Isothermal titration calorimetric assessment of lignin conversion by laccases

Thermal treatment of alkali lignin to eliminate its inhibition of pancreatic proteases in vitro

This study aims to investigate how alkali lignin inhibits protein digestion and explore thermal treatment as a potential solution. Solid alkali lignin species pre-heated at different temperatures (150, 200, and 250 °C) and soluble acid-differentiated fractions are subjected to in vitro protein digestion. A range of techniques, including Thermogravimetric Analysis (TGA), Size-Exclusion Chromatography (SEC), Zeta Potential Analyzer, 1H NMR, Isothermal Titration Calorimetry (ITC), and Molecular Docking, were used to investigate the inhibitory mechanism of alkali lignin on pancreatic proteases hydrolysis. Our results suggest that soluble alkali lignin inhibits pancreatic trypsin and chymotrypsin, with the acid-differentiated soluble fraction (LgpH<1) displaying the strongest inhibition and proteases' binding affinity due to the abundance of polar groups (e.g., -OH, -CHO), which facilitate hydrogen-bond formation. Furthermore, pre-heating lignin (200 °C) was confirmed effective for removing LgpH<1 and its negative nutritional influence, providing a feasible strategy for overcoming the negative impact of alkali lignin on protein digestion.

Recent advances in laccase activity assays: A crucial challenge for applications on complex substrates

Despite being one of the first enzymes discovered in 1883, the determination of laccase activity remains a scientific challenge, and a barrier to the full use of laccase as a biocatalyst. Indeed, laccase, an oxidase of the blue multi-copper oxidases family, has a wide range of substrates including substituted phenols, aromatic amines and lignin-related compounds. Its one-electron mechanism requires only oxygen and releases water as a reaction product. These characteristics make laccase a biocatalyst of interest in many fields of applications including pulp and paper industry, biorefineries, food, textile, and pharmaceutical industries. But to fully envisage the use of laccase at an industrial scale, its activity must be reliably quantifiable on complex substrates and in complex matrices. This review aims to describe current and emerging methods for laccase activity assays and place them in the context of a potential industrial use of the enzyme.

Laccase-catalyzed lignin depolymerization in deep eutectic solvents: challenges and prospects

Lignin has enormous potential as a renewable feedstock for depolymerizing to numerous high-value chemicals. However, lignin depolymerization is challenging owing to its recalcitrant, heterogenous, and limited water-soluble nature. From the standpoint of environmental friendliness and sustainability, enzymatic depolymerization of lignin is of great significance. Notably, laccases play an essential role in the enzymatic depolymerization of lignin and are considered the ultimate green catalysts. Deep eutectic solvent (DES), an efficient media in biocatalysis, are increasingly recognized as the newest and utmost green solvent that highly dissolves lignin. This review centers on a lignin depolymerization strategy by harnessing the good lignin fractionating capability of DES and the high substrate and product selectivity of laccase. Recent progress and insights into the laccase-DES interactions, protein engineering strategies for improving DES compatibility with laccase, and controlling the product selectivity of lignin degradation by laccase or in DES systems are extensively provided. Lastly, the challenges and prospects of the alliance between DES and laccase for lignin depolymerization are discussed. The collaboration of laccase and DES provides a great opportunity to develop an enzymatic route for lignin depolymerization.