Abstract: This invention provides methods for obtaining specific and stable integration of nucleic acids into eukaryotic cells. The invention makes use of site-specific recombination systems that use prokaryotic recombinase polypeptides, such as the ?C31 integrase, that can mediate recombination between the recombination sites, but not between hybrid recombination sites that are formed upon the recombination. Thus, the recombination is irreversible in the absence of additional factors. Eukaryotic cells that contain the recombinase polypeptides, or genes that encode the recombinases, are also provided.

Abstract: The present invention includes compositions and methods for site-specific polynucleotide replacement in eukaryotic cells. These methods include single polynucleotide replacement as well as gene stacking methods. Preferred eukaryotic cells for use in the present invention are plant cells and mammalian cells.

Abstract: Prokaryotic recombination systems have been adapted to function in eukaryotes in order to achieve one or more of the following: DNA site specific excision, translocation, integration and inversion. These recombination systems are identified as seven members of the small serine resolvase subfamily: CinH, ParA, Tn1721, Tn5053, Tn21, Tn402, and Tn501 and three members of the large serine resolvase subfamily: Bxb1, U153, and TP901-1. These recombination systems represent new tools for the genetic manipulation of eukaryotic genomes.

Abstract: Prokaryotic recombination systems have been adapted to function in eukaryotes in order to achieve one or more of the following: DNA site specific excision, translocation, integration and inversion. These recombination systems are identified as seven members of the small serine resolvase subfamily: CinH, ParA, Tn1721, Tn5053, Tn21, Tn402, and Tn501 and three members of the large serine resolvase subfamily: Bxb1, U153, and TP901-1. These recombination systems represent new tools for the genetic manipulation of eukaryotic genomes.

Abstract: The present invention includes compositions and methods for site-specific polynucleotide replacement in eukaryotic cells. These methods include single polynucleotide replacement as well as gene stacking methods. Preferred eukaryotic cells for use in the present invention are plant cells and mammalian cells.

Abstract: This invention provides methods for obtaining specific and stable integration of nucleic acids into eukaryotic cells. The invention makes use of site-specific recombination systems that use prokaryotic recombinase polypeptides, such as the &PHgr;C31 integrase, that can mediate recombination between the recombination sites, but not between hybrid recombination sites that are formed upon the recombination. Thus, the recombination is irreversible in the absence of additional factors. Eukaryotic cells that contain the recombinase polypeptides, or genes that encode the recombinases, are also provided.

Abstract: The present invention includes compositions and methods for site-specific polynucleotide replacement in eukaryotic cells. These methods include single polynucleotide replacement as well as gene stacking methods. Preferred eukaryotic cells for use in the present invention are plant cells and mammalian cells.

Abstract: The present invention provides methods for producing a transgenic cell having a stably integrated, single copy of an exogenous polynucleotide sequence. The method, which resolves repeated insertions of the introduced polynucleotide sequence into a single copy, involves introducing into a genetic locus of a cell a polynucleotide sequence flanked on each end by a recombination site. The recombination sites are oriented such that contact with a recombinase would not result in deletion of the polynucleotide sequence from the construct. The multiple, tandem copies of the introduced polynucleotide locus are then contacted with a recombinase that catalyzes recombination among the recombination sites. As a result of this method, the multiple, tandem copies are resolved to a single copy.

Abstract: A method is disclosed for producing a protein which expresses bioluminescence activity which involves combining two polydeoxyribonucleotides, one containing a continuous sequence of codons encoding a polypeptide which comprises a single covalently bonded molecular structure and which catalyzes the oxidation of insect luciferin to yield light and the other which causes DNA transcription, and obtaining the polypeptide by transcription and subsequent translation. The insect luciferin is derived from bioluminescent insect, preferably Diptera and Coleoptera (fireflies and beetles). Hybrid proteins are similarly formed by inclusion of an additional polydeoxyribonucleotide encoding for a second polypeptide such that their respective polypeptide-encoding reading frames form a continuous reading frame.

Abstract: A method is disclosed for producing a protein which expresses bioluminescence activity which involves combining two polydeoxyribonucleotides, one containing a continuous sequence of codons encoding a polypeptide which comprises a single covalently bonded molecular structure and which catalyzes the oxidation of insect luciferin to yield light and the other which causes DNA transcription, and obtaining the polypeptide by transcription and subsequent translation. The insect luciferin is derived from bioluminescent insect, preferably Diptera and Coleoptera (fireflies and beetles). Hybrid proteins are similarly formed by inclusion of an additional polydeoxyribonucleotide encoding for a second polypeptide such that their respective polypeptide-encoding reading frames form a continuous reading frame.