Recognize fish as food in policy discourse and development funding

The international development community is off-track from meeting targets for alleviating global malnutrition. Meanwhile, there is growing consensus across scientific disciplines that fish plays a crucial role in food and nutrition security. However, this 'fish as food' perspective has yet to translate into policy and development funding priorities. We argue that the traditional framing of fish as a natural resource emphasizes economic development and biodiversity conservation objectives, whereas situating fish within a food systems perspective can lead to innovative policies and investments that promote nutrition-sensitive and socially equitable capture fisheries and aquaculture. This paper highlights four pillars of research needs and policy directions toward this end. Ultimately, recognizing and working to enhance the role of fish in alleviating hunger and malnutrition can provide an additional long-term development incentive, beyond revenue generation and biodiversity conservation, for governments, international development organizations, and society more broadly to invest in the sustainability of capture fisheries and aquaculture.

Harmful or harmless: Biological effects of marennine on marine organisms

Marennine is a water-soluble blue-green pigment produced by the marine diatom Haslea ostrearia. The diatom and its pigment are well known from oyster farming areas as the source of the greening of oyster gills, a natural process increasing their market value in Western France. Blooms of blue Haslea are also present outside oyster ponds and hence marine organisms can be exposed, periodically and locally, to significant amounts of marennine in natural environments. Due to its demonstrated antibacterial activities against marine pathogenic bacteria (e.g. Vibrio) and possible prophylactic effects toward bivalve larvae, marennine is of special interest for the aquaculture industry, especially bivalve hatcheries. The present study aimed to provide new insights into the effects of marennine on a large spectrum of marine organisms belonging to different phyla, including species of aquaculture interest and organisms frequently employed in standardised ecotoxicological assays. Different active solutions containing marennine were tested: partially purified Extracellular Marennine (EMn), and concentrated solutions of marennine present in H. ostrearia culture supernatant; the Blue Water (BW) and a new process called Concentrated Supernatant (CS). Biological effects were meanwhile demonstrated in invertebrate species for the three marennine-based solutions at the highest concentrations tested (e.g., decrease of fertilization success, delay of embryonic developmental stages or larval mortality). Exposure to low concentrations did not impact larval survival or development and even tended to enhance larval physiological state. Furthermore, no effects of marennine were observed on the fish gill cell line tested. Marennine could be viewed as a Jekyll and Hyde molecule, which possibly affects the earliest stages of development of some organisms but with no direct impacts on adults. Our results emphasize the need to determine dosages that optimize beneficial effects and critical concentrations not to be exceeded before considering the use of marennine in bivalve or fish hatcheries.

Ectyoplasia ferox, an experimentally tractable model for vertical microbial transmission in marine sponges

The oviparous sponge Ectyoplasia ferox is commonly found in Florida and the Bahamas. Every year in August and/or September about 6 days after a full moon, E. ferox will shed embryo-containing spawning material into the seawater from which hundreds to thousands of larvae will hatch per host individual. In order to investigate vertical microbial transmission in E. ferox, 16S rRNA gene library construction and denaturing gradient gel electrophoresis was employed. Microbial symbionts from six phyla and the unknown lineage SAUL were shown to be vertically transmitted. The identification of 21 VT clusters, of which 19 were situated within sponge-specific or sponge-coral-specific clusters, indicated that a large fraction of the symbiotic microbial consortium was present in the sexual reproductive stages. Spawning led to a 50 % reduction of microbial numbers in the adult sponge mesohyl. We furthermore provide the first evidence that the symbiotic microbial consortia of E. ferox were generally metabolically active within the reproductive stages. Finally, we propose E. ferox as a model system for vertical transmission owing to the ease of experimental access to all sexual reproductive stages, and to experimental tractability in the laboratory including the possibility of rearing symbiont-free juvenile sponges.

Assessing the complex sponge microbiota: core, variable and species-specific bacterial communities in marine sponges

