⊟Summary[edit | edit source]

pan ID^?: SAUPAN002343000
symbol^?: folE2
synonym:
description^?: GTP cyclohydrolase I FolE2
- GTP cyclohydrolase I FolE2
- GTP cyclohydrolase
- putative GTP cyclohydrolase
- GTP cyclohydrolase, putative
- GTP cyclohydrolase FolE2
- GTP cyclohydrolase I type 2
strand^?: -
coordinates^?: 2883677..2884555
synteny block^?: BlockID0016420
occurrence^?: in 100% of 34 strains

folE2 : GTP cyclohydrolase I ^[1]

GTP cyclohydrolase is the first committed step for multiple pathways including folate synthesis and queuosine synthesis. Staphylococci only possess one form of GTP cyclohydrolase. The "FolE2" nomenclature denotes a structural variant of the originally-described "FolE" enzyme. Some organisms possess both forms; staphylococci only make FolE2.

⊟Orthologs[edit | edit source]

COL:

N315:

NCTC8325:

Newman:

USA300_FPR3757:

JSNZ:

JSNZ_000524 (folE2)

04-02981:

SA2981_0543

08BA02176:

C248_0641

11819-97:

MS7_0556 (folE2)

6850:

RSAU_000520

71193:

ST398NM01_0641

ECT-R 2:

ECTR2_520

ED133:

SAOV_0601c

ED98:

SAAV_0529

HO 5096 0412:

SAEMRSA15_04930

JH1:

SaurJH1_0603

JH9:

SaurJH9_0589

JKD6008:

SAA6008_00574

JKD6159:

SAA6159_00520

LGA251:

SARLGA251_05020

M013:

M013TW_0554

MRSA252:

SAR0570

MSHR1132:

SAMSHR1132_05100

MSSA476:

SAS0524

Mu3:

SAHV_0564

Mu50:

SAV0566

MW2:

MW0521

RF122:

SAB0516c

ST398:

SAPIG0641

T0131:

SAT0131_00627

TCH60:

HMPREF0772_12622

TW20:

SATW20_06360

USA300_TCH1516:

USA300HOU_0560

VC40:

SAVC_02420

⊟Genome Viewer[edit | edit source]

⊟Alignments[edit | edit source]

alignment of orthologues:
CLUSTAL format alignment by MAFFT L-INS-i (v7.307)

COL             MTEFDLSTREGRWKHFGSVDPIEGTKPTTKNEMTDLQSTHKDFLFEIEEVGIKNLVYPVL
N315            MTEFDLSTREGRWKHFGSVDPIEGTKPTTKNEMTDLQSTHKDFLFEIEEVGIKNLVYPVL
NCTC8325        MTEFDLSTREGRWKHFGSVDPIEGTKPTTKNEMTDLQSTHKDFLFEIEEVGIKNLVYPVL
Newman          MTEFDLSTREGRWKHFGSVDPIEGTKPTTKNEMTDLQSTHKDFLFEIEEVGIKNLVYPVL
USA300_FPR3757  MTEFDLSTREGRWKHFGSVDPIEGTKPTTKNEMTDLQSTHKDFLFEIEEVGIKNLVYPVL
                ************************************************************

COL             VDQYQTAGTFSFSTSLTKDEKGINMSRIIESVEKHYDNGIELEFNTLYQVLRTLQTNMKQ
N315            VDQYQTAGTFSFSTSLTKDEKGINMSRIIESVEKHYDNGIELEFNTLYQVLRTLQTNMKQ
NCTC8325        VDQYQTAGTFSFSTSLTKDEKGINMSRIIESVEKHYDNGIELEFNTLYQVLRTLQTNMKQ
Newman          VDQYQTAGTFSFSTSLTKDEKGINMSRIIESVEKHYDNGIELEFNTLYQVLRTLQTNMKQ
USA300_FPR3757  VDQYQTAGTFSFSTSLTKDEKGINMSRIIESVEKHYDNGIELEFNTLYQVLRTLQTNMKQ
                ************************************************************

COL             NAAGVDVSGKWFFDRYSPTTNIKAVGNADVTYGLAIDGDKVTRKELTIEATVTTLCPCSK
N315            NAAGVDVSGKWFFDRYSPTTNIKAVGNADVTYGLAIDGDKVTRKELTIEATVTTLCPCSK
NCTC8325        NAAGVDVSGKWFFDRYSPTTNIKAVGNADVTYGLAIDGDKVTRKELTIEATVTTLCPCSK
Newman          NAAGVDVSGKWFFDRYSPTTNIKAVGNADVTYGLAIDGDKVTRKELTIEATVTTLCPCSK
USA300_FPR3757  NAAGVDVSGKWFFDRYSPTTNIKAVGNADVTYGLAIDGDKVTRKELTIEATVTTLCPCSK
                ************************************************************

COL             EISEYSAHNQRGVVTVKTYINKDQDIVDDYKNKILDAMEANASSILYPILKRPDEKRVTE
N315            EISEYSAHNQRGVVTVKTYINKDQNIVDDYKNKILDAMEANASSILYPILKRPDEKRVTE
NCTC8325        EISEYSAHNQRGVVTVKTYINKDQDIVDDYKNKILDAMEANASSILYPILKRPDEKRVTE
Newman          EISEYSAHNQRGVVTVKTYINKDQDIVDDYKNKILDAMEANASSILYPILKRPDEKRVTE
USA300_FPR3757  EISEYSAHNQRGVVTVKTYINKDQDIVDDYKNKILDAMEANASSILYPILKRPDEKRVTE
                ************************:***********************************

