Adhesion mechanisms of the mussel foot proteins mfp-1 and mfp-3

Lin, Qi; Gourdon, Delphine; Sun, Chengjun; Holten‐Andersen, Niels; Anderson, Travers H.; Waite, J. Herbert; Israelachvili, Jacob N.

doi:10.1073/pnas.0607852104

Cited by 488 publications

(407 citation statements)

References 35 publications

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“…1e). [13][14][15] DOPA demonstrates high affinity for chemically distinct substrates via covalent or noncovalent interactions. Dopamine contains both side chain functionalities of DOPA and lysine, which resembles mussel adhesive proteins (Fig.…”

Section: Introductionmentioning

confidence: 99%

Fusion of nacre, mussel, and lotus leaf: bio-inspired graphene composite paper with multifunctional integration

et al. 2013

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Multifunctional integration is an inherent characteristic for biological materials with multiscale structures. Learning from nature is an effective approach for scientists and engineers to construct multifunctional materials. In nature, mollusks (abalone), mussels, and the lotus have evolved different and optimized solutions to survive. Here, bio-inspired multifunctional graphene composite paper was fabricated in situ through the fusion of the different biological solutions from nacre (brick-and-mortar structure), mussel adhesive protein (adhesive property and reducing character), and the lotus leaf (self-cleaning effect). Owing to the special properties (self-polymerization, reduction, and adhesion), dopamine could be simultaneously used as a reducing agent for graphene oxide and as an adhesive, similar to the mortar in nacre, to crosslink the adjacent graphene. The resultant nacre-like graphene paper exhibited stable superhydrophobicity, self-cleaning, anticorrosion, and remarkable mechanical properties underwater. Multifunctional integration is an inherent characteristic for biological materials with multiscale structures.Learning from nature is an effective approach for scientists and engineers to construct multifunctional materials. In nature, mollusks (abalone), mussels, and the lotus have evolved different and optimized solutions to survive. Here, bio-inspired multifunctional graphene composite paper was fabricated in situ through the fusion of the different biological solutions from nacre (brick-and-mortar structure), mussel adhesive protein (adhesive property and reducing character), and the lotus leaf (self-cleaning effect).Owing to the special properties (self-polymerization, reduction, and adhesion), dopamine could be simultaneously used as a reducing agent for graphene oxide and as an adhesive, similar to the mortar in nacre, to crosslink the adjacent graphene. The resultant nacre-like graphene paper exhibited stable superhydrophobicity, self-cleaning, anti-corrosion, and remarkable mechanical properties underwater.

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Section: Introductionmentioning

confidence: 99%

Fusion of nacre, mussel, and lotus leaf: bio-inspired graphene composite paper with multifunctional integration

et al. 2013

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“…Moreover, the specialized mfp‐3 and mfp‐5 that constitute the adhesion interface of mussels, reached maximum adhesive energy values at pH 5.5 on silica of 2.99 and 2.44 mJ m −2 with a contact time of 60 min,23 respectively, which are still below the average work of adhesion attained by polyU 1 C after only 60 s of contact time. It has also to be noted that a complete loss of adhesive function was reported at pH 7–7.522 for several mfps, including mfp‐1, whereas the artificial mfp analogues are able to perform at pH 6.8.…”

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confidence: 95%

“…A similar trend for coatings of polyU 1 C and polyU 2 C with respect to masses and thicknesses on alumina surfaces is evident for coatings on fluoropolymer substrates (Supporting Information, Figure S43). The latter are known to be highly challenging for coating, on which nonetheless marine mussels can effectively adhere well 22. Estimated areal mass densities of 31±3 mg m −2 and 18±1 mg m −2 (Voight model) give theoretical layer thicknesses of 26±2 nm and 15±1 nm for polyU 1 C and polyU 2 C , respectively.…”

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confidence: 99%

Polymerizing Like Mussels Do: Toward Synthetic Mussel Foot Proteins and Resistant Glues

et al. 2018

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A novel strategy to generate adhesive protein analogues by enzyme‐induced polymerization of peptides is reported. Peptide polymerization relies on tyrosinase oxidation of tyrosine residues to Dopaquinones, which rapidly form cysteinyldopa‐moieties with free thiols from cysteine residues, thereby linking unimers and generating adhesive polymers. The resulting artificial protein analogues show strong adsorption to different surfaces, even resisting hypersaline conditions. Remarkable adhesion energies of up to 10.9 mJ m−2 are found in single adhesion events and average values are superior to those reported for mussel foot proteins that constitute the gluing interfaces.

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“…Recruitment of the atomic force microscope, nanoindentation, and the surface force apparatus (SFA) has contributed much to understanding the physical and mechanical properties of mussel byssus and byssal proteins particularly the mfps. [5][6][7][8][9] However, structural studies at different length scales have been hampered by considerable challenges, including a menagerie of peculiar post-translational modifications, mfp sequence polymorphism, 2,10 the inability to crystallize any of the mfps, difficulty of purifying mg quantities, and the instability of mfps in solution. 11 This has lead to a variety of experimental approximations, which may or may not be biologically relevant.…”

Section: Introductionmentioning

confidence: 99%

Three intrinsically unstructured mussel adhesive proteins, mfp‐1, mfp‐2, and mfp‐3: Analysis by circular dichroism

Hwang

Waite

2012

Protein Science

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Mussel foot proteins (mfps) mediate fouling by the byssal holdfast and have been extensively investigated as models for versatile polymer-mediated underwater adhesion and coatings. However, insights into the structural properties of mfps have lagged far behind the nanomechanical advances, owing in part to the inability of these proteins to crystallize as well as their limited solubility. Here, solution secondary structures of mfp-1, mfp-2, and mfp-3, localized in the mussel byssal cuticle, adhesive plaque, and plaque-substratum interface, respectively, were investigated using circular dichroism. All three have significant extended coil solution structure, but two, mfp-1 and mfp-2, appear to have punctuated regions of structure separated by unstructured domains. Apart from its punctuated distribution, the structure in mfp-1 resembles other structural proteins such as collagen and plant cell-wall proteins with prominent polyproline II helical structure. As in collagen, PP II structure of mfp-1 is incrementally disrupted by increasing the temperature and by raising pH. However, no recognizable change in mfp-1's PP II structure was evident with the addition with Ca 21 and Fe 31 . In contrast, mfp-2 exhibits Ca 21 -and disulfidestabilized epidermal growth factor-like domains separated by unstructured sequence. Mfp-2 showed calcium-binding ability. Bound calcium in mfp-2 was not removed by chelation at pH 5.5, but it was released upon reduction of disulfide bonds. Mfp-3, in contrast, appears to consist largely of unstructured extended coils.

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Adhesion mechanisms of the mussel foot proteins mfp-1 and mfp-3

Cited by 488 publications

References 35 publications

Fusion of nacre, mussel, and lotus leaf: bio-inspired graphene composite paper with multifunctional integration

Fusion of nacre, mussel, and lotus leaf: bio-inspired graphene composite paper with multifunctional integration

Polymerizing Like Mussels Do: Toward Synthetic Mussel Foot Proteins and Resistant Glues

Three intrinsically unstructured mussel adhesive proteins, mfp‐1, mfp‐2, and mfp‐3: Analysis by circular dichroism

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