[1]	NUCLEOTIDE SEQUENCE [MRNA]. TISSUE=Liver; PubMed=1542660 [NCBI, ExPASy, EBI, Israel, Japan] Lomri N., Gu Q., Cashman J.R.; "Molecular cloning of the flavin-containing monooxygenase (form II) cDNA from adult human liver."; Proc. Natl. Acad. Sci. U.S.A. 89:1685-1689(1992).
[2]	NUCLEOTIDE SEQUENCE [MRNA]. TISSUE=Liver; PubMed=8654418 [NCBI, ExPASy, EBI, Israel, Japan] Dolphin C.T., Cullingford T.E., Shephard E.A., Smith R.L., Phillips I.R.; "Differential developmental and tissue-specific regulation of expression of the genes encoding three members of the flavin-containing monooxygenase family of man, FMO1, FMO3 and FM04."; Eur. J. Biochem. 235:683-689(1996).
[3]	NUCLEOTIDE SEQUENCE [GENOMIC DNA]. DOI=10.1006/geno.1997.5031; PubMed=9417913 [NCBI, ExPASy, EBI, Israel, Japan] Dolphin C.T., Riley J.H., Smith R.L., Shephard E.A., Phillips I.R.; "Structural organization of the human flavin-containing monooxygenase 3 gene (FMO3), the favored candidate for fish-odor syndrome, determined directly from genomic DNA."; Genomics 46:260-267(1997).
[4]	NUCLEOTIDE SEQUENCE [GENOMIC DNA], AND VARIANTS HIS-132; LYS-158; CYS-205; MET-257; ALA-277; GLY-308; PRO-360 AND GLN-362. Livingston R.J., Rieder M.J., Rajkumar N., Downing T.K., Olson A.N., Nguyen C.P., Gildersleeve H., Cassidy C.M., Johnson E.J., Swanson J.E., McFarland I., Yool B., Park C., Nickerson D.A.; "NIEHS-SNPs, environmental genome project, NIEHS ES15478, Department of Genome Sciences, Seattle, WA (URL: http://egp.gs.washington.edu)."; Submitted (JAN-2005) to the EMBL/GenBank/DDBJ databases.
[5]	NUCLEOTIDE SEQUENCE [LARGE SCALE GENOMIC DNA]. DOI=10.1038/nature04727; PubMed=16710414 [NCBI, ExPASy, EBI, Israel, Japan] Gregory S.G., Barlow K.F., McLay K.E., Kaul R., Swarbreck D., Dunham A., Scott C.E., Howe K.L., Woodfine K., Spencer C.C.A., Jones M.C., Gillson C., Searle S., Zhou Y., Kokocinski F., McDonald L., Evans R., Phillips K., Atkinson A., Cooper R., Jones C., Hall R.E., Andrews T.D., Lloyd C., Ainscough R., Almeida J.P., Ambrose K.D., Anderson F., Andrew R.W., Ashwell R.I.S., Aubin K., Babbage A.K., Bagguley C.L., Bailey J., Beasley H., Bethel G., Bird C.P., Bray-Allen S., Brown J.Y., Brown A.J., Buckley D., Burton J., Bye J., Carder C., Chapman J.C., Clark S.Y., Clarke G., Clee C., Cobley V., Collier R.E., Corby N., Coville G.J., Davies J., Deadman R., Dunn M., Earthrowl M., Ellington A.G., Errington H., Frankish A., Frankland J., French L., Garner P., Garnett J., Gay L., Ghori M.R.J., Gibson R., Gilby L.M., Gillett W., Glithero R.J., Grafham D.V., Griffiths