Trimethylamine N-oxygenation in cynomolgus macaques genotyped for flavin-containing monooxygenase 3 (FMO3)

Polymorphic human and cynomolgus macaque flavin-containing monooxygenases (FMO) 3 are important oxygenation enzymes for nitrogen-containing drugs. Inter-animal variability of FMO3-dependent drug oxygenations in vivo is suspected in cynomolgus macaques because such variability is evident in humans. Therefore, this follow-up study was performed to investigate the pharmacokinetics of orally administered deuterium-labeled trimethylamine in three cynomolgus macaques genotyped for FMO3. Trimethylamine-d₉ was rapidly absorbed and attained plasma concentrations greater than the background levels of non-labeled trimethylamine. Trimethylamine-d₉ was then converted to trimethylamine-d₉ N-oxide. The half-lives, maximum plasma concentrations, and areas under the curve for trimethylamine-d₉ and its N-oxygenated metabolite and the total clearance for orally administered trimethylamine-d₉ were not different among the heterozygote for Q506K FMO3, the heterozygote for V325I FMO3, and the heterozygote for both S99N and F510S FMO3. Trimethylamine N-oxygenation activities mediated by liver microsomes prepared from the same three animals were not substantially different. However, recombinant proteins of the corresponding cynomolgus FMO3 variants showed apparent reduced trimethylamine N-oxygenation activities compared with the wild-type proteins. This study suggests only limited polymorphic effects on the in vivo catalytic function of cynomolgus FMO3. These findings yield important insights in terms of both quantitative and qualitative variations of polymorphic FMO3 in cynomolgus liver.     

A family study of compound variants of flavin-containing monooxygenase 3 (FMO3) in Japanese subjects found by urinary phenotyping for trimethylaminuria

Phenotype–gene analyses and the increasing availability of mega-databases have revealed the impaired human flavin-containing monooxygenase 3 (FMO3) variants associated with the metabolic disorder trimethylaminuria. In this study, a novel compound variant of FMO3, p.[(Val58Ile; Tyr229His)], was identified in a 1-year-old Japanese girl who had impaired FMO3 metabolic capacity (70%) in terms of urinary trimethylamine N-oxide excretion levels divided by total levels of trimethylamine and its N-oxide. One cousin in the family had the same p.[(Val58Ile); (Tyr229His)]; [(Glu158Lys; Glu308Gly)] FMO3 haplotype and had a similar FMO3 metabolic capacity (69%). In a family study, the novel p.[(Val58Ile); (Tyr229His)] compound FMO3 variant was also detected in the proband 1's mother and aunt. Another novel compound FMO3 variant p.[(Glu158Lys; Met260Lys; Glu308Gly; Ile426Thr)] was identified in a 7-year-old girl, proband 2. This novel compound FMO3 variant was inherited from her mother. Recombinant FMO3 Val58Ile; Tyr229His variant and Glu158Lys; Met260Lys; Glu308Gly; Ile426Thr variant showed moderately decreased capacities for trimethylamine N-oxygenation compared to wild-type FMO3. Analysis of trimethylaminuria phenotypes in family studies has revealed compound missense FMO3 variants that impair FMO3-mediated N-oxygenation in Japanese subjects; moreover, these variants could result in modified drug clearances.     

Evaluation of xenobiotic N- and S-oxidation by variant flavin-containing monooxygenase 1 (FMO1) enzymes.

The flavin-containing monooxygenase gene family (FMO1-6) in humans encodes five functional isoforms that catalyze the monooxygenation of numerous N-, P- and S-containing drugs and toxicants. A previous single nucleotide polymorphism (SNP) analysis of FMO1 in African-Americans identified seven novel SNPs. To determine the functional relevance of the coding FMO1 variants (H97Q, I303V, I303T, R502X), they were heterologously expressed using a baculovirus system. Catalytic efficiency and stereoselectivity of N- and S-oxygenation was determined in the FMO1 variants using several substrates. The I303V variant showed catalytic constants equal to wild-type FMO1 for methimazole and methyl p-tolyl sulfide. Catalytic efficiency (V(max)/K(m)) of methyl p-tolyl sulfide oxidation by R502X was unaltered. In contrast, methimazole oxidation by R502X was not detected. Both H97Q and I303T had elevated catalytic efficiency with regards to methyl p-tolyl sulfide (162% and 212%, respectively), but slightly reduced efficiency with regards to methimazole (81% and 78%). All the variants demonstrated the same stereoselectivity for methyl p-tolyl sulfide oxidation as wild-type FMO1. FMO1 also metabolized the commonly used insecticide fenthion to its (+)-sulfoxide, with relatively high catalytic efficiency. FMO3 metabolized fenthion to its sulfoxide at a lower catalytic efficiency than FMO1 (27%) and with less stereoselectivity (74% (+)-sulfoxide). Racemic fenthion sulfoxide was a weaker inhibitor of acetylcholinesterase than its parent compound (IC(50) 0.26 and 0.015 mM, respectively). The (+)- and (-)-sulfoxides were equally potent inhibitors of acetylcholinesterase. These data indicate that all the currently known FMO1 variants are catalytically active, but alterations in kinetic parameters were observed.     