Marine sponges are well known for their associations with highly diverse, yet very specific and often highly similar microbiota. The aim of this study was to identify potential bacterial sub-populations in relation to sponge phylogeny and sampling sites and to define the core bacterial community. 16S ribosomal RNA gene amplicon pyrosequencing was applied to 32 sponge species from eight locations around the world's oceans, thereby generating 2567 operational taxonomic units (OTUs at the 97% sequence similarity level) in total and up to 364 different OTUs per sponge species. The taxonomic richness detected in this study comprised 25 bacterial phyla with Proteobacteria, Chloroflexi and Poribacteria being most diverse in sponges. Among these phyla were nine candidate phyla, six of them found for the first time in sponges. Similarity comparison of bacterial communities revealed no correlation with host phylogeny but a tropical sub-population in that tropical sponges have more similar bacterial communities to each other than to subtropical sponges. A minimal core bacterial community consisting of very few OTUs (97%, 95% and 90%) was found. These microbes have a global distribution and are probably acquired via environmental transmission. In contrast, a large species-specific bacterial community was detected, which is represented by OTUs present in only a single sponge species. The species-specific bacterial community is probably mainly vertically transmitted. It is proposed that different sponges contain different bacterial species, however, these bacteria are still closely related to each other explaining the observed similarity of bacterial communities in sponges in this and previous studies. This global analysis represents the most comprehensive study of bacterial symbionts in sponges to date and provides novel insights into the complex structure of these unique associations.

Do associated microbial abundances impact marine demosponge pumping rates and tissue densities?

The evolution of marine demosponges has led to two basic life strategies: one involving close associations with large and diverse communities of microorganisms, termed high microbial abundance (HMA) species, and one that is essentially devoid of associated microorganisms, termed low microbial abundance (LMA) species. This dichotomy has previously been suggested to correlate with morphological differences, with HMA species having a denser mesohyl and a more complex aquiferous systems composed of longer and narrower water canals that should necessitate slower seawater filtration rates. We measured mesohyl density for a variety of HMA and LMA sponges in the Florida Keys, and seawater pumping rates for a select group of these sponges using an in situ dye technique. HMA sponges were substantially denser than LMA species, and had per unit volume pumping rates 52-94% slower than the LMA sponges. These density and pumping rate differences suggest that evolutionary differences between HMA and LMA species may have resulted in profound morphological and physiological differences between the two groups. The LMA sponge body plan moves large quantities of water through their porous tissues allowing them to rapidly acquire the small particulate organic matter (POM) that supplies the majority of their nutritional needs. In contrast, the HMA sponge body plan is suited to host large and tightly packed communities of microorganisms and has an aquiferous system that increases contact time between seawater and the sponge/microbial consortium that feeds on POM, dissolved organic matter and the raw inorganic materials for chemolithotrophic sponge symbionts. The two evolutionary patterns represent different, but equally successful patterns and illustrate how associated microorganisms can potentially have substantial effects on host evolution.

Vertical transmission of a phylogenetically complex microbial consortium in the viviparous sponge Ircinia felix

Many marine demosponges contain large amounts of phylogenetically complex yet highly sponge-specific microbial consortia within the mesohyl matrix, but little is known about how these microorganisms are acquired by their hosts. Settlement experiments were performed with the viviparous Caribbean demosponge Ircinia felix to investigate the role of larvae in the vertical transmission of the sponge-associated microbial community. Inspections by electron microscopy revealed large amounts of morphologically diverse microorganisms in the center of I. felix larvae, while the outer rim appeared to be devoid of microorganisms. In juveniles, microorganisms were found between densely packed sponge cells. Denaturing gradient gel electrophoresis (DGGE) was performed to compare the bacterial community profiles of adults, larvae, and juvenile sponges. Adults and larvae were highly similar in DGGE band numbers and banding patterns. Larvae released by the same adult individual contained highly similar DGGE banding patterns, whereas larvae released by different adult individuals showed slightly different DGGE banding patterns. Over 200 bands were excised, sequenced, and phylogenetically analyzed. The bacterial diversity of adult I. felix and its larvae was comparably high, while juveniles showed reduced diversity. In total, 13 vertically transmitted sequence clusters, hereafter termed "IF clusters," that contained sequences from both the adult sponge and offspring (larvae and/or juveniles) were found. The IF clusters belonged to at least four different eubacterial phyla and one possibly novel eubacterial lineage. In summary, it could be shown that in I. felix, vertical transmission of microorganisms through the larvae is an important mechanism for the establishment of the sponge-microbe association.

Isolation of two polyketide synthase gene fragments from the uncultured microbial symbiont of the marine bryozoan Bugula neritina

"Candidatus Endobugula sertula," the uncultured microbial symbiont of the bryozoan Bugula neritina, produces ecologically and biomedically important polyketide metabolites called bryostatins. We isolated two gene fragments from B. neritina larvae that have high levels of similarity to polyketide synthase genes. These gene fragments are clearly associated with the symbiont and not with the host.

