Relevance of mytilid shell microtopographies for fouling defence--a global comparison.

Prevention of epibiosis is of vital importance for most aquatic organisms, which can have consequences for their ability to invade new areas. Surface microtopography of the shell periostracum has been shown to have antifouling properties for mytilid mussels, and the topography shows regional differences. This article examines whether an optimal shell design exists and evaluates the degree to which shell microstructure is matched with the properties of the local fouling community. Biomimics of four mytilid species from different regional provenances were exposed at eight different sites in both northern and southern hemispheres. Tendencies of the microtopography to both inhibit and facilitate fouling were detected after 3 and 6 weeks of immersion. However, on a global scale, all microtopographies failed to prevent fouling in a consistent manner when exposed to various fouling communities and when decoupled from other shell properties. It is therefore suggested that the recently discovered chemical anti-microfouling properties of the periostracum complement the anti-macrofouling defence offered by shell microtopography.

Eight polymorphic microsatellite loci markers for the barnacle Balanus amphitrite (syn. Amphibalanus amphitrite) Darwin 1854.

Balanus amphitrite is a widespread species of barnacle. It is frequently studied, and of great importance to the marine coatings industry due to its significant abundance as a fouling organism on commercial shipping. We isolated and characterized eight highly polymorphic microsatellite loci, to aid in the determination of population genetic structure within this species. All loci showed considerable genetic variation with the number of alleles ranging from two to 14. Expected heterozygosity ranged from 0.74 to 0.98.

A comparative study of the anti-settlement properties of mytilid shells.

Marine organisms have evolved defence mechanisms to prevent epibiosis. This study investigated the anti-settlement properties of natural periostracal microtopographies of two mytilid species, Mytilus edulis (from North, Baltic and White Seas) and Perna perna (from the SW Atlantic). Resin replicas of shells were exposed to cyprids of the barnacle Semibalanus balanoides. Replicas with intact isotropic microtopographies and smooth controls were much less fouled than roughened anisotropic surfaces. This indicates that in both M. edulis and P. perna the periostracum possesses a generic anti-settlement property, at least against S. balanoides cyprids, which is not regionally adapted. Such a potential globally effective anti-settlement mechanism possibly contributes to the invasive success of Mytilidae.

Heat stress induces different forms of cell death in sea anemones and their endosymbiotic algae depending on temperature and duration.

Bleaching of reef building corals and other symbiotic cnidarians due to the loss of their dinoflagellate algal symbionts (=zooxanthellae), and/or their photosynthetic pigments, is a common sign of environmental stress. Mass bleaching events are becoming an increasingly important cause of mortality and reef degradation on a global scale, linked by many to global climate change. However, the cellular mechanisms of stress-induced bleaching remain largely unresolved. In this study, the frequency of apoptosis-like and necrosis-like cell death was determined in the symbiotic sea anemone Aiptasia sp. using criteria that had previously been validated for this symbiosis as indicators of programmed cell death (PCD) and necrosis. Results indicate that PCD and necrosis occur simultaneously in both host tissues and zooxanthellae subject to environmentally relevant doses of heat stress. Frequency of PCD in the anemone endoderm increased within minutes of treatment. Peak rates of apoptosis-like cell death in the host were coincident with the timing of loss of zooxanthellae during bleaching. The proportion of apoptosis-like host cells subsequently declined while cell necrosis increased. In the zooxanthellae, both apoptosis-like and necrosis-like activity increased throughout the duration of the experiment (6 days), dependent on temperature dose. A stress-mediated PCD pathway is an important part of the thermal stress response in the sea anemone symbiosis and this study suggests that PCD may play different roles in different components of the symbiosis during bleaching.

Oxidative-stress: comparison of species specific and tissue specific effects in the marine bivalves Mytilus edulis (L.) and Dosinia lupinus (L.).

This study describes a novel approach to the objective of identifying a suitable biomarker of oxidative-stress in marine animals and evaluates an established assay under controlled experimental conditions in vivo and in vitro. Live animals and tissue homogenates of the euryoxic blue mussel Mytilus edulis (L.), and the stenoxic smooth artemis Dosinia lupinus (L.), were exposed to oxidative-stress generated using a 60Co gamma-radiation source. In live organisms, mortality-rates were significantly different between species. M. edulis showed zero mortality and D. lupinus 30% mortality over 18 h. Protein-carbonyl (PC=O) content was determined by colourimetric assay (total protein-carbonyl) or immunodetection (for individual proteins) in four tissue types: digestive gland, mantle, adductor muscle and foot. In tissue homogenates, digestive gland and adductor muscle of both species showed significant increases (greater for D. lupinus) in PC=O content following irradiation in vitro. All tissues from live animals (with the exception of M. edulis mantle and adductor muscle of D. lupinus which died under irradiation) showed significantly different levels of PC Os following irradiation; D. lupinus PC=O levels were increased whilst in M. edulis PC=O content decreased. In D. lupinus which died during irradiation, PC=O content was greater than in those D. lupinus which survived, particularly in the adductor muscle, the former were inceased by 74% above controls. The findings support the hypothesis that species-specific adaptations to euryoxic and stenoxic environments, and metabolic requirements of different tissues, should result in differing ROS defences.