Plastic reproductive strategies in a clonal marine invertebrate

Plastic reproductive allocation may allow individuals to maximize their fitness when conditions vary. Mate availability is one condition that may determine the fitness of an individual's allocation strategy. Using a variety of methods, I detected evidence of plastic allocation to asexual (clonal) reproduction in response to mate availability in the brittle star Ophiactis savignyi. There were more mature individuals in populations in which both sexes were present, and clones from these populations had fewer clone-mates than clones from single-sex populations. Animals placed with mates in a field experiment divided less frequently than animals without a mate. These findings demonstrate that animals reduce their allocation to asexual reproduction when mates are present and when a loss of fecundity associated with cloning would decrease offspring production. This plasticity is probably adaptive because it maximizes sexual-reproductive potential when fertilization is more likely, but maximizes survival of the clone when mates are absent and gametes are unlikely to be converted to offspring.     

The distribution of male and female reproductive success in a broadcast spawning marine invertebrate

Many studies have addressed sexual selection in animals, butfew data are available on animals that release eggs and sperminto the environment for external fertilization. Although thisreproductive mode represents the ancestral condition and isstill a very common reproductive strategy, it is underrepresentedin empirical studies and theoretical treatments. Here I presentdata on the pattern of reproductive success in male and femalesea urchins. The results suggest that the strength of sexualselection and the differences between the sexes in the intensityof sexual selection depend on mate density. In general, despitethe high degree of multiple paternity, the variance in reproductivesuccess appears to be lower in males and higher in females thanit is in polygamous species with internal fertilization. Theseresults may provide insight into the patterns of effective populationsize in marine invertebrates and also more generally the evolutionarytransition from sexual monomorphism to polymorphism in adulttraits.     

Size-specific predation on marine invertebrate larvae

Predation on planktonic larval stages is frequently a major source of mortality for the offspring of benthic marine invertebrates. Mortality rate likely varies with larval size and developmental stage, but few experiments have measured how these factors affect predation rates. I used experimental reductions in egg size to test how variation in larval size affects the likelihood of predation during planktonic development. Blastomeres of the sand dollar Dendraster excentricus were separated at the two-cell stage to produce half-sized zygotes. Larvae resulting from this manipulation were tested for their susceptibility to predation relative to whole-sized siblings at four ages. Individuals from each size class were simultaneously presented as prey items to five predators (crab zoeae, crab megalopae, chaetognaths, solitary tunicates, and postlarval fish) in the laboratory. Four predators consumed significantly more half-sized larvae than whole-sized larvae, but one predator type (postlarval fish) consumed more whole-sized larvae. Predators that consumed more half-sized larvae also preferentially consumed younger larvae. In contrast, postlarval fish showed no significant prey preference based on larval age. These results suggest that assumptions of constant mortality rates during development should be modified to account for the effects of larval size and age.     

Seasonal patterns of population structure in a colonial marine invertebrate (Bugula stolonifera, Bryozoa)

For sessile invertebrates, the degree to which dispersal mechanisms transport individuals away from their natal grounds can have significant ecological implications. Even though the larvae of the marine bryozoan Bugula stolonifera have limited dispersal potential, high levels of genetic mixing have been found within their conspecific aggregations. In this study, we investigated whether this high mixing within aggregations of B. stolonifera also resulted in high mixing between aggregations. Adult colonies were collected from five sites within and one site outside of Eel Pond, Woods Hole, Massachusetts, in August 2009 and genotyped at 10 microsatellite loci. Significant genotypic differentiation was found between most sites, suggesting limited connectivity across sites, even those separated by only 100 m. This investigation was extended to determine if low levels of genetic mixing throughout the reproductive season could result in increased homogeneity between sites. Four of the five sites in Eel Pond were sampled early, mid-, and late in the reproductive season in 2010, and again in early 2011. Inter- and intra-annual genotypic differentiation was then assessed within and between sites. Results from these analyses document that low levels of mixing could result in increased homogeneity between some aggregations, but that barriers to genetic exchange prevented mixing between most sites. Further, results from inter-annual comparisons within sites suggest that any potential homogeneity achieved throughout the reproductive season will likely be lost by the beginning of the next reproductive season due to the annual cycle of colony die-back and regrowth experienced by B. stolonifera colonies in Eel Pond.     

