A Glycosylated Byssal Precursor Protein from the Green Mussel Perna viridis with Modified Dopa Side-chains

Foot tissue of the green mussel Perna viridis contains a variety of byssal precursor proteins with the unusual redox-active amino acid, Dopa (L-β-3,4-dihydroxyphenyl-α-alanine). Eight proteins were detectable in acidic extracts of the Perna foot by a redox cycling assay with nitroblue tetrazolium. In one of these, however, P. viridis foot protein-1 (Pvfp-1), activity was not due to Dopa, but to another redox-active derivative. Based on specific colorimetric derivatization with Arnow's reagent, ninhydrin and phenylisothiocyanate (Edman), mass spectrometry, the redox-active derivative in Pvfp-1 is not consistent with any known modification. Another uncommon modification of Pvfp-1 involves O-glycosylation of threonine by mannose, glucose or fucose. As in previously characterized fp-1s, the primary sequence of the Pvfp-1 (apparent mass 89?kDa) has two consensus decapeptide motifs; one is APPKPX₁TAX₂K and the other is APPPAX₁TAX₂K, where P is Pro/Hyp, and X₁ and X₂ are difucosylated threonine and a redox sensitive derivative of tyrosine or Dopa, respectively. Of these two unusual residues, X₂ is unique to Pvfp-1, whereas O-glycosylated Thr has been previously detected in freshwater mussel fp-1. The sequence homology of Pvfp-1 with the common structural motifs of the fp-1 protein family strongly suggests that the Pvfp-1 functions as the byssal coating (lacquer) protein.     

Glycosylated Hydroxytryptophan in a Mussel Adhesive Protein from Perna viridis

The 3,4-dihydroxyphenyl-l-alanine (Dopa)-containing proteins of mussel byssus play a critical role in wet adhesion and have inspired versatile new synthetic strategies for adhesives and coatings. Apparently, however, not all mussel adhesive proteins are beholden to Dopa chemistry. The cDNA-deduced sequence of Pvfp-1, a highly aromatic and redox active byssal coating protein in the green mussel Perna viridis, suggests that Dopa may be replaced by a post-translational modification of tryptophan. The N-terminal tryptophan-rich domain of Pvfp-1 contains 42 decapeptide repeats with the consensus sequences ATPKPW₁TAW₂K and APPPAW₁TAW₂K. A small collagen domain (18 Gly-X-Y repeats) is also present. Tandem mass spectrometry of isolated tryptic decapeptides has detected both C²-hexosylated tryptophan (W₁) and C²-hexosylated hydroxytryptophan (W₂), the latter of which is redox active. The UV absorbance spectrum of W₂ is consistent with 7-hydroxytryptophan, which represents an intriguing new theme for bioinspired opportunistic wet adhesion.The amino acid 3,4-dihydroxyphenyl-l-alanine (Dopa)³ occurs in many proteins of the mussel holdfast or byssus (1, 2) and has recently been incorporated into mussel-inspired synthetic polymers with versatile adhesive consequences (3–7). One byssal protein in particular, mussel foot protein-1 (Mfp-1), has been investigated from over 15 mussel byssi, where it protectively coats compliant collagen-like proteins in the thread core (8–11). Mfp-1s typically contain 10–15 mol % Dopa in a highly conserved repeating peptide structure (8). In the blue mussel Mytilus edulis fp-1 (Mefp-1), for example, the consensus decapeptide AKPSYPPTYK is repeated over 70 times in tandem, and much of the tyrosine (Y) is converted to Dopa (Y*) (Fig. 1). In stark contrast to this, only trace levels of Dopa were detected in Pvfp-1 from the green mussel Perna viridis (Linnaeus 1758) (12), a notoriously invasive fouling species originally from the Indo-Pacific region (13). Because P. viridis fp-1 (Pvfp-1) and its homologue, Mefp-1, are both strongly aromatic, quinogenic, and composed of highly polar decapeptide repeats (12), identifying the Dopa-mimetic substitutes in Pvfp-1 has been a matter of considerable interest.Open in a separate windowFIGURE 1.The common blue mussel M. edulis and green mussel P. viridis are shown with attached byssal threads. Distinct consensus decapeptide repeat sequences are associated with the repeat domains in fp-1 foot proteins of the two species. The amino acid Dopa (Y*, right panel) is prominent in mefp-1 repeats but absent from Pvfp-1. O denotes trans-4-hydroxyprolines. Residues denoted as X₁ and X₂ are shown by this study to be derived from tryptophan.     

