Reusable microsomal biocatalytic systems (bioreactors) constructed on carbon nanostructure modified electrodes are provided. The bioreactors comprise stable, biologically active immobilized enzymes such as human cytochromes P 450 (CYPs) and their redox partner proteins, e.g. CYP-NADPH (reduced nicotinamide adenine dinucleotide phosphate) reductases (CPR), on the carbon nanostructure surface. The immobilized enzymes may be present in liver microsomes, such as human liver microsomes (HLM) or as bactosomes, S9 fractions, etc. The bioreactors are used, for example, for synthesizing metabolites of interest from compounds such as drugs that are catabolized by the enzymes.

Reusable microsomal biocatalytic systems (bioreactors) constructed on carbon nanostructure modified electrodes are provided. The bioreactors comprise stable, biologically active immobilized enzymes such as human cytochromes P 450 (CYPs) and their redox partner proteins, e.g. CYP-NADPH (reduced nicotinamide adenine dinucleotide phosphate) reductases (CPR), on the carbon nanostructure surface. The immobilized enzymes may be present in liver microsomes, such as human liver microsomes (HLM) or as bactosomes, S9 fractions, etc. The bioreactors are used, for example, for synthesizing metabolites of interest from compounds such as drugs that are catabolized by the enzymes.

7-hydroxylation systems are provided, as well as methods for producing ?P-hydroxy derivatives of lithocholic acid and 3-keto-lithocholic acid from such systems. Also provided are recombinant organisms useful for the production of such enzymatic systems, and to plasmids that encode for such enzymes.

7-hydroxylation systems are provided, as well as methods for producing ?P-hydroxy derivatives of lithocholic acid and 3-keto-lithocholic acid from such systems. Also provided are recombinant organisms useful for the production of such enzymatic systems, and to plasmids that encode for such enzymes.

Provided are a cytochrome P450 (CYP716A53v2) mutant protein and the use thereof. The mutation is mutated at a site selected from the group consisting of F167V, T451A, I117S and L208C or a combination thereof on the basis of a wild-type CYP716A53v2 protein. The enzyme catalytic activity of the CYP716A53v2 mutant obtained after mutation is improved, and the yield of panaxatriol can be improved.

Provided are a cytochrome P450 (CYP716A53v2) mutant protein and the use thereof. The mutation is mutated at a site selected from the group consisting of F167V, T451A, I117S and L208C or a combination thereof on the basis of a wild-type CYP716A53v2 protein. The enzyme catalytic activity of the CYP716A53v2 mutant obtained after mutation is improved, and the yield of panaxatriol can be improved.

Generally, the present invention relates to the field of steroid hydroxylation. More specifically, the present invention relates to a method for the 21-hydroxylation of steroids in cells. It also relates to cells expressing a steroid 21-hydroxylating enzyme or steroid 21-hydroxylase, expression vectors comprising a nucleic acid encoding for a steroid 21-hydroxylase and a kit for carrying out the method for the 21-hydroxylation of steroids in cells.

Generally, the present invention relates to the field of steroid hydroxylation. More specifically, the present invention relates to a method for the 21-hydroxylation of steroids in cells. It also relates to cells expressing a steroid 21-hydroxylating enzyme or steroid 21-hydroxylase, expression vectors comprising a nucleic acid encoding for a steroid 21-hydroxylase and a kit for carrying out the method for the 21-hydroxylation of steroids in cells.

Generally, the present invention relates to the field of steroid hydroxylation. More specifically, the present invention relates to a method for the 21-hydroxylation of steroids in cells. It also relates to cells expressing a steroid 21-hydroxylating enzyme or steroid 21-hydroxylase, expression vectors comprising a nucleic acid encoding for a steroid 21-hydroxylase and a kit for carrying out the method for the 21-hydroxylation of steroids in cells.

Generally, the present invention relates to the field of steroid hydroxylation. More specifically, the present invention relates to a method for the 21-hydroxylation of steroids in cells. It also relates to cells expressing a steroid 21-hydroxylating enzyme or steroid 21-hydroxylase, expression vectors comprising a nucleic acid encoding for a steroid 21-hydroxylase and a kit for carrying out the method for the 21-hydroxylation of steroids in cells.