DB code: S00287

RLCP classification	3.943.120000.356 : Transfer
CATH domain	3.40.50.2020 : Rossmann fold	Catalytic domain
E.C.	2.4.2.9
CSA	1bd3
M-CSA	1bd3
MACiE

CATH domain	Related DB codes (homologues)
3.40.50.2020 : Rossmann fold	S00288 S00289 D00131

Uniprot Enzyme Name
UniprotKB	Protein name	Synonyms	Pfam
Q26998	Uracil phosphoribosyltransferase	EC 2.4.2.9 UMP pyrophosphorylase UPRTase UPRT	[Graphical View]
P70881	Uracil phosphoribosyltransferase	EC 2.4.2.9 UMP pyrophosphorylase UPRTase	PF00156 (Pribosyltran) [Graphical View]

KEGG enzyme name
uracil phosphoribosyltransferase UMP pyrophosphorylase UPRTase UMP:pyrophosphate phosphoribosyltransferase uridine 5'-phosphate pyrophosphorylase uridine monophosphate pyrophosphorylase uridylate pyrophosphorylase uridylic pyrophosphorylase

UniprotKB: Accession Number	Entry name	Activity	Subunit	Subcellular location	Cofactor
Q26998	UPP_TOXGO	UMP + diphosphate = uracil + 5-phospho-alpha- D-ribose 1-diphosphate.	Monomer.
P70881	UPP_BACCL	UMP + diphosphate = uracil + 5-phospho-alpha- D-ribose 1-diphosphate.	Homodimer.		Magnesium (By similarity).

KEGG Pathways
Map code	Pathways	E.C.
MAP00240	Pyrimidine metabolism

Compound table
	Cofactors	Substrates		Products		Intermediates
KEGG-id	C00305	C00106	C00119	C00105	C00013
E.C.
Compound	magnesium	Uracil	5-Phospho-alpha-D-ribose 1-diphosphate	UMP	Pyrophosphate
Type	divalent metal (Ca2+, Mg2+)	amide group,aromatic ring (with nitrogen atoms)	carbohydrate,phosphate group/phosphate ion	amide group,nucleotide	phosphate group/phosphate ion
ChEBI	18420 18420	17568 17568	17111 17111	16695 16695	29888 29888
PubChem	888 888	1174 1174	7339 7339	6030 6030	1023 21961011 1023 21961011

1bd3A	Unbound	Unbound	Unbound	Unbound	Unbound
1bd3B	Unbound	Unbound	Unbound	Unbound	Unbound
1bd3C	Unbound	Unbound	Unbound	Unbound	Unbound
1bd3D	Unbound	Unbound	Unbound	Unbound	Unbound
1bd4A	Unbound	Bound:URA	Unbound	Unbound	Unbound
1bd4B	Unbound	Bound:URA	Unbound	Unbound	Unbound
1bd4C	Unbound	Bound:URA	Unbound	Unbound	Unbound
1bd4D	Unbound	Bound:URA	Unbound	Unbound	Unbound
1upfA	Unbound	Analogue:URF	Unbound	Unbound	Analogue:SO4
1upfB	Unbound	Analogue:URF	Unbound	Unbound	Analogue:SO4
1upfC	Unbound	Analogue:URF	Unbound	Unbound	Analogue:SO4
1upfD	Unbound	Analogue:URF	Unbound	Unbound	Analogue:SO4
1upuA	Unbound	Unbound	Unbound	Bound:U5P	Unbound
1upuB	Unbound	Unbound	Unbound	Bound:U5P	Unbound
1upuC	Unbound	Unbound	Unbound	Bound:U5P	Unbound
1upuD	Unbound	Unbound	Unbound	Bound:U5P	Unbound
1jlrA	Unbound	Unbound	Unbound	Unbound	Analogue:PO4
1jlrB	Unbound	Unbound	Unbound	Unbound	Analogue:PO4
1jlrC	Unbound	Unbound	Unbound	Unbound	Analogue:PO4
1jlrD	Unbound	Unbound	Unbound	Unbound	Analogue:PO4
1jlsA	Unbound	Bound:URA	Unbound	Unbound	Analogue:PO4
1jlsB	Bound:_MG	Bound:URA	Bound:PRP	Unbound	Unbound
1jlsC	Unbound	Bound:URA	Unbound	Unbound	Unbound
1jlsD	Unbound	Bound:URA	Unbound	Unbound	Analogue:PO4
1i5eA	Unbound	Unbound	Unbound	Bound:U5P	Unbound
1i5eB	Unbound	Unbound	Unbound	Bound:U5P	Unbound

Reference for Active-site residues
resource	references	E.C.

