2-DE Mapping of the Blue Mussel Gill Proteome: The Usual Suspects Revisited.

The Blue Mussel (Mytilus edulis, L. 1758) is an ecologically important and commercially relevant bivalve. Because of its ability to bioconcentrate xenobiotics, it is also a widespread sentinel species for environmental pollution, which has been used in ecotoxicological studies for biomarker assessment. Consequently, numerous proteomics studies have been carried out in various research contexts using mussels of the genus Mytilus, which intended to improve our understanding of complex physiological processes related to reproduction, adaptation to physical stressors or shell formation and for biomarker discovery. Differential-display 2-DE proteomics relies on an extensive knowledge of the proteome with as many proteoforms identified as possible. To this end, extensive characterization of proteins was performed in order to increase our knowledge of the Mytilus gill proteome. On average, 700 spots were detected on 2-DE gels by colloidal blue staining, of which 122 different, non-redundant proteins comprising 203 proteoforms could be identified by tandem mass spectrometry. These proteins could be attributed to four major categories: (i) "metabolism", including antioxidant defence and degradation of xenobiotics; (ii) "genetic information processing", comprising transcription and translation as well as folding, sorting, repair and degradation; (iii) "cellular processes", such as cell motility, transport and catabolism; (iv) "environmental information processing", including signal transduction and signalling molecules and interaction. The role of cytoskeleton proteins, energetic metabolism, chaperones/stress proteins, protein trafficking and the proteasome are discussed in the light of the exigencies of the intertidal environment, leading to an enhanced stress response, as well as the structural and physiological particularities of the bivalve gill tissue.

Immunocytotoxicity, cytogenotoxicity and genotoxicity of cadmium-based quantum dots in the marine mussel Mytilus galloprovincialis.

There is an increased use of Quantum Dot (QDs) in biological and biomedical applications, but little is known about their marine ecotoxicology. So, the aim of this study was to investigate the possible immunocytotoxic, cytogenotoxic and genotoxic effects of cadmium telluride QDs (CdTe QDs) on the marine mussel Mytilus galloprovincialis. Mussels were exposed to 10 µg L(-1) of CdTe QDs or to soluble Cd [Cd(NO3)2] for 14 days and Cd accumulation, immunocytotoxicity [hemocyte density, cell viability, lysosomal membrane stability (LMS), differential cell counts (DCC)], cytogenotoxicity (micronucleus test and nuclear abnormalities assay) and genotoxicity (comet assay) were analyzed. Results show that in vivo exposure to QDs, Cd is accumulated in mussel soft tissues and hemolymph and induce immunotoxic effects mediated by a decrease in LMS, changes in DCC, as well as genotoxicity (DNA damage). However, QDs do not induce significant changes in hemocytes density, cell viability and cytogenetic parameters in opposition to Cd(2+). Soluble Cd is the most cytotoxic and cytogenotoxic form on Mytilus hemocytes due to a higher accumulation of Cd in tissues. Results indicate that immunotoxicity and genotoxicity of CdTe QDs and Cd(2+) are mediated by different modes of action and show that Mytilus hemocytes are important targets for in vivo QDs toxicity.

Comparison of protein-extraction methods for gills of the shore crab, Carcinus maenas (L.), and application to 2DE.

As it is well-established that protein extraction constitutes a crucial step for two-dimensional electrophoresis (2DE), this work was done as a prerequisite to further the study of alterations in the proteome in gills of the shore crab Carcinus maenas under contrasted environmental conditions. Because of the presence of a chitin layer, shore crab gills have an unusual structure. Consequently, they are considered as a hard tissue and represent a challenge for optimal protein extraction. In this study, we compared three published extraction procedures for subsequent applications to 2DE: the first one uses homogenization process, the second one included an additional TCA-acetone precipitation step, and finally, the third one associated grinding in liquid nitrogen (N2) and TCA-acetone precipitation. Extracted proteins were then resolved using 1DE and 2DE. Although interesting patterns were obtained using 1DE with the three methods, only the one involving grinding in liquid N2 and TCA-acetone precipitation led to proper resolution after 2DE, showing a good level of reproducibility at technical (85%) and biological (84%) levels. This last method is therefore proposed for analysis of gill proteomes in the shore crab.

Sample preparation for two-dimensional gel electrophoresis: considering the composition of biological material.

