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.     

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.     

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.     

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.     

Location and analysis of byssal structural proteins of Mytilus edulis

The acellular attachment organ (byssus) of the marine mussel Mytilus edulis L. is composed of threads that emanate from the body of the mussel to adhesive discs that anchor the threads to rocks, sand and other mussels. Three proteins have been purified by immunohistological methods and located to specific regions of the byssus. A collagenous protein with subunit molecular weights of 53,000, 55,000 and 65,000 is found in the matrix of the elastic thread region. Its 73,000-MW precursor was extracted from foot glands in the area proximal to the animal body and was identified by immune cross-reactivity. A cystine-rich, acidic protein was found in all regions of the byssus associated with a third protein, the polyphenolic protein. The L-dopa-containing polyphenolic protein appears in the cortex of the entire thread and adhesive plaque and at the substrate-plaque interface. Antiserum to this protein stains spherical vesicles in the phenol gland of the foot. Using immuno-electrophoretic methods, the polyphenolic protein and the cystine-rich protein were shown to form high molecular weight aggregates with aging of the byssus.     

Byssogenesis in the juvenile pink heelsplitter mussel,Potamilus alatus (Bivalvia: Unionidae)

The North American pink heelsplitter (Potamilus alatus) differs from most freshwater mussels in China by the ability to secrete an ephemeral byssus during its juvenile stage. In the present study, light microscopy, scanning electron microscopy (SEM), and transmission electron microscopy (TEM) were used to investigate this ephemeral byssal structure, and amino acid composition was analyzed and compared with that of other species. The results revealed that the byssus consists of a long byssal thread and a few adhesive plaques which are randomly set up along the thread and assembled by petioles. There is a thin but distinctive cuticle with a continuous homogeneous matrix surrounding the byssal thread. Structural variation occurred when the byssal thread was differentially stretched. Four‐stranded helical primary fasciculi, which form a stable rope‐like structure, become evident after removal of the cuticle. The primary fasciculi consist of bundles of hundreds of parallel secondary fasciculi, each measuring about 5 μm in diameter. All evidence indicates that the byssus of the pink heelsplitter has a significantly different macrostructure and microstructure than the permanent byssus of the marine mussel Mytilus. Byssogenesis ceases when juveniles exceed 30 mm in length, although it varies greatly even among juveniles of similar size. Byssus formation is influenced by substrate type. The unique characteristics of the byssus have important advantages for survival, transition, and aggregation during the early life history. This study not only provides first insight into the structure of the ephemeral byssus and its relationship to freshwater mussel development and growth, but also suggests possibilities for the synthesis of novel biopolymer materials particularly useful in freshwater ecosystems. J. Morphol. 276:1273–1282, 2015. © 2015 Wiley Periodicals, Inc.     

Probing the adhesive footprints of Mytilus californianus byssus

California mussels Mytilus californianus owe their tenacity to a holdfast known as the byssus, a fibrous extracellular structure that ends distally in flattened adhesive plaques. The "footprints" of freshly secreted plaques deposited onto glass coverslips were shown by matrix-assisted laser desorption ionization time of flight mass spectrometry to consist chiefly of proteins ranging in mass from 5200 to 6700 Da. These proteins, variants of a family known as mcfp3 (M. californianus foot protein 3), were purified from acetic acid/urea extracts of plaques and foot tissue. Mcfp3 appears to sort into fast and slow electrophoretic variants. Both are rich in Gly and Asn and exhibit post-translational hydroxylation of Tyr and Arg to Dopa and 4-hydroxyarginine, respectively, with the fast variant containing more than twice as much Lys + Arg. Both the slow and fast variants were partially sequenced from the N terminus, and the complete sequences of 12 variants were deduced from cDNA using degenerate oligonucleotides, PCR, and rapid amplification of cDNA ends. Mcfp3s are highly polar molecules and contain up to 28 mol % Dopa, which remains intact and may be crucial for adhesion to metal and mineral surfaces.     

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.     

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.     

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.     