Episymbiotic microbes as food and defence for marine isopods: unique symbioses in a hostile environment

Symbioses profoundly affect the diversity of life, often through novel biochemical services that symbionts provide to their hosts. These biochemical services are typically nutritional enhancements and less commonly defensive, but rarely both simultaneously. On the coral reefs of Papua New Guinea, we discovered unique associations between marine isopod crustaceans (Santia spp.) and episymbiotic microbes. Transmission electron microscopy and pigment analyses show that episymbiont biomass is dominated by large (20-30 microm) cyanobacterial cells. The isopods consume these photosymbionts and "cultivate" them by inhabiting exposed sunlit substrates, a behaviour made possible by symbionts' production of a chemical defence that is repulsive to fishes. Molecular phylogenetic analyses demonstrated that the symbiotic microbial communities are diverse and probably dominated in terms of population size by bacteria and small unicellular Synechococcus-type cyanobacteria. Although largely unknown in the oceans, defensive symbioses probably promote marine biodiversity by allowing niche expansions into otherwise hostile environments.

Structure of bryostatin 20: a symbiont-produced chemical defense for larvae of the host bryozoan, Bugula neritina

Larvae of the marine bryozoan Bugula neritina are defended against potential predators by high concentrations of bryostatins, which are produced by a bacterial symbiont of the bryozoan. From the larvae of B. neritina, three bryostatins, bryostatin 10 (1), the novel bryostatin 20 (2), and an as yet uncharacterized bryostatin, were isolated that were unpalatable to fish. These deterrent bryostatins represent the first example from the marine environment of a microbial symbiont producing an antipredator defense for its host. The structure of bryostatin 20 (2) was determined by spectral comparison with previously described bryostatins.

Potent cytotoxins produced by a microbial symbiont protect host larvae from predation

Larvae of the sessile marine invertebrate Bugula neritina (Bryozoa) are protected by an effective chemical defense. From the larvae, we isolated three bryostatin-class macrocyclic polyketides, including the novel bryostatin 20, that deterred feeding by a common planktivorous fish that co-occurs with B. neritina. A unique bacterial symbiont of B. neritina, Endobugula sertula, was hypothesized as the putative source of the bryostatins. We show that: (1) bryostatins are concentrated in B. neritina larvae and protect them against predation by fish; (2) the adults are not defended by bryostatins; and (3) E. sertula produces bryostatins. This study represents the first example from the marine environment of a microbial symbiont producing an anti-predator defense for its host and, in this case, specifically for the host's larval stage, which is exceptionally vulnerable to predators.

Intraspecific variation in palatability and defensive chemistry of brown seaweeds: effects on herbivore fitness

When offered a choice between brown seaweeds (Phaeophyta) from shallow inshore populations versus deeper offshore populations along the mid-Atlantic coast of the United States of America, the herbivorous amphipod Ampithoe longimana consistently preferred plants from the inshore populations. This was the case for three species (Dictyota menstrualis, Spatoglossum schroederi, and Sargassum filipendula) collected from each of a single inshore and offshore site, and for one species (D. menstrualis) collected from each of three inshore and three offshore sites. Bioassay-guided fractionation of chemical crude extracts from D. menstrualis suggested that the relative unpalatability of the offshore plants was due to the lipid-soluble secondary metabolites 4beta-hydroxydictyodial A and 18, O-dihydro-4beta-hydroxydictyodial A 18-acetate, along with minor compounds that were not fully identified. The inshore-offshore pattern did not appear to result from induction of defenses due to herbivory by mesograzers, as mesograzer densities were higher on the more palatable inshore plants. Herbivore feeding preferences for inshore versus offshore seaweeds matched the effects of those seaweeds on their fitness. When juvenile amphipods were raised on inshore versus offshore tissues of D. menstrualis, amphipod survivorship, growth, and ovulation were significantly suppressed on the offshore compared to the inshore tissues. Few previous investigations have studied intraspecific variance in seaweed palatability. We extend these by showing that between-population differences in palatability can persist for several years and by demonstrating that this variance is chemically based and has dramatic effects on herbivore fitness.

