Switch of Surface Adhesion to Cohesion by Dopa-Fe³⁺ Complexation, in Response to Microenvironment at the Mussel Plaque/Substrate Interface

Although Dopa-Fe³⁺ complexation is known to play an important role in mussel adhesion for providing mechanical properties, its function at the plaque/substrate interface, where actual surface adhesion occurs, remains unknown, with regard to interfacial mussel adhesive proteins (MAPs) type 3 fast variant (fp-3F) and type 5 (fp-5). Here, we confirmed Dopa-Fe³⁺ complexation of interfacial MAPs and investigated the effects of Dopa-Fe³⁺ complexation regarding both surface adhesion and cohesion. The force measurements using surface forces apparatus (SFA) analysis showed that intrinsic strong surface adhesion at low pH, which is similar to the local acidified environment present during the secretion of adhesive proteins, vanishes by Dopa-Fe³⁺ complexation and alternatively, strong cohesion is generated in higher pH conditions similar to seawater. A high Dopa content increased the capacity for both surface adhesion and cohesion, but not at the same time. In contrast, a lack of Dopa resulted in both weak surface adhesion and cohesion without significant effects of Fe³⁺ complexation. Our findings shed light on how mussels regulate Dopa functionality at the plaque/substrate interface, in response to the microenvironment, and might provide new insight for the design of mussel-inspired biomaterials

Mechanically Durable and Biologically Favorable Protein Hydrogel Based on Elastic Silklike Protein Derived from Sea Anemone

As biodegradable scaffolds, protein hydrogels have considerable potential, particularly for bioartificial organs and three-dimensional space-filling materials. However, their low strength and stiffness have been considered to be limitations for enduring physiological stimuli. Therefore, protein hydrogels have been commonly utilized as delivery vehicles rather than as supporting materials. In this work, sea anemone tentacle-derived recombinant silk-like protein (aneroin) was evaluated as a potential material for a mechanically durable protein hydrogel. Inspired by the natural hardening mechanism, photoinitiated dityrosine cross-linking was employed to fabricate an aneroin hydrogel. It was determined that the fabricated aneroin hydrogel was approximately 10-fold stiffer than mammalian cardiac or skeletal muscle. The aneroin hydrogel provided not only structural support but also an adequate environment for cells. It exhibited an adequate swelling ability and microstructure, which are beneficial for facilitating mass transport and cell proliferation. Based on its mechanical and biological properties, this aneroin hydrogel could be used in various biomedical applications, such as cell-containing patches, biomolecule carriers, and artificial extracellular matrices

Specific Multiplex Analysis of Pathogens Using a Direct 16S rRNA Hybridization in Microarray System

For the rapid multiplex analysis of pathogens, 16S rRNAs from cell lysates were directly applied onto a DNA microarray at room temperature (RT) for RNA–DNA hybridization. To eliminate the labeling step, seven fluorescent-labeled detector probes were cohybridized with 16S rRNA targets and adjacent specific capture probes. We found that eight pathogens were successfully discriminated by the 16S rRNA-based direct method, which showed greater specificity than the polymerase chain reaction (PCR)-labeled method due to chaperone and distance effects. A new specificity criterion for a perfect match between RNA and DNA was suggested to be 21–41% dissimilarity using correlation analysis between the mismatch and the sequence according to the guanine–cytosine (GC) percentage or the distribution of mismatches. Six categories of food matrix (egg, meat, milk, rice, vegetable, and mixed) were also tested, and the target pathogen was successfully discriminated within statistically significant levels. Finally, we found that the intrinsic abundance of 16S rRNA molecules successfully substituted PCR-based amplification with a low limit of detection of 10–10³ cells mL^–1 and a high quantitative linear correlation. Collectively, our suggested 16S rRNA-based direct method enables the highly sensitive, specific, and quantitative analysis of selected pathogens at RT within 2 h, even in food samples

Role of Pif97 in Nacre Biomineralization: In Vitro Characterization of Recombinant Pif97 as a Framework Protein for the Association of Organic–Inorganic Layers in Nacre

