Influence of food regimes and seasonality on fatty acid composition in the ragworm

García‐Alonso, Javier; Müller, Carsten T.; Hardege, Joerg D.

doi:10.3354/ab00090

Cited by 47 publications

(57 citation statements)

References 17 publications

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“…The source of the relatively small amount of DHA produced within the system units that accumulated in the lugworm tissues remains problematical. We do not exclude a bacterial origin for this, perhaps from the small number of Shewenella-or Colwellia-like Gammaproteobacteria present in the system (Ashforth 2008).The fatty acid profiles of other polychaetes whose fatty acids have been characterised is consistent with a widespread occurrence of the proposed pathway in the polychaete clade based on evidence reported for Nereis (Hediste) diversicolor (Bradshaw et al 1990, Luis & Passos 1995, Fidalgo e Costa et al 2000, García-Alonso et al 2008, Nereis virens (Olive et al 2002), a number of deep-sea vent worms (Taghon 1988, Pond et al 2002, Phleger et al 2005) and cold-water detritivorous species (Copeman & Parrish 2003), all of which show the occurrence and prominence of C20:2n-6 (the elongation product of C18:2n-6 from which C20:3n-6 is derived) and lack or low concentration of fatty acids associated with the conventional n-6 and n-3 pathways. The presence of long-chain unsaturated fatty acids in deep-sea vent worms has been considered problematic because of the general acceptance that these fatty acids are normally derived from the abundant sources present in the photic zone (for discussion see Pond et al 2002, Phleger et al 2005.…”

supporting

confidence: 61%

“…This provides clear evidence of a dietary independence for many longer chain PUFA which must therefore have been produced within system units. García-Alonso et al (2008) similarly found that the fatty acid profile of the polychaete Nereis diversicolor did not change seasonally and was not noticeably influenced by the fatty acid content of their diets. This implies the existence of mechanisms by which long-chain fatty acids can accumulate in detritivorous polychaete tisses from non-photosynthetic sources.…”

Section: Net Gain Of Specific Fatty Acidsmentioning

confidence: 70%

“…Taghon 1988, Fidalgo e Costa et al 2000, Copeman & Parrish 2003, García-Alonso et al 2008. The origin of the fatty acids in benthonic, easily cultured polychaete worms, such as Nereidae and Arenicolidae, has assumed an economic importance because their fatty acid content, coupled with their high palatability, has lead to their inclusion as a component of aquaculture brood stock diets (Izquierdo et al 2001).…”

Section: Introductionmentioning

confidence: 99%

“…These sources could include bioreactors designed to amplify naturally occurring pathways (Bergé & Barthanan 2005). Polychaetes have become well established as dietary components for shrimp and finfish hatcheries (Izquierdo et al 2001, García-Alonso et al 2008 for recent discussion), which have in turn resulted in the emergence of a polychaete farming sector in Europe and Southeast Asia. Our small-scale mesocosm study demonstrates that the biosynthesis of long-chain fatty 237 Mar Ecol Prog Ser 387: 223-239, 2009 acids occurs in the absence of light in polychaetebioturbated marine sediments to which a fermented yeast substrate has been added, and the amplification of naturally occurring ecosystem components in aquaculture production systems, e.g.…”

mentioning

confidence: 99%

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Net gain of long-chain polyunsaturated fatty acids (PUFA) in a lugworm Arenicola marina bioturbated mesocosm

Olive

Duangchinda²,

Ashforth³

et al. 2009

Mar. Ecol. Prog. Ser.