C., Griffiths-Jones S., Grocock R., Hammond S., Harrison E.S.I., Hart E., Haugen E., Heath P.D., Holmes S., Holt K., Howden P.J., Hunt A.R., Hunt S.E., Hunter G., Isherwood J., James R., Johnson C., Johnson D., Joy A., Kay M., Kershaw J.K., Kibukawa M., Kimberley A.M., King A., Knights A.J., Lad H., Laird G., Lawlor S., Leongamornlert D.A., Lloyd D.M., Loveland J., Lovell J., Lush M.J., Lyne R., Martin S., Mashreghi-Mohammadi M., Matthews L., Matthews N.S.W., McLaren S., Milne S., Mistry S., Moore M.J.F., Nickerson T., O'Dell C.N., Oliver K., Palmeiri A., Palmer S.A., Parker A., Patel D., Pearce A.V., Peck A.I., Pelan S., Phelps K., Phillimore B.J., Plumb R., Rajan J., Raymond C., Rouse G., Saenphimmachak C., Sehra H.K., Sheridan E., Shownkeen R., Sims S., Skuce C.D., Smith M., Steward C., Subramanian S., Sycamore N., Tracey A., Tromans A., Van Helmond Z., Wall M., Wallis J.M., White S., Whitehead S.L., Wilkinson J.E., Willey D.L., Williams H., Wilming L., Wray P.W., Wu Z., Coulson A., Vaudin M., Sulston J.E., Durbin R.M., Hubbard T., Wooster R., Dunham I., Carter N.P., McVean G., Ross M.T., Harrow J., Olson M.V., Beck S., Rogers J., Bentley D.R.; "The DNA sequence and biological annotation of human chromosome 1."; Nature 441:315-321(2006).
[6]	NUCLEOTIDE SEQUENCE [LARGE SCALE MRNA], AND VARIANT MET-257. TISSUE=Brain, and Lung; DOI=10.1101/gr.2596504; PubMed=15489334 [NCBI, ExPASy, EBI, Israel, Japan] The MGC Project Team; "The status, quality, and expansion of the NIH full-length cDNA project: the Mammalian Gene Collection (MGC)."; Genome Res. 14:2121-2127(2004).
[7]	VARIANTS TMAU ILE-66 AND LEU-153, AND VARIANTS LYS-158; MET-257 AND GLY-308. DOI=10.1093/hmg/7.5.839; PubMed=9536088 [NCBI, ExPASy, EBI, Israel, Japan] Treacy E.P., Akerman B.R., Chow L.M.L., Youil R., Bibeau C., Lin J., Bruce A.G., Knight M., Danks D.M., Cashman J.R., Forrest S.M.; "Mutations of the flavin-containing monooxygenase gene (FMO3) cause trimethylaminuria, a defect in detoxication."; Hum. Mol. Genet. 7:839-845(1998).
[8]	VARIANTS TMAU ILE-66 AND TRP-492. DOI=10.1002/(SICI)1098-1004(1999)13:5<376::AID-HUMU5>3.0.CO;2-A; PubMed=10338091 [NCBI, ExPASy, EBI, Israel, Japan] Akerman B.R., Forrest S.M., Chow L.M.L., Youil R., Knight M., Treacy E.P.; "Two novel mutations of the FMO3 gene in a proband with trimethylaminuria."; Hum. Mutat. 13:376-379(1999).
[9]	VARIANTS TMAU THR-52 AND LEU-387, AND VARIANTS LYS-158 AND GLY-308. DOI=10.1006/mgme.1999.2885; PubMed=10479479 [NCBI, ExPASy, EBI, Israel, Japan] Akerman B.R., Lemass H., Chow L.M.L., Lambert D.M., Greenberg C., Bibeau C., Mamer O.A., Treacy E.P.; "Trimethylaminuria is caused by mutations of the FMO3 gene in a North American cohort."; Mol. Genet. Metab. 68:24-31(1999).
