Characterization of the purified microsomal FAD-containing monooxygenase from mouse and pig liver

Properties and Mechanisms of Flavin-Dependent Monooxygenases and Their Applications in Natural Product Synthesis

Natural products are usually highly complicated organic molecules with special scaffolds, and they are an important resource in medicine. Natural products with complicated structures are produced by enzymes, and this is still a challenging research field, its mechanisms requiring detailed methods for elucidation. Flavin adenine dinucleotide (FAD)-dependent monooxygenases (FMOs) catalyze many oxidation reactions with chemo-, regio-, and stereo-selectivity, and they are involved in the synthesis of many natural products. In this review, we introduce the mechanisms for different FMOs, with the classical FAD (C4a)-hydroperoxide as the major oxidant. We also summarize the difference between FMOs and cytochrome P450 (CYP450) monooxygenases emphasizing the advantages of FMOs and their specificity for substrates. Finally, we present examples of FMO-catalyzed synthesis of natural products. Based on these explanations, this review will expand our knowledge of FMOs as powerful enzymes, as well as implementation of the FMOs as effective tools for biosynthesis.

Benzydamine as a useful substrate of hepatic flavin-containing monooxygenase activity in veterinary species

Benzydamine (BZ), a weak base and an indazole derivative with analgesic and antipyretic properties used in human and veterinary medicine, is metabolized in human, rat, cattle and rabbit to a wide range of metabolites. One of the main metabolites, BZ N-oxide (BZ-NO), is produced in the liver and brain by flavin-containing monooxygenases (FMOs), by liver and brain enzymes. To evaluate the suitability of BZ as an FMO probe in veterinary species, BZ metabolism was studied in vitro using liver microsomes from bovine, rabbit and swine. Kinetic parameters, K(m) and V(max), of BZ-NO production, were evaluated to corroborate the pivotal role of FMOs. Inhibition studies were carried out by heat inactivation and by specific FMO chemical inhibitors: trimethylamine and methimazole. The results confirmed the presence of FMO activity in the liver and the role of BZ as a suitable marker of FMO enzyme activities for the veterinary species considered.

Characterization of sulfoxygenation and structural implications of human flavin-containing monooxygenase isoform 2 (FMO2.1) variants S195L and N413K

Catalytically active human flavin-containing monooxygenase isoform 2 (FMO2.1) is encoded by an allele detected only in individuals of African or Hispanic origin. Genotyping and haplotyping studies indicate that S195L and N413K occasionally occur secondary to the functional FMO2*1 allele encoding reference protein Gln472. Sulfoxygenation under a range of conditions reveals the role these alterations may play in individuals expressing active FMO2 and provides insight into FMO structure. Expressed S195L lost rather than gained activity as pH was increased or when cholate was present. The activity of S195L was mostly eliminated after heating at 45 degrees C for 5 min in the absence of NADPH, but activity was preserved if NADPH was present. By contrast, Gln472 was less sensitive to heat, a response not affected by NADPH. A major consequence of the S195L mutation was a mean 12-fold increase in K(m) for NADPH compared with Gln472. Modeling an S213L substitution, the equivalent site, in the structural model of FMO from the Methylophaga bacterium leads to disruption of interactions with NADP(+). N413K had the same pattern of activity as Gln472 in response to pH, cholate, and magnesium, but product formation was always elevated by comparison. N413K also lost more activity when heated than Gln472; however, NADPH attenuated this loss. The major effects of N413K were increases in velocity and k(cat) compared with Gln472. Although these allelic variants are expected to occur infrequently as mutations to the FMO2*1 allele, they contribute to our overall understanding of mammalian FMO structure and function.

Mammalian flavin-containing monooxygenases: structure/function, genetic polymorphisms and role in drug metabolism

Flavin-containing monooxygenase (FMO) oxygenates drugs and xenobiotics containing a "soft-nucleophile", usually nitrogen or sulfur. FMO, like cytochrome P450 (CYP), is a monooxygenase, utilizing the reducing equivalents of NADPH to reduce 1 atom of molecular oxygen to water, while the other atom is used to oxidize the substrate. FMO and CYP also exhibit similar tissue and cellular location, molecular weight, substrate specificity, and exist as multiple enzymes under developmental control. The human FMO functional gene family is much smaller (5 families each with a single member) than CYP. FMO does not require a reductase to transfer electrons from NADPH and the catalytic cycle of the 2 monooxygenases is strikingly different. Another distinction is the lack of induction of FMOs by xenobiotics. In general, CYP is the major contributor to oxidative xenobiotic metabolism. However, FMO activity may be of significance in a number of cases and should not be overlooked. FMO and CYP have overlapping substrate specificities, but often yield distinct metabolites with potentially significant toxicological/pharmacological consequences. The physiological function(s) of FMO are poorly understood. Three of the 5 expressed human FMO genes, FMO1, FMO2 and FMO3, exhibit genetic polymorphisms. The most studied of these is FMO3 (adult human liver) in which mutant alleles contribute to the disease known as trimethylaminuria. The consequences of these FMO genetic polymorphisms in drug metabolism and human health are areas of research requiring further exploration.