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A net gain in long-chain polyunsaturated fatty acids (PUFA) occurs in Arenicola marina bioturbated mesocosms in the light and dark when brewery yeast is the only food. Fatty acid profiles were determined by GC-MS and quantified for system units. Bacterial fatty acid biosynthesis is indicated by accumulation of the bacterial fatty acids anteiso 14:0, iso 15:0, iso 16:0, anteiso 16:0, iso 17:0, C16:1n-7 and C18:1n-7 (cis-vaccenic acid). De novo production of longer chain PUFA within the worm tissues is implicated by a chain elongation converting linoleic acid (C18:2n-6) to C20:2n-6 and subsequent desaturation, resulting in a gain of arachidonic acid (C20:4n-6) and eicosapentaenoic acid (C20:5n-3) via the intermediary C20:3n-6. To test for the presence of PUFA-synthesising bacteria in system units, 495 cloned 16S rDNA fragments were compared with the databases and degenerate PCR primers were designed for the ketoacyl acyl carrier protein synthase gene highly conserved in the polyketide synthase region of known PUFA-synthesising Gammaproteobacteria. Gammaproteobacteria related to known PUFA producers were not abundant (<1% of clones) and PCR primers, whose specificity was confirmed by conspecific amplification of DNA product from genomic DNA of Shewenella frigidimarina 12253 T and Colwellia psychrethraea 8813 T , did not amplify product from mesocosm DNA samples. PUFA production is therefore primarily due to processes within the lugworm A. marina. Biosynthesis by invertebrates may be significant in benthic ecosystems and their culture has the potential to contribute to non-fishery sources of essential fatty acids required for aquaculture feeds.KEY WORDS: Fatty acid biosynthesis · Elongase · PUFA · Polychaeta · Marine food web · Arenicola marina · Aquaculture nutrition · Aquaculture feeds Resale or republication not permitted without written consent of the publisherMar Ecol Prog Ser 387: [223][224][225][226][227][228][229][230][231][232][233][234][235][236][237][238][239] 2009 head shaft) lying above the feeding pocket and contribute to the diet, but algae are not utilised effectively (Rijken 1979) and the presence of cellulases has not been conclusively demonstrated (Longbottom 1970, nor since). On the other hand feeding on bacteria associated with enriched sand is considered likely. The short residence time of the ingested sand in the gut (Hüttel 1990, Chen & Mayer 1999 makes it unlikely that internal fermentation (as in ruminants) occurs; rather, the lugworm-bioturbated burrow/sand-substrate system may act as an external rumen in which bacteria are cultivated, ingested and digested -a process of food enhancement referred to as gardening (Plante & Mayer 1994. Feeding at depth on anaerobic sediment is most characteristic of A. defodiens (Cadman & Nelson-Smith 1993) but it is also observed in A. marina when feeding on sediments rich in organic material in nature (Cadée 1976) and in the laboratory (Rijken 1979), and is routinely observed in commercially farmed populations 1 (S. Craig unpubl. data, P. J. W...

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supporting

confidence: 61%

Section: Net Gain Of Specific Fatty Acidsmentioning

confidence: 70%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Net gain of long-chain polyunsaturated fatty acids (PUFA) in a lugworm Arenicola marina bioturbated mesocosm

Olive

Duangchinda²,

Ashforth³

et al. 2009

Mar. Ecol. Prog. Ser.

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“…However, their supplies are still largely dependent on wild populations, so can be affected by overfishing and habitat disturbances (Scaps 2003). Also, their nutritional contents are known to vary according to seasonal and environmental conditions (Garcia-Alonso et al 2008), and their biosecurity status has recently been questioned (Vijayan et al 2005). These factors suggest that alternative feeds or alternative production strategies for suitable polychaete species are needed.…”

Section: à2mentioning

confidence: 99%

Nutritional status of a nereidid polychaete cultured in sand filters of mariculture wastewater

Palmer¹,

Wang²,

Houlihan³

et al. 2014

Aquacult Nutr

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Trophic upgrading of long-chain polyunsaturated fatty acids by polychaetes: a stable isotope approach using Alitta virens

et al. 2021

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Polychaete worms are rich sources of polyunsaturated fatty acids (PUFA) and are increasingly incorporated into aquaculture broodstock diets. Conventionally, the build-up of PUFA in polychaetes was considered passive, with direct accumulation along the food web, originating with microalgae and other primary producers. However, it has been argued that polychaetes (and other multicellular eukaryotes) are capable of PUFA biosynthesis through the elongation and desaturation of precursor lipids. We further test this hypothesis in the ecologically and economically important nereid polychaete Alitta virens by adopting a stable isotope labelling approach. Worms were fed a 13C-1-palmitic acid (C16:0) enriched diet with the resulting isotopically enriched lipid products identified over a 7-day period. The data showed strong evidence of lipid elongation and desaturation, but with a high rate of PUFA turnover. A putative biosynthetic pathway is proposed, terminating with docosahexaenoic acid (DHA) via arachidonic (AA) and eicosapentaenoic acids (EPA) and involving a Δ8 desaturase.

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Influence of food regimes and seasonality on fatty acid composition in the ragworm

Cited by 47 publications

References 17 publications

Net gain of long-chain polyunsaturated fatty acids (PUFA) in a lugworm Arenicola marina bioturbated mesocosm

Net gain of long-chain polyunsaturated fatty acids (PUFA) in a lugworm Arenicola marina bioturbated mesocosm

Nutritional status of a nereidid polychaete cultured in sand filters of mariculture wastewater

Trophic upgrading of long-chain polyunsaturated fatty acids by polychaetes: a stable isotope approach using Alitta virens

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