[10]	VARIANTS TMAU SER-61; LEU-153; ILE-434 AND TRP-492, AND CHARACTERIZATION OF VARIANTS TMAU SER-61; LEU-153; ILE-434 AND TRP-492. DOI=10.1097/00008571-200012000-00005; PubMed=11191884 [NCBI, ExPASy, EBI, Israel, Japan] Dolphin C.T., Janmohamed A., Smith R.L., Shephard E.A., Phillips I.R.; "Compound heterozygosity for missense mutations in the flavin-containing monooxygenase 3 (FM03) gene in patients with fish-odour syndrome."; Pharmacogenetics 10:799-807(2000).
[11]	VARIANTS HIS-132; LYS-158; MET-257; PRO-360; GLN-362 AND ARG-503. DOI=10.1124/dmd.31.2.187; PubMed=12527699 [NCBI, ExPASy, EBI, Israel, Japan] Furnes B., Feng J., Sommer S.S., Schlenk D.; "Identification of novel variants of the flavin-containing monooxygenase gene family in African Americans."; Drug Metab. Dispos. 31:187-193(2003).
[12]	VARIANTS GLU-198 AND CYS-205. DOI=10.2133/dmpk.18.333; PubMed=15618753 [NCBI, ExPASy, EBI, Israel, Japan] Fujieda M., Yamazaki H., Togashi M., Saito T., Kamataki T.; "Two novel single nucleotide polymorphisms (SNPs) of the FMO3 gene in Japanese."; Drug Metab. Pharmacokinet. 18:333-335(2003).
[13]	VARIANT TMAU LYS-32. DOI=10.1097/00008571-200308000-00007; PubMed=12893987 [NCBI, ExPASy, EBI, Israel, Japan] Zhang J., Tran Q., Lattard V., Cashman J.R.; "Deleterious mutations in the flavin-containing monooxygenase 3 (FMO3) gene causing trimethylaminuria."; Pharmacogenetics 13:495-500(2003).
[14]	BIOPHYSICOCHEMICAL PROPERTIES, CHARACTERIZATION OF VARIANTS TMAU SER-61; ILE-66; LEU-153 AND TRP-492, AND CHARACTERIZATION OF VARIANTS LYS-158; MET-257 AND GLY-308. DOI=10.1016/j.abb.2007.04.014; PubMed=17531949 [NCBI, ExPASy, EBI, Israel, Japan] Yeung C.K., Adman E.T., Rettie A.E.; "Functional characterization of genetic variants of human FMO3 associated with trimethylaminuria."; Arch. Biochem. Biophys. 464:251-259(2007).
[15]	VARIANTS ASP-24; LYS-61; LYS-158; MET-257; GLY-308 AND ASN-416, BIOPHYSICOCHEMICAL PROPERTIES, AND CHARACTERIZATION OF VARIANTS ASP-24; LYS-61 AND ASN-416. DOI=10.1124/jpet.106.112268; PubMed=17050781 [NCBI, ExPASy, EBI, Israel, Japan] Koukouritaki S.B., Poch M.T., Henderson M.C., Siddens L.K., Krueger S.K., VanDyke J.E., Williams D.E., Pajewski N.M., Wang T., Hines R.N.; "Identification and functional analysis of common human flavin-containing monooxygenase 3 genetic variants."; J. Pharmacol. Exp. Ther. 320:266-273(2007).

