DB code: T00050

RLCP classification	3.133.300000.396 : Transfer
CATH domain	3.90.63.10 : mRNA Capping Enzyme; Chain A, domain 1	Catalytic domain
	2.40.50.140 : OB fold (Dihydrolipoamide Acetyltransferase, E2P)	Catalytic domain
	4.10.87.10 : mRNA Capping Enzyme; Chain	Catalytic domain
E.C.	2.7.7.50
CSA
M-CSA
MACiE

CATH domain	Related DB codes (homologues)
2.40.50.140 : OB fold (Dihydrolipoamide Acetyltransferase, E2P)	M00220 M00186 D00291 D00294 T00254

Uniprot Enzyme Name
UniprotKB	Protein name	Synonyms	RefSeq	Pfam
Q84424	mRNA-capping enzyme	GTP--RNA guanylyltransferase mRNA guanylyltransferase EC 2.7.7.50	NP_048451.1 (Protein) NC_000852.5 (DNA/RNA sequence)	PF03919 (mRNA_cap_C) PF01331 (mRNA_cap_enzyme) [Graphical View]
P78587	mRNA-capping enzyme subunit alpha	GTP--RNA guanylyltransferase GTase mRNA guanylyltransferase EC 2.7.7.50		PF03919 (mRNA_cap_C) PF01331 (mRNA_cap_enzyme) [Graphical View]

KEGG enzyme name
mRNA guanylyltransferase mRNA capping enzyme messenger RNA guanylyltransferase Protein 2

UniprotKB: Accession Number	Entry name	Activity	Subunit	Subcellular location	Cofactor
Q84424	MCE_PBCV1	GTP + (5'')pp-Pur-mRNA = diphosphate + G(5'')ppp-Pur-mRNA.	Monomer.		Magnesium or manganese.
P78587	MCE1_CANAL	GTP + (5'')pp-Pur-mRNA = diphosphate + G(5'')ppp-Pur-mRNA.	The mRNA-capping enzyme is composed of two separate chains alpha and beta, respectively a mRNA guanylyltransferase and an RNA 5''-triphosphatase.	Nucleus.

KEGG Pathways
Map code	Pathways	E.C.

Compound table
	Cofactors		Substrates		Products		Intermediates
KEGG-id	C00305	C00034	C00044	C02100	C00013	C02031
E.C.
Compound	Magnesium	Manganese	GTP	(5')ppPur-mRNA	Pyrophosphate	G(5')pppR-RNA	GMP covalently bonded to Lys82
Type	divalent metal (Ca2+, Mg2+)	heavy metal	amide group,amine group,nucleotide	nucleic acids,phosphate group/phosphate ion	phosphate group/phosphate ion	amide group,amine group,nucleic acids,nucleotide
ChEBI	18420 18420	18291 35154 18291 35154	15996 15996		29888 29888
PubChem	888 888	23930 23930	6830 6830		1023 21961011 1023 21961011

1ckmA01	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1ckmB01	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1cknA01	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1cknB01	Unbound	Bound:_MN	Unbound	Unbound	Analogue:SO4	Unbound	Unbound
1ckoA01	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1p16A01	Unbound	Unbound	Unbound	Unbound	Analogue:PO4_7001	Unbound	Unbound
1p16B01	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1ckmA02	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1ckmB02	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1cknA02	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1cknB02	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1ckoA02	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1p16A03	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1p16B03	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound
1ckmA03	Unbound	Unbound	Bound:GTP	Unbound	Unbound	Unbound	Unbound
1ckmB03	Unbound	Unbound	Bound:GTP	Unbound	Unbound	Unbound	Unbound
1cknA03	Unbound	Unbound	Bound:GTP	Unbound	Unbound	Unbound	Unbound
1cknB03	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Bound:GPL
1ckoA03	Unbound	Unbound	Unbound	Unbound	Unbound	Bound:GP3	Unbound
1p16A02	Unbound	Unbound	Unbound	Unbound	Unbound	Unbound	Bound:__G
1p16B02	Unbound	Unbound	Bound:GTP	Unbound	Unbound	Unbound	Unbound

Reference for Active-site residues
resource	references	E.C.
literature [11]