Non-synonymous genetic variants of flavin-containing monooxygenase 3 (FMO3) in cynomolgus macaques

Polymorphic human flavin-containing monooxygenase (FMO) 3 is an important drug-metabolizing enzyme for nitrogen- or sulfur-containing compounds. Cynomolgus macaques, a non-human primate species widely used in drug metabolism studies, have corresponding FMO3 molecular and enzymatic similarities to humans; however, genetic polymorphisms have not been investigated in macaques. In this study, re-sequencing of FMO3 in 64 cynomolgus and 32 rhesus macaques found a total of 18 non-synonymous variants. Nine variants were unique to cynomolgus macaques, of which 4 (including Q506K) were found only in Indochinese, 4 (including V299I, E348H, and G530A) only in Indonesian lineages, and one was common. Other five variants (including S504T at >10% allele frequencies) were unique to rhesus macaques. By functional characterization using cynomolgus FMO3 proteins heterologously expressed in Escherichia coli, FMO3 R509H variant appeared to suppress methimazole and benzydamine S- or N-oxygenations. Seven variants showed substantially lower benzydamine N-oxygenation as compared with wild-type FMO3 protein. Further analysis indicated that two of these variants, FMO3 G530A and R417H, showed significantly lower benzydamine N-oxygenation in liver microsomes of the homozygotes as compared with wild-type animals. Therefore, inter-animal variability of FMO3-dependent drug metabolism is at least partly accounted for by genetic polymorphisms in cynomolgus and rhesus macaques, similar to humans.     

A series of simple detection systems for genetic variants of flavin-containing monooxygenase 3 (FMO3) with impaired function in Japanese subjects

Increasing numbers of single-nucleotide substitutions of the human flavin-containing monooxygenase 3 (FMO3) gene are being recorded in mega-databases. Phenotype–gene analyses revealed impaired FMO3 variants associated with the metabolic disorder trimethylaminuria. Here, a series of reliable FMO3 genotyping confirmation methods was assembled and developed for 45 impaired FMO3 variants, mainly found in Japanese populations, using singleplex or duplex polymerase chain reaction (PCR)–restriction fragment length polymorphism (RFLP) methods and singleplex, duplex, or tetraplex allele-specific PCR methods. Nine PCR-RFLP procedures with single restriction enzymes and fourteen duplex PCR-RFLP procedures (for p.Trp41Ter and p.Thr329Ala, p.Met66Val and p.Leu163Pro, p.Pro70Leu and p.Glu308Gly, p.Asn114Ser and p.Ser195Leu, p.Glu158Lys and p.Ile441Thr, p.Cys197Ter and p.Trp388Ter, p.Arg205Cys and p.Val257Met, p.Arg205His and p.Cys397Ser, p.Met211ArgfsTer10 and p.Arg492Trp, p.Arg223Gln and p.Leu473Pro, p.Met260Val and p.Thr488Ala, p.Tyr269His and p.Ala311Pro, p.Ser310Leu and p.Gly376Glu, and p.Gln470Ter and p.Arg500Ter) were newly established along with eight singleplex (for p.Pro153GlnfsTer14, p.Gly191Cys, p.Pro248Thr, p.Ile486Met, and p.Pro496Ser, among others), one duplex (p.Ile199Ser and p.Asp286Tyr), and one tetraplex (p.Ile7Thr, p.Val58Ile, p.Thr201Lys, and p.Gly421Val) allele-specific PCR systems. This series of systems should facilitate the easy detection in a clinical setting of FMO3 variants in Japanese subjects susceptible to low drug clearances or drug reactions possibly caused by impaired FMO3 function.     

