DB code: M00034

RLCP classification	3.100.219010.98 : Transfer
CATH domain	3.40.50.140 : Rossmann fold	Catalytic domain
	1.10.460.10 : Topoisomerase I; domain 2
	2.70.20.10 : Topoisomerase I; domain 3
	1.10.290.10 : Topoisomerase I; domain 4	Catalytic domain
	-.-.-.- :
	3.30.65.10 : Bacterial Topoisomerase I; domain 1
	2.20.25.10 : N-terminal domain of TfIIb
E.C.	5.99.1.2
CSA	1ecl
M-CSA	1ecl
MACiE

CATH domain	Related DB codes (homologues)
1.10.290.10 : Topoisomerase I; domain 4	M00158
1.10.460.10 : Topoisomerase I; domain 2	M00158
2.20.25.10 : N-terminal domain of TfIIb	M00207
2.70.20.10 : Topoisomerase I; domain 3	M00158
3.40.50.140 : Rossmann fold	M00158

Uniprot Enzyme Name
UniprotKB	Protein name	Synonyms	RefSeq	Pfam
P06612	DNA topoisomerase 1	EC 5.99.1.2 DNA topoisomerase I Omega-protein Relaxing enzyme Swivelase Untwisting enzyme	NP_415790.1 (Protein) NC_000913.2 (DNA/RNA sequence) YP_489542.1 (Protein) NC_007779.1 (DNA/RNA sequence)	PF08272 (Topo_Zn_Ribbon) PF01131 (Topoisom_bac) PF01751 (Toprim) PF01396 (zf-C4_Topoisom) [Graphical View]

KEGG enzyme name
DNA topoisomerase type I DNA topoisomerase untwisting enzyme relaxing enzyme nicking-closing enzyme swivelase omega-protein deoxyribonucleate topoisomerase topoisomerase type I DNA topoisomerase

UniprotKB: Accession Number	Entry name	Activity	Subunit	Subcellular location	Cofactor
P06612	TOP1_ECOLI	ATP-independent breakage of single-stranded DNA, followed by passage and rejoining.	Monomer.

KEGG Pathways
Map code	Pathways	E.C.

Compound table
	Cofactors	Substrates	Products	Intermediates
KEGG-id	C00305	C00271	C00271
E.C.
Compound	Magnesium	Single-stranded DNA	Single-stranded DNA
Type	divalent metal (Ca2+, Mg2+)	nucleic acids	nucleic acids
ChEBI	18420 18420
PubChem	888 888

1cy0A01	Unbound	Unbound	Unbound
1cy1A01	Unbound	Unbound	Unbound
1cy2A01	Unbound	Unbound	Unbound
1cy4A01	Unbound	Unbound	Unbound
1cy6A01	Unbound	Unbound	Unbound
1cy7A01	Unbound	Unbound	Unbound
1cy8A01	Unbound	Unbound	Unbound
1eclA01	Unbound	Unbound	Unbound
1mw8X01	Unbound	Unbound	Unbound
1mw9X01	Unbound	Unbound	Unbound
1cy0A02	Unbound	Unbound	Unbound
1cy1A02	Unbound	Unbound	Unbound
1cy2A02	Unbound	Unbound	Unbound
1cy4A02	Unbound	Unbound	Unbound
1cy6A02	Unbound	Unbound	Unbound
1cy7A02	Unbound	Unbound	Unbound
1cy8A02	Unbound	Unbound	Unbound
1eclA02	Unbound	Unbound	Unbound
1mw8X02	Unbound	Unbound	Unbound
1mw9X02	Unbound	Unbound	Unbound
1cy0A03	Unbound	Unbound	Unbound
1cy1A03	Unbound	Unbound	Unbound
1cy2A03	Unbound	Unbound	Unbound
1cy4A03	Unbound	Unbound	Unbound
1cy6A03	Unbound	Unbound	Unbound
1cy7A03	Unbound	Unbound	Unbound
1cy8A03	Unbound	Unbound	Unbound
1cy9A02	Unbound	Unbound	Unbound
1cy9B02	Unbound	Unbound	Unbound
1cyyA02	Unbound	Unbound	Unbound
1cyyB02	Unbound	Unbound	Unbound
1eclA03	Unbound	Unbound	Unbound
1mw8X03	Unbound	Unbound	Unbound
1mw9X03	Unbound	Unbound	Unbound
1cy0A04	Unbound	Unbound	Unbound
1cy1A04	Unbound	Unbound	Unbound
1cy2A04	Unbound	Unbound	Unbound
1cy4A04	Unbound	Unbound	Unbound
1cy6A04	Unbound	Unbound	Unbound
1cy7A04	Unbound	Unbound	Unbound
1cy8A04	Unbound	Unbound	Unbound
1cy9A01	Unbound	Unbound	Unbound
1cy9B01	Unbound	Unbound	Unbound
1cyyA01	Unbound	Unbound	Unbound
1cyyB01	Unbound	Unbound	Unbound
1eclA04	Unbound	Unbound	Unbound
1mw8X04	Unbound	Bound:C-T-T-C-G-G-G(chain Y)	Unbound
1mw9X04	Unbound	Unbound	Unbound
1yuaA01	Unbound	Unbound	Unbound
1yuaA02	Unbound	Unbound	Unbound

