Rv1908c - catalase-peroxidase-peroxynitritase T katG
Protein Domains

Gene Information
LocusRv1908c
SymbolkatG
Gene Namecatalase-peroxidase-peroxynitritase T katG
Location2153889 - 2156111 (-)
SpeciesMycobacterium tuberculosis H37Rv complete genome.
LengthGene:2223 bp
Protein:741 aa
External LinksTuberculist
Target Gene Information
String Protein-Protein Interactions
STITCH Chemical-Protein Interactions
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Orthologs
Orthogroup Number18922
Related GenesMAP1668c MAV_2753 MSMEG_3729 MT1959 MUL_2190 nfa29500 SCO0560
Transcriptional Regulation
Operons View gene in operon browser
Regulatory Network
Search for regulators of Rv1908c
Expression Correlation Genes with Correlated Expression
Scatterplot of Gene Expression

Sequence
Proteins
Genomic Sequence
Community Annotations Pending Curatorial Review
FieldValueStatusCreatorDate
TermTBRXN:SPODM superoxide dismutase - ISSactivenjamshidi2012-10-05
KatG is a bifunctional enzyme . PMID 15840564
RA. Ghiladi, GM. Knudsen et al. The Met-Tyr-Trp cross-link in Mycobacterium tuberculosis catalase-peroxidase (KatG): autocatalytic formation and effect on enzyme catalysis and spectroscopic properties. J. Biol. Chem. 2005
TermEC:1.15.1.1 Superoxide dismutase. - ISSactivenjamshidi2012-10-05
KatG is a bifunctional enzyme . PMID 15840564
RA. Ghiladi, GM. Knudsen et al. The Met-Tyr-Trp cross-link in Mycobacterium tuberculosis catalase-peroxidase (KatG): autocatalytic formation and effect on enzyme catalysis and spectroscopic properties. J. Biol. Chem. 2005
TermTBRXN:PRDX Peroxidase (multiple substrates) - ISSactivenjamshidi2012-10-05
added during gap filling; peroxidase activity of multiple substrates has been associated based on sequence (verfified again by SEED), methanol metabolism has been demonstrated in literature (PMID 12486050)
authors,SW. Park,EH. Hwang,H. Park,JA. Kim,J. Heo,KH. Lee,T. Song,E. Kim,YT. Ro,SW. Kim,YM. Kim Growth of mycobacteria on carbon monoxide and methanol. J. Bacteriol. 2003
TermEC:1.11.1.7 Peroxidase. - ISSactivenjamshidi2012-10-05
added during gap filling; peroxidase activity of multiple substrates has been associated based on sequence (verfified again by SEED), methanol metabolism has been demonstrated in literature (PMID 12486050)
authors,SW. Park,EH. Hwang,H. Park,JA. Kim,J. Heo,KH. Lee,T. Song,E. Kim,YT. Ro,SW. Kim,YM. Kim Growth of mycobacteria on carbon monoxide and methanol. J. Bacteriol. 2003
TermTBRXN:CAT catalase - ISSactivenjamshidi2012-10-05
PMID: 15231843. the catalase activity is more crucial to its survival than the peroxidase activity PMID: 16315359
authors,NA. Eady,NA. Jesmin,S. Servos,AE. Cass,JM. Nagy,KA. Brown Probing the function of Mycobacterium tuberculosis catalase-peroxidase by site-directed mutagenesis. Dalton Trans 2005
TermEC:1.11.1.6 Catalase. - ISSactivenjamshidi2012-10-05
PMID: 15231843. the catalase activity is more crucial to its survival than the peroxidase activity PMID: 16315359
authors,NA. Eady,NA. Jesmin,S. Servos,AE. Cass,JM. Nagy,KA. Brown Probing the function of Mycobacterium tuberculosis catalase-peroxidase by site-directed mutagenesis. Dalton Trans 2005
TermTBRXN:CAT catalase - ISSactivenjamshidi2012-10-05
PMID: 15231843. the catalase activity is more crucial to its survival than the peroxidase activity PMID: 16315359
authors,T. Bertrand,NA. Eady,JN. Jones,null. Jesmin,JM. Nagy,B. Jamart-Grégoire,EL. Raven,KA. Brown Crystal structure of Mycobacterium tuberculosis catalase-peroxidase. J. Biol. Chem. 2004
TermEC:1.11.1.6 Catalase. - ISSactivenjamshidi2012-10-05
PMID: 15231843. the catalase activity is more crucial to its survival than the peroxidase activity PMID: 16315359
authors,T. Bertrand,NA. Eady,JN. Jones,null. Jesmin,JM. Nagy,B. Jamart-Grégoire,EL. Raven,KA. Brown Crystal structure of Mycobacterium tuberculosis catalase-peroxidase. J. Biol. Chem. 2004
TermTBRXN:CAT catalase - IDAactivenjamshidi2012-10-05
