DB code: S00231

RLCP classification	1.15.8310.1250 : Hydrolysis
CATH domain	3.20.20.140 : TIM Barrel	Catalytic domain
E.C.	3.1.8.1
CSA	1ez2
M-CSA	1ez2
MACiE	M0159

CATH domain	Related DB codes (homologues)
3.20.20.140 : TIM Barrel	S00232 M00186 D00673 D00675 D00801 D00873 M00030 M00225 M00226

Uniprot Enzyme Name
UniprotKB	Protein name	Synonyms	Pfam
P0A433	Parathion hydrolase	EC 3.1.8.1 Phosphotriesterase PTE	PF02126 (PTE) [Graphical View]
P0A434	Parathion hydrolase	EC 3.1.8.1 Phosphotriesterase PTE	PF02126 (PTE) [Graphical View]

KEGG enzyme name
aryldialkylphosphatase organophosphate hydrolase paraoxonase A-esterase aryltriphosphatase organophosphate esterase esterase B1 esterase E4 paraoxon esterase pirimiphos-methyloxon esterase OPA anhydrase organophosphorus hydrolase phosphotriesterase paraoxon hydrolase OPH organophosphorus acid anhydrase

UniprotKB: Accession Number	Entry name	Activity	Subunit	Subcellular location	Cofactor
P0A433	OPD_FLAS2	An aryl dialkyl phosphate + H(2)O = dialkyl phosphate + an aryl alcohol.	Homodimer (By similarity).	Cell membrane, Peripheral membrane protein (By similarity).	Binds 2 zinc ions per subunit (By similarity).
P0A434	OPD_BREDI	An aryl dialkyl phosphate + H(2)O = dialkyl phosphate + an aryl alcohol.	Homodimer.	Cell membrane, Peripheral membrane protein.	Binds 2 zinc ions per subunit.

KEGG Pathways
Map code	Pathways	E.C.
MAP00361	gamma-Hexachlorocyclohexane degradation

Compound table
	Cofactors	Substrates		Products		Intermediates
KEGG-id	C00038	C03254	C00001	C02534	C15584
E.C.
Compound	Zinc	Aryl dialkyl phosphate	H2O	Dialkyl phosphate	Phenol
Type	heavy metal	aromatic ring (only carbon atom),phosphate group/phosphate ion	H2O	phosphate group/phosphate ion	aromatic ring (only carbon atom)
ChEBI	29105 29105		15377 15377		15882 15882
PubChem	32051 32051		22247451 962 22247451 962		20488062 996 20488062 996

1dpmA	Bound:2x_ZN	Analogue:EBP_900	Bound:HOH_7	Unbound	Unbound
1dpmB	Bound:2x_ZN	Analogue:EBP_902	Bound:HOH_17	Unbound	Unbound
1eywA	Bound:2x_ZN	Analogue:TEN	Bound:HOH_410	Unbound	Unbound
1ez2A	Bound:2x_ZN	Analogue:DII	Bound:HOH_1551	Unbound	Unbound
1ez2B	Bound:2x_ZN	Analogue:DII	Bound:HOH_2609	Unbound	Unbound
1hzyA	Bound:2x_ZN	Unbound		Unbound	Unbound
1hzyB	Bound:2x_ZN	Unbound		Unbound	Unbound
1i03A	Analogue:2x_CD	Unbound		Unbound	Unbound
1i03B	Analogue:2x_CD	Unbound		Unbound	Unbound
1i0bA	Analogue:2x_MN	Unbound		Unbound	Unbound
1i0bB	Analogue:2x_MN	Unbound		Unbound	Unbound
1i0dA	Analogue:_ZN,_CD	Unbound		Unbound	Unbound
1i0dB	Analogue:_ZN,_CD	Unbound		Unbound	Unbound
1jgmA	Analogue:2x_CD	Unbound		Unbound	Unbound
1jgmB	Analogue:2x_CD	Unbound		Unbound	Unbound
1p6bA	Bound:3x_ZN	Unbound		Unbound	Unbound
1p6bB	Bound:3x_ZN	Unbound		Analogue:EFS	Unbound
1p6cA	Bound:2x_ZN	Analogue:DII	Bound:HOH_205	Unbound	Unbound
1p6cB	Bound:2x_ZN	Analogue:DII	Bound:HOH_16	Unbound	Unbound
1pscA	Analogue:2x_CD	Unbound		Unbound	Unbound
1pscB	Analogue:2x_CD	Unbound		Unbound	Unbound
1ptaA	Unbound	Unbound		Unbound	Unbound