Reference for Active-site residues
resource	references	E.C.
Swiss-prot P06612, literature [8], [11] & [17]

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

1cy0A01	GLU 9;LYS 13;ASP 111;ARG 136
1cy1A01	GLU 9;LYS 13;ASP 111;ARG 136
1cy2A01	GLU 9;LYS 13;ASP 111;ARG 136
1cy4A01	GLU 9;LYS 13;ASP 111;ARG 136
1cy6A01	GLU 9;LYS 13;ASP 111;ARG 136
1cy7A01	GLU 9;LYS 13;ASP 111;ARG 136
1cy8A01	GLU 9;LYS 13;ASP 111;ARG 136
1eclA01	GLU 9;LYS 13;ASP 111;ARG 136
1mw8X01	GLU 9;LYS 13;ASP 111;ARG 136
1mw9X01	GLU 9;LYS 13;ASP 111;ARG 136
1cy0A02
1cy1A02
1cy2A02
1cy4A02
1cy6A02
1cy7A02
1cy8A02
1eclA02
1mw8X02
1mw9X02
1cy0A03
1cy1A03
1cy2A03
1cy4A03
1cy6A03
1cy7A03
1cy8A03
1cy9A02
1cy9B02
1cyyA02
1cyyB02
1eclA03
1mw8X03
1mw9X03
1cy0A04	TYR 319;ARG 321;HIS 365
1cy1A04	TYR 319;ARG 321;HIS 365
1cy2A04	TYR 319;ARG 321;HIS 365
1cy4A04	TYR 319;ARG 321;HIS 365
1cy6A04	TYR 319;ARG 321;HIS 365
1cy7A04	TYR 319;ARG 321;HIS 365
1cy8A04	TYR 319;ARG 321;HIS 365
1cy9A01	TYR 319;ARG 321;HIS 365
1cy9B01	TYR 319;ARG 321;HIS 365
1cyyA01	TYR 319;ARG 321;HIS 365
1cyyB01	TYR 319;ARG 321;HIS 365
1eclA04	TYR 319;ARG 321;HIS 365
1mw8X04	TYR 319;ARG 321;				mutant H365R
1mw9X04	TYR 319;ARG 321;				mutant H365R
1yuaA01
1yuaA02

References for Catalytic Mechanism
References	Sections	No. of steps in catalysis
[4]	Fig.5, p.142-145
[8]
[9]
[10]	p.965-967
[11]	p.920-921
[12]	Fig.3
[15]	Fig.2, p.195-198
[17]	Fig.2, p.13243-13245
[18]	Fig.1