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

1bd3A	ASP 164;ASP 235;ASP 238
1bd3B	ASP 164;ASP 235;ASP 238
1bd3C	ASP 164;ASP 235;ASP 238
1bd3D	ASP 164;ASP 235;ASP 238
1bd4A	ASP 164;ASP 235;ASP 238
1bd4B	ASP 164;ASP 235;ASP 238
1bd4C	ASP 164;ASP 235;ASP 238
1bd4D	ASP 164;ASP 235;ASP 238
1upfA	ASP 164;ASP 235;ASP 238
1upfB	ASP 164;ASP 235;ASP 238
1upfC	ASP 164;ASP 235;ASP 238
1upfD	ASP 164;ASP 235;ASP 238
1upuA	ASP 164;ASP 235;ASP 238
1upuB	ASP 164;ASP 235;ASP 238
1upuC	ASP 164;ASP 235;ASP 238
1upuD	ASP 164;ASP 235;ASP 238
1jlrA	ASP 164;ASP 235;ASP 238
1jlrB	ASP 164;ASP 235;ASP 238
1jlrC	ASP 164;ASP 235;ASP 238
1jlrD	ASP 164;ASP 235;ASP 238
1jlsA	ASP 164;ASP 235;ASP 238
1jlsB	ASP 164;ASP 235;ASP 238
1jlsC	ASP 164;ASP 235;ASP 238
1jlsD	ASP 164;ASP 235;ASP 238
1i5eA	ASP 131;ASP 200;ASP 203
1i5eB	ASP 131;ASP 200;ASP 203

References for Catalytic Mechanism
References	Sections	No. of steps in catalysis
[3]	p.3228-3229
[5]	p.81-83
[6]	p.943-944, Fig.8	1

References
[1]
Resource
Comments
Medline ID
PubMed ID	8080452
Journal	Biochem Pharmacol
Year	1994
Volume	48
Pages	781-92
Authors	Iltzsch MH, Tankersley KO
Title	Structure-activity relationship of ligands of uracil phosphoribosyltransferase from Toxoplasma gondii.
Related PDB
Related UniProtKB
[2]
Resource
Comments
Medline ID
PubMed ID	8765224
Journal	Biochim Biophys Acta
Year	1996
Volume	1296
Pages	16-22
Authors	Linde L, Jensen KF
Title	Uracil phosphoribosyltransferase from the extreme thermoacidophilic archaebacterium Sulfolobus shibatae is an allosteric enzyme, activated by GTP and inhibited by CTP.
Related PDB
Related UniProtKB
[3]
Resource
Comments
Medline ID
PubMed ID	9628859
Journal	EMBO J
Year	1998
Volume	17
Pages	3219-32
Authors	Schumacher MA, Carter D, Scott DM, Roos DS, Ullman B, Brennan RG
Title	Crystal structures of Toxoplasma gondii uracil phosphoribosyltransferase reveal the atomic basis of pyrimidine discrimination and prodrug binding.
Related PDB	1bd3 1bd4 1upf 1upu
Related UniProtKB	Q26998
[4]
Resource
Comments
Medline ID
PubMed ID	10079076
Journal	Biochemistry
Year	1999
Volume	38
Pages	3327-34
Authors	Lundegaard C, Jensen KF
Title	Kinetic mechanism of uracil phosphoribosyltransferase from Escherichia coli and catalytic importance of the conserved proline in the PRPP binding site.
Related PDB
Related UniProtKB
[5]
Resource
Comments
Medline ID
PubMed ID	11773618
Journal	Proc Natl Acad Sci U S A
Year	2002
Volume	99
Pages	78-83
Authors	Schumacher MA, Bashor CJ, Song MH, Otsu K, Zhu S, Parry RJ, Ullman B, Brennan RG
Title	The structural mechanism of GTP stabilized oligomerization and catalytic activation of the Toxoplasma gondii uracil phosphoribosyltransferase.
Related PDB	1jlr 1jls
Related UniProtKB
[6]
Resource
Comments
Medline ID
PubMed ID	12037295
Journal	Acta Crystallogr D Biol Crystallogr
Year	2002
Volume	58
Pages	936-45
Authors	Kadziola A, Neuhard J, Larsen S
Title	Structure of product-bound Bacillus caldolyticus uracil phosphoribosyltransferase confirms ordered sequential substrate binding.
Related PDB	1i5e
Related UniProtKB
[7]
Resource
Comments
Medline ID
PubMed ID	12482852
Journal	J Biol Chem
Year	2003
Volume	278
Pages	6921-7
Authors	Grabner GK, Switzer RL
Title	Kinetic studies of the uracil phosphoribosyltransferase reaction catalyzed by the Bacillus subtilis pyrimidine attenuation regulatory protein PyrR.
Related PDB
Related UniProtKB