Reference for Active-site residues
resource	references	E.C.
PDB;1psc, 1p6b & literature [8] & [20]

Active-site residues
PDB	Catalytic residues	Cofactor-binding residues	Modified residues	Main-chain involved in catalysis	Comment

1dpmA	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 902(carbamylated)		LYS-FMT carbamylated Lys
1dpmB	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 904(carbamylated)		LYS-FMT carbamylated Lys
1eywA	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);KCX 169(Zinc-1 & Zinc-2)	KCX 169(carbamylated)		KCX carbamylated Lys
1ez2A	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);KCX 169(Zinc-1 & Zinc-2)	KCX 169(carbamylated)		KCX carbamylated Lys
1ez2B	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);KCX 169(Zinc-1 & Zinc-2)	KCX 169(carbamylated)		KCX carbamylated Lys
1hzyA	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 369(carbamylated)		LYS-FMT carbamylated Lys169
1hzyB	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 369(carbamylated)		LYS-FMT carbamylated Lys169
1i03A	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	CBX 369(carbamylated)		LYS-CBX carbamylated Lys169
1i03B	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	CBX 369(carbamylated)		LYS-CBX carbamylated Lys169
1i0bA	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 369(carbamylated)		LYS-FMT carbamylated Lys169
1i0bB	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 369(carbamylated)		LYS-FMT carbamylated Lys169
1i0dA	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 369(carbamylated)		LYS-FMT carbamylated Lys169
1i0dB	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 369(carbamylated)		LYS-FMT carbamylated Lys169
1jgmA	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);KCX 169(Zinc-1 & Zinc-2)	KCX 169(carbamylated)		KCX carbamylated Lys
1jgmB	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);KCX 169(Zinc-1 & Zinc-2)	KCX 169(carbamylated)		KCX carbamylated Lys
1p6bA	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LCX 169(Zinc-1 & Zinc-2)	LCX 169(carbamylated)		LCX carbamylated Lys, mutant H254G, H257W, I303T
1p6bB	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LCX 169(Zinc-1 & Zinc-2)	LCX 169(carbamylated)		LCX carbamylated Lys, mutant H254G, H257W, I303T
1p6cA		HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LCX 169(Zinc-1 & Zinc-2)	LCX 169(carbamylated)		LCX carbamylated Lys, mutant H254G, H257W, I303T
1p6cB	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LCX 169(Zinc-1 & Zinc-2)	LCX 169(carbamylated)		LCX carbamylated Lys, mutant H254G, H257W, I303T
1pscA	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 901(carbamylated)		LYS-FMT carbamylated Lys
1pscB	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)	FMT 902(carbamylated)		LYS-FMT carbamylated Lys
1ptaA	ASP 301	HIS 55;HIS 57;ASP 301(Zinc-1);HIS 201;HIS 230(Zinc-2);LYS 169(Zinc-1 & Zinc-2)

References for Catalytic Mechanism
References	Sections	No. of steps in catalysis
[1]	Fig.6, p.21502
[3]	p.9154
[4]	p.15005
[8]	p.7978
[9]	Fig.3, p.10908-10911
[10]	Fig.6, p.6024-6025
[12]	p.1982
[16]	Fig.6, p.17450
[17]	Scheme 12,p.87-88
[20]	p.2722