References
[1]
Resource
Comments
Medline ID
PubMed ID	2560190
Journal	Proteins
Year	1989
Volume	6
Pages	231-9
Authors	Lynn RM, Wang JC
Title	Peptide sequencing and site-directed mutagenesis identify tyrosine-319 as the active site tyrosine of Escherichia coli DNA topoisomerase I.
Related PDB
Related UniProtKB
[2]
Resource
Comments
Medline ID
PubMed ID	1650356
Journal	J Biol Chem
Year	1991
Volume	266
Pages	14317-20
Authors	Tse-Dinh YC
Title	Zinc (II) coordination in Escherichia coli DNA topoisomerase I is required for cleavable complex formation with DNA.
Related PDB
Related UniProtKB
[3]
Resource
Comments
Medline ID
PubMed ID	8396651
Journal	J Mol Biol
Year	1993
Volume	232
Pages	1213-6
Authors	Lima CD, Wang JC, Mondragon A
Title	Crystallization of a 67 kDa fragment of Escherichia coli DNA topoisomerase I.
Related PDB
Related UniProtKB
[4]
Resource
Comments	X-RAY CRYSTALLOGRAPHY (2.2 ANGSTROMS) OF 1-590.
Medline ID	94159070
PubMed ID	8114910
Journal	Nature
Year	1994
Volume	367
Pages	138-46
Authors	Lima CD, Wang JC, Mondragon A
Title	Three-dimensional structure of the 67K N-terminal fragment of E. coli DNA topoisomerase I.
Related PDB	1ecl
Related UniProtKB	P06612
[5]
Resource
Comments	STRUCTURE BY NMR OF 745-865.
Medline ID	95298771
PubMed ID	7779808
Journal	Biochemistry
Year	1995
Volume	34
Pages	7622-8
Authors	Yu L, Zhu CX, Tse-Dinh YC, Fesik SW
Title	Solution structure of the C-terminal single-stranded DNA-binding domain of Escherichia coli topoisomerase I.
Related PDB	1yua
Related UniProtKB	P06612
[6]
Resource
Comments
Medline ID
PubMed ID	8703937
Journal	Biochemistry
Year	1996
Volume	35
Pages	9661-6
Authors	Yu L, Zhu CX, Tse-Dinh YC, Fesik SW
Title	Backbone dynamics of the C-terminal domain of Escherichia coli topoisomerase I in the absence and presence of single-stranded DNA.
Related PDB
Related UniProtKB
[7]
Resource
Comments
Medline ID
PubMed ID	9792804
Journal	Biochem Biophys Res Commun
Year	1998
Volume	251
Pages	509-14
Authors	Ahumada A, Tse-Dinh YC
Title	The Zn(II) binding motifs of E. coli DNA topoisomerase I is part of a high-affinity DNA binding domain.
Related PDB
Related UniProtKB
[8]
Resource
Comments
Medline ID
PubMed ID	9497321
Journal	J Biol Chem
Year	1998
Volume	273
Pages	6050-6
Authors	Chen SJ, Wang JC
Title	Identification of active site residues in Escherichia coli DNA topoisomerase I.
Related PDB
Related UniProtKB
[9]
Resource
Comments
Medline ID
PubMed ID	9535856
Journal	J Biol Chem
Year	1998
Volume	273
Pages	8783-9
Authors	Zhu CX, Roche CJ, Papanicolaou N, DiPietrantonio A, Tse-Dinh YC
Title	Site-directed mutagenesis of conserved aspartates, glutamates and arginines in the active site region of Escherichia coli DNA topoisomerase I.
Related PDB
Related UniProtKB
[10]
Resource
Comments	X-ray crystallography
Medline ID
PubMed ID	10504732
Journal	Nat Struct Biol
Year	1999
Volume	6
Pages	961-8
Authors	Feinberg H, Changela A, Mondragon A
Title	Protein-nucleotide interactions in E. coli DNA topoisomerase I.
Related PDB	1cy0 1cy1 1cy2 1cy4 1cy6 1cy7 1cy8
Related UniProtKB
[11]
Resource
Comments	X-ray crystallography
Medline ID
PubMed ID	10504724
Journal	Nat Struct Biol
Year	1999
Volume	6
Pages	918-22
Authors	Feinberg H, Lima CD, Mondragon A
Title	Conformational changes in E. coli DNA topoisomerase I.
Related PDB	1cy9 1cyy
Related UniProtKB
[12]
Resource
Comments
Medline ID
PubMed ID	10504717
Journal	Nat Struct Biol
Year	1999
Volume	6
Pages	900-2
Authors	Keck JL, Berger JM
Title	Enzymes that push DNA around.
Related PDB
Related UniProtKB
[13]
Resource
Comments
Medline ID
PubMed ID	10873443
Journal	J Mol Biol
Year	2000
Volume	299
Pages	1165-77
Authors	Grishin NV
Title	C-terminal domains of Escherichia coli topoisomerase I belong to the zinc-ribbon superfamily.
Related PDB
Related UniProtKB
[14]
Resource
Comments
Medline ID
PubMed ID	10873470
Journal	J Mol Biol
Year	2000
Volume	300
Pages	353-62
Authors	Podobnik M, McInerney P, O'Donnell M, Kuriyan J
Title	A TOPRIM domain in the crystal structure of the catalytic core of Escherichia coli primase confirms a structural link to DNA topoisomerases.
Related PDB
Related UniProtKB
[15]
Resource
Comments
Medline ID
PubMed ID	11034544
Journal	Adv Cancer Res
Year	2001
Volume	80
Pages	189-216
Authors	Pourquier P, Pommier Y
Title	Topoisomerase I-mediated DNA damage.
Related PDB
Related UniProtKB
[16]
Resource
Comments
Medline ID
PubMed ID	11722677
Journal	J Clin Pharm Ther
Year	2001
Volume	26
Pages	405-16
Authors	Topcu Z
Title	DNA topoisomerases as targets for anticancer drugs.
Related PDB
Related UniProtKB
[17]
Resource
Comments
Medline ID
PubMed ID	11809772
Journal	J Biol Chem
Year	2002
Volume	277
Pages	13237-45
Authors	Perry K, Mondragon A
Title	Biochemical characterization of an invariant histidine involved in Escherichia coli DNA topoisomerase I catalysis.
Related PDB
Related UniProtKB
[18]
Resource
Comments
Medline ID
PubMed ID	14604525
Journal	Structure (Camb)
Year	2003
Volume	11
Pages	1349-58
Authors	Perry K, Mondragon A
Title	Structure of a complex between E. coli DNA topoisomerase I and single-stranded DNA.
Related PDB	1mw8 1mw9
Related UniProtKB

