Meng Wang scite author profile

Vault nanoparticles packaged with enzymes were synthesized as agents for efficiently degrading environmental contaminants. Enzymatic biodegradation is an attractive technology for in situ cleanup of contaminated environments because enzyme-catalyzed reactions are not constrained by nutrient requirements for microbial growth and often have higher biodegradation rates. However, the limited stability of extracellular enzymes remains a major challenge for practical applications. Encapsulation is a recognized method to enhance enzymatic stability, but it can increase substrate diffusion resistance, lower catalytic rates, and increase the apparent half-saturation constants. Here, we report an effective approach for boosting enzymatic stability by single-step packaging into vault nanoparticles. With hollow core structures, assembled vault nanoparticles can simultaneously contain multiple enzymes. Manganese peroxidase (MnP), which is widely used in biodegradation of organic contaminants, was chosen as a model enzyme in the present study. MnP was incorporated into vaults via fusion to a packaging domain called INT, which strongly interacts with vaults' interior surface. MnP fused to INT and vaults packaged with the MnP-INT fusion protein maintained peroxidase activity. Furthermore, MnP-INT packaged in vaults displayed stability significantly higher than that of free MnP-INT, with slightly increased Km value. Additionally, vault-packaged MnP-INT exhibited 3 times higher phenol biodegradation in 24 h than did unpackaged MnP-INT. These results indicate that the packaging of MnP enzymes in vault nanoparticles extends their stability without compromising catalytic activity. This research will serve as the foundation for the development of efficient and sustainable vault-based bioremediation approaches for removing multiple contaminants from drinking water and groundwater.

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Iron isotope behavior during fluid/rock interaction in K-feldspar alteration zone – A model for pyrite in gold deposits from the Jiaodong Peninsula, East China

Zhu

Jiang

Mathur

et al. 2018

Geochimica et Cosmochimica Acta

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Synthesis and assembly of human vault particles in yeast

Wang

Kickhoefer

Rome

et al. 2018

Biotech & Bioengineering

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Vault particles are the largest naturally occurring ribonucleoprotein complexes found in the cytoplasm. In all 78 copies of major vault protein (MVP) assemble on polyribosome templates, forming recombinant vault particles, which are of great interest as encapsulation carriers for therapeutics delivery and enzyme stabilization. Baculovirus-insect cell expression is the only system that has been developed for recombinant vault synthesis, but it has low scalability and slow production rate. In this study, we demonstrated the first use of yeast cells for the production of vault particles with full integrity and functionality solely by expressing the complementary DNA (cDNA) encoding MVP. Vaults synthesized in Pichia pastoris yeast cells are morphologically indistinguishable from recombinant vault particles produced in insect cells, and are able to package and stabilize enzymes resulting in improved longevity and catalytic efficiency. Thus, our results imply that the yeast system is an economical alternative to insect cells for the production of recombinant vaults. The consistency of vault morphology between yeast and insect cell systems also underlines that polyribosome templating may be conserved among eukaryotes, which promises the synthesis and assembly of recombinant human vault particles in other eukaryotic organisms.

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Immobilized fungal enzymes: Innovations and potential applications in biodegradation and biosynthesis

Gao

Shah

Kwok

et al. 2022

Biotechnology Advances

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Meng Wang

Vault Nanoparticles Packaged with Enzymes as an Efficient Pollutant Biodegradation Technology

Iron isotope behavior during fluid/rock interaction in K-feldspar alteration zone – A model for pyrite in gold deposits from the Jiaodong Peninsula, East China

Synthesis and assembly of human vault particles in yeast

Immobilized fungal enzymes: Innovations and potential applications in biodegradation and biosynthesis

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