Comments

FUNCTION: Involved in the oxidative metabolism of a variety of xenobiotics such as drugs and pesticides. It N-oxygenates primary aliphatic alkylamines as well as secondary and tertiary amines. Plays an important role in the metabolism of trimethylamine (TMA), via the production of TMA N-oxide (TMAO). Is also able to perform S-oxidation when acting on sulfide compounds.
CATALYTIC ACTIVITY: N,N-dimethylaniline + NADPH + O₂ = N,N-dimethylaniline N-oxide + NADP⁺ + H₂O.
COFACTOR: FAD.

BIOPHYSICOCHEMICAL PROPERTIES:

Kinetic parameters:	K_M=21 µM for trimethylamine (at pH 8.5);
	K_M=31 µM for trimethylamine (at pH 7.4 and 37 degrees Celsius);
	K_M=43 µM for benzydamine (at pH 7.4 and 37 degrees Celsius);
	K_M=55.7 µM for ethylenethiourea (at pH 8.5);
	K_M=71.8 µM for methimazole (at pH 8.5);
	K_M=150.1 µM for sulindac (at pH 8.5);
	K_M=248 µM for methyl p-tolyl sulfide (at pH 7.4 and 37 degrees Celsius);

SUBCELLULAR LOCATION: Microsome membrane. Endoplasmic reticulum membrane.
TISSUE SPECIFICITY: Liver.
DISEASE: Defects in FMO3 are the cause of trimethylaminuria (TMAU) [MIM:602079]; also known as fish-odor syndrome. TMAU is an inborn error of metabolism associated with an offensive body odor and caused by deficiency of FMO-mediated N-oxidation of amino-trimethylamine (TMA) derived from foodstuffs. Such individuals excrete relatively large amounts of TMA in their urine, sweat, and breath, and exhibit a fishy body odor characteristic of the malodorous free amine.
SIMILARITY: Belongs to the FMO family.
WEB RESOURCE: Name=GeneReviews; URL="http://www.genetests.org/query?gene=FMO3";.

Copyright

Copyrighted by the UniProt Consortium, see http://www.uniprot.org/terms. Distributed under the Creative Commons Attribution-NoDerivs License.

Cross-references

Sequence databases

EMBL

M83772; AAA86284.1; -; mRNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
Z47552; CAA87632.1; -; mRNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
U39967; AAC51932.1; -; Genomic_DNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
U39961; AAC51932.1; JOINED; Genomic_DNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
U39962; AAC51932.1; JOINED; Genomic_DNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
U39963; AAC51932.1; JOINED; Genomic_DNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
U39964; AAC51932.1; JOINED; Genomic_DNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
U39965; AAC51932.1; JOINED; Genomic_DNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
U39966; AAC51932.1; JOINED; Genomic_DNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
AY895830; AAW65372.1; -; Genomic_DNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
AL021026; CAA15908.1; -; Genomic_DNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]
BC032016; AAH32016.1; -; mRNA.	[EMBL / GenBank / DDBJ] [CoDingSequence]

PIR

A38228; A38228.
S62367; S51130.

RefSeq

NP_001002294.1; -.
NP_008825.4; -.

UniGene

Hs.445350

3D structure databases

ModBase

P31513.

PTM databases

PhosphoSite

P31513; -.

Enzyme and pathway databases

BioCyc

MetaCyc:ENSG00000007933-MON; -.

Reactome

REACT_2063; Metabolism of xenobiotics.

Polymorphism databases

NIEHS-SNPs

FMO3.

Organism-specific databases

HIX0001325; -.

HGNC:3771; FMO3.

HPA008065; -.
HPA013750; -.

MIM

136132; gene. [NCBI / EBI]
602079; phenotype. [NCBI / EBI]

Orphanet

35056; Trimethylaminuria.

PharmGKB

PA166; -.

GeneCards

P31513.

Gene expression databases

ArrayExpress

P31513; -.

CleanEx

HS_FMO3; -.

GermOnline

ENSG00000007933; Homo sapiens.

Ontologies

GO:0016021;	Cellular component: integral to membrane (inferred from electronic annotation from UniProtKB-KW).
GO:0031227;	Cellular component: intrinsic to endoplasmic reticulum membrane (inferred from electronic annotation from InterPro).
GO:0005792;	Cellular component: microsome (traceable author statement from ProtInc).
GO:0050660;	Molecular function: FAD binding (inferred from electronic annotation from InterPro).
GO:0004499;	Molecular function: flavin-containing monooxygenase activity (inferred from electronic annotation from InterPro).
GO:0050661;	Molecular function: NADP binding (inferred from electronic annotation from InterPro).
GO:0055114;	Biological process: oxidation reduction (inferred from electronic annotation from UniProtKB-KW).
QuickGo view.

Family and domain databases

InterPro

IPR012143; dManiline_mOase.
IPR013027; FAD_pyr_nucl-diS_OxRdtase.
IPR000960; Flavin_mOase.
IPR002255; Flavin_mOase_3.
Graphical view of domain structure.

Pfam

PF00743; FMO-like; 1.
Pfam graphical view of domain structure.

PIRSF

PIRSF000332; FMO; 1.

PRINTS

PR00368; FADPNR.
PR00370; FMOXYGENASE.
PR01123; FMOXYGENASE3.

ProDom

PD000139; FAD_pyr_redox; 1.
[Domain structure / List of seq. sharing at least 1 domain]

ProtoNet

P31513.

