Lipid, sterols and fatty acid composition of abyssal holothurians and ophiuroids from the North-East Pacific Ocean: Food web implications

Drazen, Jeffrey C.; Phleger, Charles F.; Guest, Michaela Anne; Nichols, Peter D.

doi:10.1016/j.cbpb.2008.05.013

Cited by 98 publications

(119 citation statements)

References 55 publications

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“…The FA 23:1 is rarely reported in marine systems, but was also identified in the SIMPER analysis as being particularly abundant and important for driving depth differences in Psolus. Although the exact source of this relatively novel FA is unknown, it has also been identified in abyssal holothurians (Drazen et al 2008).…”

Section: Discussionmentioning

confidence: 99%

Fatty acid and stable isotope biomarkers suggest microbe‐induced differences in benthic food webs between depths

Galloway

Lowe²,

Sosik

et al. 2013

Limnology & Oceanography

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Benthic marine consumers inhabiting the subphotic zone rely on subsidies of energy synthesized by macrophytes and phytoplankton in the photic zone. The effects of this energy subsidy on the trophic ecology of deep invertebrates are generally unknown. We used fatty acids (FA) and multiple stable isotopes (MSI) as trophic biomarkers to compare tissues from conspecifics of primary and secondary consumers in photic and subphotic habitats (15 and 100 m depth) at three sites in the San Juan Archipelago, Washington. FA composition differed across depths for all five species and MSI differed across depths for six of seven species. We found a general pattern of enrichment in d 13 C from shallow to deep for all consumers. d 15 N was consistently enriched in deep herbivores and suspension feeders, but did not differ in predators. Total v-3 FA were lower in deep primary consumers, whereas predator v-3 FA did not differ between depths. Total bacterial marker FA were lower in deep suspension feeders but higher in deep predators. The results suggest a possible mechanism for the differences in FA and enrichment between habitats: deep consumers potentially ingest detritus that has been biochemically altered by microbes during transport. We found support for this hypothetical mechanism in an algal aging experiment. Aged algae colonized by microbes responded with increases in bacterial FA, and decreases in v-3 FA. This study highlights the power of combining FA and MSI biomarkers, and provides evidence for the importance of organic matter degradation to food web studies.

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Section: Discussionmentioning

confidence: 99%

Fatty acid and stable isotope biomarkers suggest microbe‐induced differences in benthic food webs between depths

Galloway

Lowe²,

Sosik

et al. 2013

Limnology & Oceanography

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show abstract

“…En lo que tiene que ver con el tipo de compuestos lipídicos, se encontró prevalencia de los ácidos grasos monoinsaturados AGMI (50%) sobre los ácidos grasos saturados AGS (37%) en la composición de ácidos grasos totales, mientras que el contenido de ácidos grasos poliinsaturados AGPI fue solo del 13% el cual resulta ser un porcentaje bajo ya que los valores de AGPI para equinoideos se encuentran entre 30 y 40% (Martínez-Pita et al 2010), debido a que estos organismos tiene como principal fuente de alimentación las algas y el fitoplancton que son grandes productores de AGPI (Drazen et al 2008, Guzmán et al 2012. Este comportamiento en el contenido de AGPI en M. quinquiesperforata sugiere que este organismo modifica estructuralmente los ácidos grasos que adquiere en la dieta, convirtiendo los AGPI en AGMI y AGS, esto sugerido también por el alto contenido de AGMI, los cuales están asociados con funciones de mantenimiento de la fluidez de la membrana en especies de aguas profundas, las cuales deben soportar bajas temperaturas y altas presiones (Drazen et al 2008).…”

Section: Discussionunclassified

“…Este comportamiento en el contenido de AGPI en M. quinquiesperforata sugiere que este organismo modifica estructuralmente los ácidos grasos que adquiere en la dieta, convirtiendo los AGPI en AGMI y AGS, esto sugerido también por el alto contenido de AGMI, los cuales están asociados con funciones de mantenimiento de la fluidez de la membrana en especies de aguas profundas, las cuales deben soportar bajas temperaturas y altas presiones (Drazen et al 2008). Si bien M. quinquiesperforata, al igual que todos los clipasteroideos, es una especie de aguas someras (Pereira 2011), es probable que el alto contenido de AGMI presente en ella también cumpla la función antes descrita, lo que podría sugerir baja fluidez de la membrana, teniendo en cuenta que los clipasteroideos solo puedan habitar en aguas de poca profundidad.…”