Mapping chemical gradients within and along a fibrous structural tissue, mussel byssal threads

The byssal thread of a mussel is an extraorganismic connective tissue that exhibits a striking end-to-end gradient in mechanical properties and thus provides a unique opportunity for studying how gradients are made. Mfp-1 (Mytilus foot protein-1) is a conspicuous component of the protective outer cuticle of byssal threads given its high 3,4-dihydroxyphenylalanine (Dopa) content at 10-15 mol %. Amino acid analysis of mfp-1 extracted from successive foot sections of Mytilus galloprovincialis reveals a post-translationally mediated gradient with highest Dopa levels present in mfp-1 from the accessory gland near the tip of the foot decreasing gradually toward the base. The Dopa content of successive segments of byssal threads decreases from the distal to the proximal end and thus reflects the trend of mfp-1 in the foot. Inductively coupled plasma analysis indicates that certain metal ions including iron follow the trend in Dopa along the thread. Energy-dispersive x-ray spectrometry showed that iron, when present, was concentrated in the cuticle of the threads but sparse in the core. The axial iron gradient appears most closely correlated with the Dopa gradient. The direct incubation of mussels and byssal threads in Fe(3+) supplemented seawater showed that byssal threads are unable to sequester iron from the seawater. Instead, particulate/soluble iron is actively taken up by mussels during filter feeding and incorporated into byssal threads during their secretion. Our results suggest that mussels may exploit the interplay between Dopa and metals to tailor the different parts of threads for specific mechanical properties.     

Adhesion of mussel foot protein mefp-5 to mica: an underwater superglue

Mussels have a remarkable ability to attach their holdfast, or byssus, opportunistically to a variety of substrata that are wet, saline, corroded, and/or fouled by biofilms. Mytilus edulis foot protein-5 (Mefp-5) is one of several proteins in the byssal adhesive plaque of the mussel M. edulis. The high content of 3,4-dihydroxyphenylalanine (Dopa) (～30 mol %) and its localization near the plaque-substrate interface have often prompted speculation that Mefp-5 plays a key role in adhesion. Using the surface forces apparatus, we show that on mica surfaces Mefp-5 achieves an adhesion energy approaching E(ad) = ～-14 mJ/m(2). This exceeds the adhesion energy of another interfacial protein, Mefp-3, by a factor of 4-5 and is greater than the adhesion between highly oriented monolayers of biotin and streptavidin. The adhesion to mica is notable for its dependence on Dopa, which is most stable under reducing conditions and acidic pH. Mefp-5 also exhibits strong protein-protein interactions with itself as well as with Mefp-3 from M. edulis.     

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．     

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.     

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.     

Conservative Structure of the Plaque Matrix Protein of Mussels in the Genus Mytilus

: The complementary DNA encoding the byssal plaque matrix protein (fp-2) of the mussel Mytilus coruscus was isolated. The predicted amino acid sequence (474 amino acids) consists of four parts: the signal peptide, the amino-terminal nonrepetitive domain, the central repetitive domain containing 11 repeats of an epidermal growth factor–like motif, and the carboxy-terminal nonrepetitive domain. The amino acid sequence is 82.7%, similar to that of fp-2 of Mytilus galloprovincialis, and the basic structure including number and motif of repeats is highly conservative. Amino acid substitutions are less frequent in ``consensus positions' of the central repetitive domain (13.1%), and most of them are changes from irregular amino acids to regular ones. Thus, the structure of fp-2 was found to be conservative between species. It was presumed that the basic structure of fp-2 is unchangeable to maintain the flexible and durable matrix structure and that variation is not required because fp-2 is protected by other surface proteins.     

