Abstract: A method of producing promorphinan, morphinan, nal-opioid, and nor-opioid alkaloid products through the increased conversion of a promorphinan alkaloid to a morphinan alkaloid. The method comprises contacting the promorphinan alkaloid with at least one enzyme. Contacting the promorphinan alkaloid with the at least one enzyme converts the promorphinan alkaloid to a morphinan alkaloid.

Abstract: A method of epimerizing an (S)-1-benzylisoquinoline alkaloid to an (R)-1-benzylisoquinoline alkaloid is provided. The method comprises contacting the (S)-1-benzylisoquinoline alkaloid with at least one enzyme. Contacting the (S)-1-benzylisoquinoline alkaloid with the at least one enzyme converts the (S)-1-benzylisoquinoline alkaloid to an (R)-1-benzylisoquinoline alkaloid.

Abstract: A method of demethylizing an opioid to a nor-opioid is provided. The method comprises contacting an opioid with at least one enzyme. Contacting the opioid with the at least one enzyme converts the opioid to a nor-opioid. A method of converting a nor-opioid to a nal-opioid is provided. The method comprises contacting a nor-opioid with at least one enzyme. Contacting the nor-opioid with the at least one enzyme converts the nor-opioid to a nal-opioid.

Abstract: A method of demethylizing an opioid to a nor-opioid is provided. The method comprises contacting an opioid with at least one enzyme. Contacting the opioid with the at least one enzyme converts the opioid to a nor-opioid. A method of converting a nor-opioid to a nal-opioid is provided. The method comprises contacting a nor-opioid with at least one enzyme. Contacting the nor-opioid with the at least one enzyme converts the nor-opioid to a nal-opioid.

Abstract: Methods and systems are provided for producing codeinone within an engineered non-plant cell. The method comprises, within the engineered non-plant cell, producing a thebaine product. The method also comprises, within the engineered non-plant cell, contacting the thebaine product with an enzyme having thebaine 6-O-demethylase activity, thereby producing a neopinone product. Additionally, the method comprises, within the engineered non-plant cell, contacting the neopinone product with a neopinone isomerase, thereby producing a codeinone product.

Abstract: Aspects of the invention include host cells that are engineered to produce benzylisoquinoline alkaloids (BIAs). The host cells include heterologous coding sequences for a variety of enzymes involved in synthetic pathways from starting compounds to BIAs of the host cell. Also provided are methods of producing the BIAs of interest by culturing the host cells under culture conditions that promote expression of enzymes encoded by the heterologous coding sequences of the host cells. Aspects of the invention further include compositions, e.g., host cells, starting compounds and kits, etc., that find use in methods of the invention.

Abstract: Aspects of the invention include host cells that are engineered to produce benzylisoquinoline alkaloids (BIAs). The host cells include heterologous coding sequences for a variety of enzymes involved in synthetic pathways from starting compounds to BIAs of the host cell. Also provided are methods of producing the BIAs of interest by culturing the host cells under culture conditions that promote expression of enzymes encoded by the heterologous coding sequences of the host cells. Aspects of the invention further include compositions, e.g., host cells, starting compounds and kits, etc., that find use in methods of the invention.

Abstract: Aspects of the invention include host cells that are engineered to produce benzylisoquinoline alkaloids (BIAs). The host cells include heterologous coding sequences for a variety of enzymes involved in synthetic pathways from starting compounds to BIAs of the host cell. Also provided are methods of producing the BIAs of interest by culturing the host cells under culture conditions that promote expression of enzymes encoded by the heterologous coding sequences of the host cells. Aspects of the invention further include compositions, e.g., host cells, starting compounds and kits, etc., that find use in methods of the invention.

Abstract: Aspects of the invention include host cells that are engineered to produce benzylisoquinoline alkaloids (BIAs). The host cells include heterologous coding sequences for a variety of enzymes involved in synthetic pathways from starting compounds to BIAs of the host cell. Also provided are methods of producing the BIAs of interest by culturing the host cells under culture conditions that promote expression of enzymes encoded by the heterologous coding sequences of the host cells. Aspects of the invention further include compositions, e.g., host cells, starting compounds and kits, etc., that find use in methods of the invention.

Abstract: A method of demethylizing an opioid to a nor-opioid is provided. The method comprises contacting an opioid with at least one enzyme. Contacting the opioid with the at least one enzyme converts the opioid to a nor-opioid. A method of converting a nor-opioid to a nal-opioid is provided. The method comprises contacting a nor-opioid with at least one enzyme. Contacting the nor-opioid with the at least one enzyme converts the nor-opioid to a nal-opioid.

Abstract: A method of producing promorphinan, morphinan, nal-opioid, and nor-opioid alkaloid products through the increased conversion of a promorphinan alkaloid to a morphinan alkaloid. The method comprises contacting the promorphinan alkaloid with at least one enzyme. Contacting the promorphinan alkaloid with the at least one enzyme converts the promorphinan alkaloid to a morphinan alkaloid.