Diverse sugar-binding specificities of marine invertebrate C-type lectins

The sugar-binding specificities of C-type lectins isolated from marine invertebrates were investigated by frontal affinity chromatography (FAC) using 100 oligosaccharides. The lectins included BRA-2 and BRA-3, multiple lectins from the hemolymph of the acorn barnacle, Megabalanus rosa, and BRL from the acorn barnacle, Balanus rostatus. The diverse sugar-binding specificities of the C-type lectins were determined by FAC analysis. BRA-2 recognized alpha2-6 sialylation but not alpha2-3 sialylation on glycans. On the other hand, BRA-3 showed high affinity for oligosaccharides with alpha-linked non-reducing terminal galactose, but not for sialylated forms, and BRL showed enhanced recognition activity towards Lewis(x) and Lewis(a) epitopes.     

The extraction of glycogen from marine invertebrate tissues

Summary 1. It is shown that the extraction by 5% trichloracetic acid of glycogen from the tissues of some typical marine invertebrates(Balanus balanoides, Nephtys hombergi, Carcinus maenas, Mytilus edulis) is a function of the homogenization procedure.2. In agreement with work on rat tissues, glycogen fractions cannot be differentiated by their solubility in cold 5% trichloracetic acid. Total glycogen only need be determined.

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Die Glykogenextraktion aus dem Gewebe mariner Invertebraten

Kurzfassung Es wird der Nachweis geführt, daß die Glykogenextraktion aus den Geweben einiger mariner Invertebraten(Balanus balanoides, Nephtys hombergi, Carcinus maenas, Mytilus edulis) durch 5% Trichloressigsäure von dem Homogenisierungsverfahren abhängt. In Übereinstimmung mit Untersuchungen an Rattengewebe können die Glykogenfraktionen nicht durch ihre Löslichkeit in kalter 5% Trichloressigsäure unterschieden werden. Daher ist nur die Bestimmung des Gesamt-Glykogengehaltes angebracht.

     

Sulfide permeability in the marine invertebrate Urechis caupo

Summary Hydrogen sulfide can reach toxic concentrations in the burrow-water of the echiuran worm Urechis caupo during low tide. Its two large epithelial surfaces, the thick muscular body wall and the thin-walled hindgut are in constant contact with the environment. Hindgut inflation of up to 2 ml water·g wet weight^-1 causes tissue stretch. To determine if these body surfaces present a barrier to sulfide influx, the total permeability coefficient P_T was measured at different degrees of stretch in diffusion chambers at pH 6.0, 7.0, and 8.0, and specific permeability coefficients P_H2S and P_HS^- were calculated. Both the body wall and the hindgut were more permeable to H₂S than HS^-. The body wall showed no significant increase in sulfide permeability with natural degrees of stretch, and the mean P_H2S and P_HS^- were 0.17 and 0.063 cm·h^-1, respectively. The sulfide permeability of the hindgut was increased by stretch, with the relative permeability of H₂S increasing faster than that of HS^-. Unstretched hindgut mean P_H2S and P_HS^- were 0.095 and 0.11 cm·h^-1, respectively, and stretched hindgut mean P_H2S and P_HS^- were 1.8 and 0.16 cm·h^-1, respectively. A model of sulfide influx in the natural environment indicates that even if the hindgut is kept uninflated, the coelomic fluid of U. caupo would have toxic sulfide concentrations well before the end of a 2-h tidal exposure in the absence of a sulfide elimination mechanism.Abbreviations P permeability coefficient - P_T total permeability coefficient - PD transepithelial potential difference     

Enzymatic hydrogen sulfide production in marine invertebrate tissues

At least some mammalian tissues produce H2S in vitro from L-cysteine at rates sufficient to have physiological effects. To determine whether tissues of macrofaunal invertebrates have the same capacity, we measured H2S production in tissue homogenates of the Manila clam Tapes philippinarum and the lugworm Arenicola marina. Tissue homogenates from both animals produced significant quantities of H2S gas upon addition of L-cysteine and the enzyme cofactor pyridoxal-5PRIME;-phosphate (10 mmol l(-1) and 2 mmol l(-1), respectively), while only tissues from T. philippinarum produced measurable H2S in the absence of added substrate or cofactor. In T. philippinarum tissues, H2S production was completely inhibited by the cystathionine beta-synthase (CBS) inhibitor aminooxyacetic acid (AOAA), suggesting that the majority of H2S production was via CBS pathways, while in A. marina body wall, AOAA inhibited only half of the total H2S production, indicating that the CBS pathway was not the only major source of H2S production. H2S production in tissues of T. philippinarum but not A. marina was doubled by the addition of a second thiol substrate (2.5 mmol l(-1) 2-mercaptoethanol), suggesting the presence of an 'activated serine sulfhydrase pathway', which had previously been demonstrated only in some microfauna.     

