Abstract: The present invention encompasses modified luciferases, methods for making modified luciferases, and assays utilizing modified luciferases. Modified luciferases of the invention show increased activity over wildtype luciferases and also show increased stability of signal. The present invention also encompasses multiplex assays utilizing multiple luciferases with different emission spectra.

Abstract: Luciferase enzymes with greatly increased thermostability, e.g., at least half lives of 2 hours at 50° C., cDNAs encoding the novel luciferases, and hosts transformed to express the luciferases, are disclosed. Methods of producing the luciferases include recursive mutagenesis. The luciferases are used in conventional methods, some employing kits.

Abstract: Luciferase enzymes with greatly increased thermostability, e.g., at least half lives of 2 hours at 50° C., cDNAs encoding the novel luciferases, and hosts transformed to express the luciferases, are disclosed. Methods of producing the luciferases include recursive mutagenesis. The luciferases are used in conventional methods, some employing kits.

Abstract: An object of the present invention is to provide a mutant luciferase having luciferase activity with an altered emission spectrum. A specific amino acid residue(s) is substituted in a luciferase derived from Cypridina noctiluca and then the resulting mutant luciferase having luciferase activity with an emission spectrum differing from that of the wild-type luciferase is screened for.

Abstract: Luciferase enzymes with greatly increased thermostability, e.g., at least half lives of 2 hours at 50° C., cDNAs encoding the novel luciferases, and hosts transformed to express the luciferases, are disclosed. Methods of producing the luciferases include recursive mutagenesis. The luciferases are used in conventional methods, some employing kits.

Abstract: An object of the present invention is to provide a mutant luciferase having luciferase activity with an altered emission spectrum. A specific amino acid residue(s) is substituted in a luciferase derived from Cypridina noctiluca and then the resulting mutant luciferase having luciferase activity with an emission spectrum differing from that of the wild-type luciferase is screened for.

Abstract: Luciferase enzymes with greatly increased thermostability, e.g., at least half lifes of 2 hours at 50° C., cDNAs encoding the novel luciferases, and hosts transformed to express the luciferases, are disclosed. Methods of producing the luciferases include recursive mutagenesis. The luciferases are used in conventional methods, some employing kits.

Abstract: A firefly luciferase having the amino acid sequence of firefly luciferase, wherein the amino acid corresponding to position 287 of Heike firefly luciferase is replaced with alanine, or wherein the amino acid corresponding to position 392 is replaced with isoleucine. The firefly luciferase has improved thermostability and storage stability. A firefly luciferase gene coding for the firefly luciferase. By utilizing this gene, it is possible to efficiently produce firefly luciferase with increased stability. It is also possible to obtain firefly luciferase with further increased stability by combination with a mutation in which the amino acid at position 326 is replaced with serine, and/or a mutation in which the amino acid at position 467 is replaced with isoleucine.

Abstract: An isolated recombinant luciferase having luciferase activity. The recombinant luciferase has an amino acid sequence which differs from the wild-type luciferase from Phtotinus pyralis, Luciola mingrelica, Luciola cruciata, Luciola lateralis, Hotaria parvula, Pyrophorus plagiophthalamus, Lampyris noctiluca, Pyrocoelia miyako or Photinus pennsylvanica. In the seguence of the recombinant luciferase, the amino acid residue corresponding to phenylalanine 295 in Photinus pyralis wild-type luciferase or to leucine 297 in Luciola mingrelica, Luciola cruciata or Luciola lateralis wild-type luciferases, is mutated compared to the corresponding amino acid which appears in the corresponding wild-type luciferase sequence. The recombinant luciferase has increased thermostability compared to the corresponding wild-type luciferase.

Abstract: Luciferase enzymes with greatly increased thermostability, e.g., at least half lives of 2 hours at 50° C., cDNAs encoding the novel luciferases, and hosts transformed to express the luciferases, are disclosed. Methods of producing the luciferases include recursive mutagenesis. The luciferases are used in conventional methods, some employing kits.

Abstract: An isolated recombinant luciferase having luciferase activity. The recombinant luciferase has an amino acid sequence which differs from the wild-type luciferase from Photinus pyralis, Luciola mingrelica, Luciola cruciata, Luciola lateralis, Hotaria parvula, Pyrophorus plagiophthalamus, Lampyris noctiluca, Pyrocoelia miyako or Photinus pennsylvanica. In the sequence of the recombinant luciferase, the amino acid residue corresponding to phenylalanine 295 in Photinus pyralis wild-type luciferase or to leucine 297 in Luciola mingrelica, Luciola cruciata or Luciola lateralis wild-type luciferases, is mutated compared to the corresponding amino acid which appears in the corresponding wild-type luciferase sequence. The recombinant luciferase has increased thermostability compared to the corresponding wild-type luciferase.