Helpful habitant or pernicious passenger: interactions between an infaunal bivalve, an epifaunal hydroid and three potential predators

The importance of positive interspecific interactions within physically stressful habitats has received increased attention from community ecologists. The exposed sandy beach is an example of a physically rigorous environment where biological interactions have long been considered insignificant. We examined the interaction between the infaunal clam, Donax variabilis, and the hydroid, Lovenella gracilis, on exposed sandy beaches in North Carolina. Epibiotic occupation of Donax by hydroids has been repeatedly observed on ocean beaches but rarely investigated. By providing a stable substrate for attachment, the clam facilitates the persistence of the hydroid in the intertidal beach; however, benefits or costs experienced by the host as a result of this association are unknown. By exposing clams with and without hydroid colonies to multiple types of clam predators, we tested the effectiveness of the hydroid, which possesses stinging nematocysts, in defending its host. The hydroid defended the clam against one common predator, the Florida pompano ( Trachinotus carolinus). Against speckled crabs ( Arenaeus cribrarius) and ghost crabs ( Ocypode quadrata), however, the hydroid offered no protection for its host and instead facilitated predation. The epibiotic hydroid, which projects above the surface of the sand, allowed the crabs to more readily detect clams below the surface. In the field, we evaluated the effect of the hydroid on the tidally synchronized migrations and burrowing speed of the clam. The hydroid, which can form large colonies on the posterior end of the clam, had no effect on Donax burrowing speed, but did reduce the speed of transport of clams by wave swash. Depending on relative predation pressure, the occupation of D. variabilis by L. gracilis can alternately be characterized as beneficial or detrimental to the host.

Chemical defense of early life stages of benthic marine invertebrates

Accurate knowledge of factors affecting the survival of early life stages of marine invertebrates is critically important for understanding their population dynamics and the evolution of their diverse reproductive and life-history characteristics. Chemical defense is an important determinant of survival for adult stages of many sessile benthic invertebrates, yet relatively little consideration has been given to chemical defenses at the early life stages. This review examines the taxonomic breadth of early life-stage chemical defense in relation to various life-history and reproductive characteristics, as well as possible constraints on the expression of chemical defense at certain life stages. Data on the localization of defensive secondary metabolites in larvae and the fitness-related consequences of consuming even a small amount of toxic secondary metabolites underpin proposals regarding the potential for Müllerian and Batesian mimicry to occur among marine larvae. The involvement of microbial symbionts in the chemical defense of early life stages illustrates its complexity for some species. As our knowledge of chemical defenses in early life stages grows, we will be able to more rigorously examine connections among phylogeny, chemical defenses, and the evolution of reproductive and life-history characteristics among marine invertebrates.

Tridentatols D-H, nematocyst metabolites and precursors of the activated chemical defense in the marine hydroid Tridentata marginata (Kirchenpauer 1864)

The marine hydroid Tridentata marginata (Kirchenpauer 1864) produces tridentatols A-C (1-3), of which 1 is a potent deterrent to fish predation. This paper reports the structures of five additional secondary metabolites, tridentatols D-H (4-8), that have been isolated from this hydroid. When hydroid tissue is crushed, as attacking predators would do, tridentatols E-H (5-8), which do not deter fish feeding, are rapidly converted to tridentatols A-D (1-4), thereby repelling potential predators. Additionally, the tridentatols were isolated from this hydroid's nematocysts (i.e., stinging organelles), representing the first report of a nonprotein venom produced by cnidarian nematocysts. The structures of 4-8 were determined by interpretation of their spectral data.

Copper-nuclease efficiency correlates with cytotoxicity for the 4-methoxypyrrolic natural products

The DNA-targeting activities of the 4-methoxypyrrolic natural products, that include prodigiosin (1), tambjamine E (2), and the blue pigment (3), have been compared using fluorescence spectroscopy to study DNA binding and agarose gel electrophoresis to assess their ability to facilitate oxidative copper-promoted DNA cleavage. Fluorescence emission titration of 3 with calf-thymus DNA (CT-DNA) shows that the natural product occupies a site size (n) of ca. two base pairs and possesses an affinity constant (K) of approximately 6x10(5) x M(-1). Similar to prodigiosin (1), the blue pigment 3 was found to facilitate oxidative double-strand DNA (dsDNA) cleavage without the aid of an external reducing agent. Quantitation of ds- (n2) and ss- (n1) breaks provided n1:n2 ratios of approximately 8-12, which were significantly greater than the number expected from the accumulation of ss-breaks (approximately 120). This was contrasted by the nicking activity of tambjamine E (2), which only generates ss-breaks in the presence of copper. The superior copper-nuclease activity of 1 and 3 also correlated with their superior anticancer properties against leukemia (HL-60) cells. These results are discussed with respect to the mode of cytotoxicity by the 4-methoxypyrrolic natural products.

Corydendramines A and B, defensive natural products of the marine hydroid Corydendrium parasiticum

Two novel piperidinol metabolites, corydendramines A (1) and B (2), have been isolated from the marine hydroid Corydendrium parasiticum. The structures of these compounds, which deter feeding by a potential hydroid predator, were determined by interpretation of their spectral data.

