Among the various aspects of the present disclosure relates to methods and compositions useful in convert inflammatory dietary fatty acids (omega 6) to anti-inflammatory fatty acids (omega 3). Specifically, the present disclosure provides methods and compositions for increasing n-3 desaturase expression or activity in a subject. The disclosure provides various compositions for providing increased n-3 desaturase expression or activity including a variety of viral vector and engineered microorganisms The disclosure provides, in part, methods for reducing local and/or systemic inflammation, improving wound healing, preventing premature cellular enescence, treating or preventing a disease, disorder, or condition related to inflammation or obesity and treating or preventing arthritis.

The disclosure relates to the biosynthesis of terpenoids, such as, for example, geraniol and derivatives thereof, using genetic engineering. In particular, the disclosure relates to the biosynthesis of nepetalactol, nepetalactone, dihydronepetalactone, and derivatives thereof. The disclosure provides recombinant cells genetically engineered to produce high levels of nepetalactol, nepetalactone and/or dihydronepetalactone. The disclosure also provides methods of producing nepetalactol, nepetalactone and dihydronepetalactone using cell-based systems as well as cell-free systems.

Described herein are an immobilized enzyme, and a preparation method therefor and a use thereof. The immobilized enzyme includes activated PEI and an enzyme covalently bonded to the activated PEI, where the enzyme is selected from any one of a transaminase, a ketoreductase, a monooxygenase, an ammonia lyase, an ene-reductase, an imine reductase, an amino acid dehydrogenase and a nitrilase.

Disclosed herein are primers for amplifying enone oxidoreductase, having a sequence selected from the group consisting of SEQ ID Nos. 1 to 13, from mango. Also disclosed herein is a nucleotide sequence of SEQ ID No. 14 encoding enone oxidoreductase, for enzyme production in an artificial system thus generating the desired flavor in food products.

The complex chemistry underlying the extensive transformations involved in terpene indole alkaloid synthesis makes identification of the biosynthetic genes challenging. The present invention relates to methods for producing a terpene indole alkaloid derivative, comprising the steps of: (1) providing a terpene indole alkaloid; and (2) providing a first enzyme termed “Precondylocarpine Acetate Synthase” (PAS) or a functional variant or homologue thereof; and/or a second enzyme termed “Dehydroprecondylocarpine Acetate Synthase” (DPAS) or a functional variant or homologue thereof, and optionally providing further identified enzymes involved in this pathway. The invention also encompasses related kits, enzymes, expression vectors, host cells and plants.

Recombinant microorganisms comprising at least one exogenous nucleic acid sequence and capable of producing adipate semialdehyde are provided. Adipate semialdehyde may be produced in a synthesis pathway utilizing a single thiolase reaction. Adipate semialdehyde may also be produced from intermediates consisting of alpha, omega difunctional aliphatic organic molecules. Methods of using recombinant microorganisms to produce 6-aminocaproic acid, adipic acid, hexamethylenediamine and 1.6-hexanediol are also provided.

A method for reducing a substrate selected from 2-methyl-5-nitropyridine and methyl 4-(2-fluoro-3-nitrobenzyl)piperazine-1-carboxylate is provided catalysed by a nitroreductase and a disproportionation agent.

The present disclosure provides isolated nepetalactone oxidoreductase polypeptides (NORs), nepetalactol synthases (NEPSs), and related polynucleotides, engineered host cells, and cultures, as well as methods for producing NORs and NEPSs, and for using them to produce nepetalactol, nepetalactone, and dihydronepetalactone. The present disclosure also provides methods for engineering cells (e.g., microbial cells) to produce nepetalactone from a fermentation substrate such as glucose, as well as engineered cells having this capability and related cultures and methods for producing nepetalactone.

The invention relates to an enzymatic method for producing a reaction product. A method of recycling a biological cofactor is also provided. The invention also relates to systems and apparatuses for conducting such methods.

The present disclosure describes the engineering of microbial cells for fermentative production of 4-APEA and related products and provides novel engineered microbial cells and cultures, as well as related 4-APEA production methods.