一种新型贻贝足丝抗氧化蛋白的原核重组表达及功能

贻贝足丝及其足丝蛋白相关研究对于开发新型水下生物粘附剂具有重要的仿生学意义。足丝蛋白在其粘附过程中需要维持一定的还原态,而目前已报道的足丝抗氧化蛋白仅有MFP-6。此前在厚壳贻贝足丝中鉴定到一种新型的富含半胱氨酸和甘氨酸的足丝蛋白质,该蛋白质被命名为Cys/Gly-Rich-Protein（CGRP）,但是CGRP蛋白在足丝中的作用及机制尚不明确。为此,针对CGRP蛋白,在序列分析基础上,利用原核重组表达手段获得其重组蛋白质,采用2,2-联苯基-1-苦基肼基（2,2-diphenyl-1-picryl hydrazyl radical,DPPH）法检测CGRP重组蛋白经不同条件处理后的抗氧化活性。序列分析结果表明,CGRP蛋白含16.5%的半胱氨酸和10%的甘氨酸,其序列中含有两段半胱氨酸位置保守的重复序列,结构预测表明,其优势构象以无规卷曲为主。同源蛋白质搜索结果表明,CGRP蛋白在数据库中尚无高同源性蛋白质存在。通过密码子优化结合原核重组表达策略成功表达出CGRP重组蛋白,所获得的CGRP重组蛋白具有明显的抗氧化活性,且该活性在其半胱氨酸还原后显著增强(0.91±0.05 vs 0.71±0.11, P<0.01)而在半胱氨酸烷基化之后显著下降(0.08±0.03 vs 0.71±0.11, P<0.01),表明CGRP蛋白的抗氧化活性与其序列中半胱氨酸的自由巯基有关。本研究提示,CGRP蛋白是足丝中一种新的具有抗氧化功能的蛋白质,在足丝粘附过程中推测与MFP-6一起参与了富含多巴的足丝粘附蛋白的还原态维持,对贻贝足丝在固化和粘附过程中防止提前粘附具有重要意义。     

Proteins in load-bearing junctions: the histidine-rich metal-binding protein of mussel byssus

Building complex load-bearing scaffolds depends on effective ways of joining functionally different biomacromolecules. The junction between collagen fibers and foamlike adhesive plaques in mussel byssus is robust despite the strikingly dissimilar connected structures. mcfp-4, the matrix protein from this junction, and its presecreted form from the foot tissue of Mytilus californianus were isolated and characterized. mcfp-4 has a mass of approximately 93 kDa as determined by MALDI-TOF mass spectrometry. Its composition is dominated by histidine (22 mol %), but levels of lysine, arginine, and aspartate are also significant. A small amount of 3,4-dihydroxyphenyl-l-alanine (2 mol %) can be detected by amino acid analysis and redox cycling assays. The cDNA-deduced sequence of mcfp-4 reveals multiple variants with highly repetitive internal structures, including approximately 36 tandemly repeated His-rich decapeptides (e.g., HVHTHRVLHK) in the N-terminal half and 16 somewhat more degenerate aspartate-rich undecapeptides (e.g., DDHVNDIAQTA) in the C-terminal half. Incubation of a synthetic peptide based on the His-rich decapeptide with Fe3+, Co2+, Ni2+, Zn2+, and Cu2+ indicates that only Cu is strongly bound. MALDI-TOF mass spectrometry of the peptide modified with diethyl pyrocarbonate before and after Cu binding suggests that histidine residues dominate Cu binding. In contrast, the aspartate-rich undecapeptides preferentially bind Ca2+. mcfp-4 is strategically positioned to function as a macromolecular bifunctional linker by using metal ions to couple its own His-rich domains to the His-rich termini of the preCOLs. Ca2+ may mediate coupling of the C-terminus to other calcium-binding plaque proteins.     

Mussel glue fromMytilus californianus Conrad: a comparative study

Summary Marine mussels secrete a byssus in order to attach to solid surfaces in the sea. The polyphenolic protein is the glue in the adhesive plaques of the byssus. InMytilus californianus, the polyphenolic protein has an apparent molecular weight of 85,000±5,000 and is rich in the amino acids lysine, 3,4-dihydroxyphenylalanine, serine, threonine, and hydroxyproline. In composition it resembles the polyphenolic protein ofM. edulis (M _r=125,000), although theM. edulis protein contains significantly less isoleucine and more alanine. Tryptic digestion ofM. californianus polyphenolic protein revealed two types of repeating decapeptides (1) (Ser/Thr)-Thr-(Tyr/Dopa)-Hyp-Hyp-Thr-Dopa-Lys-Hyp-Lys and (2) Ile-(Thr/Ser)-(Tyr/Dopa)-Hyp-Hyp-Thr-Dopa-Lys-Hyp-Lys. Residues 2 to 8 are identical with residues 4–10 inM. edulis decapeptides.Abbreviation Dopa 3,4hydroxyphenylalanine     