PMID: 15231843. the catalase activity is more crucial to its survival than the peroxidase activity PMID: 16315359
authors,NA. Eady,NA. Jesmin,S. Servos,AE. Cass,JM. Nagy,KA. Brown Probing the function of Mycobacterium tuberculosis catalase-peroxidase by site-directed mutagenesis. Dalton Trans 2005
TermEC:1.11.1.6 Catalase. - IDAactivenjamshidi2012-10-05
PMID: 15231843. the catalase activity is more crucial to its survival than the peroxidase activity PMID: 16315359
authors,NA. Eady,NA. Jesmin,S. Servos,AE. Cass,JM. Nagy,KA. Brown Probing the function of Mycobacterium tuberculosis catalase-peroxidase by site-directed mutagenesis. Dalton Trans 2005
TermTBRXN:CAT catalase - IDAactivenjamshidi2012-10-05
PMID: 15231843. the catalase activity is more crucial to its survival than the peroxidase activity PMID: 16315359
authors,T. Bertrand,NA. Eady,JN. Jones,null. Jesmin,JM. Nagy,B. Jamart-Grégoire,EL. Raven,KA. Brown Crystal structure of Mycobacterium tuberculosis catalase-peroxidase. J. Biol. Chem. 2004
TermEC:1.11.1.6 Catalase. - IDAactivenjamshidi2012-10-05
PMID: 15231843. the catalase activity is more crucial to its survival than the peroxidase activity PMID: 16315359
authors,T. Bertrand,NA. Eady,JN. Jones,null. Jesmin,JM. Nagy,B. Jamart-Grégoire,EL. Raven,KA. Brown Crystal structure of Mycobacterium tuberculosis catalase-peroxidase. J. Biol. Chem. 2004
InteractionTranscription Rv1909cactivekaveri.verma2012-10-05
Mutation studies
AS. Pym, P. Domenech et al. Regulation of catalase-peroxidase (KatG) expression, isoniazid sensitivity and virulence by furA of Mycobacterium tuberculosis. Mol. Microbiol. 2001
InteractionPhysicalInteraction Rv1908cactivejgalag2012-10-05
Yeast two-hybrid (Physical interaction)
M. Wilming & K. Johnsson Inter- and intramolecular domain interactions of the catalase-peroxidase KatG from M. tuberculosis. FEBS Lett. 2001
InteractionPhysicalInteraction Rv1908cactivejgalag2012-10-05
Yeast two-hybrid (Physical interaction)
M. Wilming & K. Johnsson Inter- and intramolecular domain interactions of the catalase-peroxidase KatG from M. tuberculosis. FEBS Lett. 2001
InteractionRegulatory Rv0117activeshahanup862012-10-05
Co-expression (Functional linkage)
M. Guo, H. Feng et al. Dissecting transcription regulatory pathways through a new bacterial one-hybrid reporter system. Genome Res. 2009
InteractionRegulatedBy Rv3416activeyamir.moreno2012-10-05
One hybrid reporter system. Physical binding of the regulator to the regulated promoter proved by using electrophoretic mobility shift assay. .
M. Guo, H. Feng et al. Dissecting transcription regulatory pathways through a new bacterial one-hybrid reporter system. Genome Res. 2009
InteractionRegulatedBy Rv2034activeyamir.moreno2012-10-05
One hybrid reporter system. Physical binding of the regulator to the regulated promoter proved by using electrophoretic mobility shift assay. .
M. Guo, H. Feng et al. Dissecting transcription regulatory pathways through a new bacterial one-hybrid reporter system. Genome Res. 2009
InteractionRegulatedBy Rv0117activeyamir.moreno2012-10-05
One hybrid reporter system. Physical binding of the regulator to the regulated promoter proved by using electrophoretic mobility shift assay. .
M. Guo, H. Feng et al. Dissecting transcription regulatory pathways through a new bacterial one-hybrid reporter system. Genome Res. 2009
InteractionRegulatedBy Rv0117activeyamir.moreno2012-10-05
E.coli orthology based inference. Orthologous pair regulator-target found in E.coli.
G. Balázsi, AP. Heath et al. The temporal response of the Mycobacterium tuberculosis gene regulatory network during growth arrest. Mol. Syst. Biol. 2008
InteractionRegulatedBy Rv0117activeyamir.moreno2012-10-05
E.coli orthology based inference. Orthologous pair regulator-target found in E.coli.
authors,M. Madan Babu,SA. Teichmann,L. Aravind Evolutionary dynamics of prokaryotic transcriptional regulatory networks. J. Mol. Biol. 2006