Comments
The N-terminal domain structures of this enzyme indicated that it is homologous to DNA topoisomrase III (M00158 in EzCatDB), suggesting that it might have a similar catalytic mechanism to that. Accoriding to the literature [8], although magnesium ion is required for the activity, it is not required for the DNA cleavage and religation (or Auto-transfer of DNA segment). It might be required for the conformational changes in the enzyme-DNA complexes in the movements of DNA strands (or DNA passage). Arg136 seems to be required for the DNA relaxation activity, despite that it is not involved in the DNA cleavage. According to the literature [8], [11] & [17], it catalyzes the following reactions: (A) Binding of the single-stranded DNA region: (B) Auto-transfer of DNA segment: 1st step: the cleavage of single-stranded DNA (pre-strand passage): (B#) His365 modulates the pKa of Glu9 through Asp111 (see [17]). (B1) Arg321 acts as a modulator, which activates the nucleophile, Tyr319, by lowering its pKa. (B2) The activated nucleophile, Tyr319, makes a nucleophilic attack on the phosphorus atom of the scissile phosphodiester bond, forming a pentacovalent transition state. (B3) The negatively charged transition state is stabilized by Lys13 & Arg321. (B4) Glu9 acts as a general acid to protonate the leaving 3'-hydroxyl group, resulting in the formation of a phosphotyrosine intermediate. (C) DNA helix passage through the gate, formed by the cleaved DNA: (B') Auto-transfer of DNA segment: 2nd step: the religation of single-stranded DNA (post-strand passage): (B1') Glu9 acts as a general base to deprotonate the 3'-hydroxyl group. (B2') The activated 3'-hydroxyl group makes a nucleophilic attack on the phosphorus atom of the phosphotyrosine intermediate, forming a pentacovalent transition state again. (B3') The negatively charged transition state is stabilized by Lys13 & Arg321. (B4') Tyr319 is released. (D) Relase of the trapped DNA:

Comments

The N-terminal domain structures of this enzyme indicated that it is homologous to DNA topoisomrase III (M00158 in EzCatDB), suggesting that it might have a similar catalytic mechanism to that.
Accoriding to the literature [8], although magnesium ion is required for the activity, it is not required for the DNA cleavage and religation (or Auto-transfer of DNA segment). It might be required for the conformational changes in the enzyme-DNA complexes in the movements of DNA strands (or DNA passage). Arg136 seems to be required for the DNA relaxation activity, despite that it is not involved in the DNA cleavage.
According to the literature [8], [11] & [17], it catalyzes the following reactions:
(A) Binding of the single-stranded DNA region:
(B) Auto-transfer of DNA segment: 1st step: the cleavage of single-stranded DNA (pre-strand passage):
(B#) His365 modulates the pKa of Glu9 through Asp111 (see [17]).
(B1) Arg321 acts as a modulator, which activates the nucleophile, Tyr319, by lowering its pKa.
(B2) The activated nucleophile, Tyr319, makes a nucleophilic attack on the phosphorus atom of the scissile phosphodiester bond, forming a pentacovalent transition state.
(B3) The negatively charged transition state is stabilized by Lys13 & Arg321.
(B4) Glu9 acts as a general acid to protonate the leaving 3'-hydroxyl group, resulting in the formation of a phosphotyrosine intermediate.
(C) DNA helix passage through the gate, formed by the cleaved DNA:
(B') Auto-transfer of DNA segment: 2nd step: the religation of single-stranded DNA (post-strand passage):
(B1') Glu9 acts as a general base to deprotonate the 3'-hydroxyl group.
(B2') The activated 3'-hydroxyl group makes a nucleophilic attack on the phosphorus atom of the phosphotyrosine intermediate, forming a pentacovalent transition state again.
(B3') The negatively charged transition state is stabilized by Lys13 & Arg321.
(B4') Tyr319 is released.
(D) Relase of the trapped DNA:

Created	Updated
2004-04-27	2010-05-14