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1. Feeding Rate of Mussels with Microplastics and Surfactants

   Flores, Y ; Haynes, V ; Ward, E ( February 2018 , Ocean Sciences)

   Suspension-feeding mollusks (e.g., bivalves) play a key role in improving the water quality of coastal environments by filtering out suspended matter from the water column. Microplastics are becoming ubiquitous in the marine environment, so it is important to understand if these particles affect feeding processes of bivalves. Additionally, previous studies regarding the impact of microplastic on bivalve physiology have not independently tested for the effects of surfactants which are often added to commercially available plastic particles to prevent aggregation. We measured the clearance rate of mussels (Mytilus edulis) exposed to one type of microplastic and three common surfactants. Mussels were given a dose of microalgal food (1 x 104 cells/mL) and 10-m polystyrene spheres (Polybead; 1 x 104 beads/mL). Experimental treatments tested were washed microspheres and microspheres coated with each of the following surfactants at a concentration of 2mg/L: triton X-100, benzalkonium chloride, and sodium dodecyl sulfate. These surfactants are nonionic, cationic, and anionic, respectively. Control mussels were given a microalgal diet only (2 x 104 cells/mL). Each mussel was placed in an individual 1-L chamber and exposed to one of the aforementioned treatments. Water samples were taken at the start of the experiment (t=0) and then every 10 minutes for 30 minutes to determine clearance rates. Particle concentrations were measured using an electronic particle counter (Coulter Counter) at an appropriate size range for the algae and microspheres. Our results indicate that microspheres with or without surfactant had no effect on clearance rates of mussel compared to those of the controls. Further, our research suggests that the use of polystyrene microspheres in future experiments without initial washing does not affect the clearance rate of mussels. 

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2. Density of Compatible Ligands on the Surface of Food Particles Modulates Sorting Efficiency in the Blue Mussel Mytilus edulis

   https://doi.org/10.3389/fmars.2022.882356  

   Pales Espinosa, Emmanuelle ; Eckstein, Margot ; Allam, Bassem ( May 2022 , Frontiers in Marine Science)

   The adhesion between food particles and mucus is a fundamental process in particle sorting in suspension-feeding bivalves that requires specific recognition. Interactions between carbohydrate-binding proteins (lectins) expressed on the feeding organs and carbohydrates present on microbial cell surface can provide this specificity. Microalga cell surface carbohydrates (MCSC) represent unique patterns that can be considered as species-specific fingerprints. In this study, sorting efficiencies in blue mussels Mytilus edulis fed with microalgae having modified MCSC and engineered microspheres coated with target carbohydrates was measured. The nature and quantities of surface carbohydrates required to trigger sorting in mussels was evaluated and the relationship between ligand quantities and sorting efficiency (SE) was determined. Mussels fed with Chlamydomonas which MCSC were blocked with ConA or PEA lectins (affinity to mannose and glucose) led to a significant decrease of the sorting efficiencies, not observed when the lectin UEA (affinity to fucose) was used. The ability of commercial lectins to inhibit sorting was not linear and a threshold was noted between 30 and 45 ug lectins per million algae cells. Further, mussels were fed with microspheres coated with neoglycoproteins. Results showed that glucose-BSA, but not fucose-BSA, has an effect on particle sorting in mussels, and 1.08 x 10 9 molecules of glucose per microspheres, corresponding to a density of 6.99 x 10 6 molecules of glucose per µm 2 , triggers particle selection. These findings support that selection of food particles by mussels rely on the strength of the bond between suspended particle and the mucosal layer that mediate sorting, and that these bonds depend on the quantity of compatible ligands on each particle. 

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3. An examination of the use of antibiotics as a method to experimentally perturb the microbiota of suspension‐feeding bivalves

   https://doi.org/10.1111/ivb.12352  

   Griffin, Tyler W. ; Pierce, Melissa L. ; Nigro, Lisa M. ; Holohan, Bridget A. ; Ward, J. Evan ( November 2021 , Invertebrate Biology)