Comparative proteomic analyses in ecotoxicology and related fields require reproducible display of as many proteins as possible. In addition, it should be possible to carry out a quantitative comparison in a reliable manner. Sample preparation represents one of the essential steps toward these aims. In their work, Wu et al. describe how to deal with different recalcitrant tissues of varying species (Proteomics 2013, 13, 3205-3210). Their work underlines the necessity to adapt sample preparation to the specific requirements of the biological material. Beyond that Wu et al. present TRIzol® as feasible means for combined extraction of proteins and RNA. Indeed, using TRI-reagent extraction for proteomics, they resolve two problems at a time: that of removing contaminating compounds and that of simultaneous analysis of gene and protein expression.

Impact of toxicant exposure on the proteomic response to intertidal condition in Mytilus edulis.

Intertidal blue mussels display physiological adaptations to emersion-submersion cycle that can be impacted by response to chemicals. In order to study the interference of cellular response to pollutants on intertidal physiology, we analysed proteomic (2-DE) responses in gills of mussels exposed for 14 days to regular emersion (intertidal condition) or continuous submersion (subtidal condition) and to a mixture (B[a]P/phenantrene) of polycyclic aromatic hydrocarbons (PAHs). Antioxidant activities were measured as general stress markers. In clean context, emersion generated several over-expressions of proteins mainly involved in cytoskeleton, chaperoning, energetic metabolism and transcription regulation. Mussels exposed to PAHs showed equivalent accumulation levels of contaminants in both physiological conditions but an increased GST activity specifically in intertidal context, highlighting the high degree of stress underwent in this group, as well as over-expressions of Cu/Zn SOD and stress proteins in subtidal context. Presence of contaminants partly impacted the response to emersion: cytoskeletal rearrangements and energetic adjustments were mostly maintained whereas stress response was dramatically altered. These findings highlight the potential adverse effects of toxicants on physiological adjustments linked to air-exposure, thus suggesting to take into account in the evaluation of environmental risk the multiplicity of stresses that wild animals are likely to encounter.

Tidal height influences the levels of enzymatic antioxidant defences in Mytilus edulis.

We investigated the potential variability of enzymatic antioxidant activities in blue mussels Mytilus edulis from a single intertidal population but living at different tidal heights. Activity levels of antioxidant enzymes (Cu/Zn superoxide dismutase, catalase, glutathione peroxidase, glutathione reductase, glutathione transferase) were measured in the gills and digestive gland of mussels sampled at high shore (HS, air-exposure>6h/12h) and low shore (LS, air-exposure<2h/12h) of an intertidal zone (Yport, Normandie, France) for two consecutive autumns. In both tissues, levels of each enzymatic activity (except GST) were clearly higher in HS mussels than in LS for the two years. These results suggest an ability to acclimate the enzymatic antioxidant defences to the degree of undergone stress, confirming the importance of environmental conditions in the antioxidant responses. Therefore, the location of organisms on the shore should be taken into account in sampling for ecotoxicological studies.

Differential pattern of Cu/Zn superoxide dismutase isoforms in relation to tidal spatio-temporal changes in the blue mussel Mytilus edulis.

Inducible antioxidant defences in marine organisms such as mussel bivalves are commonly used as biomarkers of pollutant-induced oxidative stress and their variations proposed as one of the biological effect measurements for assessment of contamination impact in aquatic environments. Among them, the copper/zinc superoxide dismutases (Cu/Zn-SODs) are metalloenzymes which play a key role in the protection of cells in case of oxidative stress. In order to observe possible variations of an antioxidant response in relation to tidal oscillations, the copper/zinc superoxide dismutase activity (Cu/Zn-SOD) was characterized in the digestive gland and gills of blue mussels sampled at high and low shore throughout the tidal cycle. Determination of SOD activity was performed on gels after isoelectro-focusing, allowing the revelation of three isoforms. In both tissues, high-shore mussels exhibited a higher level of total SOD activity than low-shore mussels. During emersion, a decrease of total SOD activity appeared in digestive gland for both groups. In high-shore mussels, the less acidic form contributed to 75% of the total activity, the second one to 20% and the more acidic one to 5% in both tissues before air exposure. During emersion, the relative contribution of the three isoforms to the total activity was markedly changed with a significant decrease in intensity of the first isoform and parallel increases in the two other ones. After re-immersion a progressive recovery of proportions of SOD isoforms was observed. In low-shore mussels, the relative contribution of the three isoforms to the total SOD activity showed similar changes. The observed variations could correspond to changes in the redox status of the mussels during tidal oscillations.