Field preservation of marine invertebrate tissue for DNA analyses

Successful preservation of tissue samples is a prerequisite for long field studies in remote areas. However, there is little published information concerning field preservation of marine invertebrate tissues for DNA analyses. This omission is significant because marine biodiversity is centered in the Indo-Pacific, where immediate DNA analysis is often impossible. Consequently, we used an assay based on polymerase chain reaction (PCR) to examine the effect of five storage solutions and three temperature regimens on the degradation of DNA from four common classes of marine invertebrates (Anthozoa, Gastropoda, Polychaeta, and Scyphozoa). Control samples were cryopreserved. Storage solution and the type of tissue preserved were the best predictors of preservation success. The length of time in storage and the storage temperature also affected the preservation of DNA. A field test demonstrates that a solution of dimethylsulfoxide and sodium chloride (DMSO-NaCl) preserves a wide range of tissues for DNA analyses and is very simple to use in remote field locations.     

Evolution of feeding structure plasticity in marine invertebrate larvae: a possible trade-off between arm length and stomach size

The ability of an organism to alter its morphology in response to environmental conditions (phenotypic plasticity) occurs in several species of marine invertebrates. Examples are sea urchin and sand dollar larvae (plutei). When food is scarce, plutei produce longer food-gathering structures (larval arms and a ciliary band) and smaller stomachs than when food is abundant. However, it is unclear whether stomach size is actually induced through changes in morphogenesis or simply by food distending the stomach. Distinguishing between these two hypotheses is possible because plutei morphologically respond to food concentrations and change the length of their food-gathering structures before they are capable of feeding. More importantly, these two hypotheses provide insights to whether a trade-off exists between the response in food-gathering structures and the response in stomach size—a possible explanation for the evolution of feeding-structure plasticity in marine invertebrate larvae. In this study, I investigated whether sea urchin larvae (Strongylocentrotus purpuratus and S. franciscanus) reared in different amounts of food produced stomachs of different sizes before they were capable of feeding. Prior to having the ability to ingest food, larvae produced larger stomachs and shorter arms when food was abundant than when food was scarce, consistent with the hypothesis that food induced changes in morphogenesis. In addition, there was a strong negative correlation between the magnitude of plasticity in larval arm length and the magnitude of plasticity in stomach size. These results are consistent with the idea that a trade-off exists between the response in arm length and the response in stomach size, and at least in part, explains the evolution of feeding structure plasticity in plutei. This may also explain why feeding-structure plasticity has evolved in larvae of other taxa (e.g. other echinoderms and gastropods).     

Ecological regulation of development: induction of marine invertebrate metamorphosis

In the marine environment a wide range of invertebrates have a pelagobenthic lifecycle that includes planktonic larval and benthic adult phases. Transition between these morphologically and ecologically distinct phases typically occurs when the developmentally competent larva comes into contact with a species-specific environmental cue. This cue acts as a morphogenetic signal that induces the completion of the postlarval/juvenile/adult developmental program at metamorphosis. The development of competence often occurs hours to days after the larva is morphologically mature. In the non-feeding--lecithotrophic--larvae of the ascidian Herdmania curvata and the gastropod mollusc Haliotis asinina, gene expression patterns in pre-competent and competent stages are markedly different, reflecting the different developmental states of these larval stages. For example, the expression of Hemps, an EGF-like signalling peptide required for the induction of Herdmania metamorphosis, increases in competent larvae. Induction of settlement and metamorphosis results in further changes in developmental gene expression, which apparently is necessary for the complete transformation of the larval body plan into the adult form.     

Cytotoxicity from sulfide exposure in a sulfide-tolerant marine invertebrate

It is unknown whether sulfide-tolerant marine invertebrates suffer cytotoxicity from sulfide exposure in vivo at environmentally-relevant concentrations. We tested this with the mudflat polychaete Glycera dibranchiata. Exposure of live animals to sulfide up to 2.4 mmol l^− 1 for 24 h did not affect animal survival, and animal condition (gross appearance and activity) was unaffected at sulfide concentrations up to 0.25 mmol l^− 1. However, animal condition was decreased at higher sulfide concentrations (P < 0.0001, n = 33). Coelomic fluid obtained from the animals showed decreased erythrocyte count (P = 0.0035, n = 14), indicating cell loss, and increased propidium iodide and Hoechst 33324 staining (P < 0.0001 and P = 0.0003, respectively, n = 14), indicating loss of plasma membrane integrity, even at sulfide concentrations that produced no change in animal condition. When G. dibranchiata were allowed a 72 h recovery period following 24 h sulfide exposure, there was no overall improvement in condition (P ≥ 0.12, n = 7-8), and worms that had been exposed to 1 mmol l^−  1 sulfide still had an erythrocyte count that was less than half that of control animals (P = 0.028, n = 7). The inability to completely recover the cell count was at least partially due to impaired production of new erythrocytes, since analysis of BrdU incorporation indicated that erythrocyte proliferation was reduced from 2% per day in control animals to 0.12% per day in animals exposed to 1 mmol l^− 1 sulfide (P = 0.010, n = 21). Together, these findings indicate that at least some sulfide-tolerant marine invertebrates experience significant cellular injury and impaired tissue proliferation when exposed to environmentally relevant sulfide concentrations, even when the appearance and behavior of the animal appear unaffected.     

