Abstract
BackgroundEnzymes degrading plant biomass polymers are widely used in biotechnological applications. Their efficiency can be limited by non-specific interactions occurring with some chemical motifs. In particular, the lignin component is known to bind enzymes irreversibly. In order to determine interactions of enzymes with their substrates, experiments are usually performed on isolated simple polymers which are not representative of plant cell wall complexity. But when using natural plant substrates, the role of individual chemical and structural features affecting enzyme-binding properties is also difficult to decipher.ResultsWe have designed and used lignified model assemblies of plant cell walls as templates to characterize binding properties of multi-modular cellulases. These three-dimensional assemblies are modulated in their composition using the three principal polymers found in secondary plant cell walls (cellulose, hemicellulose, and lignin). Binding properties of enzymes are obtained from the measurement of their mobility that depends on their interactions with the polymers and chemical motifs of the assemblies. The affinity of the multi-modular GH45 cellulase was characterized using a statistical analysis to determine the role played by each assembly polymer. Presence of hemicellulose had much less impact on affinity than cellulose and model lignin. Depending on the number of CBMs appended to the cellulase catalytic core, binding properties toward cellulose and lignin were highly contrasted.ConclusionsModel assemblies bring new insights into the molecular determinants that are responsible for interactions between enzymes and substrate without the need of complex analysis. Consequently, we believe that model bioinspired assemblies will provide relevant information for the design and optimization of enzyme cocktails in the context of biorefineries.Electronic supplementary materialThe online version of this article (doi:10.1186/s13068-016-0428-y) contains supplementary material, which is available to authorized users.
Highlights
Enzymes degrading plant biomass polymers are widely used in biotechnological applications
We have investigated the interactions of a set of modulated endoglucanases from glycoside hydrolase family 45 (GH45) appended or not to one carbohydrate-binding module (CBM) or five CBMs from family 1 [29]
Characterization of the bioinspired assemblies Gelation of different assemblies varying in their polymer composition was first followed by spectrofluorescence. 3D spectra were measured at two different time points for three representative assemblies containing 0.5 % feruloylated arabinoxylan (FAX)/0.5 % FAX + 1.0 % cellulose nanocrystal (CNC)/0.5 % FAX + 1.0 % CNC + 0.2 % coniferyl alcohol (CA): before triggering gelation and 2 h after gelation had started (Fig. 1)
Summary
Enzymes degrading plant biomass polymers are widely used in biotechnological applications. Their efficiency can be limited by non-specific interactions occurring with some chemical motifs. In order to determine interactions of enzymes with their sub‐ strates, experiments are usually performed on isolated simple polymers which are not representative of plant cell wall complexity. When using natural plant substrates, the role of individual chemical and structural features affecting enzyme-binding properties is difficult to decipher. Plant biomass is a highly complex matrix made of polysaccharides (cellulose and hemicellulose) and phenol-based polymers (lignin). They are connected to each other by numerous covalent and non-covalent interactions, to make the socalled lignocellulose. Carbohydrate active enzymes (CAZymes) can have various modular organizations with catalytic domains and one or more non-enzymatic modules such as carbohydrate-binding modules (CBMs), which help targeting enzyme substrates [3, 4]
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