grover, Renaud

Published

2016