Genetic variants of flavin-containing monooxygenase 3 (FMO3) in Japanese subjects identified by phenotyping for trimethylaminuria and found in a database of genome resources

The oxygenation of food-derived trimethylamine to its N-oxide is a representative reaction mediated by human flavin-containing monooxygenase 3 (FMO3). Impaired FMO3 enzymatic activity is associated with trimethylaminuria (accumulation of substrate), whereas trimethylamine N-oxide (metabolite) is associated with arteriosclerosis. We previously reported FMO3 single-nucleotide and/or haplotype variants with low FMO3 metabolic capacity using urinary phenotyping and the whole-genome sequencing of Japanese populations. Here, we further analyze Japanese volunteers with self-reported malodor and interrogate an updated Japanese database for novel FMO3 single-nucleotide and/or haplotype variants. After 3 years of follow up, seven probands were found to harbor the known impaired FMO3 variant p.(Gly191Cys) identified in the database or novel variants/haplotypes including p.(Met66Val), p.(Arg223Gln), p.(Glu158Lys;Glu308Gly;Arg492Trp), and p.(Glu158Lys;Glu308Gly;Pro496Ser). The known severe mutation p.(Cys197Ter) (a TG deletion) and four variants including p.(Tyr269His) and p.(Pro496Ser) were first detected in the updated genome panel. Among previously unanalyzed FMO3 variants, the trimethylamine/benzydamine N-oxygenation activities of recombinant p.(Met66Val), p.(Arg223Gln), p.(Tyr269His), p.(Glu158Lys;Glu308Gly;Arg492Trp), and p.(Glu158Lys;Glu308Gly;Pro496Ser) FMO3 variant proteins were severely decreased (V_max/K_m <10% of wild-type). Although the present novel mutations or alleles were relatively rare, both in self-reported Japanese trimethylaminuria sufferers and in the genomic database panel, three common FMO3 missense or deletion variants severely impaired FMO3-mediated N-oxygenation of trimethylamine.     

In vitro evaluation of potential in vivo probes for human flavin-containing monooxygenase (FMO): metabolism of benzydamine and caffeine by FMO and P450 isoforms

AIMS To determine the FMO and P450 isoform selectivity for metabolism of benzydamine and caffeine, two potential in vivo probes for human FMO. METHODS Metabolic incubations were conducted at physiological pH using substrate concentrations of 0.01-10 mM with either recombinant human FMOs, P450s or human liver microsomes serving as the enzyme source. Products of caffeine and benzydamine metabolism were analysed by reversed-phase h.p.l.c. with u.v. and fluorescence detection. RESULTS CYP1A2, but none of the human FMOs, catalysed metabolism of caffeine. In contrast, benzydamine was a substrate for human FMO1, FMO3, FMO4 and FMO5. Apparent Km values for benzydamine N-oxygenation were 60 +/- 8 microM, 80 +/- 8 microM, > 3 mM and > 2 mM, for FMO1, FMO3, FMO4 and FMO5, respectively. The corresponding Vmax values were 46 +/- 2 min-1, 36 +/- 2 min-1, < 75 min-1 and < 1 min-1. Small quantities of benzydamine N-oxide were also formed by CYPs 1A1, 1A2, 2C19, 2D6 and 3A4. CONCLUSIONS: FMO1 and FMO3 catalyse benzydamine N-oxygenation with the highest efficiency. However, it is likely that the metabolic capacity of hepatic FMO3 is a much greater contributor to plasma levels of the N-oxide metabolite in vivo than is extrahepatic FMO1. Therefore, benzydamine, but not caffeine, is a potential in vivo probe for human FMO3.     

Genetic variants of flavin-containing monooxygenase 3 (FMO3) derived from Japanese subjects with the trimethylaminuria phenotype and whole-genome sequence data from a large Japanese database