Genome annotation databases

Ensembl

ENSG00000007933; Homo sapiens. [Contig view]

GeneID

2328; -.

KEGG

hsa:2328; -.

Phylogenomic databases

HOGENOM

P31513; -.

HOVERGEN

P31513; -.

Other

NextBio

9447; -.

SOURCE

FMO3; Homo sapiens.

UniRef

View cluster of proteins with at least 50% / 90% / 100% identity.

Keywords

Disease mutation; Endoplasmic reticulum; FAD; Flavoprotein; Membrane; Microsome; Monooxygenase; NADP; Oxidoreductase; Polymorphism; Transmembrane.

Features

Feature table viewer

`Key`	`From To`	`Length`	`Description`	`FTId`
`INIT_MET`	`1 1`		`Removed (By similarity).`
`CHAIN`	`2 532`	`531`	`Dimethylaniline monooxygenase [N-oxide-forming] 3.`	`PRO_0000147654`
`NP_BIND`	`9 14`	`6`	`FAD (Potential).`
`NP_BIND`	`191 196`	`6`	`NADP (Potential).`
`VARIANT`	`24 24`	`1`	`E -> D (modest increase in catalytic efficiency toward trimethylamine, methimazole, ethylenethiourea and sulindac).`	`VAR_042705`
`VARIANT`	`32 32`	`1`	`E -> K (in TMAU).`	`VAR_037306`
`VARIANT`	`52 52`	`1`	`A -> T (in TMAU).`	`VAR_008146`
`VARIANT`	`61 61`	`1`	`N -> K (loss of activity).`	`VAR_042706`
`VARIANT`	`61 61`	`1`	`N -> S (in TMAU; more than 90% reduction in catalytic efficiency toward trimethylamine, benzydamine and methyl p-tolyl sulfide).`	`VAR_037307`
`VARIANT`	`66 66`	`1`	`M -> I (in TMAU; loss of activity; affects FAD binding).`	`VAR_002423`
`VARIANT`	`132 132`	`1`	`D -> H (in dbSNP:rs12072582 [NCBI]).`	`VAR_015364`
`VARIANT`	`153 153`	`1`	`P -> L (in TMAU; 90% reduction in catalytic efficiency toward trimethylamine and benzydamine; 34% reduction in catalytic efficiency toward methyl p-tolyl sulfide; nearly no effect on affinity for these substrates).`	`VAR_002424`
`VARIANT`	`158 158`	`1`	`E -> K (35%, 45% and 71% increase in catalytic efficiency toward trimethylamine, benzydamine and methyl p-tolyl sulfide, respectively; dbSNP:rs2266782 [NCBI]).`	`VAR_002425`
`VARIANT`	`198 198`	`1`	`D -> E.`	`VAR_018345`
`VARIANT`	`205 205`	`1`	`R -> C (in dbSNP:rs28363549 [NCBI]).`	`VAR_018346`
`VARIANT`	`257 257`	`1`	`V -> M (65% increase in catalytic efficiency toward trimethylamine and 60% reduction toward benzydamine and methyl p-tolyl sulfide; dbSNP:rs1736557 [NCBI]).`	`VAR_002426`
`VARIANT`	`277 277`	`1`	`V -> A (in dbSNP:rs2066530 [NCBI]).`	`VAR_014845`
`VARIANT`	`308 308`	`1`	`E -> G (16% reduction in catalytic efficiency toward trimethylamine and 40% increase toward benzydamine and methyl p-tolyl sulfide; dbSNP:rs2266780 [NCBI]).`	`VAR_002427`
`VARIANT`	`360 360`	`1`	`L -> P (in dbSNP:rs28363581 [NCBI]).`	`VAR_015365`
`VARIANT`	`362 362`	`1`	`E -> Q (in dbSNP:rs2066532 [NCBI]).`	`VAR_014846`
`VARIANT`	`387 387`	`1`	`R -> L (in TMAU).`	`VAR_008147`
`VARIANT`	`416 416`	`1`	`K -> N (2-fold decrease in affinity for trimethylamine; 3-fold decrease in catalytic efficiency toward methimazole; 3-fold increase in catalytic efficiency toward sulindac; 30% increase in catalytic efficiency toward ethylenethiourea).`	`VAR_042707`
`VARIANT`	`434 434`	`1`	`M -> I (in TMAU; profoundly alters enzyme function).`	`VAR_037308`
`VARIANT`	`492 492`	`1`	`R -> W (in TMAU; loss of activity; affects FAD binding).`	`VAR_008145`
`VARIANT`	`503 503`	`1`	`G -> R.`	`VAR_015366`
`CONFLICT`	`298 298`		`S -> T (in Ref. 1; AAA86284).`
`CONFLICT`	`369 369`		`I -> L (in Ref. 1; AAA86284).`
`CONFLICT`	`400 405`		`PSMEDM -> GPFYGKTL (in Ref. 1; AAA86284).`
`CONFLICT`	`410 410`		`N -> I (in Ref. 1; AAA86284).`
`CONFLICT`	`418 419`		`KW -> ANG (in Ref. 1; AAA86284).`
`CONFLICT`	`444 445`		`KP -> T (in Ref. 1; AAA86284).`
`CONFLICT`	`449 449`		`W -> M (in Ref. 1; AAA86284).`
`CONFLICT`	`454 454`		`D -> G (in Ref. 1; AAA86284).`
`CONFLICT`	`461 462`		`VY -> L (in Ref. 1; AAA86284).`
`CONFLICT`	`478 478`		`Q -> S (in Ref. 1; AAA86284).`
`CONFLICT`	`486 486`		`I -> M (in Ref. 2; CAA87632).`

