Recent advances in the biological depolymerization and upcycling of polyethylene terephthalate.

Polyethylene terephthalate (PET) is favored for its exceptional properties and widespread daily use. This review highlights recent advancements that enable the development of biological tools for PET decomposition, transforming PET into valuable platform chemicals and materials in upcycling processes. Enhancing PET hydrolases' catalytic activity and efficiency through protein engineering strategies is a priority, facilitating more effective PET waste management. Efforts to create novel PET hydrolases for large-scale PET depolymerization continue, but cost-effectiveness remains challenging. Hydrolyzed monomers must add additional value to make PET recycling economically attractive. Valorization of hydrolysis products through the upcycling process is expected to produce new compounds with different values and qualities from the initial polymer, making the decomposed monomers more appealing. Advances in synthetic biology and enzyme engineering hold promise for PET upcycling. While biological depolymerization offers environmental benefits, further research is needed to make PET upcycling sustainable and economically feasible.

Functionalization of OMVs for Biocatalytic Applications.

Outer membrane vesicles (OMVs) are miniature versions of gram-negative bacteria that contain almost the same content as their parent cells, particularly in terms of membrane composition. Using OMVs as biocatalysts is a promising approach due to their potential benefits, including their ability to be handled similarly to bacteria while lacking potentially pathogenic organisms. To employ OMVs as biocatalysts, they must be functionalized with immobilized enzymes to the OMV platform. Various enzyme immobilization techniques are available, including surface display and encapsulation, each with advantages and disadvantages depending on the objectives. This review provides a concise yet comprehensive overview of these immobilization techniques and their applications in utilizing OMVs as biocatalysts. Specifically, we discuss the use of OMVs in catalyzing the conversion of chemical compounds, their role in polymer degradation, and their performance in bioremediation.

Enhanced Lipid Production in Yarrowia lipolytica Po1g by Over-expressing lro1 Gene under Two Different Promoters.

Yarrowia lipolytica is a well-known oleaginous yeast that naturally accumulates lipids to more than 20% of their dry cell weight. Due to its brief doubling time and Generally Recognized as Safe (GRAS) properties, Y. lipolytica has been exploited for the production of commercially valuable lipids. Among the genes related to the lipid synthesis, the gene YALI0E16797g (LRO1) encoding a major triacylglycerol synthase of Y. lipolytica shows a significant impact during the acylation process. Thus, in the present work, we explore the contributions of hp4d or TEFintron promoters to the response of LRO1 expression on lipid accumulation by molecular cloning technology. Results showed that over-expression of LRO1 led to higher lipid content as well as lipid yield. The one with the hp4d promoter showed the highest lipid content of 12% wt. However, such an enhancement also caused a growth defect of cells. On the other hand, the lipid content of the cells over-expressing LRO1 with TEFintron promoter revealed only a modest increase in lipid content, but it promoted cell growth. Therefore, all things considered the one with the TEFintron promoter showed the highest lipid yield.