Flavin-containing monooxygenase 3 (FMO3) is a polymorphic xenobiotic- and dietary compound-metabolizing enzyme associated with the genetic disorder trimethylaminuria. We phenotyped 428 Japanese subjects using traditional urinary phenotyping assays and identified two subjects with <20% FMO3 metabolic capacity. Both subjects had novel frameshift mutations. Proband 1 harbored a novel CC deletion resulting in p.[(Pro153Gln fs; Phe166Ter)] FMO3, which was in trans configuration with p.(Cys197Ter). Proband 2 harbored a novel T deletion resulting in p.[(Met211Arg fs; Val220Ter)] FMO3, which was in trans configuration with p.[(Val257Met; Met260Val)]. We also analyzed a new large Japanese database for novel single nucleotide substitutions of FMO3 and identified the following variants with very low frequencies (<∼0.1%): p.(Lys56Glu), p.(Ser112Asn), p.(Asn164Lys), p.(Gly191Cys), p.(Ile199Ser), p.(Pro248Thr), p.(Pro248Leu), p.(Asp286Tyr), and p.(Ala311Pro). Recombinant FMO3 proteins of the above and unanalyzed variants underwent kinetic analysis of their trimethylamine/benzydamine N-oxygenation activities. Gly191Cys, Ile199Ser, Asp286Tyr, and Ala311Pro variant FMO3 proteins exhibited severely decreased activities (V_max/K_m <5% of wild-type). Although these new variants were rare alleles in Japanese self-reported trimethylaminuria sufferers and in the large genomic database, we found that most Japanese individuals compound heterozygous or homozygous for any of these missense FMO3 variants or known severe mutations [e.g., p.(Cys197Ter)] had impaired FMO3-dependent N-oxygenation of malodorous trimethylamine.     

Further survey of genetic variants of flavin-containing monooxygenase 3 (FMO3) in Japanese subjects found in an updated database of genome resources and identified by phenotyping for trimethylaminuria

The number of single-nucleotide substitutions of human flavin-containing monooxygenase 3 (FMO3) recorded in mega-databases is increasing. Moreover, phenotype–gene analyses have revealed impaired FMO3 variants associated with the metabolic disorder trimethylaminuria. In this study, four novel amino-acid substituted FMO3 variants, namely p.(Gly191Asp), p.(Glu414Gln), p.(Phe510Ser), and p.(Val530CysfsTer1), were identified in the whole-genome sequences in the Japanese population reference panel (8.3K JPN) of the Tohoku Medical Megabank Organization. Additionally, four variants, namely p.(Ile369Thr), p.(Phe463Val), p.(Arg500Gln), and p.(Ala526Thr) FMO3, were found in the 8.3K JPN database but were already recorded in the National Center for Biotechnology Information database. Novel FMO3 variants p.[(Met1Leu)] and p.[(Trp231Ter)] were also identified in phenotype–gene analyses of 290 unrelated subjects with self-reported malodor. Among the eight recombinant FMO3 variants tested (except for p.[(Met1Leu)] and p.[(Trp231Ter)]), Arg500Gln and Gly191Asp FMO3, respectively, had lower and much lower capacities for trimethylamine and/or benzydamine N-oxygenation activities than wild-type FMO3. Because another FMO3 mutation p.[(Gly191Cys)] with diminished recombinant protein activity was previously detected in two independent probands, Gly191 would appear to be important for FMO3 catalytic function. Analysis of whole-genome sequence data and trimethylaminuria phenotypes revealed missense FMO3 variants that severely impaired FMO3-mediated N-oxygenations in Japanese subjects that could be susceptible to low drug clearances.     

The effect of lovastatin on oxidative stress and antioxidant enzymes in hydrogen peroxide intoxicated rat

Oxidative stress has been linked to the development of many diseases and hastens the progression of cardiovascular diseases. Since lovastatin is used worldwide as a cholesterol lowering drug, the present study was undertaken to evaluate the antioxidant property of lovastatin against H₂O₂ induced oxidative stress in rats. Four study groups of rats of four animals each were treated with DMSO (control), H₂O₂ (OS), lovastatin (L) and H₂O₂ + lovastatin (OSL). On the 15th day the animals were sacrificed, and the liver and heart tissues were analyzed for oxidative stress biomarkers and anti-oxidant enzymes. Results of the OSL-group showed a reduction in thiobarbituric acid reactive substances in liver (42.7%) and heart tissue (8%) compared with the control group. An increase was observed in the activity of the antioxidant enzymes, catalase (34.6% in liver and 33.3% in heart) and glutathione peroxidase (50.5% in liver and 34.7% in heart). A commensurate increase in the activity of G6PDH was observed indicating an enhanced requirement of NADPH. The ratio GSH:GSSG in liver (1.05) and heart (0.84) was satisfactorily regulated compared to the control group (1.01 in liver and 0.93 in heart). These results suggest that lovastatin possesses antioxidant activity and reduces oxidative stress.     