Environmental post-processing increases the adhesion strength of mussel byssus adhesive

Marine mussels (Mytilus trossulus) attach to a wide variety of surfaces underwater using a protein adhesive that is cured by the surrounding seawater environment. In this study, the influence of environmental post-processing on adhesion strength was investigated by aging adhesive plaques in a range of seawater pH conditions. Plaques took 8–12 days to achieve full strength at pH 8, nearly doubling in adhesion strength (+94%) and increasing the work required to dislodge (+59%). Holding plaques in low pH conditions prevented strengthening, causing the material to tear more frequently under tension. The timescale of strengthening is consistent with the conversion of DOPA to DOPA-quinone, a pH dependent process that promotes cross-linking between adhesive proteins. The precise arrangement of DOPA containing proteins away from the adhesive-substratum interface emphasizes the role that structural organization can have on function, an insight that could lead to the design of better synthetic adhesives and metal-coordinating hydrogels.     

厚壳贻贝足丝盘黏附蛋白mcofp-3的重组真核表达

厚壳贻贝(Mytilus coruscus)黏附蛋白分子mcofp-3(M.coruscusfoot protein-3)主要分布于贻贝足丝盘,贻贝在水环境下的黏附过程中起到关键作用,但因其难溶于水且在贻贝足丝盘中含量极低,故妨碍了对其进行深入研究。为建立厚壳贻贝足丝蛋白mcofp-3的真核表达体系,并获得足够的mcofp-3黏附蛋白进行后续研究,采用酵母表达体系对mcofp-3进行了重组表达。通过PCR方法克隆厚壳贻贝的mcofp-3基因,构建mcofp-3的酵母真核表达载体pVT102U/α/mcofp-3,鉴定结果表明,重组表达质粒pVT102U/α/mcofp-3由真核载体pVT102U/α和mcofp-3的成熟肽DNA片段组成,插入的mcofp-3成熟肽DNA片段与预期序列完全一致;采用LiAC转化法将重组表达质粒转化到S78酿酒酵母中,经过RT-PCR分析以及1.0%的琼脂糖凝胶电泳检测,结果表明,重组的mcofp-3得到了成功的转录;发酵菌液经阳离子交换柱及高效液相色谱分离,以及Tris-Tricine-SDS-PAGE检测,结果表明,重组的厚壳贻贝黏附蛋白分子mcofp-3得到了成功表达,表达...     

Adsorption behavior and enzymatically or chemically induced cross‐linking of a mussel adhesive protein

The adsorption behavior of the mussel adhesive protein Mytilus edulis foot protein‐1 (Mefp‐1) has been investigated on a negatively charged polar SiO₂ surface and an electrically inert non‐polar CH₃‐terminated thiolated gold surface. How the structure of adsorbed Mefp‐1 is changed upon chemically and enzymatically induced cross‐linking using sodium periodate (NaIO₄) and catechol oxidase, both of which transform DOPA residues in Mefp‐1 into highly reactive o‐quinones, was also investigated. The results are compared with those resulting from addition of Cu²⁺ to adsorbed Mefp‐1, which forms complexes with and catalyses oxidation of DOPA residues, previously suggested to participate in the cohesive and adhesive properties of the byssus thread of M. edulis. By combining surface plasmon resonance (SPR) and quartz crystal microbalance/dissipation (QCM‐D) measurements, the effects of these agents were investigated with respect to changes in the amount of coupled water, the viscoelastic properties (rigidity) and the hydrodynamic thickness of the protein adlayers. The layer of Mefp‐1 formed on the bare CH₃‐terminated surface was elongated, flexible and coupled hydrodynamically a substantial amount of water, whereas Mefp‐1 formed a rigidly attached adlayer on the SiO₂ surface. Upon enzymatically and chemically induced cross‐linking of Mefp‐1 formed on the CH₃ surface, the rigidity of the adlayer(s) increased significantly. A similar increase in the rigidity was observed also upon addition of Cu²⁺, suggesting that the high level of metal ions present in the byssus thread might be essential for the cohesive and adhesive properties of this protein. For the mass‐uptake kinetics of enzymatically induced cross‐linking, three different phases were observed and are interpreted as competition between binding of protein and release of coupled water. For the reaction with NaIO₄ and Cu²⁺, only release of water affected the coupled mass. The importance of this type of information for an improved understanding of the strong adhesion and cohesive properties in marine environments is discussed.     