Abstract: An isolated recombinant luciferase having luciferase activity. The recombinant luciferase has an amino acid sequence which differs from the wild-type luciferase from Photinus pyralis, Luciola mingrelica, Luciola cruciata, Luciola lateralis, Hotaria parvula, Pyrophorus plagiophthalamus, Lampyris noctiluca, Pyrocoelia miyako or Photinus pennsylvanica. In the sequence of the recombinant luciferase, the amino acid residue corresponding to phenylalanine 295 in Photinus pyralis wild-type luciferase or to leucine 297 in Luciola mingrelica, Luciola cruciata or Luciola lateralis wild-type luciferases, is mutated compared to the corresponding amino acid which appears in the corresponding wild-type luciferase sequence. The recombinant luciferase has increased thermostability compared to the corresponding wild-type luciferase.

Abstract: Luciferase enzymes with greatly increased thermostability, e.g., at least half lives of 2 hours at 50° C., cDNAs encoding the novel luciferases, and hosts transformed to express the luciferases, are disclosed. Methods of producing the luciferases include recursive mutagenesis. The luciferases are used in conventional methods, some employing kits.

Abstract: Luciferase enzymes with greatly increased thermostability, e.g., at least half lives of 2 hours at 50° C., cDNAs encoding the novel luciferases, and hosts transformed to express the luciferases, are disclosed. Methods of producing the luciferases include recursive mutagenesis. The luciferases are used in conventional methods, some employing kits.

Abstract: Luciferase enzymes with greatly increased thermostability, e.g., at least half lives of 2 hours at 50° C., cDNAs encoding the novel luciferases, and hosts transformed to express the luciferases, are disclosed. Methods of producing the luciferases include recursive mutagenesis. The luciferases are used in conventional methods, some employing kits.

Abstract: The invention comprises modified luciferase proteins which are more resistant to inhibition by test chemicals than wild type luciferase. The modified luciferases also contain greater thermostability than wild type luciferase.

Abstract: A polynucleotide encoding a modified luciferase polypeptide. The modified luciferase polypeptide has at least 60% amino acid sequence identity to a wild-type Oplophorus luciferase and includes at least one amino acid substitution at a position corresponding to an amino acid in a wild-type Oplophorus luciferase of SEQ ID NO:1. The modified luciferase polypeptide has at least one of enhanced luminescence, enhanced signal stability, and enhanced protein stability relative to the wild-type Oplophorus luciferase.

Abstract: A codon optimized and stabilized luciferase gene based upon the sequence of the natural luciferase gene isolated from Luciola cruciata (Japanese firefly) and a novel recombinant DNA characterized by incorporating this new gene coding for a novel luciferase into a vector DNA for improved activities in mammalian cells, are disclosed. This new luciferase exhibits long-wavelength light emission, as well as improved thermostability and higher expression levels in mammalian cell systems, compared to native luciferase.

Abstract: A recombinant protein having luciferase activity and at least 60% similarity to a wild-type luciferase wherein in the sequence of the enzyme, the amino acid residue corresponding to residue 357 in Photinus pyralis luciferase is mutated as compared to the corresponding wild-type luciferase, such that the luciferase enzyme is able to emit light at a different wavelength as compared to the corresponding wild-type luciferase and/or has enhanced thermostability as compared to the corresponding wild-type luciferase. In general, the residue corresponding to 357 in Photinus pyralis luciferase is changed from an acidic amino acid to a non-acidic amino acid, and preferably an uncharged polar amino acid such as tyrosine. Mutant luciferases in accordance with the invention can produce a large (50 nm) wavelength shift in emitted light and have good thermostability. The resultant colour shift can be reversed by addition of coenzyme A. These properties make the mutant particularly useful in a variety of assays.

Abstract: A polynucleotide encoding a modified luciferase polypeptide. The modified luciferase polypeptide has at least 60% amino acid sequence identity to a wild-type Oplophorus luciferase and includes at least one amino acid substitution at a position corresponding to an amino acid in a wild-type Oplophorus luciferase of SEQ ID NO:1. The modified luciferase polypeptide has at least one of enhanced luminescence, enhanced signal stability, and enhanced protein stability relative to the wild-type Oplophorus luciferase.