Novel Proteins Identified in the Insoluble Byssal Matrix of the Freshwater Zebra Mussel

The freshwater zebra mussel, Dreissena polymorpha, is an invasive, biofouling species that adheres to a variety of substrates underwater, using a proteinaceous anchor called the byssus. The byssus consists of a number of threads with adhesive plaques at the tips. It contains the unusual amino acid 3, 4-dihydroxyphenylalanine (DOPA), which is believed to play an important role in adhesion, in addition to providing structural integrity to the byssus through cross-linking. Extensive DOPA cross-linking, however, renders the zebra mussel byssus highly resistant to protein extraction, and therefore limits byssal protein identification. We report here on the identification of seven novel byssal proteins in the insoluble byssal matrix following protein extraction from induced, freshly secreted byssal threads with minimal cross-linking. These proteins were identified by LC-MS/MS analysis of tryptic digests of the matrix proteins by spectrum matching against a zebra mussel cDNA library of genes unique to the mussel foot, the organ that secretes the byssus. All seven proteins were present in both the plaque and thread. Comparisons of the protein sequences revealed common features of zebra mussel byssal proteins, and several recurring sequence motifs. Although their sequences are unique, many of the proteins display similarities to marine mussel byssal proteins, as well as to adhesive and structural proteins from other species. The large expansion of the byssal proteome reported here represents an important step towards understanding zebra mussel adhesion.     

The byssus of the zebra mussel (Dreissena polymorpha): spatial variations in protein composition

The notorious biofouling organism Dreissena polymorpha (the zebra mussel) attaches to a variety of surfaces using a byssus, a series of protein threads that connect the animal to adhesive plaques secreted onto hard substrata. Here, the use of matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) to characterize the composition of different regions of the byssus is reported. All parts of the byssus show mass peaks corresponding to small proteins in the range of 3.7-7 kDa, with distinctive differences between different regions. Indeed, spectra from thread and plaques are almost completely non-overlapping. In addition, several peaks were identified that are unique to the interfacial region of the plaque, and therefore likely represent specialized adhesive proteins. These results indicate a high level of control over the distribution of proteins, presumably with different functions, in the byssus of this freshwater species.     

The byssus of the zebra mussel (Dreissena polymorpha): spatial variations in protein composition

The notorious biofouling organism Dreissena polymorpha (the zebra mussel) attaches to a variety of surfaces using a byssus, a series of protein threads that connect the animal to adhesive plaques secreted onto hard substrata. Here, the use of matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) to characterize the composition of different regions of the byssus is reported. All parts of the byssus show mass peaks corresponding to small proteins in the range of 3.7–7 kDa, with distinctive differences between different regions. Indeed, spectra from thread and plaques are almost completely non-overlapping. In addition, several peaks were identified that are unique to the interfacial region of the plaque, and therefore likely represent specialized adhesive proteins. These results indicate a high level of control over the distribution of proteins, presumably with different functions, in the byssus of this freshwater species.     

Byssal proteins of the freshwater zebra mussel,Dreissena polymorpha

The freshwater zebra mussel (Dreissena polymorpha) is a notorious biofouling organism. It adheres to a variety of substrata underwater by means of a proteinaceous structure called the byssus, which consists of a number of threads with adhesive plaques at the tips. The byssal proteins are difficult to characterize due to extensive cross-linking of 3,4-dihydroxyphenylalanine (DOPA), which renders the mature structure largely resistant to protein extraction and immunolocalization. By inducing secretion of fresh threads and plaques in which cross-linking is minimized, three novel zebra mussel byssal proteins were identified following extraction and separation by gel electrophoresis. Peptide fragment fingerprinting was used to match tryptic digests of several gel bands against a cDNA library of genes expressed uniquely in the mussel foot, the organ which secretes the byssus. This allowed identification of a more complete sequence of Dpfp2 (D. polymorpha foot protein 2), a known DOPA-containing byssal protein, and a partial sequence of Dpfp5, a novel protein with several typical characteristics of mussel adhesive proteins.     

