Facile treatment to fine-tune cellulose crystals in cellulose-silk biocomposites through hydrogen peroxide.

The modulation of structural fibrous protein and polysaccharide biopolymers for the design of biomaterials is still relatively challenging due to the non-trivial nature of the transformation from a biopolymer's native state to a more usable form. To gain insight into the nature of the molecular interaction between silk and cellulose chains, we characterized the structural, thermal and morphological properties of silk-cellulose biocomposites regenerated from the ionic liquid, 1-ethyl-3-methylimidazolium acetate (EMIMAc), as a function of increasing coagulation agent concentrations. We found that the cellulose crystallinity and crystal size are dependent on the coagulation agent, hydrogen peroxide solution. The interpretation of our results suggests that the selection of a proper coagulator is a critical step for controlling the physicochemical properties of protein-polysaccharide biocomposite materials.

Identification and secondary structure analysis of a keratin-like fibrous protein discovered in ligament of the bivalve Siliqua radiata.

A novel keratin-like fibrous protein K58 with molecular weight of about 58 kDa was discovered in bivalve Siliqua radiata ligament and identified by amino acid composition and MALDI-TOF-TOF analysis. We found that the protein is composed of cylindrical fibers (~160 nm in diameter) and contains high glycine (27.4%) and phenylalanine (10.5%) contents. Furthermore, it is homologous to keratin type II cytoskeletal 1, with repeat motifs of SGGG and SYGSGG. FTIR and secondary structure analysis indicate that K58 is composed of 46.2% ß-sheet, 33.4% ß-turn, 13.1% α-helix, and 4.7% disordered structure. This structure feature is closely related to the superior tensile strength, elasticity, and solvent resistance property of K58. These discoveries provide some evidence for evolution of keratin and fibrous proteins and prompt further studies of ligament fibrous proteins.