Molecular and histological identification of Marteilioides infection in Suminoe Oyster Crassostrea ariakensis, Manila Clam Ruditapes philippinarum and Pacific Oyster Crassostrea gigas on the south coast of Korea

The oyster ovarian parasite Marteilioides chungmuensis has been reported from Korea and Japan, damaging the oyster industries. Recently, Marteilioides-like organisms have been identified in other commercially important marine bivalves. In this study, we surveyed Marteilioides infection in the Manila clam Ruditapes philippinarum, Suminoe oyster Crassostrea ariakensis, and Pacific oyster Crassostrea gigas, using histology and Marteilioides-specific small subunit (SSU) rDNA PCR. The SSU rDNA sequence of M. chungmuensis (1716 bp) isolated from C. gigas in Tongyoung bay was 99.9% similar to that of M. chungmuensis reported in Japan. Inclusions of multi-nucleated bodies in the oocytes, typical of Marteilioides infection, were identified for the first time in Suminoe oysters. The SSU rDNA sequence of a Marteilioides-like organism isolated from Suminoe oysters was 99.9% similar to that of M. chungmuensis. Marteilioides sp. was also observed from 7 Manila clams of 1840 individuals examined, and the DNA sequences of which were 98.2% similar to the known sequence of M. chungmuensis. Unlike Marteilioides infection of Pacific oysters, no remarkable pathological symptoms, such as large multiple lumps on the mantle, were observed in infected Suminoe oysters or Manila clams. Distribution of the infected Manila clams, Suminoe oysters and Pacific oysters was limited to small bays on the south coast, suggesting that the southern coast is the enzootic area of Marteilioides infection.     

A new microsporidium from the oyster Ostrea lutaria in New Zealand

Microsporidium rapuae n. sp. (Microsporida) forms cysts within the connective tissue surrounding the gut epithelium of the oyster Ostrea lutaria. Except for encapsulation of the cysts by fibroblasts no pathogenic effects were observed. Each cyst contained a large number of spores possessing long well-developed polar filaments. This is the third Microspora recorded from Bivalvia (Mollusca), and the first which does not belong to the family Chytridiopsidae (Minisporida).     

Effect of food preservation on the grazing behavior and on the gut flora of the harpacticoid copepod Paramphiascella fulvofasciata

Harpacticoids owe their ‘reputation’ as primary consumers in aquatic food webs to their substantial grazing on diatoms, thus assuring an efficient energy flow to higher trophic levels. Due to the complex feeding behavior of harpacticoids, the nature and dynamics of diatom-harpacticoid trophic interactions remain poorly understood. In addition, there is a growing interest from aquaculture industry in mass-culturing harpacticoids with algal foods but the labor costs of maintaining algal stock cultures are high. This study focuses on the palatability of preserved diatoms for copepods and considers the possible role of bacterially mediated effects on diatom food uptake.The grazing of Paramphiascella fulvofasciata on a preserved freeze-dried diatom diet was tested and compared to the grazing on fresh cells. P. fulvofasciata assimilated the preserved diet, but assimilation of fresh cells was higher. When both cell types were mixed, no selective feeding was observed. Community fingerprinting of the bacteria associated with diatoms and fecal pellets suggests that the copepod gut flora was modified depending on the food source. Furthermore, the results suggest that the egestion of gut bacteria enriches the microenvironment and this can have an additional influence on the feeding behavior of the copepod.Experimental research using preserved foods must take into account that copepod grazing assimilations of fresh foods are likely to be significantly higher. Yet, the stated high assimilation of the mixed diet, encourages further exploration of the application of preserved ‘balanced’ foods for harpacticoid mass-culturing.     

Brugia pahangi: Feeding and nutrient uptake in vitro and in vivo

Incubation in vitro of adult Brugia pahangi in an apparatus which permitted the separate exposure of the anterior, middle, or posterior region of the worms to medium-containing radioactively labeled d-glucose, l-leucine, and adenosine has provided evidence that these materials are taken up in physiologically significant amounts by a transcuticular route. No evidence for an oral ingestion of materials has been obtained from worms in vitro, but in vivo an oral uptake of Trypan blue has been demonstrated. The ultrastructure and cytochemical staining reactions for nonspecific esterase, acid phosphatase (EC-3.1.3.2), and leucine naphthylamidase of the gut and body wall are described.     