Abstract: Methods and engineered yeast cells for generating a benzylisoquinoline alkaloid product are provided herein. A method comprises providing engineered yeast cells and a feedstock to a reactor. In the reactor, the engineered yeast cells are subjected to fermentation by incubating the engineered yeast cells for a time period to produce a solution comprising the BIA product and cellular material. The solution comprises not more than one class of molecule selected from the group of protoberberine, morphinan, isopavine, aporphine, and benzylisoquinoline. Additionally, at least one separation unit is used to separate the BIA product from the cellular material to provide the product stream comprising the BIA product.

Abstract: Aspects of the invention include host cells that are engineered to produce benzylisoquinoline alkaloids (BIAs). The host cells include heterologous coding sequences for a variety of enzymes involved in synthetic pathways from starting compounds to BIAs of the host cell. Also provided are methods of producing the BIAs of interest by culturing the host cells under culture conditions that promote expression of enzymes encoded by the heterologous coding sequences of the host cells. Aspects of the invention further include compositions, e.g., host cells, starting compounds and kits, etc., that find use in methods of the invention.

Abstract: Methods and engineered yeast cells for generating a benzylisoquinoline alkaloid product are provided herein. A method comprises providing engineered yeast cells and a feedstock to a reactor. In the reactor, the engineered yeast cells are subjected to fermentation by incubating the engineered yeast cells for a time period to produce a solution comprising the BIA product and cellular material. The solution comprises not more than one class of molecule selected from the group of protoberberine, morphinan, isopavine, aporphine, and benzylisoquinoline. Additionally, at least one separation unit is used to separate the BIA product from the cellular material to provide the product stream comprising the BIA product.

Abstract: A method of demethylizing an opioid to a nor-opioid is provided. The method comprises contacting an opioid with at least one enzyme. Contacting the opioid with the at least one enzyme converts the opioid to a nor-opioid. A method of converting a nor-opioid to a nal-opioid is provided. The method comprises contacting a nor-opioid with at least one enzyme. Contacting the nor-opioid with the at least one enzyme converts the nor-opioid to a nal-opioid.

Abstract: Methods and engineered yeast cells for generating a benzylisoquinoline alkaloid product are provided herein. A method comprises providing engineered yeast cells and a feedstock to a reactor. In the reactor, the engineered yeast cells are subjected to fermentation by incubating the engineered yeast cells for a time period to produce a solution comprising the BIA product and cellular material. The solution comprises not more than one class of molecule selected from the group of protoberberine, morphinan, isopavine, aporphine, and benzylisoquinoline. Additionally, at least one separation unit is used to separate the BIA product from the cellular material to provide the product stream comprising the BIA product.

Abstract: A method of demethylizing an opioid to a nor-opioid is provided. The method comprises contacting an opioid with at least one enzyme. Contacting the opioid with the at least one enzyme converts the opioid to a nor-opioid. A method of converting a nor-opioid to a nal-opioid is provided. The method comprises contacting a nor-opioid with at least one enzyme. Contacting the nor-opioid with the at least one enzyme converts the nor-opioid to a nal-opioid.

Abstract: Aspects of the invention include host cells that are engineered to produce benzylisoquinoline alkaloids (BIAs). The host cells include heterologous coding sequences for a variety of enzymes involved in synthetic pathways from starting compounds to BIAs of the host cell. Also provided are methods of producing the BIAs of interest by culturing the host cells under culture conditions that promote expression of enzymes encoded by the heterologous coding sequences of the host cells. Aspects of the invention further include compositions, e.g., host cells, starting compounds and kits, etc., that find use in methods of the invention.

Abstract: Methods and engineered yeast cells for generating a benzylisoquinoline alkaloid product are provided herein. A method comprises providing engineered yeast cells and a feedstock to a reactor. In the reactor, the engineered yeast cells are subjected to fermentation by incubating the engineered yeast cells for a time period to produce a solution comprising the BIA product and cellular material. The solution comprises not more than one class of molecule selected from the group of protoberberine, morphinan, isopavine, aporphine, and benzylisoquinoline. Additionally, at least one separation unit is used to separate the BIA product from the cellular material to provide the product stream comprising the BIA product.

Abstract: Aspects of the invention include host cells that are engineered to produce benzylisoquinoline alkaloids (BIAs). The host cells include heterologous coding sequences for a variety of enzymes involved in synthetic pathways from starting compounds to BIAs of the host cell. Also provided are methods of producing the BIAs of interest by culturing the host cells under culture conditions that promote expression of enzymes encoded by the heterologous coding sequences of the host cells. Aspects of the invention further include compositions, e.g., host cells, starting compounds and kits, etc., that find use in methods of the invention.