Thermoreversible lysozyme hydrogels: properties and an insight into the gelation pathway

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Abstract

The gelation behaviour of aqueous solutions of hen egg white lysozyme (HEWL) in the presence of 20 mM DTT in the concentration range 0.7 to 4.0 mM has been investigated using microDSC, FTIR, cryoTEM, SANS and oscillatory rheology. The macroscopic critical gelation concentration, Cgel, was found to be 3.0 mM. The disruption of the disulfide bonds by the DTT and the destabilisation of the protein were found to be a prerequisite for the formation of b-sheet rich fibrils under the mild conditions used in this work. Using our methodology the hydrogels obtained have a pH of 7, hence are suitable for cell culture, and are also thermoreversible. The hydrogel melting temperature was found to increase with increasing concentration and a similar structure was observed across the concentration range investigated. Our results suggest these systems are composed of a well defined regular network where single b-sheet rich fibrils (3 nm diameter) form initially, then two of these fibrils associate two-by-two to form junctions (6 nm diameter) and then on cooling further aggregate to form larger bundles of fibres. The network mesh size was found to decrease with increasing concentration. Our results suggest that below Cgel small unconnected gel-like aggregates exist that have a similar structure to the hydrogels obtained above Cgel. Using our data we propose a model for the denaturation and gelation behaviour of our system. During the first heating an a-helix to beta-sheet molecular transition for the protein conformation occurs resulting in b-sheet rich fibrils forming through the self-assembly of beta-sheet rich denaturated proteins. At high temperature the solution contains b-sheet rich fibrils with dissolved protein. On cooling an increase in the amount of beta-sheet was observed via FTIR suggesting that as the temperature is decreased more and more protein forms b-sheet rich fibrils. At the gelation temperature these fibrils associate two-by-two to form the network junctions resulting in the macroscopic gelation of the sample. Our results suggest the network junctions are formed via specific hydrophobic interactions. The hydrogels elastic modulus was found to scale as C^2.45 for C > Cgel.

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