Feeding and survival rates of the copepods Euterpina acutifrons Dana and Acartia grani Sars on the dinoflagellates Alexandrium minutum Balech and Gyrodinium corsicum Paulmier and the Chryptophyta Rhodomonas baltica Karsten

Here we studied the feeding performances and survival rates of the copepods Euterpina acutifrons and Acartia grani exposed to cultures of the toxic dinoflagellates Alexandrium minutum and Gyrodinium corsicum and the nontoxic Chryptophyta Rhodomonas baltica. The presence of hemolysins in G. corsicum was also analysed. For both copepod species, high ingestion rates on A. minutum and lower but similar rates on G. corsicum and R. baltica were found. After 120 h, only the E. acutifrons that grazed on G. corsicum or R. baltica showed 100% survival, whereas survival of the copepods that grazed on A. minutum was significantly lower. A. grani was more sensitive to the dinoflagellates, and at 120 h showed survival rates of 70% on G. corsicum and 60% on A. minutum. These results support the hypothesis that the feeding interactions between copepods and toxic dinoflagellates are highly species-specific. Long-term observations indicated that E. acutifrons can graze on G. corsicum without impairing their feeding or growth performances. Both copepod species consumed A. minutum in the short-term, but their long-term impact on this and other toxic marine dinoflagellates would be limited by the toxic effects of these flagellates. We did not find any evidence of haemolytic activity in extracts of G. corsicum. Toxins other than haemolysins may be responsible for the deleterious effects observed on A. grani.     

The mitochondrial genomes of Amphiascoides atopus and Schizopera knabeni (Harpacticoida: Miraciidae) reveal similarities between the copepod orders Harpacticoida and Poecilostomatoida

Members of subclass Copepoda are abundant, diverse, and—as a result of their variety of ecological roles in marine and freshwater environments—important, but their phylogenetic interrelationships are unclear. Recent studies of arthropods have used gene arrangements in the mitochondrial (mt) genome to infer phylogenies, but for copepods, only seven complete mt genomes have been published. These data revealed several within-order and few among-order similarities. To increase the data available for comparisons, we sequenced the complete mt genome (13,831 base pairs) of Amphiascoides atopus and 10,649 base pairs of the mt genome of Schizopera knabeni (both in the family Miraciidae of the order Harpacticoida). Comparison of our data to those for Tigriopus japonicus (family Harpacticidae, order Harpacticoida) revealed similarities in gene arrangement among these three species that were consistent with those found within and among families of other copepod orders. Comparison of the mt genomes of our species with those known from other copepod orders revealed the arrangement of mt genes of our Harpacticoida species to be more similar to that of Sinergasilus polycolpus (order Poecilostomatoida) than to that of T. japonicus. The similarities between S. polycolpus and our species are the first to be noted across the boundaries of copepod orders and support the possibility that mt-gene arrangement might be used to infer copepod phylogenies. We also found that our two species had extremely truncated transfer RNAs and that gene overlaps occurred much more frequently than has been reported for other copepod mt genomes.     

Feeding efficiency of a marine copepod Acartia erythraea on eight different algal diets

Acartia erythraea is a dominant zooplankton copepod in the South China coastal waters during summer. This paper examined its feeding behavior (food gut passage, clearance rate and ingestion rate) on eight phytoplankton diets. The food gut passage time and ingestion rate were negatively related to the size and concentration of food supply, whereas the clearance rate was positively related to the food concentration. The ingestion rate decreased with the food concentration when it reached a threshold level. Generally, the clearance rate of copepods decreased with increasing cell density, but was very low at both low and high algal densities when the food were small in sizes. The optimum food size was about 10 μm for the copepods, and the dinoflagellate, Prorocentrum minimum, was considered as a good food choice for A. erythraea.     

