The flavin-containing monooxygenase (FMO) protein family specializes in the oxidation of xeno-substrates in order to facilitate the excretion of these compounds from living organisms. These enzymes can oxidize a wide array of heteroatoms, particularly soft nucleophiles, such as amines, sulfides, and phosphites. This reaction requires an oxygen, an NADPH cofactor, and an FAD prosthetic group. FMOs share several structural features, such as a NADPH binding domain, FAD binding domain, and a conserved arginine residue present in the active site. Recently, FMO enzymes have received a great deal of attention from the pharmaceutical industry both as a drug target for various diseases and as a means to metabolize pro-drug compounds into active pharmaceuticals. These monooxygenases are often misclassified because they share activity profiles similar to those of (CYP450), which is the major contributor to oxidative xenobiotic metabolism. However, a key difference between the two enzymes lies in how they proceed to oxidize their respective substrates; CYP enzymes make use of an oxygenated heme prosthetic group, while the FMO family utilizes FAD to oxidize its substrates.

Prior to the 1960s, the oxidation of xenotoxic materials was thought to be completely accomplished by . However, in the early 1970s, Dr. Daniel Ziegler from the University of Texas at Austin discovered a hepatic flavoprotein isolated from pig liver that was found to oxidize a vast array of various amines to their corresponding nitro state. This flavoprotein named "Ziegler's enzyme" exhibited unusual chemical and spectrometric properties. Upon further spectroscopic characterization and investigation of the substrate pool of this enzyme, Dr. Ziegler discovered that this enzyme solely bound FAD molecule that could form a C4a-hydroxyperoxyflavin intermediate, and that this enzyme could oxidize a wide variety of substrates with no common structural features, including phosphines, sulfides, selenium compounds, amongst others. Once this was noticed, Dr. Ziegler's enzyme was reclassified as a broadband flavin monooxygenase.

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