References
[1]
Resource
Comments
Medline ID
PubMed ID	2174875
Journal	J Biol Chem
Year	1990
Volume	265
Pages	21498-503
Authors	Dumas DP, Raushel FM
Title	Chemical and kinetic evidence for an essential histidine in the phosphotriesterase from Pseudomonas diminuta.
Related PDB
Related UniProtKB
[2]
Resource
Comments
Medline ID
PubMed ID	1320014
Journal	J Biol Chem
Year	1992
Volume	267
Pages	13278-83
Authors	Omburo GA, Kuo JM, Mullins LS, Raushel FM
Title	Characterization of the zinc binding site of bacterial phosphotriesterase.
Related PDB
Related UniProtKB
[3]
Resource
Comments
Medline ID
PubMed ID	8396425
Journal	Biochemistry
Year	1993
Volume	32
Pages	9148-55
Authors	Omburo GA, Mullins LS, Raushel FM
Title	Structural characterization of the divalent cation sites of bacterial phosphotriesterase by 113Cd NMR spectroscopy.
Related PDB
Related UniProtKB
[4]
Resource
Comments	X-RAY CRYSTALLOGRAPHY (2.0 ANGSTROMS).
Medline ID	95092756
PubMed ID	7999757
Journal	Biochemistry
Year	1994
Volume	33
Pages	15001-7
Authors	Benning MM, Kuo JM, Raushel FM, Holden HM
Title	Three-dimensional structure of phosphotriesterase: an enzyme capable of detoxifying organophosphate nerve agents.
Related PDB	1pta
Related UniProtKB	P16648
[5]
Resource
Comments	ACTIVE SITE.
Medline ID	94206935
PubMed ID	8155644
Journal	Biochemistry
Year	1994
Volume	33
Pages	4265-72
Authors	Kuo JM, Raushel FM
Title	Identification of the histidine ligands to the binuclear metal center of phosphotriesterase by site-directed mutagenesis.
Related PDB
Related UniProtKB	P16648
[6]
Resource
Comments
Medline ID
PubMed ID	7864632
Journal	Arch Biochem Biophys
Year	1995
Volume	316
Pages	765-72
Authors	Chae MY, Omburo GA, Lindahl PA, Raushel FM
Title	Utilization of copper as a paramagnetic probe for the binuclear metal center of phosphotriesterase.
Related PDB
Related UniProtKB
[7]
Resource
Comments
Medline ID
PubMed ID	7827033
Journal	Biochemistry
Year	1995
Volume	34
Pages	750-4
Authors	Banzon JA, Kuo JM, Fischer DR, Stang PJ, Raushel FM
Title	Histidine-254 is essential for the inactivation of phosphotriesterase with the alkynyl phosphate esters and diethyl pyrocarbonate.
Related PDB
Related UniProtKB
[8]
Resource
Comments	X-RAY CRYSTALLOGRAPHY (2.0 ANGSTROMS).
Medline ID	95315185
PubMed ID	7794910
Journal	Biochemistry
Year	1995
Volume	34
Pages	7973-8
Authors	Benning MM, Kuo JM, Raushel FM, Holden HM
Title	Three-dimensional structure of the binuclear metal center of phosphotriesterase.
Related PDB	1psc
Related UniProtKB	P16648
[9]
Resource
Comments
Medline ID
PubMed ID	8718883
Journal	Biochemistry
Year	1996
Volume	35
Pages	10904-12
Authors	Hong SB, Raushel FM
Title	Metal-substrate interactions facilitate the catalytic activity of the bacterial phosphotriesterase.
Related PDB
Related UniProtKB
[10]
Resource
Comments	X-RAY CRYSTALLOGRAPHY (2.1 ANGSTROMS).
Medline ID	96214508
PubMed ID	8634243
Journal	Biochemistry
Year	1996
Volume	35
Pages	6020-5
Authors	Vanhooke JL, Benning MM, Raushel FM, Holden HM
Title	Three-dimensional structure of the zinc-containing phosphotriesterase with the bound substrate analog diethyl 4-methylbenzylphosphonate.
Related PDB	1dpm
Related UniProtKB	P16648
[11]
Resource
Comments
Medline ID
PubMed ID	9220990
Journal	Biochemistry
Year	1997
Volume	36
Pages	9022-8
Authors	Hong SB, Mullins LS, Shim H, Raushel FM
Title	Mechanism-based inhibitors for the inactivation of the bacterial phosphotriesterase.
Related PDB
Related UniProtKB
[12]
Resource
Comments
Medline ID
PubMed ID	9047295
Journal	Biochemistry
Year	1997
Volume	36
Pages	1982-8
Authors	Kuo JM, Chae MY, Raushel FM
Title	Perturbations to the active site of phosphotriesterase.
Related PDB
Related UniProtKB
[13]
Resource
Comments
Medline ID
PubMed ID	9325279
Journal	J Biol Chem
Year	1997
Volume	272
Pages	25596-601
Authors	Watkins LM, Mahoney HJ, McCulloch JK, Raushel FM
Title	Augmented hydrolysis of diisopropyl fluorophosphate in engineered mutants of phosphotriesterase.
Related PDB
Related UniProtKB
[14]
Resource
Comments
Medline ID
PubMed ID	9408951
Journal	Proteins
Year	1997
Volume	29
Pages	553-61
Authors	Watkins LM, Kuo JM, Chen-Goodspeed M, Raushel FM
Title	A combinatorial library for the binuclear metal center of bacterial phosphotriesterase.
Related PDB
Related UniProtKB
[15]
Resource
Comments
Medline ID
PubMed ID	9548740
Journal	Biochemistry
Year	1998
Volume	37
Pages	5096-106
Authors	Buchbinder JL, Stephenson RC, Dresser MJ, Pitera JW, Scanlan TS, Fletterick RJ