Nacre is the inner layer of the mollusc shell and provides exceptional toughness via its highly organized organic–inorganic composite structure. Pif is an organic matrix protein from the nacreous layer of the pearl oyster Pinctada fucata and exhibits regulatory behavior in nacre formation. Here, we investigated features of Pif97, the N-terminal of Pif, using a recombinant form of Pif97 produced in Escherichia coli. We observed that recombinant Pif97 was able to efficiently form a complex with calcium ions. Additionally, recombinant Pif97 showed both in vitro growth inhibition of thermodynamically stable calcite, stabilization of amorphous calcium carbonate, and exclusive binding affinity to metastable aragonite and chitin. These results imply the participation of Pif97 in the calcification of nacre including the association of the inorganic phase and polysaccharide template. We propose that recombinant Pif97 has inherent characteristics of the native form, which are significant for interrelating with organic matrix and inorganic calcium carbonate during nacre biomineralization

Sprayable Adhesive Nanotherapeutics: Mussel-Protein-Based Nanoparticles for Highly Efficient Locoregional Cancer Therapy

Following surgical resection for primary treatment of solid tumors, systemic chemotherapy is commonly used to eliminate residual cancer cells to prevent tumor recurrence. However, its clinical outcome is often limited due to insufficient local accumulation and the systemic toxicity of anticancer drugs. Here, we propose a sprayable adhesive nanoparticle (NP)-based drug delivery system using a bioengineered mussel adhesive protein (MAP) for effective locoregional cancer therapy. The MAP NPs could be administered to target surfaces in a surface-independent manner through a simple and easy spray process by virtue of their unique adhesion ability and sufficient dispersion property. Doxorubicin (DOX)-loaded MAP NPs (MAP@DOX NPs) exhibited efficient cellular uptake, endolysosomal trafficking, and subsequent low pH microenvironment-induced DOX release in cancer cells. The locally sprayed MAP@DOX NPs showed a significant inhibition of tumor growth <i>in vivo</i>, resulting from the prolonged retention of the MAP@DOX NPs on the tumor surface. Thus, this adhesive MAP NP-based spray therapeutic system provides a promising approach for topical drug delivery in adjuvant cancer therapy

Surface-Independent Antibacterial Coating Using Silver Nanoparticle-Generating Engineered Mussel Glue

During implant surgeries, antibacterial agents are needed to prevent bacterial infections, which can cause the formation of biofilms between implanted materials and tissue. Mussel adhesive proteins (MAPs) derived from marine mussels are bioadhesives that show strong adhesion and coating ability on various surfaces even in wet environment. Here, we proposed a novel surface-independent antibacterial coating strategy based on the fusion of MAP to a silver-binding peptide, which can synthesize silver nanoparticles having broad antibacterial activity. This sticky recombinant fusion protein enabled the efficient coating on target surface and the easy generation of silver nanoparticles on the coated-surface under mild condition. The biosynthesized silver nanoparticles showed excellent antibacterial efficacy against both Gram-positive and Gram-negative bacteria and also revealed good cytocompatibility with mammalian cells. In this coating strategy, MAP-silver binding peptide fusion proteins provide hybrid environment incorporating inorganic silver nanoparticle and simultaneously mediate the interaction of silver nanoparticle with surroundings. Moreover, the silver nanoparticles were fully synthesized on various surfaces including metal, plastic, and glass by a simple, surface-independent coating manner, and they were also successfully synthesized on a nanofiber surface fabricated by electrospinning of the fusion protein. Thus, this facile surface-independent silver nanoparticle-generating antibacterial coating has great potential to be used for the prevention of bacterial infection in diverse biomedical fields

Mussel-Mimetic Protein-Based Adhesive Hydrogel

Hydrogel systems based on cross-linked polymeric materials which could provide both adhesion and cohesion in wet environment have been considered as a promising formulation of tissue adhesives. Inspired by marine mussel adhesion, many researchers have tried to exploit the 3,4-dihydroxyphenylalanine (DOPA) molecule as a cross-linking mediator of synthetic polymer-based hydrogels which is known to be able to achieve cohesive hardening as well as adhesive bonding with diverse surfaces. Beside DOPA residue, composition of other amino acid residues and structure of mussel adhesive proteins (MAPs) have also been considered important elements for mussel adhesion. Herein, we represent a novel protein-based hydrogel system using DOPA-containing recombinant MAP. Gelation can be achieved using both oxdiation-induced DOPA quinone-mediated covalent and Fe³⁺-mediated coordinative noncovalent cross-linking. Fe³⁺-mediated hydrogels show deformable and self-healing viscoelastic behavior in rheological analysis, which is also well-reflected in bulk adhesion strength measurement. Quinone-mediated hydrogel has higher cohesive strength and can provide sufficient gelation time for easier handling. Collectively, our newly developed MAP hydrogel can potentially be used as tissue adhesive and sealant for future applications