COL             RAYENPRFVEDLIRLIAADLVEFDWLDGFDIECRNEESIHQHDAFAKLKYRK
N315            RAYENPRFVEDLIRLIAADLVEFDWLDGFDIECRNEESIHQHDAFAKLKYRK
NCTC8325        RAYENPRFVEDLIRLIAADLVEFDWLDGFDIECRNEESIHQHDAFAKLKYRK
Newman          RAYENPRFVEDLIRLIAADLVEFDWLDGFDIECRNEESIHQHDAFAKLKYRK
USA300_FPR3757  RAYENPRFVEDLIRLIAADLVEFDWLDGFDIECRNEESIHQHDAFAKLKYRK
                ****************************************************

↑ Basma El Yacoubi, Shilah Bonnett, Jessica N Anderson, Manal A Swairjo, Dirk Iwata-Reuyl, Valérie de Crécy-Lagard
Discovery of a new prokaryotic type I GTP cyclohydrolase family.
J Biol Chem: 2006, 281(49);37586-93
[PubMed:17032654] [WorldCat.org] [DOI] (P p)Geoffrey Hutinet, Manal A Swarjo, Valérie de Crécy-Lagard
Deazaguanine derivatives, examples of crosstalk between RNA and DNA modification pathways.
RNA Biol: 2017, 14(9);1175-1184
[PubMed:27937735] [WorldCat.org] [DOI] (I p)Matthew R Jordan, Jiefei Wang, Andy Weiss, Eric P Skaar, Daiana A Capdevila, David P Giedroc
Mechanistic Insights into the Metal-Dependent Activation of Zn II-Dependent Metallochaperones.
Inorg Chem: 2019, 58(20);13661-13672
[PubMed:31247880] [WorldCat.org] [DOI] (I p)Laura Antoine, Philippe Wolff, Eric Westhof, Pascale Romby, Stefano Marzi
Mapping post-transcriptional modifications in Staphylococcus aureus tRNAs by nanoLC/MSMS.
Biochimie: 2019, 164;60-69
[PubMed:31295507] [WorldCat.org] [DOI] (I p)Jorge Díaz-Rullo, José Eduardo González-Pastor
tRNA queuosine modification is involved in biofilm formation and virulence in bacteria.
Nucleic Acids Res: 2023, 51(18);9821-9837
[PubMed:37638766] [WorldCat.org] [DOI] (I p)Valérie de Crécy-Lagard, Geoffrey Hutinet, José D D Cediel-Becerra, Yifeng Yuan, Rémi Zallot, Marc G Chevrette, R M Madhushi N Ratnayake, Marshall Jaroch, Samia Quaiyum, Steven Bruner
Biosynthesis and function of 7-deazaguanine derivatives in bacteria and phages.
Microbiol Mol Biol Rev: 2024, 88(1);e0019923
[PubMed:38421302] [WorldCat.org] [DOI] (I p)

[1] Basma El Yacoubi, Shilah Bonnett, Jessica N Anderson, Manal A Swairjo, Dirk Iwata-Reuyl, Valérie de Crécy-Lagard
Discovery of a new prokaryotic type I GTP cyclohydrolase family.
J Biol Chem: 2006, 281(49);37586-93
[PubMed:17032654] [WorldCat.org] [DOI] (P p)Geoffrey Hutinet, Manal A Swarjo, Valérie de Crécy-Lagard
Deazaguanine derivatives, examples of crosstalk between RNA and DNA modification pathways.
RNA Biol: 2017, 14(9);1175-1184
[PubMed:27937735] [WorldCat.org] [DOI] (I p)Matthew R Jordan, Jiefei Wang, Andy Weiss, Eric P Skaar, Daiana A Capdevila, David P Giedroc
Mechanistic Insights into the Metal-Dependent Activation of Zn II-Dependent Metallochaperones.
Inorg Chem: 2019, 58(20);13661-13672
[PubMed:31247880] [WorldCat.org] [DOI] (I p)Laura Antoine, Philippe Wolff, Eric Westhof, Pascale Romby, Stefano Marzi
Mapping post-transcriptional modifications in Staphylococcus aureus tRNAs by nanoLC/MSMS.
Biochimie: 2019, 164;60-69
[PubMed:31295507] [WorldCat.org] [DOI] (I p)Jorge Díaz-Rullo, José Eduardo González-Pastor
tRNA queuosine modification is involved in biofilm formation and virulence in bacteria.
Nucleic Acids Res: 2023, 51(18);9821-9837
[PubMed:37638766] [WorldCat.org] [DOI] (I p)Valérie de Crécy-Lagard, Geoffrey Hutinet, José D D Cediel-Becerra, Yifeng Yuan, Rémi Zallot, Marc G Chevrette, R M Madhushi N Ratnayake, Marshall Jaroch, Samia Quaiyum, Steven Bruner
Biosynthesis and function of 7-deazaguanine derivatives in bacteria and phages.
Microbiol Mol Biol Rev: 2024, 88(1);e0019923
[PubMed:38421302] [WorldCat.org] [DOI] (I p)

[1]

Navigation menu

Contents

⊟Summary[edit | edit source]

⊟Orthologs[edit | edit source]

⊟Genome Viewer[edit | edit source]

⊟Alignments[edit | edit source]

COL
N315
NCTC8325
Newman
USA300_FPR3757
JSNZ

Search

Navigation menu

⊟Summary[edit | edit source]

⊟Orthologs[edit | edit source]

⊟Genome Viewer[edit | edit source]

⊟Alignments[edit | edit source]