Title	Biochemical characterization and crystallographic structure of an Escherichia coli protein from the phosphotriesterase gene family.
Related PDB
Related UniProtKB
[16]
Resource
Comments
Medline ID
PubMed ID	9651332
Journal	J Biol Chem
Year	1998
Volume	273
Pages	17445-50
Authors	Shim H, Hong SB, Raushel FM
Title	Hydrolysis of phosphodiesters through transformation of the bacterial phosphotriesterase.
Related PDB
Related UniProtKB
[17]
Resource
Comments
Medline ID
PubMed ID	10800593
Journal	Adv Enzymol Relat Areas Mol Biol
Year	2000
Volume	74
Pages	51-93
Authors	Raushel FM, Holden HM
Title	Phosphotriesterase: an enzyme in search of its natural substrate.
Related PDB
Related UniProtKB
[18]
Resource
Comments
Medline ID
PubMed ID	11118318
Journal	Biochem Biophys Res Commun
Year	2000
Volume	279
Pages	516-9
Authors	Gopal S, Rastogi V, Ashman W, Mulbry W
Title	Mutagenesis of organophosphorus hydrolase to enhance hydrolysis of the nerve agent VX.
Related PDB
Related UniProtKB
[19]
Resource
Comments	X-ray crystallography
Medline ID
PubMed ID	10871616
Journal	J Biol Chem
Year	2000
Volume	275
Pages	30556-60
Authors	Benning MM, Hong SB, Raushel FM, Holden HM
Title	The binding of substrate analogs to phosphotriesterase.
Related PDB	1eyw 1ez2
Related UniProtKB
[20]
Resource
Comments	X-ray crystallography
Medline ID
PubMed ID	11258882
Journal	Biochemistry
Year	2001
Volume	40
Pages	2712-22
Authors	Benning MM, Shim H, Raushel FM, Holden HM
Title	High resolution X-ray structures of different metal-substituted forms of phosphotriesterase from Pseudomonas diminuta.
Related PDB	1hzy 1i0b 1i0d 1i03 1jgm
Related UniProtKB
[21]
Resource
Comments
Medline ID
PubMed ID	11170459
Journal	Biochemistry
Year	2001
Volume	40
Pages	1325-31
Authors	Chen-Goodspeed M, Sogorb MA, Wu F, Hong SB, Raushel FM
Title	Structural determinants of the substrate and stereochemical specificity of phosphotriesterase.
Related PDB
Related UniProtKB
[22]
Resource
Comments
Medline ID
PubMed ID	11170460
Journal	Biochemistry
Year	2001
Volume	40
Pages	1332-9
Authors	Chen-Goodspeed M, Sogorb MA, Wu F, Raushel FM
Title	Enhancement, relaxation, and reversal of the stereoselectivity for phosphotriesterase by rational evolution of active site residues.
Related PDB
Related UniProtKB
[23]
Resource
Comments
Medline ID
PubMed ID	11456615
Journal	J Am Chem Soc
Year	2001
Volume	123
Pages	817-26
Authors	Koca J, Zhan CG, Rittenhouse RC, Ornstein RL
Title	Mobility of the active site bound paraoxon and sarin in zinc-phosphotriesterase by molecular dynamics simulation and quantum chemical calculation.
Related PDB
Related UniProtKB
[24]
Resource
Comments
Medline ID
PubMed ID	11206385
Journal	J Chem Inf Comput Sci
Year	2001
Volume	41
Pages	8-17
Authors	Krauss M
Title	Ab initio structure of the active site of phosphotriesterase.
Related PDB
Related UniProtKB
[25]
Resource
Comments
Medline ID
PubMed ID	11599021
Journal	Proteins
Year	2001
Volume	45
Pages	183-9
Authors	Pang YP
Title	Successful molecular dynamics simulation of two zinc complexes bridged by a hydroxide in phosphotriesterase using the cationic dummy atom method.
Related PDB
Related UniProtKB
[26]
Resource
Comments
Medline ID
PubMed ID	11929226
Journal	J Am Chem Soc
Year	2002
Volume	124
Pages	3498-9
Authors	Li WS, Li Y, Hill CM, Lum KT, Raushel FM
Title	Enzymatic synthesis of chiral organophosphothioates from prochiral precursors.
Related PDB
Related UniProtKB
[27]
Resource
Comments	X-ray crystallography
Medline ID
PubMed ID	15369336
Journal	J Am Chem Soc
Year	2003
Volume	125
Pages	8990-1
Authors	Hill CM, Li WS, Thoden JB, Holden HM, Raushel FM
Title	Enhanced degradation of chemical warfare agents through molecular engineering of the phosphotriesterase active site.
Related PDB	1p6b 1p6c
Related UniProtKB
[28]
Resource
Comments
Medline ID
PubMed ID	12548728
Journal	J Comput Chem
Year	2003
Volume	24
Pages	368-78
Authors	Koca J, Zhan CG, Rittenhouse RC, Ornstein RL
Title	Coordination number of zinc ions in the phosphotriesterase active site by molecular dynamics and quantum mechanics.
Related PDB
Related UniProtKB
[29]
Resource
Comments
Medline ID
PubMed ID	15018612
Journal	Biochem J
Year	2004
Volume	380
Pages	627-33
Authors	Rochu D, Viguie N, Renault F, Crouzier D, Froment MT, Masson P
Title	Contribution of the active-site metal cation to the catalytic activity and to the conformational stability of phosphotriesterase: temperature- and pH-dependence.
Related PDB
Related UniProtKB