Sequence information

Length: 532 AA [This is the length of the unprocessed precursor]

Molecular weight: 60033 Da [This is the MW of the unprocessed precursor]

CRC64: 729E41D53EFC4110 [This is a checksum on the sequence]

        10         20         30         40         50         60 
MGKKVAIIGA GVSGLASIRS CLEEGLEPTC FEKSNDIGGL WKFSDHAEEG RASIYKSVFS 

        70         80         90        100        110        120 
NSSKEMMCFP DFPFPDDFPN FMHNSKIQEY IIAFAKEKNL LKYIQFKTFV SSVNKHPDFA 

       130        140        150        160        170        180 
TTGQWDVTTE RDGKKESAVF DAVMVCSGHH VYPNLPKESF PGLNHFKGKC FHSRDYKEPG 

       190        200        210        220        230        240 
VFNGKRVLVV GLGNSGCDIA TELSRTAEQV MISSRSGSWV MSRVWDNGYP WDMLLVTRFG 

       250        260        270        280        290        300 
TFLKNNLPTA ISDWLYVKQM NARFKHENYG LMPLNGVLRK EPVFNDELPA SILCGIVSVK 

       310        320        330        340        350        360 
PNVKEFTETS AIFEDGTIFE GIDCVIFATG YSFAYPFLDE SIIKSRNNEI ILFKGVFPPL 

       370        380        390        400        410        420 
LEKSTIAVIG FVQSLGAAIP TVDLQSRWAA QVIKGTCTLP SMEDMMNDIN EKMEKKRKWF 

       430        440        450        460        470        480 
GKSETIQTDY IVYMDELSSF IGAKPNIPWL FLTDPKLAME VYFGPCSPYQ FRLVGPGQWP 

       490        500        510        520        530 
GARNAILTQW DRSLKPMQTR VVGRLQKPCF FFHWLKLFAI PILLIAVFLV LT

P31513 in FASTA format

View entry in original UniProtKB/Swiss-Prot format
View entry in raw text format (no links)
Report form for errors/updates in this UniProtKB/Swiss-Prot entry

	BLAST submission on ExPASy/SIB or at NCBI (USA)		Sequence analysis tools: ProtParam, ProtScale, Compute pI/Mw, PeptideMass, PeptideCutter, Dotlet (Java)
	ScanProsite, MotifScan		Submit a homology modeling request to SWISS-MODEL
	NPSA Sequence analysis tools