Effect of dissolved domoic acid on the grazing rate of krill Euphasia pacifica

Bargu, Sibel; Lefebvre, Kathi A.; Silver, Mary W.

doi:10.3354/meps312169

Cited by 41 publications

(21 citation statements)

References 38 publications

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“…Similarly, Ginsburg and Paul (2001) showed that A. parvula preferentially feeds on seaweeds that contain secondary metabolites at relatively low concentrations, but is deterred by high concentrations of these same compounds (Ginsburg and Paul 2001). In fact, chemical defenses of marine algae are often concentration dependent, with feeding deterrence occurring above a certain threshold value (Steinberg 1988, Bargu et al 2006). In the multiple-choice feeding assay with the female gametophyte, A. parvula preferred the more nutritious lateral branches to the main axis or the reproductive cystocarps.…”

Section: Discussionmentioning

confidence: 99%

Sex and Life‐history Stage Alter Herbivore Responses to a Chemically Defended Red Alga

Vergés

Paul

Steinberg

2008

Ecology

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Intraspecific variation in resistance to herbivory among genders and life-history phases of primary producers can significantly alter the ecological and evolutionary consequences of plant-herbivore interactions. Seaweeds (macroalgae) with complex life histories have multiple distinct phases with associated variation in traits that can potentially lead to differences in resistance to consumers and provide a unique system in which to simultaneously test the effects of sex and life-history stage on herbivory. We tested the susceptibility to grazing of the three life-history stages and separate sexes of the chemically defended red alga Asparagopsis armata against the sea hare Aplysia parvula, and we related this to the plant quality traits of different stages and genders. Differences in nutrient content and halogenated secondary metabolites between life-history phases were highly sex dependent. Male gametophytes had a low concentration of secondary metabolites and the highest nutrient content. The highest secondary metabolite content was found within the female gametophyte, in the wall of the reproductive structures (cystocarps) that contain the microscopic carposporophyte phase. Feeding choices by A. parvula were consistent with differences in algal quality and defense and resulted in the haploid male gametophytes being the most preferred food type. The diploid carposporophyte found inside the chemically rich cystocarps was the least consumed life-history stage. Selective herbivory of male gametophytes by A. parvula is consistent with an observed shift in gametophyte sex ratio in the field from unity at the beginning of the reproductive season to female bias at the end. The variation in susceptibility to herbivory found between sex and life-history stages of A. armata represents the first example of sex-biased consumption in seaweeds and may contribute to the maintenance of complex life histories such as those found in red algae.

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Section: Discussionmentioning

confidence: 99%

Sex and Life‐history Stage Alter Herbivore Responses to a Chemically Defended Red Alga

Vergés

Paul

Steinberg

2008

Ecology

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“…Consumption of mollusks and fish contaminated with domoic acid has caused deaths and neurological damage in humans (6, 7), seabirds (10), and marine mammals (11). Dissolved domoic acid can affect marine microbial ecology by ligating micronutrients [e.g., iron (12)] and suppressing grazing by krill (13) and copepods (14). Although biological degradation in the water column has not been reported, both direct (15) and indirect (16) photodegradation contribute to domoic acid loss in seawater.…”

Section: Dom* Anmentioning

confidence: 99%

Halogen radicals contribute to photooxidation in coastal and estuarine waters

Parker

Mitch

2016

Proc. Natl. Acad. Sci. U.S.A.