Comments
This enzyme is activated in vitro by the addition of carbon dioxide, which carbamates the sidechain of Lys169, according to the literature [12]. This modified lysine residue is essential to bridge the two metal cofactors. Although early work (literature [1] & [4]) suggested that a general base to activate a water molecule, the water can be activated by the metal cofactor without any general base, according to the more recent literature ([8], [9], [10], [14]). In any case, the metal cofactors play the following roles (see [9]): (a) They can decrease pKa of th bound wate, increasing its nucleophilicity. (b) They can polarize the P=O bond (or P=S bond), and thereby facilitate the approach of the attacking hydroxyl ion, by increasing the electrophilic character of the phosphoryl core. (c) They can neutralize the development of the negative charge on the leaving group. The most recent literature [20] and structural information suggested that the catalytic reaction of this enzyme proceeds via SN2-like mechanism as follows: (1) Phosphoryl-oxygen bond is polarized by its interaction with zinc-2. (2) A water or hydroxide ion bridging the two zinc ions is activated by the two zinc ions (particulary zinc-1) and Asp301 (as a general base). (3) The activated water makes a nucleophilic attack on the phosphorus atom, releasing the leaving phenol group.

Comments

This enzyme is activated in vitro by the addition of carbon dioxide, which carbamates the sidechain of Lys169, according to the literature [12]. This modified lysine residue is essential to bridge the two metal cofactors.
Although early work (literature [1] & [4]) suggested that a general base to activate a water molecule, the water can be activated by the metal cofactor without any general base, according to the more recent literature ([8], [9], [10], [14]).
In any case, the metal cofactors play the following roles (see [9]):
(a) They can decrease pKa of th bound wate, increasing its nucleophilicity.
(b) They can polarize the P=O bond (or P=S bond), and thereby facilitate the approach of the attacking hydroxyl ion, by increasing the electrophilic character of the phosphoryl core.
(c) They can neutralize the development of the negative charge on the leaving group.
The most recent literature [20] and structural information suggested that the catalytic reaction of this enzyme proceeds via SN2-like mechanism as follows:
(1) Phosphoryl-oxygen bond is polarized by its interaction with zinc-2.
(2) A water or hydroxide ion bridging the two zinc ions is activated by the two zinc ions (particulary zinc-1) and Asp301 (as a general base).
(3) The activated water makes a nucleophilic attack on the phosphorus atom, releasing the leaving phenol group.

Created	Updated
2005-03-10	2009-04-15