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

1ckmA01	ARG 106
1ckmB01	ARG 106
1cknA01	ARG 106
1cknB01	ARG 106
1ckoA01	ARG 106
1p16A01	ARG 92
1p16B01	ARG 92
1ckmA02	LYS 236;ASP 244;ARG 295;LYS 298;ASN 302
1ckmB02	LYS 236;ASP 244;ARG 295;LYS 298;ASN 302
1cknA02	LYS 236;ASP 244;ARG 295;LYS 298;ASN 302
1cknB02	LYS 236;ASP 244;ARG 295;LYS 298;ASN 302
1ckoA02	LYS 236;ASP 244;ARG 295;LYS 298;ASN 302
1p16A03	LYS 243;ASP 251;ARG 342;LYS 345;ASN 349
1p16B03	LYS 243;ASP 251;ARG 342;LYS 345;ASN 349
1ckmA03	LYS 82;ASP 213;LYS 234
1ckmB03	LYS 82;ASP 213;LYS 234
1cknA03	LYS 82;ASP 213;LYS 234
1cknB03	;ASP 213;LYS 234		GPL 82		GPL guanylated lysine
1ckoA03	LYS 82;ASP 213;LYS 234
1p16A02	LYS 67;ASP 220;LYS 241
1p16B02	LYS 67;ASP 220;LYS 241

References for Catalytic Mechanism
References	Sections	No. of steps in catalysis
[8]	Fig.7, p.549-552
[10]	p.9575-9576
[11]	Fig.4, p.1508-1509
[15]
[16]	p.1556-1558
[17]	p.761-762