Green mussel Perna viridis L.: attachment behaviour and preparation of antifouling surfaces

The green mussel Perna viridis LINNE can be kept in simulated seawater for more than 6 months in good condition. The mussel forms many threads by secreting an adhesive protein from the foot, and attaches with more than 50 byssal threads, which makes most mussels clump together. In order to investigate the preparation of the antifouling surfaces toward green mussels, the attachment of mussels was tested using glass surfaces modified with silane coupling agents, together with non-treated material surfaces such as glass and silicone. The correlation between the attachment percentage and the mean number of the secreted byssus was highly significant, indicating that the mussel selects a favorable surface prior to the secretion of byssus. The relationships between the mussel attachment and the surface chemical parameters (surface free energy (sfe) and its dispersion and polar components) were examined based on a working hypothesis, which we have previously reported. The result of statistical regression test indicated that a certain correlation was found between the dispersion component and the mussel attachment, while the polar component did not correlate to the mussel attachment. The present surface chemical approach provided an additional clue for the preparation of ecologically clean antifouling materials that takes into account the combination of the wettability of both the marine adhesive proteins (MAP) and the modified surfaces.     

利用蛋白质组学手段鉴定新型贻贝足丝蛋白

贻贝通过足腺分泌特有的足丝并以此粘附于水下各种基质表面.贻贝足丝中富含各种粘附蛋白,其优异的水下粘附性能使其成为开发新型生物粘合剂的候选分子.厚壳贻贝足丝粘附能力强,本文采用尿素及盐酸胍抽提结合二维双向电泳技术（two-dimensional electrophoresis, 2-DE）,分别对厚壳贻贝足丝纤维和足丝盘的蛋白质进行分离及染色;采用串联质谱技术结合常规搜库和表达序列标签（EST) 数据库搜索,对分离获得的蛋白质点进行鉴定,从中获得了mfp-3、mfp-6、胶原蛋白以及3种未曾报道过的新型贻贝足丝蛋白成分.上述研究为深入了解厚壳贻贝足丝蛋白的分子多样性、探讨其粘附机理以及从中筛选具有应用前景的贻贝足丝蛋白奠定了基础.     

基于illumina测序的厚壳贻贝足组织转录组研究

贻贝足丝是贻贝足组织分泌的足丝蛋白形成的非细胞组织,具有在水环境下的极强粘附性能,是当前生物粘附剂及抗腐蚀材料的研发热点．为进一步了解贻贝足丝蛋白的分子多样性特征,采用新一代Illumina高通量测序平台对厚壳贻贝(Mytilus coruscus)足组织进行转录组测序,首次构建了厚壳贻贝足组织的转录组数据库．共计获得7 199 799 840 nt的碱基数据经过序列拼接和组装,获得88 825条unigene．对上述unigene开展了序列注释,共计37 007条unigene获得注释．在此基础上,经序列检索和比对,从中筛选出与目前已知的11种足丝蛋白同源的56条unigene序列并进行分析．结果表明,厚壳贻贝足丝蛋白具有明显的氨基酸偏好性,部分足丝蛋白具有重复序列,且厚壳贻贝足丝蛋白与其他种类的贻贝足丝蛋白具有较高的序列相似性．上述结果为后续贻贝足丝蛋白的批量鉴定以及在此基础上的贻贝足丝形成、固化以及粘附机制相关研究奠定了基础．     

Spatial distribution of proteins in the quagga mussel adhesive apparatus

The invasive freshwater mollusc Dreissena bugensis (quagga mussel) sticks to underwater surfaces via a proteinacious ‘anchor’ (byssus), consisting of a series of threads linked to adhesive plaques. This adhesion results in the biofouling of crucial underwater industry infrastructure, yet little is known about the proteins responsible for the adhesion. Here the identification of byssal proteins extracted from freshly secreted byssal material is described. Several new byssal proteins were observed by gel electrophoresis. Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry was used to characterize proteins in different regions of the byssus, particularly those localized to the adhesive interface. Byssal plaques and threads contain in common a range of low molecular weight proteins, while several proteins with higher mass were observed only in the plaque. At the adhesive interface, a plaque-specific ~8.1 kDa protein had a relative increase in signal intensity compared to the bulk of the plaque, suggesting it may play a direct role in adhesion.     

