Abstract: A substantially pure Candida host cell is provided for the biotransformation of a substrate to a product wherein the host cell is characterized by a first genetic modification class that comprises one or more genetic modifications that collectively or individually disrupt at least one alcohol dehydrogenase gene in the substantially pure Candida host cell.

Abstract: Novel proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are novel polynucleotides capable of encoding these proteins, compositions that include one or more of these novel proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these novel compounds, diversification methods involving the novel compounds, and methods of using the compounds. Some of the novel methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: The invention provides methods employing iterative cycles of recombination and selection/screening for evolution of whole cells and organisms toward acquisition of desired properties. Examples of such properties include enhanced recombinogenicity, genome copy number, and capacity for expression and/or secretion of proteins and secondary metabolites.

Abstract: Novel proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are novel polynucleotides capable of encoding these proteins, compositions that include one or more of these novel proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these novel compounds, diversification methods involving the novel compounds, and methods of using the compounds. Some of the novel methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: Novel proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are novel polynucleotides capable of encoding these proteins, compositions that include one or more of these novel proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these novel compounds, diversification methods involving the novel compounds, and methods of using the compounds. Some of the novel methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: Novel proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are novel polynucleotides capable of encoding these proteins, compositions that include one or more of these novel proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these novel compounds, diversification methods involving the novel compounds, and methods of using the compounds. Some of the novel methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: A substantially pure Candida host cell for the production of a ?-carboxyl-?-hydroxy fatty acid having a carbon chain length in the range from C6 to C22, a ?,?-dicarboxylic fatty acid having a carbon chain length in the range from C6 to C22, or mixtures thereof, is provided. The Candida host cell is characterized by a first genetic modification class and a second genetic modification class. The first genetic modification class comprises one or more genetic modifications that disrupt the peroxisomal ?-oxidation pathway. The second genetic modification class comprises one or more genetic modifications that collectively or individually disrupt at least one gene selected from the group consisting of a CYP52A type cytochrome P450, a fatty alcohol oxidase, and an alcohol dehydrogenase.

Abstract: Methods of recombining nucleic acids, including homologous nucleic acids, are provided. Families of gene shuffling oligonucleotides and their use in recombination procedures, as well as polymerase and ligase mediated recombination methods are also provided.

Abstract: Proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are polynucleotides capable of encoding these proteins, compositions that include one or more of these proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these compounds, diversification methods involving the compounds, and methods of using the compounds. Some of the methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: Methods of recombining nucleic acids, including homologous nucleic acids, are provided. Families of gene shuffling oligonucleotides and their use in recombination procedures, as well as polymerase and ligase mediated recombination methods are also provided.

Abstract: The present invention is generally directed to the evolution of new metabolic pathways and the enhancement of bioprocessing through a process herein termed recursive sequence recombination. Recursive sequence recombination entails performing iterative cycles of recombination and screening or selection to “evolve” individual genes, whole plasmids or viruses, multigene clusters, or even whole genomes. Such techniques do not require the extensive analysis and computation required by conventional methods for metabolic engineering.

Abstract: Proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are polynucleotides capable of encoding these proteins, compositions that include one or more of these proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these compounds, diversification methods involving the compounds, and methods of using the compounds. Some of the methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: In silico nucleic acid recombination methods, related integrated systems utilizing genetic operators and libraries made by in silico shuffling methods are provided.

Abstract: Methods of recombining nucleic acids, including homologous nucleic acids, are provided. Families of gene shuffling oligonucleotides and their use in recombination procedures, as well as polymerase and ligase mediated recombination methods are also provided.

Abstract: Novel proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are novel polynucleotides capable of encoding these proteins, compositions that include one or more of these novel proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these novel compounds, diversification methods involving the novel compounds, and methods of using the compounds. Some of the novel methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: Proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are polynucleotides capable of encoding these proteins, compositions that include one or more of these proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these compounds, diversification methods involving the compounds, and methods of using the compounds. Some of the methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: Proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are polynucleotides capable of encoding these proteins, compositions that include one or more of these proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these compounds, diversification methods involving the compounds, and methods of using the compounds. Some of the methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: Proteins are provided herein, including proteins capable of catalyzing the acetylation of glyphosate and other structurally related proteins. Also provided are polynucleotides capable of encoding these proteins, compositions that include one or more of these proteins and/or polynucleotides, recombinant cells and transgenic plants comprising these compounds, diversification methods involving the compounds, and methods of using the compounds. Some of the methods and compounds provided herein can be used to render an organism, such as a plant, resistant to glyphosate.

Abstract: The invention provides methods employing iterative cycles of recombination and selection/screening for evolution of whole cells and organisms toward acquisition of desired properties. Examples of such properties include enhanced recombinogenicity, genome copy number, and capacity for expression and/or secretion of proteins and secondary metabolites.

Abstract: In silico nucleic acid recombination methods, related integrated systems utilizing genetic operators and libraries made by in silico shuffling methods are provided. One disclosed method involves identifying and producing a polypeptide. The method may involve (a) receiving data identifying sequences of two or more parental polypeptides or parental nucleic acids that encode the polypeptides; (b) selecting one or more cross-over sites on the sequences thereby defining one or more recombinant polypeptides or recombinant nucleic acids; (c) selecting at least one of the recombinant polypeptides or recombinant nucleic acids; (d) recombining one or more oligonucleotides, at least one of which has a sequence matching some or all of that of the recombinant polypeptides or recombinant nucleic acids selected in (c); (e) selecting at least some of the recombined oligonucleotides produced in (d); and (f) producing a polypeptide encoded by the selected nucleic acid.