   Suspension‐feeding bivalves are critical members of aquatic ecosystems worldwide, which is why research into their host‐associated microbiota is growing. Experiments that artificially diminish the native microbial communities of bivalvesin vivowill be increasingly necessary to evaluate the functional role of microbes within their hosts. Previous methods to manipulate the microbiome of bivalves lack standardization and, often, verification of successful disturbance. The goal of this study was to evaluate antibiotic administration as a method for perturbing the gut microbiome of bivalves in two separate, but related, experiments. In the first, a mixture of antibiotics was delivered to eastern oysters for 4 days to probe effects on gut microbial carbon usage, diversity, and taxonomic composition. In the second, the same antibiotic mixture was administered to blue mussels for 21 days to probe effects on microbial abundance, diversity, and taxonomic composition. In both experiments, animals were administered antibiotics in isolation, and stringent sterilization methods were employed, which included sterilized seawater and microalgal food. The results of the oyster experiment revealed that antibiotics substantially reduced microbial carbon usage and perturbed community composition. In the mussel experiment, antibiotics lowered microbial abundance and species richness and significantly altered community composition. Taken together, results from the two experiments demonstrate that antibiotics can be used to effectively alter the function and composition of the gut microbial community of bivalves. Future research that aims to perturb the microbiomes of suspension‐feeding animals should incorporate aspects similar to the protocols described herein. Additionally, future studies must include verification, ideally high‐throughput DNA sequencing coupled with microbial quantification, that the antibiotic perturbation was successful.

    

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4. The gut bacterial microbiome of the Threeridge mussel, Amblema plicata , varies between rivers but shows a consistent core community

   https://doi.org/10.1111/fwb.13905  

   Lawson, Lauren A. ; Atkinson, Carla L. ; Jackson, Colin R. ( March 2022 , Freshwater Biology)

   Freshwater mussels are important for nutrient cycling and ecosystem health as they filter feed on their surrounding water. This filter feeding makes these bivalves especially sensitive to conditions in their environment. Gut microbial communities (microbiomes) have been recognised as important to both host organism and ecosystem health; however, how freshwater mussel microbiomes are organised and influenced is unclear.

   In this study, the gut bacterial microbiome of Threeridge mussel,Amblema plicata, was compared across two river basins, five rivers, and nine local sites in the south‐eastern U.S.A. Mussel gut tissue was dissected, DNA extracted, and the microbiome characterised by high throughput sequencing of the V4 region of the 16S ribosomal RNA gene.

   Planctomycetes, Firmicutes, and Cyanobacteria were the most common bacterial phyla within the guts of all sampledA.plicata. However, the relative abundances of these major bacterial phyla differed between mussels sampled from different rivers and river basins, as did the relative abundance of specific bacterial operational taxonomic units (OTUs). Despite these differences, a core microbiome was identified across all mussels, with eight OTUs being consistent members of theA.plicatamicrobiome at all sites, the most abundant OTU identifying as a member of the family Planctomycetaceae. Geographic distance between sites was not correlated with similarity in the structure of the gut microbiome, which was more related to site physicochemistry.

   Overall, these results suggest that while physicochemical conditions affect the composition of transient bacteria in the Threeridge mussel gut microbiome, the core microbiome is largely unaffected, and a portion of theA.plicatamicrobiome is retained regardless of the river system.

   How long transient bacteria remain in the gut, and to what extent these transient microbes aid in host function is still unknown. Core microbiota have been found to aid in multiple functions within animal hosts, and within freshwater mussels this core microbiome may aid in nutrient processing and cycling. Therefore, it is important to look at both transient and core microbes when studying the structure of freshwater invertebrate microbiomes.

    

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5. Mussels Repair Shell Damage despite Limitations Imposed by Ocean Acidification

   https://doi.org/10.3390/jmse10030359  

   George, Matthew N. ; O’Donnell, Michael J. ; Concodello, Michael ; Carrington, Emily ( March 2022 , Journal of Marine Science and Engineering)

   Bivalves frequently withstand shell damage that must be quickly repaired to ensure survival. While the processes that underlie larval shell development have been extensively studied within the context of ocean acidification (OA), it remains unclear whether shell repair is impacted by elevated pCO2. To better understand the stereotypical shell repair process, we monitored mussels (Mytilus edulis) with sublethal shell damage that breached the mantle cavity within both field and laboratory conditions to characterize the deposition rate, composition, and integrity of repaired shell. Results were then compared with a laboratory experiment wherein mussels (Mytilus trossulus) repaired shell damage in one of seven pCO2 treatments (400–2500 µatm). Shell repair proceeded through distinct stages; an organic membrane first covered the damaged area (days 1–15), followed by the deposition of calcite crystals (days 22–43) and aragonite tablets (days 51–69). OA did not impact the ability of mussels to close drill holes, nor the microstructure, composition, or integrity of end-point repaired shell after 10 weeks, as measured by µCT and SEM imaging, energy-dispersive X-ray (EDX) analysis, and mechanical testing. However, significant interactions between pCO2, the length of exposure to treatment conditions, the strength and inorganic content of shell, and the physiological condition of mussels within OA treatments were observed. These results suggest that while OA does not prevent adult mussels from repairing or mineralizing shell, both OA and shell damage may elicit stress responses that impose energetic constraints on mussel physiology. 

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