Amine oxidase (copper-containing) (AOC) (
EC1.4.3.21 and
EC1.4.3.22; formerly
EC1.4.3.6) is a family of
amine oxidaseenzymes which includes both
primary-amine oxidase and
diamine oxidase; these enzymes catalyze the oxidation of a wide range of biogenic amines including many neurotransmitters, histamine and xenobiotic amines. They act as a disulphide-linked homodimer. They catalyse the oxidation of primary amines to aldehydes, with the subsequent release of ammonia and hydrogen peroxide, which requires one copper ion per subunit and topaquinone as cofactor:[2]
Copper-containing amine oxidases are found in bacteria, fungi, plants and animals. In prokaryotes, the enzyme enables various amine substrates to be used as sources of carbon and nitrogen.[3][4]
The copper amine oxidase 3-dimensional structure was determined through
X-ray crystallography.[1]
The copper amine oxidases occur as mushroom-shaped homodimers of 70-95 kDa, each monomer containing a copper ion and a covalently bound
redox cofactor,
topaquinone (TPQ). TPQ is formed by post-translational modification of a conserved tyrosine residue. The copper ion is coordinated with three
histidine residues and two water molecules in a distorted square pyramidal geometry, and has a dual function in catalysis and TPQ biogenesis. The catalytic domain is the largest of the 3-4 domains found in copper amine oxidases, and consists of a beta sandwich of 18 strands in two sheets. The active site is buried and requires a conformational change to allow the substrate access.
The N2 and N3 N-terminal domains share a common structural fold, its core consisting of alpha-beta(4), where the helix is packed against the coiled anti-parallel beta-sheets. An additional domain is found at the N-terminal of some copper amine oxidases, as well as in related
proteins such as
cell wallhydrolase and N-acetylmuramoyl-L-alanine
amidase. This domain consists of a five-stranded antiparallel
beta-sheet twisted around an alpha
helix.[5][6]
Function
In eukaryotes they have a broader range of functions, including cell differentiation and growth, wound healing, detoxification and cell signalling;[7] one AOC enzyme (
AOC3) functions as a
vascular adhesion protein (VAP-1) in some mammalian tissues.[1]
^Murray JM, Convery MA, Phillips SE, McPherson MJ, Knowles PF, Parsons MR, Wilmot CM, Blakeley V, Corner AS, Alton G, Palcic MM (1997). "Catalytic mechanism of the quinoenzyme amine oxidase from Escherichia coli: exploring the reductive half-reaction". Biochemistry. 36 (7): 1608–1620.
doi:
10.1021/bi962205j.
PMID9048544.
^Tanizawa K, Guss JM, Freeman HC, Yamaguchi H, Wilce MC, Dooley DM, Matsunami H, Mcintire WS, Ruggiero CE (1997). "Crystal structures of the copper-containing amine oxidase from Arthrobacter globiformis in the holo and apo forms: implications for the biogenesis of topaquinone". Biochemistry. 36 (51): 16116–16133.
doi:
10.1021/bi971797i.
PMID9405045.
McEwen CM Jr (1965). "Human plasma monoamine oxidase. 1. Purification and identification". J. Biol. Chem. 240 (5): 2003–10.
PMID5888801.
Mondovi B, Costa MT, Agro AF, Rotilio G (1967). "Pyridoxal phosphate as a prosthetic group of pig kidney diamine oxidase". Arch. Biochem. Biophys. 119 (1): 373–81.
doi:
10.1016/0003-9861(67)90468-7.
PMID4964016.
Amine oxidase (copper-containing) (AOC) (
EC1.4.3.21 and
EC1.4.3.22; formerly
EC1.4.3.6) is a family of
amine oxidaseenzymes which includes both
primary-amine oxidase and
diamine oxidase; these enzymes catalyze the oxidation of a wide range of biogenic amines including many neurotransmitters, histamine and xenobiotic amines. They act as a disulphide-linked homodimer. They catalyse the oxidation of primary amines to aldehydes, with the subsequent release of ammonia and hydrogen peroxide, which requires one copper ion per subunit and topaquinone as cofactor:[2]
Copper-containing amine oxidases are found in bacteria, fungi, plants and animals. In prokaryotes, the enzyme enables various amine substrates to be used as sources of carbon and nitrogen.[3][4]
The copper amine oxidase 3-dimensional structure was determined through
X-ray crystallography.[1]
The copper amine oxidases occur as mushroom-shaped homodimers of 70-95 kDa, each monomer containing a copper ion and a covalently bound
redox cofactor,
topaquinone (TPQ). TPQ is formed by post-translational modification of a conserved tyrosine residue. The copper ion is coordinated with three
histidine residues and two water molecules in a distorted square pyramidal geometry, and has a dual function in catalysis and TPQ biogenesis. The catalytic domain is the largest of the 3-4 domains found in copper amine oxidases, and consists of a beta sandwich of 18 strands in two sheets. The active site is buried and requires a conformational change to allow the substrate access.
The N2 and N3 N-terminal domains share a common structural fold, its core consisting of alpha-beta(4), where the helix is packed against the coiled anti-parallel beta-sheets. An additional domain is found at the N-terminal of some copper amine oxidases, as well as in related
proteins such as
cell wallhydrolase and N-acetylmuramoyl-L-alanine
amidase. This domain consists of a five-stranded antiparallel
beta-sheet twisted around an alpha
helix.[5][6]
Function
In eukaryotes they have a broader range of functions, including cell differentiation and growth, wound healing, detoxification and cell signalling;[7] one AOC enzyme (
AOC3) functions as a
vascular adhesion protein (VAP-1) in some mammalian tissues.[1]
^Murray JM, Convery MA, Phillips SE, McPherson MJ, Knowles PF, Parsons MR, Wilmot CM, Blakeley V, Corner AS, Alton G, Palcic MM (1997). "Catalytic mechanism of the quinoenzyme amine oxidase from Escherichia coli: exploring the reductive half-reaction". Biochemistry. 36 (7): 1608–1620.
doi:
10.1021/bi962205j.
PMID9048544.
^Tanizawa K, Guss JM, Freeman HC, Yamaguchi H, Wilce MC, Dooley DM, Matsunami H, Mcintire WS, Ruggiero CE (1997). "Crystal structures of the copper-containing amine oxidase from Arthrobacter globiformis in the holo and apo forms: implications for the biogenesis of topaquinone". Biochemistry. 36 (51): 16116–16133.
doi:
10.1021/bi971797i.
PMID9405045.
McEwen CM Jr (1965). "Human plasma monoamine oxidase. 1. Purification and identification". J. Biol. Chem. 240 (5): 2003–10.
PMID5888801.
Mondovi B, Costa MT, Agro AF, Rotilio G (1967). "Pyridoxal phosphate as a prosthetic group of pig kidney diamine oxidase". Arch. Biochem. Biophys. 119 (1): 373–81.
doi:
10.1016/0003-9861(67)90468-7.
PMID4964016.