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.

Analysis of six novel flavin-containing monooxygenase 3 (FMO3) gene variants found in a Japanese population suffering from trimethylaminuria.

Polymorphic human flavin-containing monooxygenase 3 (FMO3) is associated with the inherited disorder trimethylaminuria. Several FMO3 variants have been observed in a variety of ethnic groups, including a Japanese cohort suffering from trimethylaminuria. The aim of this study was to screen another self-reported Japanese trimethylaminuria cohort for novel FMO3 variants and to investigate these new variants. Subjects with low FMO3 metabolic capacities were identified by measuring the urinary trimethylamine and trimethylamine N-oxide concentrationsin171 Japanese volunteers. The FMO3 genes from these subjects and their family members were then sequenced. Heterozygotes or homozygotes for novel single-nucleotide polymorphisms c.20 T > C p.(Ile7Thr), c.122 G > A p.(Trp41Ter), c.127T > A p.(Phe43Ile), c.488 T > C p.(Leu163Pro), and c.1127G > A p.(Gly376Glu) and a heterozygote for the novel duplication c.850_860dupTTTAACGATGA p.(Glu287AspfsTer17) were identified. In addition, the known (but as yet uncharacterized) single-nucleotide polymorphism c.929 C > T p.(Ser310Leu) was found. Pedigree analysis revealed the p.(Ser310Leu) FMO3 allele in cis configuration with c.929 C > T p.(Glu158Lys). These variant FMO3 proteins recombinantly expressed in Escherichia coli membranes exhibited decreased N-oxygenation activities toward trimethylamine and benzydamine. Although the allele frequencies of these seven variants were low, the present results suggest that individuals homozygous or heterozygous for any of these novel missense or duplicationFMO3 variants or known nonsense mutations such as p.(Cys197Ter) may possess abnormal activities toward trimethylamine N-oxygenation.