Cloning, expression and characterization of PURase gene from Pseudomonas sp. AKS31.

Polyurethane (PUR) is a soil and aquatic contaminant throughout the world. Towards bioremediation, in a previous study, a soil bacterium, Pseudomonas sp. AKS31, capable of efficiently degrading PUR was isolated. Polyurethanase (PURase) enzyme is capable of cleaving the ester bond of PUR and is considered as a key regulator of PUR biodegradation. Hence, for a high yield, easy purification, and further characterization, the aim of this study was to clone and overexpress the PURase gene of this isolate. The current study also investigated structural aspects of this enzyme through predictive bioinformatics analyses. In this context, the PURase gene of the isolate was cloned and expressed in E. coli using pET28(a)+ vector. The obtained recombinant protein was found insoluble. Therefore, first, the protein was made soluble with urea and purified using nickel-NTA beads. The purified enzyme exhibited substantial activities when tested on the LA-PUR plate. Bioinformatics-based analysis of the protein revealed the presence of a lipase serine active site and indicated that this PURase belongs to the Family 1.3 lipase. Hence, the present study shows that active PURase can be produced in large quantities using a prokaryotic expression system and thus, provides an effective strategy for in-vitro PUR-degradation.

Two polyurethanases PueA and PueB are major extracellular lipases partly secreted by the mediation of their cognate ABC exporter AprDEF in Pseudomonas protegens Pf-5.

Two polyurethanases PueA and PueB from Pseudomonas protegens Pf-5 have been reported to have hydrolytic activity against synthetic p-nitrophenyl palmitate of lipase substrate, and PueA may play a more effective role in this activity. However, it is still unknown whether PueA and PueB play similar parts in the lipase activity against natural acylglycerols and achieve the extracellular secretion via their cognate ABC exporter AprDEF. In this study, we investigated these questions through the construction of four markerless deletion mutants in Pf5139 (Δupp derivative of Pf-5), two heterologous co-expression strains and their three control strains in lipase-free Escherichia coli BL21(DE3), and detected their lipase activities by the tributyrin plate assay and the liquid culture assay. The results showed that PueA and PueB, classified as subfamily I.3 lipases, are major extracellular lipases involved in the uptake of oil in Pf-5, and PueA plays a leading role in extracellular lipase activity. In addition, the extracellular secretion of PueA and PueB can be partly mediated via AprDEF in Pf-5 and BL21(DE3). Finally, PueA and PueB are also able to achieve the extracellular secretion without the assistance of AprDEF in Pf-5 and BL21(DE3).

Polyurethane biodegradation by Serratia sp. HY-72 isolated from the intestine of the Asian mantis Hierodula patellifera.

Polyurethane (PU), currently replacing existing synthetic materials worldwide, is a synthetic polymer derived from polyols, isocyanates, and a chain extender added by condensation reactions. PU wastes which are difficult to recycle, are commonly discarded in landfills and flow into ecosystems, thereby causing serious environmental problems. In recent years, insect-associated microbes have become a promising, eco-friendly strategy as an alternative to plastic recycling. This study aimed to evaluate the potential of Serratia sp. HY-72 strain isolated from the intestine of the Asian mantis (Hierodula patellifera) for PU degradation. The 65 kDa family I.3 lipase which degrades PU was identified and characterized, with a specific activity of 2,883 U mg-1. The bacterial filtrates and the recombinant lipase degraded Impranil (a colloidal polyester-PU dispersion, 100 g l-1) by 85.24 and 78.35% after 72 h incubation, respectively. Fourier transform infrared spectroscopy analysis revealed changes in Impranil functional groups, with decreased C=O functional group and aliphatic chain signals, and increased N-H bending with C-N stretching and C-O stretching. The current study also revealed that the HY-72 strain biodegraded the commercial PU foams (polyester- and polyether- PU) with 23.95 and 10.95% weight loss after 2 weeks, respectively with changes in surface morphology and structure such as cracks, roughness, and surface roughening. Altogether, this is one of the few studies reporting biodegradation of PU by the insect-associated microbe. These findings suggest that the insect-associated microbe could be a promising resource for biodegradation and recycling of plastic waste.

Computational studies of polyurethanases from Pseudomonas.

Polyurethanes (PU) are multifunctional polymers, used in automotive industry, in coatings, rigid and flexible foams, and also in biomimetic materials. In the same way as all plastic waste, the incorrect disposal of these materials leads to the accumulation of polyurethanes in the environment. To reduce the amount of waste as well as add value to degradation products, bioremediation methods have been studied for waste management of PU. Enzymes of the hydrolases class have been experimentally tested for enzymatic degradation of PU, with very promising results. In this work, two enzymes that can degrade polyurethanes were studied by molecular dynamics simulations: a protease and an esterase, both from Pseudomonas. From molecular dynamics simulations analysis, it was observed the stability of the structures, both in the simulations of the free enzymes and in the simulations of the complexes with a PU monomer. Hydrogen bonds were formed with the monomer and the enzymes throughout the simulation time, and the interaction free energy was found to be strongly negative, pointing to strong interactions in both cases.

Identification and characterization of a polyurethanase with lipase activity from Serratia liquefaciens isolated from cold raw cow's milk.

Lipases are associated with food spoilage and are also used in various biotechnological applications. In this study, we sought to purify, identify, and characterize a lipase from S. liquefaciens isolated from cold raw cow's milk. The lipase partially purified by ultrafiltration and gel filtration showed a specific activity of 2793 U/mg. By zymography, the enzyme presented approximately 65 kDa, and LC-MS/MS allowed the identification of a polyurethanase with a conserved domain of family I.3 lipase. The modeled and validated structure of polyurethanase was able to bind to different fatty acids and urethane by molecular docking. The polyurethanase showed optimum activity at pH 8.0 and 30 °C. In the presence of ions, activity was decreased, except for Ca2+, Mg2+, and Ba2+. Reducing agents did not alter the activity, while amino acid modifiers reduced enzyme activity. It is concluded that polyurethanase with lipase activity represents a potential enzyme for the deterioration of milk and dairy products, as well as a candidate for industrial applications.

Polyurethanases: Three-dimensional structures and molecular dynamics simulations of enzymes that degrade polyurethane.

The global production of plastics increases every year, because these materials are widely used in several segments of modern life. Polyurethanes are a very important class of polymers, used in many areas of everyday life, from automotive equipments to mattresses. The waste management usually involves accumulation in landfills, incineration, and reuse processes. However, bioremediation processes are being increasingly tested, due to the efficiency of enzymes in the degradation, besides adding value to the generated waste. Several experimental tests indicate that hydrolases, such as proteases, ureases, and esterases, are able to degrade polyurethanes. In this work, the three-dimensional structure of enzymes that are experimentally know to degrade polyurethanes were obtained for the first time, by the technique of homology modeling. The theoretical models showed good stereochemical quality and through molecular dynamics simulations analysis it was observed the stability of the structures. The molecular docking results indicated that all ligands, monomers of polyurethane, showed favorable interactions with the modeled enzymes.