Enzyme-particle Complexes Facilitate Pickering Interfacial Biocatalysis.

Pickering interfacial biocatalysis (PIB), where biocatalysts stabilize emulsions through carrier coupling or polymer grafting, has emerged as a powerful platform for organic synthesis due to its ability to accommodate water-insoluble substrates within enzymatic cascade reactions. PIB provides a large interfacial area for two-phase reactions, reducing diffusional resistance and enhancing transformation efficiency. The performance of PIB relies heavily on enzyme-particle conjugates, which serve a dual function: stabilizing the emulsion and acting as the active biocatalysts in the system.

Stable nanoscale sea-island structure of biobased polyamide 56/poly (butylene adipate-co-terephthalate) blends compatibilized by interfacial hyperbranched structure: Toward biobased polymer blends with ultrahigh toughness.

Developing biobased materials is a considerably effective approach to save fossil resources and reduce emissions. Biobased polyamide 56 (PA56) is an excellent engineering material, but it has low toughness. Herein, to enhance the toughness of PA56, an ultra-tough biodegradable material, i.

Enzyme-Polymer-Conjugate-Based Pickering Emulsions for Cell-Free Expression and Cascade Biotransformation.

In this study, we addressed the limitations of conventional enzyme-polymer-conjugate-based Pickering emulsions for interfacial biocatalysis, which traditionally suffer from nonspecific and uncontrollable conjugation positions that can impede catalytic performance. By introducing a non-canonical amino acid (ncAA) at a specific site on target enzymes, we enabled precise polymer-enzyme conjugation. These engineered conjugates then acted as biocatalytically active emulsifiers to stabilize Pickering emulsions, while encapsulating a cell-free protein synthesis (CFPS) system in the aqueous phase for targeted enzyme expression.

Cell-free metabolic engineering enables selective biotransformation of fatty acids to value-added chemicals.

Fatty acid-derived products such as alkanes, fatty aldehydes, and fatty alcohols have many applications in the chemical industry. These products are predominately produced from fossil resources, but their production processes are often not environmentally friendly. While microbes like have been engineered to convert fatty acids to corresponding products, the design and optimization of metabolic pathways in cells for high productivity is challenging due to low mass transfer, heavy metabolic burden, and intermediate/product toxicity.