Two antifeedant lignans from the freshwater macrophyte Saururus cernuus

Two diarylbutane derivatives of dihydroguaiaretic acid have been isolated from emergent portions of the southeastern United States freshwater angiosperm Saururus cernuus L. (Saururaceae). Bioassay-guided fractionation of organic extracts of S. cernuus led to the compounds, sauriols A and B, in addition to five previously known lignoids. These metabolites deter feeding by the omnivorous crayfish Procambarus clarkii. The two lignans were identified by analysis of nuclear magnetic resonance and mass spectral data, and by comparison with spectral data of dihydroguaiaretic acid.

Potent antioxidant activity of a dithiocarbamate-related compound from a marine hydroid

Recently, we discovered a novel class of natural products, named the tridentatols, in a marine hydroid. Close examination of their molecular structures suggested that they may have antioxidant activity. This observation prompted us to evaluate in vitro the capacity of one of these tridentatols, viz. tridentatol A, to inhibit lipid peroxidation using human low density lipoprotein (LDL) as an experimental model. LDL was incubated with 5 microM cupric chloride (Cu2+) in the absence and presence of tridentatol A or a reference antioxidant standard, i.e. vitamin E. The onset of rapid formation of conjugated lipid hydroperoxides was delayed in a concentration-dependent manner by tridentatol A. More specifically, LDL incubated with Cu2+ had a lag-phase time (the elapsed time before the onset of rapid formation of conjugated lipid hydroperoxides) of 150 min. However, when 0.5 microM tridentatol A was present during incubation, the lag phase time was extended to 225 min. With 1 microM tridentatol A, the lag phase time was 300 min. The same concentrations of vitamin E produced noticeably lower lag phase times. Thus, compared with vitamin E, tridentatol A better protected against the formation of conjugated lipid hydroperoxides in LDL. Direct colorimetric measurements of both lipid hydroperoxides and thiobarbituric acid-reactive substances confirmed the greater potency of tridentatol A relative to vitamin E. Furthermore, tridentatol A negated the Cu2+-induced increase in electrophoretic mobility of LDL to a greater extent than vitamin E. In conclusion, tridentatol A is a powerful antioxidant against lipid peroxidation of LDL and is significantly more potent than vitamin E in this regard.

A phenolic antioxidant from the freshwater orchid, Habenaria repens

Recently, an unusual compound named habenariol was isolated from the freshwater orchid, Habenaria repens. Its phenolic structure suggested that habenariol should have substantial antioxidant activity. This possibility was investigated by evaluating the capacity of habenariol to inhibit copper-induced lipid peroxidation of human low density lipoprotein (LDL), a popular experimental model. LDL was incubated with 5 microM cupric chloride in the presence and absence of habenariol or a positive control, viz., alpha-tocopherol. Both kinetic and end-point spectrophotometric assays were used to determine extent of lipid peroxidation of LDL. In the kinetic assay, the time elapsing before the onset of rapid formation of conjugated lipid hydroperoxides in LDL (marked by a sharp increase in UV absorbance) was prolonged by habenariol, indicative of an antioxidant effect. In the end-point assay, direct colorimetric measurement confirmed habenariol's ability to inhibit formation of lipid hydroperoxides. However, in both assays, habenariol was less potent than alpha-tocopherol in inhibiting lipid peroxidation of LDL.

Chronic stimulation of the left vagal nerve in children: effect on swallowing

PURPOSE

To learn whether stimulation of the left vagal nerve would influence swallowing.

METHODS

Eight children receiving intermittent left vagal nerve stimulation (VNS) for their pharmacoresistant epilepsy underwent barium swallow studies with their generators off, on, and at maximally tolerated settings.

RESULTS

Laryngeal penetration of barium was present in three patients without stimulation, and was caused by VNS in one other patient. Aspiration never occurred.

CONCLUSIONS

Stimulation of the left vagal nerve under conditions used to treat epilepsy does not cause aspiration.

Alternatamides A-D: new bromotryptamine peptide antibiotics from the Atlantic marine bryozoan Amathia alternata

Four new bromotryptamine peptides, alternatamides A-D (1-4), have been isolated from the Atlantic bryozoan Amathia alternata. The structures of the alternatamides were assigned primarily on the basis of 2D NMR data. The absolute stereochemistry of the N-methylleucine amino acid was shown to be L (2'S) by hydrolysis and comparison with standards. The alternatamides show modest antibacterial activities against several Gram-positive bacteria.