DB code: S00404

RLCP classification	1.15.9400.1180 : Hydrolysis
CATH domain	3.40.600.10 : ECO RV Endonuclease; Chain A	Catalytic domain
E.C.	3.1.21.4
CSA
M-CSA
MACiE

CATH domain	Related DB codes (homologues)

Uniprot Enzyme Name
UniprotKB	Protein name	Synonyms	RefSeq	Pfam
P04390	Type-2 restriction enzyme EcoRV	R.EcoRV EC 3.1.21.4 Type II restriction enzyme EcoRV Endonuclease EcoRV	NP_863580.1 (Protein) NC_005019.1 (DNA/RNA sequence) YP_007316617.1 (Protein) NC_019982.1 (DNA/RNA sequence)	PF09233 (Endonuc-EcoRV) [Graphical View]

KEGG enzyme name
type II site-specific deoxyribonuclease type II restriction enzyme

UniprotKB: Accession Number	Entry name	Activity	Subunit	Subcellular location	Cofactor
P04390	T2E5_ECOLX	Endonucleolytic cleavage of DNA to give specific double-stranded fragments with terminal 5''-phosphates.	Homodimer.		Binds 2 magnesium ions per subunit.

KEGG Pathways
Map code	Pathways	E.C.

Compound table
	Cofactors	Substrates		Products		Intermediates
KEGG-id	C00305	C00039	C00001	C00578	C00039
E.C.
Compound	Magnesium	DNA	H2O	DNA 5'-phosphate	DNA
Type	divalent metal (Ca2+, Mg2+)	nucleic acids	H2O	nucleic acids,phosphate group/phosphate ion	nucleic acids
ChEBI	18420 18420		15377 15377
PubChem	888 888		22247451 962 22247451 962

1az0A	Analogue:_CA	Bound:A-A-A-G-A-T-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1az0B	Analogue:_CA	Bound:A-A-A-G-A-T-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1az3A	Unbound	Unbound		Unbound	Unbound
1az3B	Unbound	Unbound		Unbound	Unbound
1az4A	Unbound	Unbound		Unbound	Unbound
1az4B	Unbound	Unbound		Unbound	Unbound
1b94A	Analogue:_CA	Bound:A-A-A-G-A-T-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1b94B	Analogue:_CA	Bound:A-A-A-G-A-T-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1b95A	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1b95B	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1b96A	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1b96B	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1b97A	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1b97B	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1bgbA	Unbound	Bound:G-G-G-A-T-A-T-C-C-C (chain D:double stranded DNA)		Unbound	Unbound
1bgbB	Unbound	Bound:C-G-G-G-A-T-A-T-C-C-C (chain C:double stranded DNA)		Unbound	Unbound
1bssA	Analogue:2x_CA	Bound:A-A-A-G-A-T-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1bssB	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1bsuA	Analogue:_CA	Analogue:A-A-G-A-5CM-I-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1bsuB	Analogue:_CA	Analogue:A-A-A-G-A-5CM-I-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1buaA	Unbound	Analogue:A-A-A-G-A-C-I-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1buaB	Unbound	Analogue:A-A-A-G-A-C-I-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1eo3A	Bound:2x_MG	Analogue:A-A-G-A-TSP-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1eo3B	Bound:2x_MG	Analogue:C-A-A-G-A-TSP-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1eo4A	Analogue:4x_MN	Analogue:A-A-G-A-TSP-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1eo4B	Analogue:_MN	Analogue:C-A-A-G-A-TSP-A-T-C-T (chain D:double stranded DNA)		Unbound	Unbound
1eonA	Analogue:2x_CL	Analogue:A-A-A-G-A-TSP-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1eonB	Analogue:2x_CL	Analogue:C-A-A-G-A-TSP-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1eooA	Unbound	Bound:G-A-A-G-A-T-A-T-C-T-T-C (chain C:double stranded DNA)		Unbound	Unbound
1eooB	Unbound	Bound:G-A-A-G-A-T-A-T-C-T-T-C (chain D:double stranded DNA)		Unbound	Unbound
1eopA	Unbound	Bound:A-A-G-A-T-A-T-C-T-T-A (chain C:double stranded DNA)		Unbound	Unbound
1eopB	Unbound	Bound:A-A-G-A-T-A-T-C-T-T-A (chain D:double stranded DNA)		Unbound	Unbound
1rv5A	Unbound	Unbound		Analogue:A-T-C-T-T (chain C:cleaved DNA)	Bound:A-A-A-G-A-T (chain C:cleaved DNA)
1rv5B	Unbound	Unbound		Analogue:A-T-C-T-T (chain D:cleaved DNA)	Bound:A-A-A-G-A-T (chain D:cleaved DNA)
1rvaA	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1rvaB	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1rvbA	Unbound	Bound:A-A-A-G-A-T-A-T-C-T-T (chain C:double stranded DNA)		Unbound	Unbound
1rvbB	Bound:2x_MG	Bound:A-A-A-G-A-T-A-T-C-T-T (chain D:double stranded DNA)		Unbound	Unbound
1rvcA	Bound:2x_MG	Unbound		Bound:A-T-C-T-T (chain D)	Bound:A-A-A-G-A-T (chain C)
1rvcB	Bound:2x_MG	Unbound		Bound:A-T-C-T-T (chain F)	Bound:A-A-A-G-A-T (chain E)
1rveA	Unbound	Unbound		Unbound	Unbound
1rveB	Unbound	Unbound		Unbound	Unbound
2rveA	Unbound	Unbound		Analogue:C-G-A-G-C-T-C-G (chain C)	Analogue:C-G-A-G-C-T-C-G (chain F)
2rveB	Unbound	Unbound		Analogue:C-G-A-G-C-T-C-G (chain E)	Analogue:C-G-A-G-C-T-C-G (chain D)
4rveA	Unbound	Bound:G-G-G-A-T-A-T-C-C-C (chain E:double stranded DNA)		Unbound	Unbound
4rveB	Unbound	Bound:G-G-G-A-T-A-T-C-C-C (chain D:double stranded DNA)		Unbound	Unbound
4rveC	Unbound	Bound:G-G-G-A-T-A-T-C-C-C (chain F:single stranded DNA)		Unbound	Unbound