Coating proteins: structure and cross-linking in fp-1 from the green shell mussel Perna canaliculus

The protein family known as fp-1 provides mussel byssus with a protective outer coating and has drawn much attention for its water resistant bioadhesive properties in vitro. A new fp-l isolated from the green shell mussel Perna canaliculus (pcfp-1) reveals a composition dominated by only four amino acids: 3,4-dihydroxyphenyl-L-alanine (dopa), lysine, proline, and valine at approximately 20 mol % each. SDS-PAGE and MALDI-TOF mass spectrometry detected size variants at 48 and 52 kDa in preparations of purified Pcfp-1. The N-terminal sequence enabled construction of oligonucleotide primers for PCR and RACE-derived cDNAs from which the complete sequence of four variants was deduced. pcfp-1 deviates from all known homologues in other mussels in several notable respects: its mass is half, most of its sequence is represented by 75 tandem repeats of a tetrapeptide, i.e., PY*VK, in which Y* is dopa, prolines are not hydroxylated, and thiolate cysteines are clustered in homologous sequences at both the amino and carboxy termini. Amino acids in the repeat sequence show a striking resemblance to proline-rich cell wall proteins with tandemly repeated PPVYK pentapeptides [Hong, J. C., Nagao, R. T., and Key, J. L. (1987) J. Biol. Chem. 262, 8367-8376]. Cysteine plays a key role in cross-linking pcfp-1 by forming adducts with dopaquinone. Significant 5-S-cysteinyldopa and smaller amounts of 2-S-cysteinyldopa were detected in hydrolysates of the byssal threads of P. canaliculus. The cross-links could also be formed by oxidation of pcfp-1 in vitro using mushroom tyrosinase. Cysteinyldopa cross-links were present in trace amounts only in the byssus of other mussel species.     

Mini-review: The role of redox in Dopa-mediated marine adhesion

3, 4-Dihydroxyphenylanine (Dopa)-containing proteins are key to wet adhesion in mussels and possibly other sessile organisms also. However, Dopa-mediated adhesive bonding is a hard act to follow in that, at least in mussels, bonding depends on Dopa in both reduced and oxidized forms, for adhesion and cohesion, respectively. Given the vulnerability of Dopa to spontaneous oxidation, the most significant challenge to using it in practical adhesion is controlling Dopa redox in a temporally- and spatially defined manner. Mussels appear to achieve such control in their byssal attachment plaques, and factors involved in redox control can be measured with precision using redox probes such as the diphenylpicryl hydrazyl (DPPH) free radical. Understanding the specifics of natural redox control may provide fundamentally important insights for adhesive polymer engineering and antifouling strategies.     

Mini-review: The role of redox in Dopa-mediated marine adhesion

3, 4-Dihydroxyphenylanine (Dopa)-containing proteins are key to wet adhesion in mussels and possibly other sessile organisms also. However, Dopa-mediated adhesive bonding is a hard act to follow in that, at least in mussels, bonding depends on Dopa in both reduced and oxidized forms, for adhesion and cohesion, respectively. Given the vulnerability of Dopa to spontaneous oxidation, the most significant challenge to using it in practical adhesion is controlling Dopa redox in a temporally- and spatially defined manner. Mussels appear to achieve such control in their byssal attachment plaques, and factors involved in redox control can be measured with precision using redox probes such as the diphenylpicryl hydrazyl (DPPH) free radical. Understanding the specifics of natural redox control may provide fundamentally important insights for adhesive polymer engineering and antifouling strategies.     

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.     