ADHESION IN BYSSALLY ATTACHED BIVALVES

The byssus is a structure produced by marine bivalve molluscs to adhere, usually permanently, to substrata under water. As the adhesion of synthetic polymers to surfaces is predictably compromised by the presence of water, particularly bulk water, it is of particular interest to discover the mechanism of byssal adhesion. In most species, the byssus consists of at least four essential components: acid mucopolysaccharides, adhesive protein, fibrous proteins, and an oxidative enzyme, polyphenoloxidase. The function of the mucopolysaccharide component is still uncertain, but it can conceivably be used by the animal as a temporary adhesive, a surface modifying agent, and/or a stabilizing filler for the permanent adhesive. The adhesive protein known as the polyphenolic protein in Mytilus is but a thin plaque applied to the substrate surface by the foot of the animal. The molecular and physical properties of this adhesive protein conform remarkably well to what one expects of an ideal synthetic polymer, i.e. high molecular weight, abundance of large and polar side chains, near-zero surface contact angle, and total water-insolubility after setting. The fibrous proteins constitute the major portion of the thread or ribbon-like material connecting the animal to the adhesive plaque on the substrate surface. These proteins are packed in ordered crystalline arrays, e.g. β-pleated sheet and collagen helix (in mytilids) as is to be expected from structural tensile elements of Nature. The enzyme polyphenoloxidase is presumed to induce intermolecular cross-linking of proteins in the fibrous and adhesive portions of the byssus. In Mytilus the natural substrates of the enzymc may be the dopa-containing polyphenolic protein and accessory gland protein.     

Investigation of the loss of byssus in Mytilus galloprovincialis from mussel farms in the Adriatic Sea

A fungal infection has been found in the mussel Mytilus galloprovincialis from Adriatic Sea mussel farms. The infection ultimately results in the loss of the byssus, with serious consequences for mussel farming yield. The pathogen provokes the progressive destruction of the foot muscles, also damaging related structures such as the intra-organism part of the byssus apparatus, resulting in loss of the thread component. The affected health status of the animal is also sustained by modifications in the digestive gland structure, ranging from hyperactivity to extreme cell death in the tubula. At present, the identity of the harmful fungus is unknown.     

Composition and ultrastructure of the byssus of Mytilus edulis

Three regions of the byssus of the marine mussel Mytilus edulis L. are distinct in structural organization at the macroscopic and microscopic level and in amino acid composition. The threads that emanate from the stem at the base of the foot are divided into two regions. The proximal, elastic region has a crimped, densely staining cortex enclosing an interior matrix of spiral fibers, and its amino acid composition reflects protein heterogeneity. The more distal, rigid region has a straight, tubular cortex surrounding an inner matrix of linearly arranged bundles of fibrils and has a composition approximating pure collagen. The plaque, or disc-shaped portion, which mediates attachment to various substrates, is distinguished by a surface matrix of collagen-like fibers similar to those of the thread region and anchored on an inner spongy matrix. Compositional evidence exists for a collagenous component, a catechol-rich protein, and at least one other accessory protein in the plaque.     

MECHANICAL PROPERTIES OF MUSSEL BYSSUS THREADS

The byssus threads of the common mussel, Mytilus edulis L.,have been tested mechanically and the results from the testsrelated to the ecology of the animal. The threads are mechanicallysimilar to other crystalline polymers such as polyethylene havinga modulus of about 10⁸N m^–2 and a long relaxation time.Resilience of 60% is similar to tendon; ultimate strain is aboutfive times that of tendon at 0.44. The thread is laid down witha prestrain of 10% and so guys the mussel in position. Calculationshows that a mussel with 50 byssus threads would be able toresist all but severe winter storms (Received 1 December 1978;     

Byssus thread strength in the mussel, Mytilus edulis

Mytilus edulis attaches to the substratum by means of a proteinaceous byssus complex. This consists of three portions: a root, embedded in the pedal tissues, a stem, continuous with the root but external to the body and a number of byssus threads attached proximally to the stem and distally to the substratum via adhesive discs. Byssus strength varies seasonally on the shore, in response to changes in wave action (Price, in press). As a decline in byssal attachment strength implies a decline in strength of the constituent threads, a study was undertaken to establish the extent to which byssus thread strength is determined by age. The ultimate tensile stress, ultimate tensile strain and Young's Modulus were measured in threads of known age and length and a stepped regression performed on the results. It was found that age and length correlate significantly with tensile stress and Young's Modulus. Length is a less important influence than age on tensile stress but has a greater effect than age on Young's Modulus. Tensile strain is independent of both length and age.     