Metabolism of [(1)(4)C]prometryn in rats

[(1)(4)C]Prometryn, 2, 4-bis(isopropylamino)-6-(methylthio)-s-triazine, was orally administered to male and female rats at approximately 0.5 and 500 mg/kg; daily urine and feces were collected. After 3 or 7 days rats were sacrificed, and blood and selected tissues were isolated. The urine and feces extracts were characterized for metabolite similarity as well as for metabolite identification. Over 30 metabolites were observed, and of these, 28 were identified mostly by mass spectrometry and/or cochromatography with available reference standards. The metabolism of prometryn was shown to occur by N-demethylation, S-oxidation, S-S dimerization, OH substitution for NH(2) and SCH(3), and conjugation with glutathione or glucuronic acid. Rat liver microsomal incubations of prometryn were conducted and compared to the in vivo metabolism. Both in vivo and in vitro phase I metabolisms of prometryn were similar, with S-oxidation and N-dealkylation predominating. The involvement of cytochrome P-450 and flavin-containing monooxidase in the in vitro metabolism of prometryn was investigated.

In vitro metabolism of clenbuterol and bromobuterol by pig liver microsomes

1. Clenbuterol (CBL) and bromobuterol (BBL) were both extensively metabolized by hepatic microsomes of swine to only one polar metabolite which was separated by hplc and purified to perform mass analysis. 2. LC-MIS analysis by direct infusion into an ion trap system and after reverse-phase chromatograpy into a triple quadrupole system showed that the metabolites were the hydroxylamine-derivatives of CBL and BBL. GC-MS analysis by the CI and EI modes confirmed that the hydroxyl group was bound to the aniline nitrogen. The chemical instability of those metabolites probably as a consequence of spontaneous oxidation and reduction gave rise during the analysis to the corresponding nitroso and nitro derivatives, together with the original compound. 3. Thermal inactivation and CO complex formation were used selectively to inactivate flavin monooxygenase and cytochrome P450, respectively. Both inactivation procedures significantly reduced the formation of the hydroxyl metabolite.

1H-NMR analysis of trimethylamine in urine for the diagnosis of fish-odour syndrome

This paper reports the use of proton NMR spectroscopy for the analysis of trimethylamine in the urine of a patient with trimethylaminuria. Analysis of this compound was also performed for other members of his family. Qualitative and quantitative determination of trimethylamine and trimethylamine-N-oxide was simultaneously performed on untreated urine within a few minutes. The application of the method is discussed.

Olfactory toxicity of methimazole: dose-response and structure-activity studies and characterization of flavin-containing monooxygenase activity in the Long-Evans rat olfactory mucosa

Methimazole is a compound administered to humans for the treatment of hyperthyroidism and is used experimentally as a model substrate for the flavin-containing monooxygenase (FMO) system. Previous results from this laboratory demonstrated that methimazole is an olfactory system toxicant, causing nearly complete destruction of the olfactory epithelium in the male Long-Evans rat following a single ip dose of 300 mg/kg. The present studies were undertaken to determine the dose-response relationship for methimazole-induced olfactory mucosal damage and to determine whether or not similar damage occurs as a result of oral administration, mimicking the relevant route of human exposure. We also investigated the mechanism of olfactory toxicity of methimazole by means of a structure-activity study and began the characterization of the form(s) of FMO present in the olfactory mucosa of the male Long-Evans rat. Dose-response analysis demonstrated that methimazole causes olfactory mucosal damage at doses of 25 mg/kg ip and greater. The results of gavage studies showed that a single oral dose of 50 mg/kg also caused olfactory mucosal damage. Two structurally related compounds, methylimidazole and methylpyrrole, were not olfactory toxicants, suggesting that a reactive intermediate generated in the course of metabolizing methimazole to an S-oxide is the olfactory toxic species. Microsomal incubation studies revealed the presence of methimazole S-oxidation activity in olfactory mucosal microsomes at levels comparable to those in liver. An anti-mouse liver FMO antibody reacted on Western blots with olfactory mucosal microsomes. These findings demonstrate a dose-response for the olfactory toxicity of methimazole and suggest that characterization of human olfactory mucosal FMO activity may be necessary to assess the potential for human risk associated with therapeutic exposure to methimazole.

