Skeletal growth, respiration rate and fatty acid composition in the cold-water coral Lophelia pertusa under varying food conditions

Larsson, Ann I.; Lundälv, Tomas; Oevelen, Dick van

doi:10.3354/meps10284

Cited by 52 publications

(79 citation statements)

References 66 publications

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“…The concentration of total fatty acids (20 mg g −1 DW tissue with tissue DW contributing 5 % to total DW, as observed in this study), however, was below the range of 55-124 mg g −1 DW tissue reported by Dodds et al (2009) for L. pertusa from Rockall Bank, Mingulay Reef and New England Seamounts. Local differences can be responsible for this discrepancy as Larsson et al (2013a) reported storage fatty acids concentrations of 15 to 19 mg g −1 DW tissue from L. pertusa collected at the Tisler Reef but also the maintenance in aquaria (3 month in this study) might have altered the lipid content (Larsson et al, 2013b).…”

Section: Biochemical Characteristics Of L Pertusamentioning

confidence: 66%

Opportunistic feeding on various organic food sources by the cold-water coral <i>Lophelia pertusa</i>

et al. 2014

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Abstract. The ability of the cold-water coral Lophelia pertusa to exploit different food sources was investigated under standardized conditions in a flume. The tested food sources, dissolved organic matter (DOM, added as dissolved free amino acids), bacteria, algae, and zooplankton (Artemia) were deliberately enriched in 13 C and 15 N. The incorporation of 13 C and 15 N was traced into bulk tissue, fatty acids, hydrolysable amino acids, and the skeleton ( 13 C only) of L. pertusa. Incorporation rates of carbon (ranging from 0.8-2.4 µg C g −1 DW d −1 ) and nitrogen (0.2-0.8 µg N g −1 DW d −1 ) into coral tissue did not differ significantly among food sources indicating an opportunistic feeding strategy. Although total food assimilation was comparable among sources, subsequent food processing was dependent on the type of food source ingested and recovery of assimilated C in tissue compounds ranged from 17 % (algae) to 35 % (Artemia). De novo synthesis of individual fatty acids by L. pertusa occurred in all treatments as indicated by the 13 C enrichment of individual phospholipid-derived fatty acids (PLFAs) in the coral that were absent in the added food sources. This indicates that the coral might be less dependent on its diet as a source of specific fatty acids than expected, with direct consequences for the interpretation of in situ observations on coral nutrition based on lipid profiles.

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Section: Biochemical Characteristics Of L Pertusamentioning

confidence: 66%

Opportunistic feeding on various organic food sources by the cold-water coral <i>Lophelia pertusa</i>

et al. 2014

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“…Calculations (Eqns 16-18) revealed that less than 0.5% of energy would be required for calcification in relation to overall respiration in M. oculata (Table 2). Also, for L. pertusa only 3-5% of the available energy is allocated to calcification in comparison to respiration (Larsson et al, 2013), and metabolic carbon contribution to calcification was 1% in relation to that of the tissue pool and respiration for the CWC L. pertusa (Mueller et al, 2014). The relatively low energy requirement for upregulation of Ω a in the calcifying fluid and the maintenance of relatively high calcification rates might explain the observed resistance to ocean acidification.…”

Section: Energy Requirements For Up-regulation Of the Calicoblastic Phmentioning

confidence: 95%

“…Starvation of D. dianthus caused an initial and significant decrease in calcification after 1 week, while starvation for another 2 weeks did not result in further significant reduction of calcification rates (Naumann et al, 2013b). When L. pertusa was provided with various concentrations of food over 15 weeks, only small and non-significant changes in respiration were measured, and no effect on calcification occurred, despite the fact that food supply varied by a factor of 7.5 (Larsson et al, 2013). Also, for M. oculata (this study) the HF regime only affected the first measurements on calcification, which were taken 2 weeks after the respective feeding regimes had been applied, while during later measurements (4-10 weeks), calcification was independent of feeding regime.…”

Section: Effect Of Nutrition On Metabolic Functioningmentioning

confidence: 99%

“…Starvation triggers a continuous decline in respiration rates of L. pertusa and D. dianthus (Larsson et al, 2013;Naumann et al, 2013a). Starvation of D. dianthus caused an initial and significant decrease in calcification after 1 week, while starvation for another 2 weeks did not result in further significant reduction of calcification rates (Naumann et al, 2013b).…”

Section: Effect Of Nutrition On Metabolic Functioningmentioning

confidence: 99%

“…This is an important mechanism which allows a switch from food ingestion to a removal of undesired components, such as food remnants, metabolites with high N content (Wild et al, 2008), sediment or other particles (Larsson et al, 2013;Larsson and Purser, 2011;Zetsche et al, 2016). Also, mucus has an important role in fuelling bacterial growth in the coelenteron (Herndl and Velimirov, 1986;Weinbauer et al, 2012) and the close vicinity of the coral environment (Wild et al, 2004a(Wild et al, ,b, 2008(Wild et al, , 2009(Wild et al, , 2005.…”