Comments
According to the literature [6], one of the substrates, uracil can adopt its tautomeric enol form, with a hydroxyl group at O2 protonated from N1 atom. This enol form of uracil can donate the proton to the carboxylate of Asp235 (Asp200 at PDB 1i5e), acting as a general base, and the alpha-phosphate group of another substrate, PRPP. The movement of the proton towards OP1 of the alpha-phosphate of PRPP activates uracil itself as a nucleophile and the pyrophosphate of PRPP as a leaving group. The paper [5] also suggested that Asp235 might act as the general base, or a proton shuttle, whilst the paper itself also suggested substrate-assisted abstraction of N1 proton of uracil by alpha-phosphate of PRPP. Moreover, Asp238 increased the pKa of the sidechain of Asp235, which can abstract a proton from the scissile pyrophosphate. Moreover, the paper [6] suggested that Asp164 (Asp131 at 1i5e) might stabilize the positively charged oxocarbenium-like transition state. Although the reaction seems to be dependent on magnesium, its role has not been elucidated. As it seems to be bound to beta-phosphate group of PRPP (PDB 1jls), it may contribute to the leaving group. The reaction between the uracil N1 nucleophile and the PRPP C1' atom might proceed through an SN1 or SN2-like mechanism, or mixture of these mechanisms, to produce UMP and pyrophosphate, according to the paper [5].

Comments

According to the literature [6], one of the substrates, uracil can adopt its tautomeric enol form, with a hydroxyl group at O2 protonated from N1 atom. This enol form of uracil can donate the proton to the carboxylate of Asp235 (Asp200 at PDB 1i5e), acting as a general base, and the alpha-phosphate group of another substrate, PRPP. The movement of the proton towards OP1 of the alpha-phosphate of PRPP activates uracil itself as a nucleophile and the pyrophosphate of PRPP as a leaving group.
The paper [5] also suggested that Asp235 might act as the general base, or a proton shuttle, whilst the paper itself also suggested substrate-assisted abstraction of N1 proton of uracil by alpha-phosphate of PRPP. Moreover, Asp238 increased the pKa of the sidechain of Asp235, which can abstract a proton from the scissile pyrophosphate.
Moreover, the paper [6] suggested that Asp164 (Asp131 at 1i5e) might stabilize the positively charged oxocarbenium-like transition state.
Although the reaction seems to be dependent on magnesium, its role has not been elucidated. As it seems to be bound to beta-phosphate group of PRPP (PDB 1jls), it may contribute to the leaving group.
The reaction between the uracil N1 nucleophile and the PRPP C1' atom might proceed through an SN1 or SN2-like mechanism, or mixture of these mechanisms, to produce UMP and pyrophosphate, according to the paper [5].

Created	Updated
2002-05-02	2009-03-30