Fish odour syndrome: verification of carrier detection test

An oral trimethylamine challenge test has been used to confirm the heterozygous status of patients with 'fish-odour syndrome'. By measuring the percentage of total urinary trimethylamine-related material excreted as the N-oxide, no discrimination could be made between obligate heterozygotes (parents of 'fish-odour syndrome' patients) (n = 15; 96 +/- 2%, range 92-98%) and control individuals (parents of unaffected children) (n = 16; 96 +/- 2%, range 93-99%) on a normal diet. However, after ingesting a trimethylamine load (600 mg base) the obligate heterozygotes were clearly distinguishable (76 +/- 3%, range 71-79%) from controls (95 +/- 2%, range 91-99%) (t-test; p <0.001). One of a hundred apparently normal volunteers who were subsequently challenged with trimethylamine had a N-oxidation capacity which fell within the range found among the obligate heterozygotes.

Trimethylamine N-oxygenation and N-demethylation in rat liver microsomes

The in vitro oxidation of trimethylamine (TMA) to TMA N-oxide (TMAO) and dimethylamine (DMA) was studied in rat liver microsomes. Pretreatment of rats with phenobarbital, 3-methylcholanthrene, ethanol or pregnenolone 16 alpha-carbonitrile had little or no effect on the liver microsomal metabolism of TMA to TMAO or DMA. Changing the atmosphere in the incubation vessel from 20% oxygen/80% nitrogen (air) to 100% oxygen had a selective stimulatory effect on the N-oxygenation of TMA but did not affect TMA N-demethylation. In addition, the Km for TMA N-demethylation was 5-fold higher than for the N-oxygenation reaction. The results of these studies suggest that the enzyme systems responsible for N-demethylation and N-oxygenation are different and that they are under different regulatory control. Carbon monoxide (CO/O2 = 80/20) had little or no inhibitory effect on either the N-demethylation or N-oxygenation of TMA by liver microsomes from control or pregnenolone 16 alpha-carbonitrile-treated rats. Additional studies indicated that methimazole, an inhibitor of FAD-containing monooxygenase (FMO), was a potent inhibitor of TMA oxidation. Preincubation of liver microsomes from control or pregnenolone 16 alpha-carbonitrile-treated rats at 37 degrees for 10 min without NADP(H) (a procedure that irreversibly inactivated FMO activity) resulted in > 95% inhibition of TMA N-demethylation and N-oxygenation, and this inhibition was prevented by including a NADPH-generating system in the preincubation medium (a procedure for preventing the thermal inactivation of FMO activity). The data suggest that FMOs are the major enzymes responsible for N-demethylation and N-oxygenation of TMA in rat liver microsomes.

The flavin-containing monooxygenase of mouse kidney. A comparison with the liver enzyme

Flavin-containing monooxygenase (FMO; EC 1.14.13.8) was purified from mouse kidney microsomes and compared to that isolated from mouse liver microsomes. The purified enzymes from kidney and liver appeared as a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with an apparent molecular weight of 58,000 daltons. On wide range (pH 3.5 to 9.0) isoelectric focusing, FMOs from kidney and liver resolved as a single band with an isoelectric point of 8.2. The enzymes from both kidney and liver have a pH optimum of 9.2. Thiobenzamide-S-oxidation catalyzed by both enzymes was sensitive to inhibition by the competitive inhibitors thiourea and methimazole. At an n-octylamine concentration of 3 mM, thiobenzamide-S-oxidation by the kidney FMO was increased by 122% and that by the liver FMO by 148%. Km and Vmax values were determined and compared between the two tissue enzymes for xenobiotic substrates containing nucleophilic nitrogen, sulfur or phosphorus atoms. In general, for most FMO substrates, Km and Vmax values were similar between kidney and liver FMO with only a few exceptions. The Km and Vmax values for fenthion for kidney were only half of those observed for liver FMO. Fonofos was unusual in having a low Km as well as a low Vmax for both tissue enzymes. Anti-sera developed to the FMO purified from kidney and liver showed cross-reactivity with each purified enzyme as well as with a protein with the same molecular weight as the purified FMO present in both kidney and liver microsomes. These bands showed equal intensity based on an equivalent amount of protein. Analysis of kidney and liver FMO by proteolytic digestion followed by visualization of peptides by silver staining or immunoblotting showed only minor differences between the enzymes of the two tissues. The amino acid composition of both mouse kidney and liver FMO was low in methionine and histidine and rich in aspartate/asparagine, glutamate/glutamine, leucine, valine and glycine. Edman degradation of the purified mouse kidney and liver FMO provided a single amino acid sequence of the NH2-terminus. This sequence matched exactly with the cDNA-deduced sequence reported for the pig and rabbit liver beginning with the fifth amino acid and contained the highly conserved FAD-binding domain Gly-X-Gly-X-X-Gly, commonly found in a number of other FAD-binding proteins. These studies indicate that the renal and hepatic forms of FMO from mouse are similar enzymes that are immunologically related and show only a few minor differences.