207

220

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Although halogen radicals are recognized to form as products of hydroxyl radical (• OH) scavenging by halides, their contribution to the phototransformation of marine organic compounds has received little attention. We demonstrate that, relative to freshwater conditions, seawater halides can increase photodegradation rates of domoic acid, a marine algal toxin, and dimethyl sulfide, a volatile precursor to cloud condensation nuclei, up to fivefold. Using synthetic seawater solutions, we show that the increased photodegradation is specific to dissolved organic matter (DOM) and halides, rather than other seawater salt constituents (e.g., carbonates) or photoactive species (e.g., iron and nitrate). Experiments in synthetic and natural coastal and estuarine water samples demonstrate that the halide-specific increase in photodegradation could be attributed to photochemically generated halogen radicals rather than other photoproduced reactive intermediates [e. OH-independent pathway. Our results indicate that halogen radicals significantly contribute to the phototransformation of algal products in coastal or estuarine surface waters.halogen radicals | photochemistry | domoic acid | dimethyl sulfide | dissolved organic matter R esearch on the photochemical transformation of organic compounds in seawater has focused on freshwater-relevant pathways, including direct photolysis and dissolved organic matter (DOM)-sensitized indirect photodegradation by excited triplet state DOM ( 3 DOM*) or reactive oxygen species [e.g., hydroxyl radical ( • OH)] (1). High halide concentrations, the key characteristic distinguishing seawater from freshwater, are the predominant sink for• OH in seawater, with Br − scavenging ∼93% (Eq. 1) (2), resulting in an ∼40-fold reduction in• OH concentrations.• OH + BrThe role of the resultant Br• , as well as other radical reactive halogen species (RHS) (e.g., Cl ), in seawater photochemistry has received little attention. Here we evaluate the contribution of RHS, a family of photooxidants specific to seawater, to the photodegradation of important marine products for two reasons. Unlike diffusion-limited• OH rate constants, RHS rate constants with organic molecules span orders of magnitude (3), such that conversion of • OH to RHS focuses oxidation on more reactive molecules relative to bulk DOM. Secondly, direct halide oxidation by 3 DOM*, previously demonstrated using model triplet sensitizers (4, 5), may provide a seawater-specific,• OH-independent RHS production pathway that could increase overall radical generation rates.We investigated the importance of RHS for photooxidation of dienes and thioethers. Dienes occur in biomolecules (e.g., fatty acids) and in the marine algal toxin (6, 7), domoic acid (Fig. 1A, ii), where the diene contributes to toxicity (8). During summer 2015, a large bloom of the marine diatom Pseudo-nitzschia, extending from central California to Alaska, led to significant concern regarding the production of domoic acid, a potent neurotoxin (9). Consumption of mollusks and fish...

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“…Effectively, when harmful algal blooms degrade, they release toxins into the dissolved phase (surrounding water). Studies have been carried out to evaluate toxin accumulation or effects of dissolved toxins on early stages of development of aquatic organisms (Colman et al, 2005;Korpinen et al, 2006;Lefebvre et al, 2005;Liu et al, 2007) on planktonic species (Babica et al, 2007;Bargu et al, 2006) and on adult fish (Bakke and Horsberg, 2010;Cazenave et al, 2005). However, very little is known about the ability of bivalve molluscs to accumulate dissolved marine biotoxins (Liu et al, 2007;Novaczek et al, 1991;Plakas et al, 2002).…”

Section: Introductionmentioning

confidence: 99%

Dissolved azaspiracids are absorbed and metabolized by blue mussels (Mytilus edulis)

Jauffrais

Kilcoyne

Herrenknecht

et al. 2013

Toxicon

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The relationship between azaspiracid shellfish poisoning and a small dinoflagellate, Azadinium spinosum, has been shown recently. The organism produces AZA1 and -2, while AZA3 and other analogues are metabolic products formed in shellfish. We evaluated whether mussels were capable of accumulating dissolved AZA1 and -2, and compared the toxin profiles of these mussels at 24 h with profiles of those exposed to live or lysed A. spinosum. We also assessed the possibility of preparative production of AZA metabolites by exposing mussels to semipurified AZA1. We exposed mussels to similar concentration of AZAs: dissolved AZA1+2 (crude extract) at . Subsequently, we dissected and analysed digestive glands, gills and remaining flesh. Mussels (whole flesh) accumulated AZAs above the regulatory limit except at the lower levels of dissolved AZAs.The toxin profile of the mussels varied significantly with treatment. The gills contained 42-46%and the digestive glands 23-24% of the total toxin load using dissolved AZAs, compared to 3-12% and 75-90%, respectively, in mussels exposed to live A. spinosum. Exposure of mussels to semi-purified AZA1 produced the metabolites AZA17 (16.5%) and AZA3 (1.7%) after 4 days of exposure, but the conversion efficiency was too low to justify using this procedure for preparative isolation.

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Effect of dissolved domoic acid on the grazing rate of krill Euphasia pacifica

Cited by 41 publications

References 38 publications

Sex and Life‐history Stage Alter Herbivore Responses to a Chemically Defended Red Alga

Sex and Life‐history Stage Alter Herbivore Responses to a Chemically Defended Red Alga

Halogen radicals contribute to photooxidation in coastal and estuarine waters

Dissolved azaspiracids are absorbed and metabolized by blue mussels (Mytilus edulis)

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