References
[1]
Resource
Comments
Medline ID
PubMed ID	2159008
Journal	J Biol Chem
Year	1990
Volume	265
Pages	7669-72
Authors	Fausnaugh J, Shatkin AJ
Title	Active site localization in a viral mRNA capping enzyme.
Related PDB
Related UniProtKB
[2]
Resource
Comments
Medline ID
PubMed ID	2161527
Journal	Proc Natl Acad Sci U S A
Year	1990
Volume	87
Pages	4023-7
Authors	Guo PX, Moss B
Title	Interaction and mutual stabilization of the two subunits of vaccinia virus mRNA capping enzyme coexpressed in Escherichia coli.
Related PDB
Related UniProtKB
[3]
Resource
Comments
Medline ID
PubMed ID	8385101
Journal	J Biol Chem
Year	1993
Volume	268
Pages	7256-60
Authors	Cong P, Shuman S
Title	Covalent catalysis in nucleotidyl transfer. A KTDG motif essential for enzyme-GMP complex formation by mRNA capping enzyme is conserved at the active sites of RNA and DNA ligases.
Related PDB
Related UniProtKB
[4]
Resource
Comments
Medline ID
PubMed ID	8227060
Journal	J Biol Chem
Year	1993
Volume	268
Pages	24986-9
Authors	Niles EG, Christen L
Title	Identification of the vaccinia virus mRNA guanyltransferase active site lysine.
Related PDB
Related UniProtKB
[5]
Resource
Comments
Medline ID
PubMed ID	8195132
Journal	J Biol Chem
Year	1994
Volume	269
Pages	14974-81
Authors	Higman MA, Christen LA, Niles EG
Title	The mRNA (guanine-7-)methyltransferase domain of the vaccinia virus mRNA capping enzyme. Expression in Escherichia coli and structural and kinetic comparison to the intact capping enzyme.
Related PDB
Related UniProtKB
[6]
Resource
Comments
Medline ID
PubMed ID	7991582
Journal	Proc Natl Acad Sci U S A
Year	1994
Volume	91
Pages	12046-50
Authors	Shuman S, Liu Y, Schwer B
Title	Covalent catalysis in nucleotidyl transfer reactions: essential motifs in Saccharomyces cerevisiae RNA capping enzyme are conserved in Schizosaccharomyces pombe and viral capping enzymes and among polynucleotide ligases.
Related PDB
Related UniProtKB
[7]
Resource
Comments
Medline ID
PubMed ID	7565775
Journal	Mol Cell Biol
Year	1995
Volume	15
Pages	6222-31
Authors	Cong P, Shuman S
Title	Mutational analysis of mRNA capping enzyme identifies amino acids involved in GTP binding, enzyme-guanylate formation, and GMP transfer to RNA.
Related PDB
Related UniProtKB
[8]
Resource
Comments	X-RAY CRYSTALLOGRAPHY (2.5 ANGSTROMS)
Medline ID	97304383
PubMed ID	9160746
Journal	Cell
Year	1997
Volume	89
Pages	545-53
Authors	Hakansson K, Doherty AJ, Shuman S, Wigley DB
Title	X-ray crystallography reveals a large conformational change during guanyl transfer by mRNA capping enzymes.
Related PDB	1ckm 1ckn
Related UniProtKB	Q84424
[9]
Resource
Comments
Medline ID
PubMed ID	9371657
Journal	J Virol
Year	1997
Volume	71
Pages	9837-43
Authors	Yu L, Martins A, Deng L, Shuman S
Title	Structure-function analysis of the triphosphatase component of vaccinia virus mRNA capping enzyme.
Related PDB
Related UniProtKB
[10]
Resource
Comments
Medline ID
PubMed ID	9275164
Journal	Proc Natl Acad Sci U S A
Year	1997
Volume	94
Pages	9573-8
Authors	Wang SP, Deng L, Ho CK, Shuman S
Title	Phylogeny of mRNA capping enzymes.
Related PDB
Related UniProtKB
[11]
Resource
Comments	X-RAY CRYSTALLOGRAPHY (3.1 ANGSTROMS) OF 11-327
Medline ID	98132620
PubMed ID	9465045
Journal	Proc Natl Acad Sci U S A
Year	1998
Volume	95
Pages	1505-10
Authors	Hakansson K, Wigley DB
Title	Structure of a complex between a cap analogue and mRNA guanylyl transferase demonstrates the structural chemistry of RNA capping.
Related PDB	1cko
Related UniProtKB	Q84424
[12]
Resource
Comments
Medline ID
PubMed ID	10454631
Journal	Nucleic Acids Res
Year	1999
Volume	27
Pages	3253-8
Authors	Doherty AJ
Title	Conversion of a DNA ligase into an RNA capping enzyme.
Related PDB
Related UniProtKB
[13]
Resource
Comments
Medline ID
PubMed ID	11018011
Journal	Genes Dev
Year	2000
Volume	14
Pages	2435-40
Authors	Schroeder SC, Schwer B, Shuman S, Bentley D
Title	Dynamic association of capping enzymes with transcribing RNA polymerase II.
Related PDB
Related UniProtKB
[14]
Resource
Comments
Medline ID
PubMed ID	11463793
Journal	J Biol Chem
Year	2001
Volume	276
Pages	36116-24
Authors	Hausmann S, Ho CK, Schwer B, Shuman S
Title	An essential function of Saccharomyces cerevisiae RNA triphosphatase Cet1 is to stabilize RNA guanylyltransferase Ceg1 against thermal inactivation.
Related PDB
Related UniProtKB
[15]
Resource
Comments
Medline ID
PubMed ID	12846573
Journal	Biochemistry
Year	2003
Volume	42
Pages	8240-9
Authors	Sawaya R, Shuman S
Title	Mutational analysis of the guanylyltransferase component of Mammalian mRNA capping enzyme.
Related PDB
Related UniProtKB
[16]
Resource
Comments
Medline ID
PubMed ID	12820968
Journal	Mol Cell
Year	2003
Volume	11
Pages	1549-61
Authors	Fabrega C, Shen V, Shuman S, Lima CD
Title	Structure of an mRNA capping enzyme bound to the phosphorylated carboxy-terminal domain of RNA polymerase II.
Related PDB
Related UniProtKB
[17]
Resource
Comments
Medline ID
PubMed ID	15582400
Journal	Curr Opin Struct Biol
Year	2004
Volume	14
Pages	757-64
Authors	Shuman S, Lima CD
Title	The polynucleotide ligase and RNA capping enzyme superfamily of covalent nucleotidyltransferases.
Related PDB
Related UniProtKB