Reference for Active-site residues
resource	references	E.C.
Swiss-prot;P04390

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

1az0A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1az0B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1az3A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1az3B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1az4A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)			mutant T93A
1az4B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)			mutant T93A
1b94A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1b94B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1b95A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1b95B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1b96A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)			mutant Q69E
1b96B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)			mutant Q69E
1b97A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)			mutant Q69L
1b97B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)			mutant Q69L
1bgbA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1bgbB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1bssA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)			mutant T93A
1bssB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)			mutant T93A
1bsuA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1bsuB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1buaA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1buaB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eo3A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eo3B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eo4A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eo4B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eonA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eonB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eooA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eooB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eopA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1eopB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rv5A	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rv5B	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rvaA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rvaB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rvbA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rvbB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rvcA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rvcB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rveA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
1rveB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
2rveA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
2rveB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
4rveA	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
4rveB	LYS 92	ASP 74;ASP 90(two Mg2+ binding)
4rveC	LYS 92	ASP 74;ASP 90(two Mg2+ binding)

References for Catalytic Mechanism
References	Sections	No. of steps in catalysis
[5]	Fig.8, Fig.11, p.12-17	2
[6]	Fig.1, p.11397-11401
[10]	Fig.5, p.13492-13494	2
[12]	Fig.6, p.6583-6585
[15]	Fig1, p.6