New evidence for the involvement of Paracartia grani (Copepoda,Calanoida) in the life cycle of Marteilia refringens (Paramyxea)

The dynamics of the protozoan parasite Marteilia refringens was studied in Thau lagoon, an important French shellfish site, for 1 year in three potential hosts: the Mediterranean mussel Mytilus galloprovincialis (Mytiliidae), the grooved carpet shell Ruditapes decussatus (Veneriidae) and the copepod Paracartia grani (Acartiidae). Parasite DNA was detected by PCR in R. decussatus. In situ hybridisation showed necrotic cells of M. refringens in the digestive epithelia of some R. decussatus suggesting the non-involvement of this species in the parasite life cycle. In contrast, the detection of M. refringens in mussels using PCR appeared bimodal with two peaks in spring and autumn. Histological observations of PCR-positive mussels revealed the presence of different parasite stages including mature sporangia in spring and autumn. These results suggest that the parasite has two cycles per year in the Thau lagoon and that mussels release parasites into the water column during these two periods. Moreover, PCR detection of the parasite in the copepodid stages of P. grani between June and November supports the hypothesis of the transmission of the parasite from mussels to copepods and conversely. In situ hybridisation performed on copepodites showed labeling in some sections. Unusual M. refringens cells were observed in the digestive tract and the gonad from the third copepodid stage, suggesting that the parasite could infect a copepod by ingestion and be released through the gonad. This hypothesis is supported by the PCR detection of parasite DNA in copepod eggs from PCR-positive females, which suggests that eggs could contribute to the parasite spreading in the water and could allow overwintering of M. refringens. Finally, in order to understand the interactions between mussels and copepods, mussel retention efficiency (number of copepods retained by a mussel) was measured for all P. grani developmental stages. Results showed that all copepod stages could contribute to the transmission of the parasite, especially eggs and nauplii which were retained by up to 90%.     

Inhibition of Metarhizium anisopliae in the alimentary tract of the eastern subterranean termite Reticulitermes flavipes

Reticulitermes flavipes workers were individually inoculated with 10,000 conidia of the entomopathogenic fungus Metarhizium anisopliae. After being kept in groups of 20 individuals for 1-6 d, histopathological approach showed that most of the inoculated conidia were groomed from the surface of the cuticle by nestmates within 24 h, and that a large number of conidia was subsequently found in different parts of the gut of the groomers. Our observations showed that, among thousands of conidia found in the termite’s gut, conidial germination never occurred in all inspected specimens, even when the conidia had the chance to bind to the surface of the cuticular lining of the gut. In addition, when termites were left for decomposition several days after death caused by an external infection of M. anisopliae, the hyphal growth was generalized in the body cavity of the cadaver, but was never observed in the lumen of the gut even 2 d post-mortem. Our observation suggests that the putative biochemicals involved in the termite’s gut defense against fungal pathogens are from multiple origins.     

Predator-prey dynamics between recently established stone crabs (Menippe spp.) and oyster prey (Crassostrea virginica)

Range expansion and population establishment of individual species can have significant impacts on previously established food webs and predator-prey dynamics. The stone crab (Menippe spp.) is found throughout southwestern North Atlantic waters, from North Carolina through the Gulf of Mexico and the Central American Caribbean, including the Greater Antilles. Recent observations suggest that stone crabs have become better established on certain oyster reefs in North Carolina than in the early 1900s when they we first observed in NC. To assess the predatory impact of stone crabs on oysters, we (1) quantified stone crab densities on subtidal oyster reefs in Pamlico Sound, NC using scuba surveys, and (2) conducted laboratory predation experiments to assess the functional response of stone crabs to varying densities of oysters. We then (3) analyzed previously unpublished functional response data on another important oyster predator, the mud crab Panopeus herbstii. Finally, we (4) compared and contrasted potential predatory impacts of stone, mud and blue crabs (Callinectes sapidus). The functional response data and analyses for both stone crabs and mud crabs were consistent with a type II functional response. Mud crabs, on a m² basis, inflicted the highest proportional mortality on oysters over a 24 hour period, followed by stone and then blue crabs. Proportional mortality did not vary significantly with oyster size; however, relatively small and large oysters were consumed disproportionately less than medium-sized oysters, likely due to the mechanical inability of stone crabs to handle small oysters, and the inability to crush large oysters. Although stone crabs appear to be established in Pamlico Sound at densities equivalent to densities in other systems such as the U.S. Florida Panhandle, their predatory activities on oysters are not expected to have as significant a negative impact on oyster populations compared to other resident predators such as mud crabs.     