Flavin-containing monooxygenase: a major detoxifying enzyme for the pyrrolizidine alkaloid senecionine in guinea pig tissues

Evidence based on optimal pH, thermal stability, and enzyme inhibition data suggests that the NADPH-dependent microsomal N-oxidation of the pyrrolizidine alkaloid senecionine is carried out largely by flavin-containing monooxygenase in guinea pig liver, lung, and kidney. In contrast, the hepatic microsomal conversion of senecionine to the pyrrole metabolite (+/-)-6,7-dihydro-7-hydroxy-1-hydroxymethyl-5H-pyrrolizine (DHP) is catalyzed largely by cytochrome P450. However, the rate of senecionine N-oxide formation (detoxication) far exceeded the rate of DHP formation (activation) in guinea pig liver microsomes over a range of pHs (pH 6.8 to 9.8). In guinea pig lung and kidney microsomes, N-oxide was the major metabolite formed from senecionine with little or no production of DHP. The high rate of detoxication coupled with the low level of activation of senecionine in liver, lung, and kidney may help explain the apparent resistance of the guinea pig to intoxication by senecionine and other pyrrolizidine alkaloids.

The effect of detergents on the purified flavin-containing monooxygenase of mouse liver, kidney and lungs

1. The effect of various commonly used membrane solubilizing detergents on the activity of the microsomal xenobiotic metabolizing enzyme, the flavin-containing monooxygenase (FMO) purified from mouse liver, kidney and lungs was determined. 2. Regardless of the type of detergent used, the effect on the enzyme activity was variable depending on the type of substrate used. 3. Emulgen 911 concentrations of up to 10% had very little effect on thiobenzamide-S-oxidation by liver, kidney or lung FMO. 4. While Emulgen 911 increased substrate dependent NADPH oxidation rate by thiourea and thioacetamide, it drastically reduced the activity toward the organophosphorous compounds, disulfoton, fenthion, fonofos and phorate at low concentrations. 5. Activities of fenthion, phorate and fonofos were decreased by 80, 65 and 55% by the inclusion of 0.25% Emulgen 911 in the assay mixture. 6. This decline in FMO activity for phorate was evident regardless of the type of detergent used. In contrast, thiourea dependent NADPH oxidation rate in the presence of various detergents was variable. 7. Thiourea oxidation rate was decreased by cholate and Zwittergent 3-12, whereas it was increased in the presence of Emulgen 911, Triton X-100 and Tween 20. 8. This study shows that before FMO activity is determined in the presence of detergents their effects should be carefully evaluated.

The FAD-containing monooxygenase-catalyzed N-oxidation and demethylation of trimethylamine in rat liver microsomes

Trimethylaminuria (TMAuria), the excessive urinary excretion of the odorous trimethylamine (TMA), accompanies elimination of TMA in sweat and corresponding "fish-odor" syndrome. TMA was oxidized in vitro in rat liver microsomes from male Sprague-Dawley rats to TMA N-oxide and N-demethylated to dimethylamine (DMA). Both reactions were inhibited to 1-3% of normal activity by preincubation of microsomes without NADPH-generating system at 37 degrees C for 10 minutes indicating the FAD-containing monooxygenase-catalyzed reactions. On the other hand, the reactions were not inhibited by gas phase containing up to 80% carbon monoxide/20% oxygen mixture. The results are compatible with the hypothesis that in rat liver microsomes the N-oxygenation and N-demethylation of TMA are catalyzed only or predominantly by FAD-containing monooxygenases, and the cytochrome P-450 monooxygenases play a negligible, if any, role.