References
[1]
Resource
Comments	X-ray crystallography (3.0 Angstroms)
Medline ID	93259119
PubMed ID	8491171
Journal	EMBO J
Year	1993
Volume	12
Pages	1781-95
Authors	Winkler FK, Banner DW, Oefner C, Tsernoglou D, Brown RS, Heathman SP, Bryan RK, Martin PD, Petratos K, Wilson KS
Title	The crystal structure of EcoRV endonuclease and of its complexes with cognate and non-cognate DNA fragments.
Related PDB	1rve 2rve 4rve
Related UniProtKB	P04390
[2]
Resource
Comments	X-ray crystallography (2 Angstroms)
Medline ID
PubMed ID	7819264
Journal	Biochemistry
Year	1995
Volume	34
Pages	683-96
Authors	Kostrewa D, Winkler FK
Title	Mg2+ binding to the active site of EcoRV endonuclease: a crystallographic study of complexes with substrate and product DNA at 2 A resolution.
Related PDB	1rva 1rvb 1rvc
Related UniProtKB
[3]
Resource
Comments	catalysis
Medline ID
PubMed ID	7607482
Journal	Gene
Year	1995
Volume	157
Pages	157-62
Authors	Jeltsch A, Pleckaityte M, Selent U, Wolfes H, Siksnys V, Pingoud A
Title	Evidence for substrate-assisted catalysis in the DNA cleavage of several restriction endonucleases.
Related PDB
Related UniProtKB
[4]
Resource
Comments	X-ray crystallography (2.4 Angstroms)
Medline ID	98035052
PubMed ID	9367757
Journal	J Mol Biol
Year	1997
Volume	273
Pages	207-25
Authors	Perona JJ, Martin AM
Title	Conformational transitions and structural deformability of EcoRV endonuclease revealed by crystallographic analysis.
Related PDB
Related UniProtKB
[5]
Resource
Comments	catalysis
Medline ID
PubMed ID	9210460
Journal	Eur J Biochem
Year	1997
Volume	246
Pages	1-22
Authors	Pingoud A, Jeltsch A
Title	Recognition and cleavage of DNA by type-II restriction endonucleases.
Related PDB
Related UniProtKB
[6]
Resource
Comments
Medline ID
PubMed ID	9298958
Journal	Biochemistry
Year	1997
Volume	36
Pages	11389-401
Authors	Groll DH, Jeltsch A, Selent U, Pingoud A
Title	Does the restriction endonuclease EcoRV employ a two-metal-Ion mechanism for DNA cleavage?
Related PDB
Related UniProtKB
[7]
Resource
Comments	catalysis
Medline ID
PubMed ID	9548954
Journal	Biochemistry
Year	1998
Volume	37
Pages	5682-8
Authors	Stahl F, Wende W, Wenz C, Jeltsch A, Pingoud A
Title	Intra- vs intersubunit communication in the homodimeric restriction enzyme EcoRV: Thr 37 and Lys 38 involved in indirect readout are only important for the catalytic activity of their own subunit.
Related PDB
Related UniProtKB
[8]
Resource
Comments	X-ray crystallography (2.1 Angstroms)
Medline ID	98371008
PubMed ID	9705308
Journal	J Biol Chem
Year	1998
Volume	273
Pages	21721-9
Authors	Horton NC, Perona JJ
Title	Recognition of flanking DNA sequences by EcoRV endonuclease involves alternative patterns of water-mediated contacts.
Related PDB	1bgb
Related UniProtKB	P04390
[9]
Resource
Comments	X-ray crystallography (2.1 Angstroms)
Medline ID	98213664
PubMed ID	9545372
Journal	J Mol Biol
Year	1998
Volume	277
Pages	779-87
Authors	Horton NC, Perona JJ
Title	Role of protein-induced bending in the specificity of DNA recognition: crystal structure of EcoRV endonuclease complexed with d(AAAGAT) + d(ATCTT).
Related PDB	1rv5
Related UniProtKB	P04390
[10]
Resource
Comments	X-ray crystallography (2.15 Angstroms)
Medline ID
PubMed ID	9811827
Journal	Proc Natl Acad Sci U S A
Year	1998
Volume	95
Pages	13489-94
Authors	Horton NC, Newberry KJ, Perona JJ
Title	Metal ion-mediated substrate-assisted catalysis in type II restriction endonucleases.
Related PDB	1bss
Related UniProtKB
[11]
Resource
Comments	catalysis
Medline ID
PubMed ID	9628339
Journal	Biol Chem
Year	1998
Volume	379
Pages	467-73
Authors	Stahl F, Wende W, Jeltsch A, Pingoud A
Title	The mechanism of DNA cleavage by the type II restriction enzyme EcoRV: Asp36 is not directly involved in DNA cleavage but serves to couple indirect readout to catalysis.
Related PDB
Related UniProtKB
[12]
Resource
Comments	catalysis
Medline ID
PubMed ID	10350476
Journal	Biochemistry
Year	1999
Volume	38
Pages	6576-86
Authors	Sam MD, Perona JJ
Title	Catalytic roles of divalent metal ions in phosphoryl transfer by EcoRV endonuclease.
Related PDB
Related UniProtKB
[13]
Resource
Comments	X-ray crystallography (2.3 Angstroms)
Medline ID	99377171
PubMed ID	10446231
Journal	Nucleic Acids Res
Year	1999
Volume	27
Pages	3438-45
Authors	Thomas MP, Brady RL, Halford SE, Sessions RB, Baldwin GS
Title	Structural analysis of a mutational hot-spot in the EcoRV restriction endonuclease: a catalytic role for a main chain carbonyl group.
Related PDB	1b94 1b95 1b96 1b97
Related UniProtKB	P04390
[14]
Resource
Comments	X-ray crystallography
Medline ID
PubMed ID	10801972
Journal	Proc Natl Acad Sci U S A
Year	2000
Volume	97
Pages	5729-34
Authors	Horton NC, Perona JJ
Title	Crystallographic snapshots along a protein-induced DNA-bending pathway.
Related PDB	1eoo 1eop
Related UniProtKB
[15]
Resource
Comments
Medline ID
PubMed ID	10739241
Journal	Protein Sci
Year	2000
Volume	9
Pages	1-9
Authors	Dall'Acqua W, Carter P
Title	Substrate-assisted catalysis: molecular basis and biological significance.
Related PDB
Related UniProtKB