Tracing Vibrio parahaemolyticus in oysters (Tiostrea chilensis) using a Green Fluorescent Protein tag

Oysters feed by removing particles from the water. This food is composed of complex mixtures of living microorganisms, detritus, and inorganic particles that widely range in size. It has been speculated that some marine heterotrophic microorganisms, such as Vibrio parahaemolyticus, could enter in this digestive process and persist in the oyster tissue. Since some strains of V. parahaemolyticus are pathogenic for humans, these bacteria are considered to be a constant menace for health and aquaculture. In order to improve the safety of marine products it is imperative to obtain more knowledge about Tiostrea chilensis and its interactions with V. parahaemolyticus. In this study V. parahaemolyticus ATCC 17802 was tagged using plasmid pKV111, which carries the gfp gene that codifies a Green Fluorescent Protein (GFP), thereby allowing these strains (VpGFP) to be detected under epifluorescence microscopy. Results obtained showed that T. chilensis can filter VpGFP directly from sea water and suggested that most of them were digested by oysters. However, in the postharvest stage, a small fraction can remain in oyster tissues after depuration and VpGFP can rapidly grow if the bivalves are stored at room temperature.     

In vivo events associated with entomopathology of Beauveria bassiana for the corn earworm (Heliothis zea)

When conidia of Beauveria bassiana are injected into the hemocoel of corn earworm larvae, it appears that a positive correlation exists between exocellular proteolytic activity of the fungus and entomopathological manifestations. Once inside the hemolymph, defense mechanisms (including phagocytosis) are incapable of overcoming the fungus and one important event in a terminal mycocidal cascade involves preferential invasion of the gut wall. Such invasion helps explain the observed inhibition of feeding by infected larvae. Although histopathological changes seen in gut tissues suggest that a gut toxin is produced, evidence for such a toxin could not be obtained in preliminary tests. Biochemical changes are seen in hemolymph components; however, these are viewed as being due to general starvation rather than to specific activities of the fungus, at least up to the time that a general mycosis is established. With the host larva under physiological stress (starvation, nutrient depletion, and, possibly, toxin production in gut tissues) and failure of defense mechanisms, the infection spreads quickly and a terminal mycosis results.     

rgn gene is required for gut cell homeostasis after ingestion of sodium dodecyl sulfate in Drosophila

Resistance and resilience constitute the two complementary aspects of epithelial host defenses in Drosophila. Epithelial cell homeostasis is necessary for the recovery of damages caused by stress or infections. However, the genes responsible for gut epithelial homeostasis remain poorly understood. Here, we show that rgn^G4035 mutant flies have higher mortality than wild-type flies after ingestion of sodium dodecyl sulfate (SDS). Excessive melanization and increased necrotic cells in the gut contribute to the reduced survival of rgn^G4035 mutant flies following SDS ingestion. rgn mutant flies have a defect in the replenishment of intestinal stem cells (ISCs) following gut damage. The antimicrobial peptide (AMP) expression is affected in rgn^G4035 mutant fly guts. Together, our study provides evidence that rgn gene is essential for gut cell homeostasis following damage in Drosophila.     

Effects of hemolymph of the American oyster, Crassostrea virginica, on marine cercariae

The interactions of cellular and humoral factors of hemolymph of the American oyster, Crassostrea virginica, and several species of marine cercariae were studied. Attraction of hemocytes to dead but not to living cercariae was observed. Dead cercariae were encapsulated in vitro by oyster hemocytes. The plasma of C. virginica was apparently not toxic to the species of cercariae tested.     