Comments
According to the literature [8], [10], [11], the catalytic reaction probably proceeds as follows: (1) Asp213 acts as a general base, which deprotonates the nucleophile, the sidechain of Lys82, to activate it. (Although the literature [11] suggests an alternative mechanism, in which alpha-phosphate of GTP may act as a general base to deprotonate Lys82 and Asp213 may only modulate it by hydrogen bonding, there some factors against the substrate-assisted mechanism. Cofactor magnesium/manganese ion might neutralize the negative charge changing the pKa of the phosphate group. Moreover, the proton transfer from Lys82 to the phosphate results in the loss of an ion pair, which will not be favored. see [11]) (2) The sidechain of Lys82 makes a nucleophilic attack on the alpha-phosphate group of GTP. This process leads to the transition state in which the transferred phosphate group goes through a pentacovalent state (SN2-like reaction). (During this process, the domains are in the closed conformation.) (3) The transferred alpha-phosphate group is stabilized by Lys234 and Lys236 along with a cofactor magnesium/manganese ion. Meanwhile, Arg106, Arg295, Lys298 and Asn302 stabilize the leaving beta- and gamma-phosphate groups, along with Asp244, which might neutralize these positively charged residues. (4) Phosphoamide intermediate is formed between Lys82 and GMP, whereas the leaving beta- and gamma-phosphate is released from the enzyme as a product, diphosphate. (5) The terminal phosphate group of the second substrate, (5')ppPur-mRNA, is bound to the active site. (During this process, the enzyme is in the open conformation.) (6) The oxygen atom of the terminal phosphate group makes a nucleophilic attack on the phosphorus atom of GMP attached to Lys82. This process leads to the transition state in which the transferred phosphate group goes through a pentacovalent state (SN2-like reaction). (7) The transferred phosphate group is again stabilized by Lys234 and Lys236 along with a cofactor magnesium/manganese ion. Meanwhile, Arg106, Arg295, Lys298 and Asn302 stabilize the acceptor phosphate groups, along with Asp244, which might neutralize these positively charged residues. (8) Asp213 acts as a general acid to protonate Lys82, which is finally released from the product.

Comments

According to the literature [8], [10], [11], the catalytic reaction probably proceeds as follows:
(1) Asp213 acts as a general base, which deprotonates the nucleophile, the sidechain of Lys82, to activate it. (Although the literature [11] suggests an alternative mechanism, in which alpha-phosphate of GTP may act as a general base to deprotonate Lys82 and Asp213 may only modulate it by hydrogen bonding, there some factors against the substrate-assisted mechanism. Cofactor magnesium/manganese ion might neutralize the negative charge changing the pKa of the phosphate group. Moreover, the proton transfer from Lys82 to the phosphate results in the loss of an ion pair, which will not be favored. see [11])
(2) The sidechain of Lys82 makes a nucleophilic attack on the alpha-phosphate group of GTP. This process leads to the transition state in which the transferred phosphate group goes through a pentacovalent state (SN2-like reaction). (During this process, the domains are in the closed conformation.)
(3) The transferred alpha-phosphate group is stabilized by Lys234 and Lys236 along with a cofactor magnesium/manganese ion. Meanwhile, Arg106, Arg295, Lys298 and Asn302 stabilize the leaving beta- and gamma-phosphate groups, along with Asp244, which might neutralize these positively charged residues.
(4) Phosphoamide intermediate is formed between Lys82 and GMP, whereas the leaving beta- and gamma-phosphate is released from the enzyme as a product, diphosphate.
(5) The terminal phosphate group of the second substrate, (5')ppPur-mRNA, is bound to the active site. (During this process, the enzyme is in the open conformation.)
(6) The oxygen atom of the terminal phosphate group makes a nucleophilic attack on the phosphorus atom of GMP attached to Lys82. This process leads to the transition state in which the transferred phosphate group goes through a pentacovalent state (SN2-like reaction).
(7) The transferred phosphate group is again stabilized by Lys234 and Lys236 along with a cofactor magnesium/manganese ion. Meanwhile, Arg106, Arg295, Lys298 and Asn302 stabilize the acceptor phosphate groups, along with Asp244, which might neutralize these positively charged residues.
(8) Asp213 acts as a general acid to protonate Lys82, which is finally released from the product.

Created	Updated
2004-03-25	2009-02-26