Comments
This enzyme belongs to the type II restriction endonucleases. According to the paper [5], cleavage of DNA by restriction endonucleases yields 3'-OH and 5'-phosphate ends, where hydrolysis of the phosphodiester bonds by EcoRI and EcoRV occurs with inversion of configuration at the phosphorous atom, suggesting an attack of a water molecule in line with the 3'-OH leaving group. In general, hydrolysis of phosphodiester bonds requires three functional entities as follows [5]: (1) A general base that activates the attacking nucleophile, (2) A Lewis acid that stabilizes the extra negative charge in the pentacovalent transition state, (3) An acid that protonates or stabilizes the leaving group. The literature [5] also described the two possible catalytic mechanisms, the substrate-assisted catalysis model and the two-metal-ion mechanism, as described in the following paragraph. However, this paper supported the substrate-assisted catalysis model more favorably than the two-metal-ion mechanism. The substrate-assisted catalysis model: The attacking water molecule is oriented and deprotonated by the next phosphate group 3' to the scissile phosphate. The negative charge of the transition state could be stablized by the Mg2+ ion and the semi-conserved lysine. The metal ion is bound by the two conserved acidc amino acid residues. The 3'-O- leaving group is protonated by a Mg2+-bound water [5]. The two-metal-ion mechanism: A metal ion bound at one site is responsible for charge neutralization at the scissile phosphate. The attacking water is considered to be part of the hydration sphere of a metal ion bound at the second site [5]. The literature [10] suggests a possible mechanism, three-metal ion mechanism for type II restriction endonucleases from the structural data, as follows: A metal ion at site I ligates through water to the 3'-phosphate. A second inner-sphere water molecule on this metal dissociates to provide the attacking hydroxide ion, and this dissociation is aided by the immediately adjacent Lys92. The metal at site III provides stabilization of the incipient negative charge as the transtion state develops. An inner-sphere water on this metal is located within hydrogen-bonding distance of the leaving 3'-oxygen. Thus, the site III metal is suggested to be operative in lowering the pKa of this water, so that it may dissociate to immediately protonate the leaving anion [10]. The site II metal is purely structural [10]. Crystal structures of these type II endonucleases, EcoRV, EcoRI and PvuII bound to DNA show that the relative positions of the scissile and adjacent 3'-phosphates are conserved. Therefore, the two metal ions bound in site I and site III may have similar functions in each of these enzymes [10]. The literature [12] also supports the metal-ion mediated DNA cleavage. The mechanism involves general acid catalysis for the nucleophilic attack of hydroxide ion on the scissile phosphate, and general acid catalysis for protonation of the leaving 3'-O anion. The ionization of two distinct metal-ligated waters respectively generate the attacking hydroxide ion and the proton for donation to the leaving group [12]. ### According to the literature [6] & [11], the second magnesium ion bound to Glu45 is not involved in catalysis, which ruled out the two-metal-ion mechanism, supporting the substrate-assisted mechanism. However, the second metal might be involved in specific DNA binding. More recent study [15] focused on substrate-assisted mechanism for various enzymes, including this enzyme. Although the acidity of the substrate phosphate (pKa = 2) makes it poorly suited to the proposed role as a general base to deprotonate a water, the protein environment might perturb the pKa of the substrate phosphate significantly (see [15]). Moreover, considering the structure of 1f0o (of PvuII; S00390 in EzCatDB) and in-line attack by water on the scissile phosphoric ester bond, the substrate-assisted mechanism is more likely. Taken together, we concluded that the substrate-assisted mechanism with only one metal should be adopted for this enzyme. The reaction probably proceeds as follows: (1) Substrate-assisted water activation by the 3'-phosphate group of adjacent nucleotide of the DNA. This activated water is stabilized by lys92. (2) The activated water makes a nucleophilic attack on the phosphorus atom in line with the P-O3' bond. (3) Transition-state is stabilized by (Lys92 and) magnesium ion. (4) Another water, which is bound to magnesium ion and Asp74 and Asp90, acts as a general acid to protonate the leaving O3' atom.