Section: Function Of Mucusmentioning

confidence: 99%

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Effects of elevated pCO2 and feeding on net calcification and energy budget of the Mediterranean cold-water coral Madrepora oculata

Maier

Popp

Sollfrank

et al. 2016

Journal of Experimental Biology

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Ocean acidification is a major threat to calcifying marine organisms such as deep-sea cold-water corals (CWCs), but related knowledge is scarce. The aragonite saturation threshold (Ω a ) for calcification, respiration and organic matter fluxes were investigated experimentally in the Mediterranean Madrepora oculata. Over 10 weeks, colonies were maintained under two feeding regimes (uptake of 36.75 and 7.46 µmol C polyp) and exposed in 2 week intervals to a consecutively changing air-CO 2 mix ( pCO 2 ) of 400, 1600, 800, 2000 and 400 ppm. There was a significant effect of feeding on calcification at initial ambient pCO 2 , while with consecutive pCO 2 treatments, feeding had no effect on calcification. Respiration was not significantly affected by feeding or pCO 2 levels. Coral skeletons started to dissolve at an average Ω a threshold of 0.92, but recovered and started to calcify again at Ω a ≥1. The surplus energy required to counteract dissolution at elevated pCO 2 (≥1600 µatm) was twice that at ambient pCO 2 . Yet, feeding had no mitigating effect at increasing pCO 2 levels. This could be due to the fact that the energy required for calcification is a small fraction (1-3%) of the total metabolic energy demand and corals even under low food conditions might therefore still be able to allocate this small portion of energy to calcification. The response and resistance to ocean acidification are consequently not controlled by feeding in this species, but more likely by chemical reactions at the site of calcification and exchange processes between the calicoblastic layer and ambient seawater.

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Potential seasonal calibration for palaeoenvironmental reconstruction using skeletal microstructures and strontium measurements from the cold‐water coral Lophelia pertusa

Mouchi

Crowley

Jackson

et al. 2014

J Quaternary Science

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Lophelia pertusa is a colonial cold‐water coral species with a wide spatial distribution in recent marine waters. Analysing the chemistry of its skeleton allows reconstruction of environmental parameter variations. While numerous studies have attempted to interpret such analyses, little information is available on the microstructures of Lophelia pertusa and their temporal constraints. This study introduces newly recognized microstructures in the coral wall following growth along the radial axis. The thicknesses of these ‘micro‐layers’ are correlated with strontium concentrations and can be used to estimate seasonal growth rates of single polyps from the colony. We propose that each of these micro‐layers represents a period of 1 month of mineralization and can locate two decreasing periods in growth rate during a year: one caused by limited food availability during winter months and one in autumn linked to gametogenesis. High‐frequency study of strontium concentrations using this interpretation shows a lunar cycle. We demonstrate that while the micro‐layers are present in all L. pertusa specimens from four locations in the Atlantic Ocean and the Mediterranean Sea, growth patterns reveal a complex organization that limits their visibility. Strontium fluctuations, however, appear to be a promising mechanism by which to establish a temporal calibration.

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Skeletal growth, respiration rate and fatty acid composition in the cold-water coral Lophelia pertusa under varying food conditions

Cited by 52 publications

References 66 publications

Opportunistic feeding on various organic food sources by the cold-water coral <i>Lophelia pertusa</i>

Opportunistic feeding on various organic food sources by the cold-water coral <i>Lophelia pertusa</i>

Effects of elevated pCO2 and feeding on net calcification and energy budget of the Mediterranean cold-water coral Madrepora oculata

Potential seasonal calibration for palaeoenvironmental reconstruction using skeletal microstructures and strontium measurements from the cold‐water coral Lophelia pertusa

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Skeletal growth, respiration rate and fatty acid composition in the cold-water coral Lophelia pertusa under varying food conditions

Cited by 52 publications

References 66 publications

Opportunistic feeding on various organic food sources by the cold-water coral &lt;i&gt;Lophelia pertusa&lt;/i&gt;

Opportunistic feeding on various organic food sources by the cold-water coral &lt;i&gt;Lophelia pertusa&lt;/i&gt;

Effects of elevated pCO2 and feeding on net calcification and energy budget of the Mediterranean cold-water coral Madrepora oculata

Potential seasonal calibration for palaeoenvironmental reconstruction using skeletal microstructures and strontium measurements from the cold‐water coral Lophelia pertusa

Contact Info

Product

Resources

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Opportunistic feeding on various organic food sources by the cold-water coral <i>Lophelia pertusa</i>

Opportunistic feeding on various organic food sources by the cold-water coral <i>Lophelia pertusa</i>