Efficacy and safety of stabilised hydrogen peroxide cream (Crystacide) in mild-to-moderate acne vulgaris: a randomised,controlled trial versus benzoyl peroxide gel

Background: Benzoyl peroxide (BP) is a first-line topical treatment in acne vulgaris (AV). However, its use can cause mild skin irritation and dryness. A new formulation of hydrogen peroxide stabilised (HPS) in monoglycerides cream (Crystacide 1%), indicated in the topical treatment of superficial skin infections, is now available as an alternative treatment.

Study aim: To evaluate efficacy and local tolerability of HPS in mild-to-moderate AV in comparison with BP gel.

Methods and patients: In a randomised, prospective, investigator-masked parallel-group, 8-week trial, 60 patients (24 men, 36 women, mean age 25?±?6 years) with mild-to-moderate AV, affecting mainly the face, were enrolled in the study, after their informed consent. HPS or BP (PanOxyl gel 4%) was applied topically twice daily for 8 weeks.

Study outcomes: The study endpoints were: (1) Reduction in mean inflammatory (IL), non-inflammatory (NIL) and total (TL) acneic lesions in comparison with baseline; (2) Local tolerability assessed evaluating erythema, dryness and burning sensation, using a 0-3 qualitative score (score 0?=?poor tolerability; score 3?=?very good tolerability).

Results: TL, NIL, and IL were assessed by an investigator unaware of treatment allocation at baseline, and week 8. The tolerability score (TS) was assessed at week 4 and 8. At baseline, the two groups were well matched for the main clinical and demographic characteristics. All patients concluded the trial. At week 0, in the HPS group TL, NIL and IL (mean?±?SD) were: 35?±?8, 20?±?6 and 16?±?7. At week 8, HPS reduced TL to 16?±?7; NIL to 9?±?3 and IL to 7?±?3 (p?<?0.001). At baseline, TL, NIL and IL, in the BP group, were 32?±?9, 24?±?8 and 18?±?7, respectively. At week 8, BP reduced TL, NIL and IL to 14?±?9; 7?±?5 and 7?±?3 (p?<?0.001). In comparison with baseline values, the percentage reductions of IL were 58% and 61% for HPS and BP, respectively (p?=?n.s.). At the end of the study the TS was 2.9?±?0.2 in HPS group and 2.4?±?0.8 in BP group (p?<?0.025). Two patients in HPS group (6%) and seven patients (23%) in BP group suffered from mild-to-moderate local erythema.

Conclusions: HPS has shown to be as effective as BP in reducing both inflammatory and noninflammatory AV lesions in patients with mild-to-moderate disease. In comparison with BP 4% gel, HPS cream shows a better local tolerability profile.     

Development of a physiologically based pharmacokinetic model to predict the effects of flavin‐containing monooxygenase 3 (FMO3) polymorphisms on itopride exposure

Itopride, a substrate of FMO3, has been used for the symptomatic treatment of various gastrointestinal disorders. Physiologically based pharmacokinetic (PBPK) modeling was applied to evaluate the impact of FMO3 polymorphism on itopride pharmacokinetics (PK). The Asian populations within the Simcyp simulator were updated to incorporate information on the frequency, activity and abundance of FMO3 enzyme with different phenotypes. A meta‐analysis of relative enzyme activities suggested that FMO3 activity in subjects with homozygous Glu158Lys and Glu308Gly mutations (Lys158 and Gly308) in both alleles is ~47% lower than those carrying two wild‐type FMO3 alleles. Individuals with homozygous Lys158 and Gly308 mutations account for about 5% of the total population in Asian populations. A CL _int of 9 μl/min/pmol was optimised for itopride via a retrograde approach as human liver microsomal results would under‐predict its clearance by ~7.9‐fold. The developed itopride PBPK model was first verified with three additional clinical studies in Korean and Japanese subjects resulting in a predicted clearance of 52 to 69 l/h, which was comparable to those observed (55 to 88 l/h). The model was then applied to predict plasma concentration–time profiles of itopride in Chinese subjects with wild type or homozygous Lys158 and Gly308 FMO3 genotypes. The ratios of predicted to observed AUC of itopride in subjects with each genotype were 1.23 and 0.94, respectively. In addition, the results also suggested that for FMO3 metabolised drugs with a safety margin of 2 or more, proactive genotyping FMO3 to exclude subjects with homozygous Lys158/Gly308 alleles may not be necessary.     