Zebra mussel adhesion: structure of the byssal adhesive apparatus in the freshwater mussel, Dreissena polymorpha

The freshwater zebra mussel (Dreissena polymorpha) owes a large part of its success as an invasive species to its ability to attach to a wide variety of substrates. As in marine mussels, this attachment is achieved by a proteinaceous byssus, a series of threads joined at a stem that connect the mussel to adhesive plaques secreted onto the substrate. Although the zebra mussel byssus is superficially similar to marine mussels, significant structural and compositional differences suggest that further investigation of the adhesion mechanisms in this freshwater species is warranted. Here we present an ultrastructural examination of the zebra mussel byssus, with emphasis on interfaces that are critical to its adhesive function. By examining the attached plaques, we show that adhesion is mediated by a uniform electron dense layer on the underside of the plaque. This layer is only 10-20 nm thick and makes direct and continuous contact with the substrate. The plaque itself is fibrous, and curiously can exhibit either a dense or porous morphology. In zebra mussels, a graded interface between the animal and the substrate mussels is achieved by interdigitation of uniform threads with the stem, in contrast to marine mussels, where the threads themselves are non-uniform. Our observations of several novel aspects of zebra mussel byssal ultrastructure may have important implications not only for preventing biofouling by the zebra mussel, but for the development of new bioadhesives as well.     

Evidence for a repeating 3,4-dihydroxyphenylalanine- and hydroxyproline-containing decapeptide in the adhesive protein of the mussel, Mytilus edulis L

Previous work has shown that the permanent adhesive of the marine mussel Mytilus edulis is a protein containing large amounts of hydroxyproline (13%) and 3,4-dihydroxyphenylalanine (Dopa, 11%). The protein also known as the polyphenolic protein is produced and stored in the exocrine phenol gland of the mussel and deposited onto marine surfaces by the animal's foot during the formation of new adhesive plaques. The adhesive protein has been purified by a combination of ion exchange on sulfonylpropyl-Sephadex and gel filtration on low surface energy chromatographic media. Polyacrylamide gel electrophoresis of the protein at acidic pH shows it to consist of two components having a molecular weight of about 130,000. Treatment of the protein with clostridial collagenase reduced the molecular weight by less than 10%. The collagenase-resistant fragment contains most or all of the Hyp and Dopa. Trypsin treatment of the polyphenolic protein results in extensive degradation. The major tryptic peptide (80%) contains 10 amino acids including Hyp and Dopa and was shown by sequence analysis to be H2N-Ala-Lys-Pro-Ser-Tyr-Hyp-Hyp-Thr-Dopa-Lys-COOH. Calculations suggest that this and related sequences may be repeated as often as 75 times in the polyphenolic protein.     

Mechanism of an epibiont burden: Crepidula fornicata increases byssus thread production by Mytilus edulis

Epibionts of mussels can have detrimental effects on their basibionts,such as reduced growth rates, lower fecundity, increased mortalityand an enhanced risk of dislodgement of the overgrown bivalvesdue to stronger hydrodynamic forces. In blue mussels Mytilusedulis, the epibiotic American slipper limpet Crepidula fornicatareduces growth and survival. In a field experiment we testedthe hypothesis that an enhanced byssus thread production withhigh energetic costs for the mussels due slipper limpet epibiontsis the underlying mechanism for the epibiont burden. Byssusthread production in overgrown mussels was twice as high asin unfouled M. edulis (11 ± 0.9 and 5.4 ± 0.6byssus threads/mussel/day, respectively). A control experimentrevealed intermediate byssus thread production (8.4 ±0.8 byssus threads/mussel/day) in mussels cleaned of C. fornicataat the beginning of the experiments, indicating that C. fornicatais responsible for the effects observed. We conclude that increasedbyssus production in fouled M. edulis is a functional responseto higher drag caused by epibionts and that it is associatedwith increased energy expenditure that reduces allocation ofresources for other processes such as growth, reproduction andsurvival. Such indirect effects of epibionts, mediated by anenhanced byssus production, may be widespread in byssus-producingbivalves, with important implications for their population dynamics. (Received 12 January 2006; accepted 21 November 2006)     

