Jens Thies scite author profile

Enzymes covalently immobilized on highly porous materials are demonstrated to have very high biocatalytic activity and good recyclability, exemplified by Candida antarctica Lipase B (CAL‐B). Polymerized high internal phase emulsions (PolyHIPEs, see figure) are developed for covalent grafting of proteins (enzymes) via the reaction of the protein surface lysine residues with active ester moieties in the monolithic material.

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Controlled Assembly of Macromolecular β‐Sheet Fibrils

Smeenk

et al. 2005

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A virus-based biocatalyst

et al. 2007

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Virus particles are probably the most precisely defined nanometre-sized objects that can be formed by protein self-assembly. Although their natural function is the storage and transport of genetic material, they have more recently been applied as scaffolds for mineralization and as containers for the encapsulation of inorganic compounds. The reproductive power of viruses has been used to develop versatile analytical methods, such as phage display, for the selection and identification of (bio)active compounds. To date, the combined use of self-assembly and reproduction has not been used for the construction of catalytic systems. Here we describe a self-assembled system based on a plant virus that has its coat protein genetically modified to provide it with a lipase enzyme. Using single-object and bulk catalytic studies, we prove that the virus-anchored lipase molecules are catalytically active. This anchored biocatalyst, unlike man-made supported catalysts, has the capability to reproduce itself in vivo, generating many independent catalytically active copies.

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Elastin-Based Side-Chain Polymers: Improved Synthesis via RAFT and Stimulus Responsive Behavior

et al. 2007

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Elastin-based side-chain polymers (EBPs) were prepared by the polymerization of a methacrylate derivative of the pentapeptide valine-proline-glycine-valine-glycine (VPGVG) using reversible additionfragmentation chain transfer (RAFT) polymerization. The polymerizations proceeded in a controlled manner, yielding polymers with a narrow molecular weight distribution (polydispersity indices 1.03-1.23) and molecular weights in good agreement with those predicted from the initial monomer:initiator ratio for the conversion obtained. The dithioester end groups of the resulting polymers were removed by reaction with azo initiator-derived radicals. The lower critical solution temperature (LCST) behavior of the series of EBPs so obtained was investigated in solutions of varying pH (1.5-5.1) and polymer concentration (0.11-0.97 mg/mL) and for polymers of different degrees of polymerization (29-88 repeating units). These EBPs behaved similarly to linear polypeptides, known as elastin-like peptides (ELPs); the transition temperature decreased with increasing polymer concentration and molecular weight. Unlike ELPs, but in common with previously reported EBPs, a strong dependence of transition temperature on pH was observed due to the presence of the carboxylic acid from the C-terminal residue in the peptide side chains. Significant differences between the EBPs described here and those reported earlier were found, however, regarding the transition temperature at a given pH and its variation with molecular weight. These variations are attributed to differences in architecture between the polymers described here (higher molecular weight homopolymers) and those reported earlier (A-B-A triblock copolymers with short EBP A blocks and a PEG B block).

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Jens Thies

Covalent Enzyme Immobilization onto Photopolymerized Highly Porous Monoliths

Controlled Assembly of Macromolecular β‐Sheet Fibrils

A virus-based biocatalyst

Elastin-Based Side-Chain Polymers: Improved Synthesis via RAFT and Stimulus Responsive Behavior

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