Linking adhesive and structural proteins in the attachment plaque of Mytilus californianus

The byssal attachment of California mussels Mytilus californianus provides secure adhesion in the presence of moisture, a feat that still eludes most synthetic polymers. Matrix-assisted laser desorption ionization mass spectrometry was used to probe the footprints of byssal attachment plaques on glass cover slips for adhesive proteins. Besides the abundant mcfp-3 protein family (Zhao, H., Robertson, N. B., Jewhurst, S. A., and Waite, J. H. (2006) J. Biol. Chem. 281, 11090-11096), two new proteins, mcfp-5 and mcfp-6, with masses of 8.9 kDa and 11.6 kDa, respectively, were identified in footprints, partially characterized and completely sequenced from a cDNA library. mcfp-5 resembles mcfp-3 in its basic pI and abundant 3,4-dihydroxyphenyl-L-alanine (Dopa; 30 mol %), but is distinct in two respects: it is more homogeneous in primary sequence and is polyphosphorylated. mcfp-6 is basic and contains a small amount of Dopa (<5 mol %). In contrast to mcfp-3 and -5, tyrosine prevails at 20 mol %, and cysteine is present at 11 mol %, one-third of which remains thiolate. Given the oxidative instability of Dopa and cysteine at pH 8.2 (seawater), we tested the hypothesis that thiols serve to scavenge dopaquinones by adduct formation. Plaque footprints were hydrolyzed and screened for cysteine dopaquinone adducts using phenylboronate affinity chromatography. 5-S-Cysteinyldopa was detected at nearly 1 mol %. The results suggest that mcfp-6 may provide a cohesive link between the surface-coupling Dopa-rich proteins and the bulk of the plaque proteins.     

Population connectivity and genetic structure of Asian green mussel,Perna viridis along Indian waters assessed using mitochondrial markers

Molecular Biology Reports - Perna viridis (Linnaeus, 1758), the Asian green mussel, belonging to the family Mytilidae is widely distributed along the Indian coast. The species is majorly found in...     

Metallothionein cDNA, promoter, and genomic sequences of the tropical green mussel, Perna viridis.

The primary structure of the cDNA and metallothionein (MT) genomic sequences of the tropical green mussel (Perna viridis) was determined. The complete cDNA sequences were obtained using degenerate primers designed from known metallothionein consensus amino acid sequences from the temperate species Mytilus edulis. The amino acid sequences of P. viridis metallothionein deduced from the coding region consisted of 72 amino acids with 21 cysteine residues and 9 Cys-X-Cys motifs corresponding to Type I MT class of other species. Two different genomic sequences coding for the same mRNA were obtained. Each putative gene contained a unique 5'UTR and two unique introns located at the same splice sites. The promoters for both genes were different in length and both contained metal responsive elements and active protein-binding sites. The structures of the genomic clones were compared with those of other species. J. Exp. Zool. 284:445-453, 1999.     

Boronate Complex Formation with Dopa Containing Mussel Adhesive Protein Retards pH-Induced Oxidation and Enables Adhesion to Mica

The biochemistry of mussel adhesion has inspired the design of surface primers, adhesives, coatings and gels for technological applications. These mussel-inspired systems often focus on incorporating the amino acid 3,4-dihydroxyphenyl-L-alanine (Dopa) or a catecholic analog into a polymer. Unfortunately, effective use of Dopa is compromised by its susceptibility to auto-oxidation at neutral pH. Oxidation can lead to loss of adhesive function and undesired covalent cross-linking. Mussel foot protein 5 (Mfp-5), which contains ∼30 mole % Dopa, is a superb adhesive under reducing conditions but becomes nonadhesive after pH-induced oxidation. Here we report that the bidentate complexation of borate by Dopa to form a catecholato-boronate can be exploited to retard oxidation. Although exposure of Mfp-5 to neutral pH typically oxidizes Dopa, resulting in a>95% decrease in adhesion, inclusion of borate retards oxidation at the same pH. Remarkably, this Dopa-boronate complex dissociates upon contact with mica to allow for a reversible Dopa-mediated adhesion. The borate protection strategy allows for Dopa redox stability and maintained adhesive function in an otherwise oxidizing environment.     