Effects of artificial epibionts on byssogenesis,attachment strength,and movement in two size classes of the blue mussel,Mytilus edulis

Blue mussels (Mytilus edulis) can alter the strength of byssal attachment and move between and within mussel aggregations on wave‐swept shores, but this movement ability may be limited by epibiont fouling. We quantified the effects of artificial epibiont fouling on the production of byssal threads, attachment strength, and movement in two size classes of blue mussels. In a factorial experiment, large epibiont‐covered mussels produced more functional byssal threads (i.e., those continuous from animal to substrate) after 24 h than large unfouled and small fouled mussels, but not more than small unfouled mussels. Small unfouled mussels formed and released more byssus bundles compared to any other treatment group, which indicates increased movement. Conversely, epibiont fouling resulted in decreased numbers of byssus bundles shed, and therefore reduced movement in small mussels. Epibiont‐covered mussels started producing byssal threads sooner than unfouled mussels, while small mussels began producing byssal threads earlier compared to large mussels. Mean attachment strength from both size classes increased by 9.5% when mussels were artificially fouled, and large mussels had a 34% stronger attachment compared to small mussels. On the other hand, a 2.3% decrease in attachment strength was found with increasing byssus bundles shed. Our results suggest that fouling by artificial epibionts influences byssal thread production and attachment strength in large mussels, whereas epibionts on small mussels impact their ability to move. Mussels are able to respond rapidly to fouling, which carries implications for the dynamics of mussel beds in their intertidal and subtidal habitats, especially in relation to movement of mussels within and among aggregations.     

Interspecific comparison of the mechanical properties of mussel byssus

Byssally tethered mussels are found in a variety of habitats, including rocky intertidal, salt marsh, subtidal, and hydrothermal vents. One key to the survival of mussels in these communities is a secure attachment, achieved by the production of byssal threads. Although many studies have detailed the unique biomechanical properties of byssal threads, only a few prevalent species have been examined. This study assesses the variation in the mechanical properties of byssus in a broad range of mussel species from diverse environments, including intertidal and subtidal Mytilus edulis, Modiolus modiolus, Geukensia demissa, Bathymodiolus thermophilus, and Dreissena polymorpha. A tensometer was used to measure quasi-static and dynamic mechanical properties of individual threads, and several aspects of morphology were quantified. The results indicate that thread mechanical properties vary among mussel species, and several novel properties were observed. For example, of the species examined, D. polymorpha threads were the strongest, stiffest, least resilient, and fastest to recover after partial deformation. Threads of M. modiolus were characterized by the presence of two distinct yield regions prior to tensile failure. This comparative study not only provides insight into the ecological limitations and evolution of mussels, but also suggests new models for the design of novel biomimetic polymers.     

Ultrastructural and cytochemical study on the enzyme gland of the foot of a mollusc

The enzyme gland of the foot of the mussel Mytilus has been so far considered a gland producing and exporting a phenol oxidase catalysing the general tanning processes of byssus threads. In contrast, the present study shows that this gland produces mainly secretory granules which form the cortical layers of byssus threads. Cytochemical methods at the ultrastructural level (phosphotungstic acid at low pH, silver methenamine, periodic acid-thiosemicarbazide-silver proteinate, silver methenamine for sulphur-rich proteins demonstration) and enzyme digestion tests (pepsin, trypsin, alpha-chymotrypsin) indicate that secretory granules contain glycoproteins rich in sulphydryl groups and in aromatic amino acids. The cytochemical demonstration of phenol oxidase shows that enzyme activity is present in Golgi complex, whereas it is absent in secretory granules. For this reason, phenol oxidase does not seem to be exported and utilized for tanning of byssus threads, but it might rather be involved in the elaboration and tanning of the content of the secretory granules in the enzyme gland itself.