Abstract
BackgroundIn nature, mussel adhesive proteins (MAPs) show remarkable adhesive properties, biocompatibility, and biodegradability. Thus, they have been considered promising adhesive biomaterials for various biomedical and industrial applications. However, limited production of natural MAPs has hampered their practical applications. Recombinant production in bacterial cells could be one alternative to obtain useable amounts of MAPs, although additional post-translational modification of tyrosine residues into 3,4-dihydroxyphenyl-alanine (Dopa) and Dopaquinone is required. The superior properties of MAPs are mainly attributed to the introduction of quinone-derived intermolecular cross-links. To solve this problem, we utilized a co-expression strategy of recombinant MAP and tyrosinase in Escherichia coli to successfully modify tyrosine residues in vivo.ResultsA recombinant hybrid MAP, fp-151, was used as a target for in vivo modification, and a dual vector system of pET and pACYC-Duet provided co-expression of fp-151 and tyrosinase. As a result, fp-151 was over-expressed and mainly obtained from the soluble fraction in the co-expression system. Without tyrosinase co-expression, fp-151 was over-expressed in an insoluble form in inclusion bodies. The modification of tyrosine residues in the soluble-expressed fp-151 was clearly observed from nitroblue tetrazolium staining and liquid-chromatography-mass/mass spectrometry analyses. The purified, in vivo modified, fp-151 from the co-expression system showed approximately 4-fold higher bulk-scale adhesive strength compared to in vitro tyrosinase-treated fp-151.ConclusionHere, we reported a co-expression system to obtain in vivo modified MAP; additional in vitro tyrosinase modification was not needed to obtain adhesive properties and the in vivo modified MAP showed superior adhesive strength compared to in vitro modified protein. It is expected that this co-expression strategy will accelerate the use of functional MAPs in practical applications and can be successfully applied to prepare other Dopa/Dopaquinone-based biomaterials.
Highlights
In nature, mussel adhesive proteins (MAPs) show remarkable adhesive properties, biocompatibility, and biodegradability
Because the pET vector can be used in combination with a vector system with p15A replicon [19] and functional expression of tyrosinase from Streptomyces antibioticus was reported in E. coli under the control of T7 promoter [20], recombinant pACYC-Tyr438 plasmid was prepared from pACYCDuet-1, which carries the p15A origin
The soluble fp-151 in SDS-PAGE was separated at a higher molecular weight than its calculated molecular mass (~24 kDa), which was observed in previous reports and other recombinant MAPs [18,22,23]
Summary
Mussel adhesive proteins (MAPs) show remarkable adhesive properties, biocompatibility, and biodegradability. The superior properties of MAPs are mainly attributed to the introduction of quinone-derived intermolecular cross-links To solve this problem, we utilized a co-expression strategy of recombinant MAP and tyrosinase in Escherichia coli to successfully modify tyrosine residues in vivo. The extracted amount is not practically applicable for bioadhesives as 10,000 mussels are required to obtain ~1 g of the most extractable MAP fp-1, and at least 100 mg of protein is needed for small, conventional adhesive tests, such as tensile or shear strength analysis, for obtaining mechanical properties of adhesive biomaterials [2,8]. An in vivo modification system for tyrosine residues, such as natural MAP production in mussel, is required to prepare recombinant MAPs in bacterial expression systems
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