Multiplicity of liver microsomal flavin-containing monooxygenase in the guinea pig: its purification and characterization

Two distinct forms (FMO-I and FMO-II) of flavin-containing monooxygenase were purified from the liver microsomes of guinea pig. The minimum molecular weights estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis were 54,000 for FMO-I and 56,000 for FMO-II, respectively. Tryptic digestion of these enzymes gave different electrophoretic patterns, suggesting that FMO-I and -II have distinct amino acid sequences. The amino terminal sequence of FMO-II could not be estimated probably due to its blocking while that of FMO-I was determined to be highly homologous to the rabbit liver flavin-containing monooxygenase (J. Ozols, 1989, Biochem. Biophys. Res. Commun. 163, 49-55). Absorption maxima of FMO-I and -II were recorded at 368 and 440 nm and 381 and 456 nm, respectively. Molar ratios of FAD to both of these apoenzymes were shown to be one to one. Substrate specificity of FMO-I and -II was determined using 15 compounds as the substrate. The results showed two enzymes that exhibited overlapped but different specificity toward these substrates although FMO-I had lower activity than did FMO-II with all compounds except thiobenzamide. Of particular interest, only FMO-II showed considerably high activities for primary amines, n-octylamine, and n-decylamine. Immunoglobulin G raised against FMO-II could recognize FMO-I as well as FMO-II, but the reactivity of FMO-I toward the antibody was obviously lower than that of FMO-II. Electrophoresis followed by immunostaining revealed that microsomes of lung, kidney, urinary bladder, testis, and spleen contain the same protein as FMO-II and/or FMO-I. Only lung was shown to have an additional isozyme of FAD-monooxygenase with a molecular weight apparently higher than those of FMO-I and -II. These results strongly suggest that at least two forms of flavin-containing monooxygenases distinct from the lung-type isozyme are expressed in liver of guinea pigs.

In vitro synthesis of nitroxide free radicals by hog liver microsomes

The in vitro biooxidation of 4-hydroxy-2,2,6,6-tetramethylpiperidine (TEMP), 4-hydroxy-2,2,4,4-tetramethyl-1,3-oxazolidine (TEMO) and diphenylamine (DPA) by hog liver microsomes to their respective nitroxide free radicals, 4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO), 2,2,4,4-tetramethyl-1,3-oxazolidine-1-oxyl (TEMOO), and diphenylnitroxide (DPNO) has been investigated. For extending the life span of the liver microsomes, a calcium alginate immobilization procedure was used. The biooxidation rates of the above amines to their respective nitroxide metabolites were measured by means of oxygen uptake at 37 degrees C and pH 7.4. N-octylamine was found to be an activator in the biooxidation of the amines. The formation of the nitroxide radicals was identified by E.S.R. spectroscopy.

Distinct pulmonary and hepatic forms of flavin-containing monooxygenase in sheep

1. Flavin-containing monooxygenase (FMO) in pulmonary and hepatic microsomes from sheep was analyzed by western blotting by probing with antibodies raised against FMO purified from rabbit lung and pig liver. 2. Pulmonary microsomes from sheep contain a single major protein which cross-reacts with the antibody to rabbit lung FMO, but no band can be observed when probed with the antibody to the pig liver enzyme. Likewise, sheep liver microsomes contain a protein which cross-reacts with the antibody to pig liver FMO, but no significant staining is observed following incubation with antibody to the lung enzyme. 3. Sheep pulmonary and hepatic microsomal FMO also display a difference in activity toward chlorpromazine and n-dodecylamine. 4. Preliminary evidence suggests that sheep FMO may be induced (liver) or repressed (lung) during pregnancy. 5. Sheep are similar to rodents (rat, mouse, guinea pig, hamster and rabbit) in having distinct forms of pulmonary and hepatic FMO. The immunochemical and catalytic difference between sheep liver and lung FMO is similar to that of rabbit.

Species, organ and cellular variation in the flavin-containing monooxygenase

The distribution of the flavin-containing monooxygenase (EC1.14.13.8) (FMO) between species, organs and cell types is summarized with particular reference to the organ specific forms present in mammalian lung and liver. The role of the FMO relative to cytochrome P-450 in the oxidation of the sulfur atoms of organosulfur compounds is considered with particular reference to the hepatatoxicant thiobenzamide, the insecticide phorate and the drug, thioridazine. Of special interest is the relative role of these enzymes in complex metabolic pathways of xenobiotics.

