Coriolus versicolor laccase-based inorganic protein hybrid synthesis for application in biomass saccharification to enhance biological production of hydrogen and ethanol.

In this study, a bio-friendly inorganic protein hybrid-based enzyme immobilization system using partially purified Coriolus versicolor laccase (Cv Lac) was successfully applied to biomass hydrolysis for the enhancement of sugar production aimed at generating biofuels. After four days of incubation, the maximum Cv Lac production was achieved at 140 U/mg of total protein in the presence of inducers such as copper and wheat bran after four days of incubation. Crude Cv Lac immobilized through inorganic protein hybrids such as nanoflowers (NFs) using zinc as Zn 3 (PO 4) 2 / Cv Lac hybrid NFs (Zn/ Cv Lac-NFs) showed a maximum encapsulation yield of 93.4% and a relative activity of 265% compared to free laccase. The synthesized Zn/ Cv Lac-NFs exhibited significantly improved activity profiles and stability compared to free enzymes. Furthermore, Zn/ Cv Lac-NFs retained a significantly high residual activity of 96.2% after ten reuse cycles. The saccharification of poplar biomass improved ∼2-fold in the presence of Zn/ Cv Lac-NFs, with an 8-fold reduction in total phenolics compared to the control. The Zn/ Cv Lac-NFs treated biomass hydrolysate showed high biological hydrogen (H 2) production and ethanol conversion efficiency of up to 2.68 mol/mol of hexose and 79.0% compared to the control values of 1.27 mol of H 2 /mol of hexose and 58.4%, respectively. The Cv Lac hybrid NFs are the first time reported for biomass hydrolysis, and a significant enhancement in the production of hydrogen and ethanol was reported. The synthesis of such NFs based on crude forms of diverse enzymes can potentially be extended to a broad range of biotechnological applications. [Display omitted] • High laccase production was achieved in copper and wheat bran as inducers. • Crude laccase was efficiently immobilized as inorganic-protein hybrids. • Immobilization of laccase improved saccharification of biomass ∼2-fold. • 2.1- and 1.6-fold higher biohydrogen and ethanol production were recorded, respectively. [ABSTRACT FROM AUTHOR]