The glue protein of ribbed mussels (Geukensia demissa): a natural adhesive with some features of collagen

Summary The Atlantic ribbed musselGeukensia (Modiolus)demissa attaches itself to the roots of cord grass and other hard objects in tidal salt marshes by spinning adhesive byssal threads. The precursor of a protein apparently present in the adhesive plaques of the threads was isolated in quantity from the foot of the mussel. The protein has an apparent molecular weight of 130000, a pI of 8.1, and contains a high proportion of Gly, Glu/Gln, Lys and 3,4-dihydroxyphenyl-l-alanine (DOPA). Sequence of tryptic peptides suggests a pattern of repeated motifs, such as: Gly-DOPA-Lys, and X-Gly-DOPA-Y-Z-Gly-DOPA/Tyr-Lys, where X is Thr or Ala in octapeptides and Gln-Thr in nonapeptides. Y is variable, but more often than not hydrophobic; and Z is frequently Pro or 4-trans-hydroxyproline (Hyp). The presence of Pro-Gly and Hyp-Gly sequences of -hydroxylysine in the protein is reminiscent of typical collagens; however, the protein is not labile to clostridial collagenase, nor does collagen cross-react with antibodies raised against the mussel protein. Unlike typical collagens, Gly probably occurs only at every 4th or 5th residue in this unusual mussel protein.Abbreviations Anti-Gdfp anti-G. demissa foot protein - Dopa 3,4-dihydroxyphenylalanine - CTAB cetyltrimethylammonium bromide - HPLC high performance liquid chromatography - PAGE polyacrylamide gel electrophoresis Supported by grants from the National Science Foundation (DMB 8500301) and the Office of Naval Research (N00014-86K-0717)     

Enhanced production of Dopa-incorporated mussel adhesive protein using engineered translational machineries

Mussel adhesive proteins (MAPs) have great potential as bioglues, particularly in wet conditions. Although in vivo residue-specific incorporation of 3,4-dihydroxyphenylalanine (Dopa) in tyrosine-auxotrophic Escherichia coli cells allows for production of Dopa-incorporated bioengineered MAPs (dMAPs), the low production yield hinders the practical application of dMAPs. This low production yield of dMAPs is due to low translational activity of a noncanonical amino acid, Dopa, in E. coli cells. Herein, to enhance the production yield of dMAPs, we investigated the coexpression of Dopa-recognizing tyrosyl-tRNA synthetases (TyrRSs). To use the Dopa-specific Methanococcus jannaschii TyrRS (MjTyrRS-Dopa), we altered the anticodon of tyrosyl-tRNA amber suppressor into AUA (MjtRNA^Tyr_AUA) to recognize a tyrosine codon (AUA). Co-overexpression of MjTyrRS-Dopa and MjtRNA^Tyr_AUA increased the production yield of Dopa-incorporated MAP foot protein type 3 (dfp-3) by 57%. Similarly, overexpression of E. coli TyrRS (EcTyrRS) led to a 72% higher production yield of dfp-3. Even with coexpression of Dopa-recognizing TyrRSs, dfp-3 has a high Dopa incorporation yield (over 90%) compared to ones prepared without TyrRS coexpression.     

厚壳贻贝Mytilus coruscus足丝盘及足丝的多巴分析

多巴(3,4-1-dihydroxyphenylalanine,DOPA)是贻贝足丝粘附蛋白中的一种特殊的氨基酸,由酪氨酸经羟化后生成,与贻贝足丝粘附蛋白的强粘附性能具有直接联系.目前,已鉴定的多种贻贝足丝蛋白序列中均发现有不同含量的DOPA存在.蛋白中DOPA的定量检测对于了解DOPA在蛋白粘附中的作用以及粘附蛋白的...