Guanethidine N-oxidation in human liver microsomes

The capacity of human liver microsomes to N-oxidize guanethidine from 25 subjects has been assessed. Guanethidine N-oxidation was optimal at pH 8.5 and proceeded at only 16% of the maximal rate at pH 7.4. The mean rates of guanethidine N-oxidation at pH 8.5 and 7.4 were 2.46 +/- 0.89 (mean +/- s.d., n = 25) and 0.38 +/- 0.22 (mean +/- s.d., n = 22), respectively. Interindividual differences in the rate of guanethidine N-oxidation at pH 8.5 and 7.4 were 17- and 11-fold, respectively. The cytochrome P450 inhibitors, proadifen and 2,4-dichloro-6-phenylphenoxyethylamine (DPEA), at both pH 8.5 and 7.4 caused less than 20% reduction in the rate of guanethidine N-oxidation by human liver microsomes. These data indicate that guanethidine N-oxidation can be used as a measure of flavin-containing monooxygenase activity in human liver.

Flavin-containing monooxygenase and ascorbic acid deficiency. Qualitative and quantitative differences

Ascorbic acid deficiency causes qualitative and quantitative differences in the guinea pig hepatic flavin-containing monooxygenase (FMO). Kinetic studies with purified FMO indicated no significant change in the apparent Km of dimethylaniline or NADPH in ascorbate-supplemented or -deficient animals. Following purification of ascorbate-deficient guinea pig FMO by DEAE-cellulose and blue agarose chromatography, exogenous FAD was required for 15% of the FMO microsomal activity recovered. In contrast, only 5% of the total microsomal enzyme recovered from ascorbate-supplemented animals required exogenous FAD. Furthermore, there was an enhanced sensitivity to time-dependent nonlinearity with the purified ascorbate-deficient guinea pig FMO. The degree of time-dependent nonlinearity was related to the concentration of substrate. Also, purified ascorbate-supplemented guinea pig FMO was stable for 4 weeks at -20 degrees, whereas the ascorbate-deficient enzyme was inactivated. A decrease in the quantity of ascorbate-deficient guinea pig FMO compared to ascorbate-supplemented was indicated by a marked reduction in total FMO activity recovered from blue agarose chromatography and reduced protein staining intensity with SDS-PAGE at 56,000 daltons.

Catalytic activity and substrate specificity of the flavin-containing monooxygenase in microsomal systems: characterization of the hepatic, pulmonary and renal enzymes of the mouse, rabbit, and rat

Inhibitory antibodies against NADPH-cytochrome P-450 reductase, detergent solubilization to dissociate functional interaction between the reductase and cytochrome P-450, and selective trypsin degradation have been used to characterize flavin-containing monooxygenase activity in microsomes from different tissues and species. A comparison of assay methods is reported. The native microsome-bound flavin-containing monooxygenase of mouse, rabbit, and rat liver, lung, and kidney can metabolize compounds containing thiol, sulfide, thioamide, secondary and tertiary amine, hydrazine, and phosphine substituents. Therefore, this enzyme from these common experimental animals has catalytic capabilities similar to those of the well-characterized porcine liver enzyme. True allosteric activation by n-octylamine does not appear to be a property of either the mouse, rabbit, or rat liver enzymes, but is a property of the pig liver and mouse lung enzymes. The microsomal pulmonary flavin-containing monooxygenase of the rabbit has some unique substrate preferences which differ from the mouse lung enzyme. Both the rabbit and mouse pulmonary enzymes have recently been shown to be distinct enzyme forms. However, the rat pulmonary flavin-containing monooxygenase appears to be catalytically identical to the rat liver enzyme, and does not have any of the unusual catalytic properties of either the rabbit or mouse lung enzymes. Enzyme activity of mouse, rabbit, and rat kidney microsomes is qualitatively similar to the hepatic activities. Substrates which saturate the microsome-bound flavin-containing monooxygenase at 1.0 mM, including thiourea, thioacetamide, methimazole, cysteamine, and thiobenzamide, are metabolized at common maximal velocities. This suggests that the kinetic mechanism of the native enzyme is similar to that established for the isolated porcine liver enzyme in that the rate-limiting step of catalysis occurs after substrate binding, and that all substrates capable of saturating the microsomal enzyme should be metabolized at a common maximal velocity.