The present invention provides a method of designing an optimized gene which comprises altering a nucleotide sequence of a target protein gene, so that only preferential codons with high frequency of use in human cells are selected and a GC content of not less than 60% is achieved. A gene design method which involves the feature “only preferential codons with high frequency of use are selected and a GC content of not less than 60% is achieved” can be established as a general rule for preparing proteins with high expression level, in order to obtain chemically synthesized genes for proteins capable of high-level expression in eukaryotes.

The present invention provides a luminescent enzyme protein comprising the amino acid sequence represented by SEQ ID NO: 2, and a mutant enzyme thereof.

A novel luciferase that is distinct from conventional luciferase has been desired. A luciferase mutant comprising an amino acid sequence in which glutamic acid at position 4, arginine at position 11, leucine at position 18 and valine at position 27 are substituted with other amino acids, in the amino acid sequence of SEQ ID NO: 2.

Provided herein are enhanced luciferase enzymes for use with thermostable luciferin analogs for bioluminescent assays. In particular, the present disclosure provides compositions, assays, and methods for performing a bioluminescent assay using enhanced, high-activity luciferase enzymes compatible with thermostable luciferins, such as 5,5-disubstituted luciferin analogs.

A Bradyrhizobium monooxygenase, a gene for encoding the monooxygenase, a recombinant expression vector comprising the gene and a recombinant transformant, a method of preparing the monooxygenase by the recombinant expression transformant, and a method of preparing an optically pure chiral sulfoxide by the monooxygenase, in particular to a method of preparing prazole drugs by means of catalyzing the asymmetric oxidation of thioether, a prazole precursor. As compared with other methods of preparing an optically pure sulfoxide, the product produced by the monooxygenase of the present invention as a catalyst has high optical purity, avoids the generation of the byproduct sulfone, and has advantages of mild reaction conditions, simple and convenient operations, easy amplification, etc.

Provided herein are compositions and methods for the assembly of a tripartite or multipartite bioluminescent complex. In particular, a bioluminescent complex is formed upon the interaction of two or more peptide tags (e.g., separately or fused as a dipeptide or tripeptide) and a polypeptide component.

Disclosed herein are devices, methods, and systems for rapid detection of microorganisms using a recombinant bacteriophage. The specificity of recombinant bacteriophages for binding microorganisms allows targeted and highly specific detection of a microorganism of interest.

A Bradyrhizobium monooxygenase, a gene for encoding the monooxygenase, a recombinant expression vector comprising the gene and a recombinant transformant, a method of preparing the monooxygenase by the recombinant expression transformant, and a method of preparing an optically pure chiral sulfoxide by the monooxygenase, in particular to a method of preparing prazole drugs by means of catalyzing the asymmetric oxidation of thioether, a prazole precursor. As compared with other methods of preparing an optically pure sulfoxide, the product produced by the monooxygenase of the present invention as a catalyst has high optical purity, avoids the generation of the byproduct sulfone, and has advantages of mild reaction conditions, simple and convenient operations, easy amplification, etc.

Provided herein are enhanced luciferase enzymes for use with thermostable luciferin analogs for bioluminescent assays. In particular, the present disclosure provides compositions, assays, and methods for performing a bioluminescent assay using enhanced, high-activity luciferase enzymes compatible with thermostable luciferins, such as 5,5-disubstituted luciferin analogs.

Disclosed are luciferase polypeptides with improved light-emitting activity and their encoding nucleic acids. These molecules are useful in a range of assays including luciferase-based gene reporter assays, bioluminescence resonance energy transfer assays, protein complementation assays and other applications in which luciferase enzymes are utilized as detectable and/or quantifiable labels. Also disclosed are methods and compositions for increasing the sensitivity and/or improving the kinetics of luciferase-catalyzed reactions as well as decreasing the impact of undesirable variables.