Experimental and computer simulation studies of the micelles formed by comb-like PEG-containing polymeric surfactants as potential enzyme scaffolds.

The industrial implementation of biofuel production from lignocellulosic biomass faces a number of economic obstacles. One of these is the cost of enzymes, typically used for cellulose hydrolysis. Nature provides some hints towards the efficiency of this process, exampled in natural enzyme complexes - cellulosomes, produced by some microorganisms. Therefore, many research groups target synthetic routes to mimic such cellulosomes with synthetic structures when many questions remain to be addressed: the optimal chemical structure and size of such synthetic scaffolds, their adsorption on the cellulosic biomass particles, combinations, and best practices arrangement of enzymes in the complex. In this work, polyethylene glycol (PEG) copolymers that form micelles and accommodate enzymes in the micellar structures are systematically studied using both experimental and computer simulation techniques. Preliminary results indicate that the micelles are efficient polymer - enzymes structures for cellulose hydrolysis. While the direct quantitative comparison between the real and model systems is not always straightforward, both approaches agree on the role of the molecular architecture of the copolymers on micelle formation and their structural characteristics.