Section: Discussionunclassified

“…Los organismos pueden tener una única composición de esteroles y ácidos grasos, estos perfiles pueden ser trazables, y muchos de los compuestos son transferidos de la presa al depredador sin modificación (Drazen et al 2008). Por ejemplo, se conoce que la mayoría de los animales no pueden sintetizar ácidos grasos poliinsaturados de cadena larga tal como los ácidos eicosapentaenoico (20:5ω3), araquidónico (20:4ω6) y docosahexaenoico (22:6ω3) (Saito y Aono 2014), sin embargo, se ha logrado establecer en muchos equinodermos altos contenidos de este tipo de compuestos.…”

Section: Introductionunclassified

“…Por ejemplo, se conoce que la mayoría de los animales no pueden sintetizar ácidos grasos poliinsaturados de cadena larga tal como los ácidos eicosapentaenoico (20:5ω3), araquidónico (20:4ω6) y docosahexaenoico (22:6ω3) (Saito y Aono 2014), sin embargo, se ha logrado establecer en muchos equinodermos altos contenidos de este tipo de compuestos. Estos compuestos son comúnmente producidos por algas, fitoplancton y algunas bacterias, y son transferidos a estos organismos a través de la red alimenticia, por lo tanto, altos niveles de estos ácidos grasos son indicativos de organismos primordialmente herbívoros (Drazen et al 2008, Guzmán et al 2012). …”

Section: Introductionunclassified

See 2 more Smart Citations

Actividad antioxidante del erizo de mar Mellita quinquiesperforata (Leske) e identificación de sus compuestos lipídicos mayoritarios

2016

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Metabolic fate of docosahexaenoic acid (DHA; 22:6n‐3) in human cells: direct retroconversion of DHA to eicosapentaenoic acid (20:5n‐3) dominates over elongation to tetracosahexaenoic acid (24:6n‐3)

et al. 2016

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Docosahexaenoic acid (22:6n-3) supplementation in humans causes eicosapentaenoic acid (20:5n-3) levels to rise in plasma, but not in neural tissue where 22:6n-3 is the major omega-3 in phospholipids. We determined whether neuronal cells (Y79 and SK-N-SH) metabolize 22:6n-3 differently from non-neuronal cells (MCF7 and HepG2). We observed that 13C-labeled 22:6n-3 was primarily esterified into cell lipids. We also observed that retroconversion of 22:6n-3 to 20:5n-3 was 5- to 6-fold greater in non-neural compared to neural cells and that retroconversion predominated over elongation to tetracosahexaenoic acid (24:6n-3) by 2- to 5-fold. The putative metabolic intermediates, 13C-labeled 22:5n-3 and 13C-labeled 24:5n-3, were not detected in our assays. Analysis of the expression of enzymes involved in fatty acid beta-oxidation revealed that MCF7 cells abundantly expressed the mitochondrial enzymes CPT1A, ECI1, and DECR1, whereas the peroxisomal enzyme ACOX1 was abundant in HepG2 cells, thus suggesting that the initial site of 22:6n-3 oxidation depends on the cell type. Our data reveal that non-neural cells more actively metabolize 22:6n-3 to 20:5n-3 via channeled retroconversion, while neural cells retain 22:6n-3.

show abstract

Lipid, sterols and fatty acid composition of abyssal holothurians and ophiuroids from the North-East Pacific Ocean: Food web implications

Cited by 98 publications

References 55 publications

Fatty acid and stable isotope biomarkers suggest microbe‐induced differences in benthic food webs between depths

Fatty acid and stable isotope biomarkers suggest microbe‐induced differences in benthic food webs between depths

Actividad antioxidante del erizo de mar Mellita quinquiesperforata (Leske) e identificación de sus compuestos lipídicos mayoritarios

Metabolic fate of docosahexaenoic acid (DHA; 22:6n‐3) in human cells: direct retroconversion of DHA to eicosapentaenoic acid (20:5n‐3) dominates over elongation to tetracosahexaenoic acid (24:6n‐3)

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