Preferential manganese accumulation in dreissenid byssal threads

The elemental composition of byssal threads from two freshwater mussels Dreissena polymorpha (zebra) and Dreissena bugensis (quagga) has been determined by proton-induced X-ray emission spectroscopy. Sulphur and manganese are present at 30–100-fold higher concentrations in the threads than in ambient waters of Lake Erie. Calcium, phosphorus and copper levels are also somewhat enhanced in byssus. Since dreissenid byssus is not mineralized, Mn may be organometallically complexed to the functional side chains of byssal proteins.     

Byssus of the Green-Lipped Mussel <Emphasis Type="Italic">Perna viridis</Emphasis> (Linnaeus) as a Biomonitoring Material for Zn

Recently, Yap et al. (2003) suggested that the byssus of the green-lipped mussel Perna viridis can be a biomonitoring material for Zn although further validation is required. In this work, we did a simple correlation study between Zn concentrations in the byssus (and soft tissue) and in different geochemical fractions of the sediment. A significant (P < 0.01) Pearsons correlation coefficient (R = 0.84) between the Zn concentrations in the byssus and soft tissue indicated that the Zn level in the byssus is highly correlated to its level in the soft tissue and that the byssus could act as an excretion route for Zn. Higher R-values were found between the byssus-easily or freely, leachable and exchangeable, byssus-acid-reducible, byssus-oxidizable-organic and byssus-nonresistant fractions of the sediment, and the byssus-Zn concentration in the total sediment when compared to those found between the soft tissue and the same geochemical fractions. This indicated that the byssus was more reflective of Zn contamination in the field environment than the soft tissue. Therefore, the data further support the use of the byssus as a biomonitoring material for Zn as was originally suggested by Yap et al. [3].Original English Text Copyright © 2005 by Biologiya Morya, Yap, Ismail, Tan.This article was submitted by the authors in English.     

盐度对企鹅珍珠贝足丝分泌的影响

企鹅珍珠贝（Pteria penguin）是生产附壳珍珠的大型海水经济贝类,其依靠强壮的足丝将自身固定在硬质基底上,抵抗水流的冲击和抵御被捕食等。足丝分泌和足丝的形状很容易受到环境的影响,本实验采用盐度30为低盐度组、盐度35为中盐度组和盐度40为高盐度组,研究这3种盐度对企鹅珍珠贝足丝分泌、足丝直径和足丝拉力的影响,通过单因素方差分析法（LSD法）分析这三个足丝相关指标在3种盐度组间是否存在显著性差异。结果显示,3种盐度下企鹅珍珠贝足丝附着率无显著差异,但在整个实验周期72 h内,中盐度组的足丝分泌总数为（48.7 ± 15.1）根,显著高于低盐度组的（24.7 ± 5.0）根和高盐度组的（13.3 ± 1.5）根。在实验的前6 h内,中盐度组的足丝首次附着率显著高于低盐度组和高盐度组（P < 0.05）,但在后续的12 h、18 h、30 h、42 h、54 h和66 h这6个时间点,3个盐度组的足丝首次附着率均无显著性差异。足丝直径未受盐度变化的影响,但盐度对足丝拉力具有显著影响,中盐度组的足丝拉力显著高于低盐度组和高盐度组（P < 0.05）。上述结果表明,企鹅珍珠贝为适应一定范围内盐度的改变,会在短时间内通过抑制足丝分泌来减少能量消耗,随着对环境的适应足丝分泌会恢复。盐度影响足丝分泌且对足丝拉力影响显著,但对足丝直径无明显影响。本研究可以为企鹅珍珠贝养殖及珍珠插核培育提供理论基础。     

Byssus production rate of the White Sea blue mussel <Emphasis Type="Italic">Mytilus edulis</Emphasis> (Linnaeus, 1758) in the presence of metabolites of some hydrobionts

The byssus production of the blue mussel Mytilus edulis L. was studied in the laboratory in the presence of the metabolites of the following animals: a predator (a starfish Asterias rubens L.) and several species competing with the mussel in White Sea fouling communities (a bivalve Hiatella arctica L. and a solitary ascidian Styela rustica L.). The byssus threads and attachment plaques produced by each mussel per day were counted. The number of byssus threads and plaques was smallest in pure sea water and in the presence of metabolites produced by conspecific individuals.