Protective effects of protopine on hydrogen peroxide-induced oxidative injury of PC12 cells via Ca(2+) antagonism and antioxidant mechanisms

Calcium and lipid peroxidation play important roles in oxidative stress-induced cellular injury and apoptosis, which ultimately cause cell death. In this study we examined whether protopine had a neuroprotection against H₂O₂-induced injury in PC12 cells. Pretreatment of PC12 cells with protopine improved the cell viability, enhanced activities of superoxide dismutase, glutathione peroxidase and catalase, and decreased malondialdehyde level in the H₂O₂ injured cells. Protopine also reversed the increased intracellular Ca²⁺ concentration and the reduced mitochondrial membrane potential caused by H₂O₂ in the cells. Furthermore, protopine was able to inhibit caspase-3 expression and cell apoptosis induced by H₂O₂. In summary, this study demonstrates that protopine is able to relieve H₂O₂-induced oxidative stress and apoptosis in PC12 cells, at least in part, by Ca²⁺ antagonism and antioxidant mechanisms.     

The phenotype of a flavin-containing monooyxgenase knockout mouse implicates the drug-metabolizing enzyme FMO1 as a novel regulator of energy balance

Flavin-containing monooxygenases (FMOs) of mammals are thought to be involved exclusively in the metabolism of foreign chemicals. Here, we report the unexpected finding that mice lacking Fmos 1, 2 and 4 exhibit a lean phenotype and, despite similar food intake, weigh less and store less triglyceride in white adipose tissue (WAT) than wild-type mice. This is a consequence of enhanced whole-body energy expenditure, due mostly to increased resting energy expenditure (REE). This is fuelled, in part, by increased fatty acid β-oxidation in skeletal muscle, which would contribute to depletion of lipid stores in WAT. The enhanced energy expenditure is attributed, in part, to an increased capacity for exercise. There is no evidence that the enhanced REE is due to increased adaptive thermogenesis; instead, our results are consistent with the operation in WAT of a futile energy cycle. In contrast to FMO2 and FMO4, FMO1 is highly expressed in metabolic tissues, including liver, kidney, WAT and BAT. This and other evidence implicates FMO1 as underlying the phenotype. The identification of a novel, previously unsuspected, role for FMO1 as a regulator of energy homeostasis establishes, for the first time, a role for a mammalian FMO in endogenous metabolism. Thus, FMO1 can no longer be considered to function exclusively as a xenobiotic-metabolizing enzyme. Consequently, chronic administration of drugs that are substrates for FMO1 would be expected to affect energy homeostasis, via competition for endogenous substrates, and, thus, have important implications for the general health of patients and their response to drug therapy.     

Protective effects of kahweol and cafestol against hydrogen peroxide-induced oxidative stress and DNA damage

There is an increasing evidence that oxidative stress is implicated in the processes of inflammation and carcinogenesis. It has been shown that kahweol and cafestol, coffee-specific diterpenes, exhibit chemoprotective effects. This study investigated the effects of kahweol and cafestol, coffee-specific diterpenes, on the hydrogen peroxide (H(2)O(2))-induced oxidative stress and DNA damage in NIH3T3 cells. When the cells were treated with kahweol or cafestol, cytotoxicity, lipid peroxidation, and reactive oxygen species production induced by H(2)O(2) were markedly reduced in a dose-dependent manner. Moreover, kahweol and cafestol were shown to be highly protected against H(2)O(2)-induced oxidative DNA damage as determined by the Comet (single cell gel electrophoresis) assay and the measurement of 8-oxoguanine content in NIH3T3 cells. Kahweol and cafestol also protected hydroxyl radical-induced 2-deoxy-d-ribose degradation by ferric ion-nitrilotriacetic acid and H(2)O(2). In addition, kahweol and cafestol efficiently removed the superoxide anion generated from the xanthine/xanthine oxidase system. These results suggest that kahweol and cafestol are effective in protecting against H(2)O(2)-induced oxidative stress and DNA damage, probably via scavenging free oxygen radicals, and that kahweol and cafestol act as antioxidants.     