Settlement behaviour of marine invertebrate larvae measured by EthoVision 3.0

Submerged marine surfaces are rapidly colonized by fouling organisms. Current research is aimed at finding new, non-toxic, or at least environmentally benign, solutions to this problem. Barnacles are a major target organism for such control as they constitute a key component of the hard fouling community. A range of standard settlement assays is available for screening test compounds against barnacle cypris larvae, but they generally provide little information on mechanism(s) of action. Towards this end, a quick and reliable video-tracking protocol has been developed to study the behaviour of the cypris larvae of the barnacle, Balanus amphitrite, at settlement. EthoVision 3.0 was used to track individual cyprids in 30-mm Petri dishes. Experiments were run to determine the optimal conditions vis-a-vis acclimation time, tracking duration, number of replicates, temperature and lighting. A protocol was arrived at involving a two Petri dish system with backlighting, and tracking over a 5-min period after first acclimating the cyprids to test conditions for 2 min. A minimum of twenty replicates was required to account for individual variability in cyprid behaviour from the same batch of larvae. This methodology should be widely applicable to both fundamental and applied studies of larval settlement and with further refinements, to that of smaller fouling organisms such as microalgae and bacteria.     

Histones from nucleated erythrocytes of the marine invertebrate Sipunculus nudus

Total and lysine-rich histones were extracted from purified sipunculid erythrocyte nuclei with 0.25 N HCl and 0.74 N perchloric acid, respectively. The histones were fractionated and purified by gel filtration and ion exchange chromatography. Sipunculid PCA extract shows three lysine-rich histones, one of which may be a fraction specific to erythrocytes. The histones H₃ and H₄ of this marine invertebrate are very similar to their vertebrate homologues. Whereas no fraction H_2B has been detected in our investigation, the fraction H_2A has an unusual chromatographic behaviour if compared to its vertebrate homologue. These features may be the reflection of a peculiar distribution of histones in the chromatin of sipunculid erythrocytes.     

The marine invertebrate fauna of a British coastal salt marsh

There are few accounts in the literature of the marine fauna of European salt marshes. The marine invertebrate populations of a coastal salt marsh in eastern England were studied for two years. A total of 32 marine species were recorded. The community was composed of a subset of species from adjacent intertidal sand and mud flats, along with a brackish water component. This gave the marsh a characteristic fauna, which was dominated by infaunal and surface-living deposit feeders. The community showed a seasonal minimum in winter, and the infauna showed an additional summer decrease. This is attributed to increased interstitial salinities. Principal component analysis revealed the importance of the tidal gradient and the structure of the habitat in determining the community. The abundance of both epibenthic and infaunal predators were negatively correlated with the abundance of some prey. Also a small number of other pairwise negative interactions were revealed, but overall there was no strong evidence of interspecific competition exerting much influence on the community. The role of habitat heterogeneity and variation in the lateral movement of adult benthos and larval recruitment as promoters of diversity are discussed.     

Extracellular matrix of sea urchin and other marine invertebrate embryos

The extracellular matrix surrounding the sea urchin embryo (outer ECM) contains fibers and granules of various sizes which are organized in recognizable patterns as shown by ultrastructural studies, particularly stereoimaging techniques. The use of the ruthenium red method for retaining and staining the ECM, with modifications of the Luft (Anatomical Record 171:347-368, 1971) method for invertebrate embryos, allows for the clarification of certain structures, particularly fiber compaction in the interzonal region, and microvillus-associated bodies. The inner ECM in the sea urchin embryo includes the basal lamina and blastocoel matrix. Stereoimages show that the fibers which are loosely distributed in the blastocoel matrix become compacted around the periphery of the blastocoel to form the basal lamina. The ruthenium red method was also used on a number of marine invertebrate embryos and larvae, representing different phyla, to facilitate comparisons between their surface coats. The similarities observed in the specimens shown suggest that ECMs are widely found on marine invertebrate eggs, embryos, and larvae, and that they resemble vertebrate ECMs and may, therefore, have similar functions.