Comments

This enzyme belongs to the type II restriction endonucleases.
According to the paper [5], cleavage of DNA by restriction endonucleases yields 3'-OH and 5'-phosphate ends, where hydrolysis of the phosphodiester bonds by EcoRI and EcoRV occurs with inversion of configuration at the phosphorous atom, suggesting an attack of a water molecule in line with the 3'-OH leaving group. In general, hydrolysis of phosphodiester bonds requires three functional entities as follows [5]:
(1) A general base that activates the attacking nucleophile,
(2) A Lewis acid that stabilizes the extra negative charge in the pentacovalent transition state,
(3) An acid that protonates or stabilizes the leaving group.
The literature [5] also described the two possible catalytic mechanisms, the substrate-assisted catalysis model and the two-metal-ion mechanism, as described in the following paragraph. However, this paper supported the substrate-assisted catalysis model more favorably than the two-metal-ion mechanism.
The substrate-assisted catalysis model: The attacking water molecule is oriented and deprotonated by the next phosphate group 3' to the scissile phosphate. The negative charge of the transition state could be stablized by the Mg2+ ion and the semi-conserved lysine. The metal ion is bound by the two conserved acidc amino acid residues. The 3'-O- leaving group is protonated by a Mg2+-bound water [5].
The two-metal-ion mechanism: A metal ion bound at one site is responsible for charge neutralization at the scissile phosphate. The attacking water is considered to be part of the hydration sphere of a metal ion bound at the second site [5].
The literature [10] suggests a possible mechanism, three-metal ion mechanism for type II restriction endonucleases from the structural data, as follows:
A metal ion at site I ligates through water to the 3'-phosphate. A second inner-sphere water molecule on this metal dissociates to provide the attacking hydroxide ion, and this dissociation is aided by the immediately adjacent Lys92. The metal at site III provides stabilization of the incipient negative charge as the transtion state develops. An inner-sphere water on this metal is located within hydrogen-bonding distance of the leaving 3'-oxygen. Thus, the site III metal is suggested to be operative in lowering the pKa of this water, so that it may dissociate to immediately protonate the leaving anion [10]. The site II metal is purely structural [10].
Crystal structures of these type II endonucleases, EcoRV, EcoRI and PvuII bound to DNA show that the relative positions of the scissile and adjacent 3'-phosphates are conserved. Therefore, the two metal ions bound in site I and site III may have similar functions in each of these enzymes [10].
The literature [12] also supports the metal-ion mediated DNA cleavage. The mechanism involves general acid catalysis for the nucleophilic attack of hydroxide ion on the scissile phosphate, and general acid catalysis for protonation of the leaving 3'-O anion. The ionization of two distinct metal-ligated waters respectively generate the attacking hydroxide ion and the proton for donation to the leaving group [12].
###
According to the literature [6] & [11], the second magnesium ion bound to Glu45 is not involved in catalysis, which ruled out the two-metal-ion mechanism, supporting the substrate-assisted mechanism. However, the second metal might be involved in specific DNA binding.
More recent study [15] focused on substrate-assisted mechanism for various enzymes, including this enzyme. Although the acidity of the substrate phosphate (pKa = 2) makes it poorly suited to the proposed role as a general base to deprotonate a water, the protein environment might perturb the pKa of the substrate phosphate significantly (see [15]).
Moreover, considering the structure of 1f0o (of PvuII; S00390 in EzCatDB) and in-line attack by water on the scissile phosphoric ester bond, the substrate-assisted mechanism is more likely.
Taken together, we concluded that the substrate-assisted mechanism with only one metal should be adopted for this enzyme. The reaction probably proceeds as follows:
(1) Substrate-assisted water activation by the 3'-phosphate group of adjacent nucleotide of the DNA. This activated water is stabilized by lys92.
(2) The activated water makes a nucleophilic attack on the phosphorus atom in line with the P-O3' bond.
(3) Transition-state is stabilized by (Lys92 and) magnesium ion.
(4) Another water, which is bound to magnesium ion and Asp74 and Asp90, acts as a general acid to protonate the leaving O3' atom.

Created	Updated
2002-09-27	2009-02-26