Adhesive Properties of Adsorbed Layers of Two Recombinant Mussel Foot Proteins with Different Levels of DOPA and Tyrosine

Bilotto, Pierluigi; Labate, Cristina; Santo, Maria P. De; Deepankumar, Kanagavel; Miserez, Ali; Zappone, Bruno

doi:10.1021/acs.langmuir.9b01730

Cited by 25 publications

(42 citation statements)

References 49 publications

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“…Adhesion is thus attributed due to the progressive stretching of flexible polymer‐like segments in a random network of proteins, eventually leading to protein bond rupture. [ 14,15 ] The network is both cross‐linked (e.g., via cation–π bonds or amyloidogenic interactions inducing β‐sheet formation) and attached to the Si 3 N 4 probe and TiO 2 substrate (e.g., Dopa–surface bonds). Adhesive peaks were due to the rupture of protein bonds, either a protein–protein cross‐link or protein–surface bond.…”

Section: Resultsmentioning

confidence: 99%

“…Adhesive peaks were due to the rupture of protein bonds, either a protein–protein cross‐link or protein–surface bond. The maximum adhesive force F 0 on the order of 0.1–1.0 nN is consistent with the rupture of single bonds, [ 11e,14 ] whereas the adhesive energy W = −∫ FdD characterizes the adhesive properties of the protein network, cumulating the effect of breaking multiple bonds of different types. Both F 0 and W showed a large variation among different measurements, even when all experimental parameters such as AFM tip velocity, or dwell time and maximum load at contact were kept constant (Figure S6c,d, Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

“…Surface adhesion ultimately depends on the density and strength of the bonds that must be broken to separate the surfaces, generating failure planes at the surfaces [ 12b ] and fractures within the protein layer. [ 14 ] The interplay between surface bonds and crosslinks provides additional opportunities to engineer wet adhesives at the molecular level, e.g., to direct micro‐fracture within the protein layer where cohesive molecular domains can provide additional mechanical dissipation. [ 7b,15 ]…”

Section: Introductionmentioning

confidence: 99%

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Supramolecular β‐Sheet Suckerin–Based Underwater Adhesives

Deepankumar

Lim

Polte

et al. 2020

Adv Funct Materials

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Nature has evolved several molecular strategies to ensure adhesion in aqueous environments, where artificial adhesives typically fail. One recentlyunveiled molecular design for wet-resistant adhesion is the cohesive cross-β structure characteristic of amyloids, complementing the well-established surface-binding strategy of mussel adhesive proteins based on 3,4-l-dihydroxyphenylalanine (Dopa). Structural proteins that self-assemble into cross β-sheet networks are the suckerins discovered in the sucker ring teeth of squids. Here, light is shed on the wet adhesion of cross-β motifs by producing recombinant suckerin-12, naturally lacking Dopa, and investigating its wet adhesion properties. Surprisingly, the adhesion forces measured on mica reach 70 mN m −1 , exceeding those measured for all mussel adhesive proteins to date. The pressure-sensitive adhesion of artificial suckerins is largely governed by their cross-β motif, as evidenced using control experiments with disrupted cross-β domains that result in complete loss of adhesion. Dopa is also incorporated in suckerin-12 using a residue-specific incorporation strategy that replaces tyrosine with Dopa during expression in Escherichia coli. Although the replacement does not increase the long-term adhesion, it contributes to the initial rapid contact and enhances the adsorption onto model oxide substrates. The findings suggest that suckerins with supramolecular cross-β motifs are promising biopolymers for wet-resistant adhesion.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Supramolecular β‐Sheet Suckerin–Based Underwater Adhesives

Deepankumar

Lim

Polte

et al. 2020

Adv Funct Materials

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“…Besides, the adhesion ability of dipeptides with Lys at the N terminus (Lys-Dopa) is stronger than C terminus (Dopa-Lys), indicating that the cooperative Lys and Dopa binding to hydrophilic surfaces strongly depends on the protein sequences (29). As for the adhesive proteins, increasing studies also showed that recombinant protein enriched with Tyr rather than Dopa has strong adhesive ability (32)(33)(34)(35). All these studies are consistent with our findings based on MD simulations and lap shear experiments.…”

Section: Discussionmentioning

confidence: 99%

“…In addition, the Dopa-based peptide containing insufficient Lys exhibits limited adhesion to hydrophilic surface (30). Moreover, increasing studies showed that the peptides containing Lys and unmodified Tyr can also adsorb to hydrophilic surfaces (31)(32)(33)(34)(35). Together, although the crucial role of Dopa to enhance the mussel attachment by promoting the protein cross-linking has been well established (36)(37)(38), its effect on adhesive interaction is under debate.…”

Section: Introductionmentioning

confidence: 99%

Structure and sequence features of mussel adhesive protein lead to its salt-tolerant adhesion ability

Xue

Lao

et al. 2020

Sci. Adv.

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Mussels can strongly adhere to hydrophilic minerals in sea habitats by secreting adhesive proteins. The adhesion ability of these proteins is often attributed to the presence of Dopa derived from posttranslational modification of Tyr, whereas the contribution of structural feature is overlooked. It remains largely unknown how adhesive proteins overcome the surface-bound water layer to establish underwater adhesion. Here, we use molecular dynamics simulations to probe the conformations of adhesive protein Pvfp-5β and its salt-tolerant underwater adhesion on superhydrophilic mica. Dopa and positively charged basic residues form pairs, in this intrinsically disordered protein, and these residue pairs can lead to firm surface binding. Our simulations further suggest that the unmodified Tyr shows similar functions on surface adhesion by forming pairing structure with a positively charged residue. We confirm the presence of these residue pairs and verify the strong binding ability of unmodified proteins using nuclear magnetic resonance spectroscopy and lap shear tests.

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External Stimuli Responsive Liquid‐Infused Surfaces Switching between Slippery and Nonslippery States: Fabrications and Applications

Lou

Huang

Yang

et al. 2020

Adv Funct Materials

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Surfaces with controllable liquid wettability and related functions have gained increasing attention from interfacial scientists due to the high demand of fundamental research and practical applications. Inspired by pitch plant's excellent liquid repellency, external stimuli responsive lubricant‐infused surfaces switching between slippery state and nonslippery state under external stimuli (E‐LIS) have been developed by introducing external stimuli responsive materials as substrates, lubricants, or repellent liquids. This progress report is focused on recent development of E‐LIS. First, design strategy and fabrication of E‐LIS upon external stimuli exposure, including stress, electrical field, magnetic field, and temperature, is summarized. Then, emerging interfacial applications of E‐LIS, such as microreactors, pipetting devices, fog collection devices, and so on, are highlighted. In addition, remaining challenges and future prospects are provided.

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Adhesive Properties of Adsorbed Layers of Two Recombinant Mussel Foot Proteins with Different Levels of DOPA and Tyrosine

Cited by 25 publications

References 49 publications

Supramolecular β‐Sheet Suckerin–Based Underwater Adhesives

Supramolecular β‐Sheet Suckerin–Based Underwater Adhesives

Structure and sequence features of mussel adhesive protein lead to its salt-tolerant adhesion ability

External Stimuli Responsive Liquid‐Infused Surfaces Switching between Slippery and Nonslippery States: Fabrications and Applications

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