Improving enzymatic polyurethane hydrolysis by tuning enzyme sorption

In this study we investigated the ability of amidases to hydrolyse polyurethane polyester co-polymers. In order to improve enzyme adsorption, a polyamidase from Nocardia farcinica (PA) was fused to a polymer binding module from a polyhydroxyalkanoate depolymerase from Alcaligenes faecalis (PA_PBM). The activity of these enzymes and of various commercially available amidases on a synthesized soluble model substrate was compared. The recombinant native PA showed the highest activity of 10.5 U/mg followed by PA_PBM with an activity of 1.13 U/mg. Both enzymes were able to cleave the urethane bond in polyurethane-polyesters with different degree of crystallinity as shown by FTIR. According to LC-TOF analysis the monomer 4,4′-diaminodiphenylmethane (MDA) and the oligomers 4-hydroxybutyl (3-(3-aminobenzyl)phenyl)carbamate [B], bis(4-hydroxybutyl) (methylenebis(3,1-phenylene))dicarbamate [C] and 4-(((3-(3-(((4-hydroxybutoxy)carbonyl)amino)benzyl)phenyl)carbamoyl)oxy)butyl (4-hydroxybutyl) adipate [D] were released. The polymer with a higher content of the rigid segment, MDA, was hydrolysed to a lower extent. Interestingly, despite the lower activity on the soluble model substrate, the PA_PBM fusion enzyme was up to 4 times more active on the polymer when compared with the native enzyme, confirming the relevance of enzyme adsorption for efficient hydrolysis.