There are provided, inter alia, methods for reacting an enzyme and its substrate, methods for purifying a protein and an enzyme reactor and its use thereof.

The subject invention provides method of producing Trichoderma fungi on an industrial scale. In specific embodiments, the subject invention provides methods of producing both a liquid Trichoderma-based product and a solid-state Trichoderma-based product from the same starting seed culture and inoculant.

Provided are methods, systems, and facilities for screening, purification, and recovery of specific heavy metals and/or rare earth elements (REEs) from input materials including low-grade mines, tailings, sludge, rare earth, silt, and specific elements of Waste Electrical and Electronic Equipment (WEEE) by means of efficient microbial and/or algae screening method. The system and method of algae and microbial screening addresses the main problem of inefficient screening speed in the method of algae and microbial screening for recovery of specific heavy metals and/or REEs, which is too slow and time-consuming by integrated acceleration of the cultivation and screening of microbial and algae species of up to 50 times faster than current efficiencies by the application of a recovery rate metric model.

Provided herein are enzymatic compositions for carbohydrate antigen cleavage, methods, uses, apparatuses and systems associated therewith. In particular, the composition comprises two enzymes, GalNAcDeacetylase and Galactosaminidase and the composition may further comprise a crowding agent. Furthermore, the compositions described herein were found to have activity a temperatures and pH levels suitable for cell viability.

Provided herein are enzymatic compositions for carbohydrate antigen cleavage, methods, uses, apparatuses and systems associated therewith. In particular, the composition comprises two enzymes, GalNAcDeacetylase and Galactosaminidase and the composition may further comprise a crowding agent. Furthermore, the compositions described herein were found to have activity a temperatures and pH levels suitable for cell viability.

A method of proteolyzing a protein, including immobilizing a protein in at least one pore of a porous body, and contacting the protein immobilized in the pore and a protease immobilized on a solid surface such that the protease selectively accesses a site of the protein and proteolyzes the protein at the site.

A method of proteolyzing a protein, including immobilizing a protein in at least one pore of a porous body, and contacting the protein immobilized in the pore and a protease immobilized on a solid surface such that the protease selectively accesses a site of the protein and proteolyzes the protein at the site.

The present invention provides magnetic macroporous polymeric hybrid scaffolds for supporting and enhancing the effectiveness of bionanocatalysts (BNC). The novel scaffolds comprise cross-linked water-insoluble polymers and an approximately uniform distribution of embedded magnetic microparticles (MMP). The cross-linked polymer comprises polyvinyl alcohol (PVA) and optionally additional polymeric materials. The scaffolds may take any shape by using a cast during preparation of the scaffolds. Alternatively, the scaffolds may be ground to microparticles for use in biocatalytic reactions. Alternatively, the scaffolds may be shaped as beads for use in biocatalyst reactions. Methods for preparing and using the scaffolds are also provided.

The present invention provides engineered polypeptides that are useful for the asymmetric synthesis of β-hydroxy-α-amino acids under industrial-relevant conditions. The engineered polypeptides disclosed in this invention were developed through directed evolution based on the ability of catalytic synthesis of (2S, 3R)-2-amino-3-hydroxy-3-(4-nitrophenyl) propanoic acid. The present disclosure also provides polynucleotides encoding engineered polypeptides, host cells capable of expressing engineered polypeptides, and methods of producing β-hydroxy-α-amino acids using engineered polypeptides. Compared to other processes of preparation, the use of the engineered polypeptides of the present invention for the preparation of β-hydroxy-α-amino acids results in high purity of the desired stereoisomers, mild reaction conditions, low pollution and low energy consumption. So, it has good industrial application prospects.

The present invention provides engineered polypeptides that are useful for the asymmetric synthesis of β-hydroxy-α-amino acids under industrial-relevant conditions. The engineered polypeptides disclosed in this invention were developed through directed evolution based on the ability of catalytic synthesis of (2S, 3R)-2-amino-3-hydroxy-3-(4-nitrophenyl) propanoic acid. The present disclosure also provides polynucleotides encoding engineered polypeptides, host cells capable of expressing engineered polypeptides, and methods of producing β-hydroxy-α-amino acids using engineered polypeptides. Compared to other processes of preparation, the use of the engineered polypeptides of the present invention for the preparation of β-hydroxy-α-amino acids results in high purity of the desired stereoisomers, mild reaction conditions, low pollution and low energy consumption. So, it has good industrial application prospects.