Analysis of Stomach and Gut Microbiomes of the Eastern Oyster (Crassostrea virginica) from Coastal Louisiana,USA

We used high throughput pyrosequencing to characterize stomach and gut content microbiomes of Crassostrea virginica, the Easter oyster, obtained from two sites, one in Barataria Bay (Hackberry Bay) and the other in Terrebonne Bay (Lake Caillou), Louisiana, USA. Stomach microbiomes in oysters from Hackberry Bay were overwhelmingly dominated by Mollicutes most closely related to Mycoplasma; a more rich community dominated by Planctomyctes occurred in Lake Caillou oyster stomachs. Gut communities for oysters from both sites differed from stomach communities, and harbored a relatively diverse assemblage of phylotypes. Phylotypes most closely related to Shewanella and a Chloroflexi strain dominated the Lake Caillou and Hackberry Bay gut microbiota, respectively. While many members of the stomach and gut microbiomes appeared to be transients or opportunists, a putative core microbiome was identified based on phylotypes that occurred in all stomach or gut samples only. The putative core stomach microbiome comprised 5 OTUs in 3 phyla, while the putative core gut microbiome contained 44 OTUs in 12 phyla. These results collectively revealed novel microbial communities within the oyster digestive system, the functions of the oyster microbiome are largely unknown. A comparison of microbiomes from Louisiana oysters with bacterial communities reported for other marine invertebrates and fish indicated that molluscan microbiomes were more similar to each other than to microbiomes of polychaetes, decapods and fish.     

Unexpected role of the IMD pathway in Drosophila gut defense against Staphylococcus aureus

In this study, fruit fly of the genus Drosophila is utilized as a suitable model animal to investigate the molecular mechanisms of innate immunity. To combat orally transmitted pathogenic Gram-negative bacteria, the Drosophila gut is armed with the peritrophic matrix, which is a physical barrier composed of chitin and glycoproteins: the Duox system that produces reactive oxygen species (ROS), which in turn sterilize infected microbes, and the IMD pathway that regulates the expression of antimicrobial peptides (AMPs), which in turn control ROS-resistant pathogens. However, little is known about the defense mechanisms against Gram-positive bacteria in the fly gut. Here, we show that the peritrophic matrix protects Drosophila against Gram-positive bacteria S. aureus. We also define the few roles of ROS in response to the infection and show that the IMD pathway is required for the clearance of ingested microbes, possibly independently from AMP expression. These findings provide a new aspect of the gut defense system of Drosophila, and helps to elucidate the processes of gut-microbe symbiosis and pathogenesis.     

Minchinia armoricana sp. nov. (Haplosporida), a parasite of the European flat oyster, Ostrea edulis

Examination of European flat oysters, Ostrea edulis, from the Dutch oyster culture, but originating in France, revealed a new disease due to a protistan parasite. Light and electron microscope studies revealed that the parasite belongs to the haplosporidan genus Minchinia. Since comparison with other Minchinia spp. indicate that it is new, the name Minchinia armoricana nov. sp. is proposed. Thus far, the parasite was very rare; only two diseased oysters were observed among ca. 3700 specimens examined histologically during a 2.5-year period. The diseased oysters showed macroscopically a peculiar brown discoloration and microscopically many sporocysts with spores in the connective tissue. Beside the two diseased oysters, another one was observed with an infection of unidentified plasmodial stages in the connective tissue. These may be developmental stages of the new species M. armoricana.     

Heavy metal complexation in polluted molluscs II. Oysters (Ostrea edulis and Crassostrea gigas)

Cadmium, zinc and copper, accumulated from polluted habitats by the oysters Ostrea edulis and Crassostrea gigas, were studied. Three distinct low molecular weight (less than 3000 daltons) zinc complexes were separated from highly contaminated C. gigas, one of which may be a complex with the amino acid taurine. Only one of these zinc complexes was present in less contaminated specimens of O. edulis. On gel permeation chromatography of oyster extracts, copper was eluted together with amino acids (principally taurine) and the betaine homarine. No evidence of metallothionein type proteins was found.     

Oral infection of Hylobius pales by Metarrhizium anisopliae

Microfeeding of Hylobius pales with as few as 40 conidia of Metarrhizium anisopliae, under conditions that excluded any possibility of integumental contaminations, resulted in high mortality. When larger doses were employed, the insects succumbed faster. Histological sections revealed that the fungus invaded the host from within the buccal cavity. There was no evidence of germination and penetration inside the intestinal tract. Spores retained their viability after passing through the gut. In vitro, conidia mixed with the liquid contents of the midgut germinated within 20 hr. Germination occurred even though both yeasts and bacteria were present in the midgut contents. Fungus-killed Hylobius contained hyphae inside their digestive system, but the intima always remained intact.