Toxicity of zinc oxide (ZnO) nanoparticles on human bronchial epithelial cells (BEAS-2B) is accentuated by oxidative stress

Although several studies reported that cytotoxic effects of various nanoparticles are partially due to induction of oxidative stress, it is unclear how oxidative state of the cell per se could influence its sensitivity to cytotoxic nanoparticles. This is of clinical significance because certain pathological conditions such as inflammation is associated with elevated oxidative stress and this may alter sensitivity of cells and tissues to cytotoxic nanoparticles. Hence, this study investigated how initial exposure of BEAS-2B human bronchial epithelial cells to oxidative stress influences subsequent response to cytotoxic challenge with zinc oxide (ZnO) nanoparticles (≈10 nm). Oxidative stress was induced by exposing BEAS-2B cells to 5 and 10 μM of H₂O₂ for 45 min in PBS (with Ca²⁺). Subsequently, the H₂O₂ solutions were washed off and the cells were exposed to varying concentrations (5–25 μg/ml) of ZnO nanoparticles in culture media for 24 h, followed by cell viability assessment with the WST-8 assay. The results demonstrated that initial transient exposure of cells to oxidative stress accentuated cytotoxicity of ZnO nanoparticles. In the negative control unexposed to H₂O₂, >99% of cells remained viable up to a ZnO nanoparticle concentration of 10 μg/ml, but displayed a steep decrease in viability above 10 μg/ml ZnO. By contrast, cells that were initially exposed to 5 and 10 μM of H₂O₂, displayed a sharp drop in viability even at concentrations below 10 μg/ml ZnO. At 10 μg/ml ZnO, cells initially exposed to 10 μM H₂O₂ displayed a viability of 40.6 ± 2.0%, which is significantly lower than the corresponding values of 72.8 ± 2.0% and 99.9 ± 1.1% obtained for initial exposure to 5 μM H₂O₂ and the negative control, respectively. Hence, initial exposure of BEAS-2B cells to oxidative stress sensitized their subsequent response to cytotoxic challenge with ZnO nanoparticles.     

Developmental regulation of flavin-containing monooxygenase form 1 in the liver and kidney of fetal and neonatal rabbits

Flavin-containing monooxygenases (FMOs) comprise a multi-gene family and catalyze the oxygenation of soft nucleophilic sulfur, nitrogen, phosphorus, and selenium in xenobiotics. Previous studies have demonstrated that FMO is regulated developmentally and by the administration of certain steroid hormones. This study examined the expression of FMO form 1 in the livers and kidneys of fetal and neonatal rabbits, from day 25 of gestation through 3 weeks of age, by assaying FMO1 mRNA and protein levels, as well as catalytic activity. FMO1 mRNA and protein expression and FMO catalytic activity were present in fetal livers at the earliest time point measured (day 25 of gestation), although at levels approximately 10% of that found in adult livers. Hepatic FMO1 mRNA levels increased during and after gestation; levels were not significantly different from those measured in adult male livers. FMO1 protein content and activity rose rapidly after birth to reach 70-80% of adult levels by 3 weeks of age. The expression of FMO1 in fetal and neonatal kidneys was markedly lower than in liver. FMO1 mRNA levels never averaged more than 3.4% of adult male liver levels, but did not differ from adult kidney levels at any of the points measured. Protein levels and enzyme activity rose significantly after birth to approximately 30% of the level in adult kidneys by 3 weeks of age. The early developmental appearance of FMO1 suggests a possible role in the metabolism of xenobiotics through transplacental or lactational exposures.     

A review of the enzymology of arsenic metabolism and a new potential role of hydrogen peroxide in the detoxication of the trivalent arsenic species

This laboratory has studied the enzymology involved in the biotransformation of inorganic arsenic to dimethylarsinous acid (DMA(III)) and in human studies established that monomethylarsonous acid (MMA(III)) and DMA(III) appear in urine of people chronically exposed to arsenic. It appears that only two proteins are required for inorganic arsenic biotransformation in the human, namely, monomethylarsonic acid (MMA(V)) reductase and arsenic methyltransferase. MMA(V) reductase and the unique glutathione transferase omega (hGST-O) are identical proteins. Arsenicals with a +3 oxidation state are more toxic than the +5 species. While methylation of arsenite, MMA(III), and DMA(III) produces less toxic +5 oxidation arsenic species containing an additional methyl group such as MMA(V), dimethylarsinic acid (DMA(V)), and TMAO, a new mechanism involving hydrogen peroxide for detoxifying arsenite, MMA(III), and DMA(III) is proposed based on in vitro experiments.