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virulence, detoxification, adaptation

information pathways

cell wall and cell processes

stable RNAs

insertion seqs and phages

PE/PPE

intermediary metabolism and respiration

unknown

regulatory proteins

conserved hypotheticals

lipid metabolism

pseudogenes

Gene summary information

Gene name	echA6
Gene length	732 bp
Identifier	Rv0905
Location	1008207 bp

Protein summary information

Molecular mass	26028.8 Da
Isoelectric point	6.3617
Protein length	243 amino acids

Structural information

Protein Data Bank	3HE2
PFAM	P64014

Orthologs

M. bovis AF2122-97	Mb0929
M. marinum M	MMAR_4625
M. smegmatis MC2-155	MSMEG_5639
M. leprae TN	ML2118c
M. tuberculosis 18b	MT18B_1177
M. tuberculosis MTBC0	mtbc0_000959

Cross-references

UniProt	P9WNP1
Enzyme Classification	4.2.1.17
Gene Ontology	Fatty acid metabolic process, Enoyl-coa hydratase activity
SWISS-MODEL	P9WNP1
TB database	Rv0905

Interacting Drugs/Compounds

TDR Targets	Link

Precomputed results

BLAST	Report

General annotation

Type	CDS
Function	Could possibly oxidize fatty acids using specific components [catalytic activity: (3S)-3-hydroxyacyl-CoA = trans-2(or 3)-enoyl-CoA + H(2)O].
Product	Possible enoyl-CoA hydratase EchA6 (enoyl hydrase) (unsaturated acyl-CoA hydratase) (crotonase)
Comments	Rv0905, (MTCY31.33), len: 243 aa. Possible echA6, enoyl-CoA hydratase, highly similar to ML15184\|U15184 enoyl-CoA hydratase from Mycobacterium leprae (247 aa), FASTA score: (85.8% identity in 247 aa overlap). Also similar to many e.g. NP_250320.1\|NC_002516 probable enoyl-CoA hydratase/isomerase from Pseudomonas aeruginosa (261 aa); NP_415911.1\|NC_000913 putative enzyme from Escherichia coli strain K12 (255 aa); P24162\|ECHH_RHOCA\|FADB1 enoyl-CoA hydratase homolog from Rhodobacter capsulatus (Rhodopseudomonas capsulata) (257 aa), FASTA scores: opt: 404, E():7.8e-21, (37.3% identity in 249 aa overlap); etc.
Functional category	Lipid metabolism
Proteomics	Identified in the membrane fraction of M. tuberculosis H37Rv using 1D-SDS-PAGE and uLC-MS/MS (See Gu et al., 2003). Identified in the culture supernatant of M. tuberculosis H37Rv using mass spectrometry (See Mattow et al., 2003). Identified in the cell wall fraction of M. tuberculosis H37Rv using 2DLC/MS (See Mawuenyega et al., 2005). Identified in the membrane fraction of M. tuberculosis H37Rv using nanoLC-MS/MS (See Xiong et al., 2005). Identified by mass spectrometry in Triton X-114 extracts of M. tuberculosis H37Rv (See Malen et al., 2010). Identified by mass spectrometry in M. tuberculosis H37Rv-infected guinea pig lungs at 30 days but not 90 days (See Kruh et al., 2010). Identified by mass spectrometry in the culture filtrate, membrane protein fraction, and whole cell lysates of M. tuberculosis H37Rv (See de Souza et al., 2011). Translational start site supported by proteomics data (See de Souza et al., 2011) (See Kelkar et al., 2011).
Mutant	Non-essential gene for in vitro growth of H37Rv in a MtbYM rich medium, by Himar1 transposon mutagenesis (see Minato et al. 2019). Non-essential gene for in vitro growth of H37Rv, by analysis of saturated Himar1 transposon libraries (see DeJesus et al. 2017). Non essential gene by Himar1 transposon mutagenesis in H37Rv strain (see Sassetti et al., 2003). Non-essential gene for in vitro growth of H37Rv, by Himar1 transposon mutagenesis (See Griffin et al., 2011). Check for mutants available at TARGET website

Coordinates

Type	Start	End	Orientation
CDS	1008207	1008938	+

Genomic sequence

Feature type Upstream flanking region (bp) Downstream flanking region (bp) Update

Protein sequence

>Mycobacterium tuberculosis H37Rv|Rv0905|echA6
MIGITQAEAVLTIELQRPERRNALNSQLVEELTQAIRKAGDGSARAIVLTGQGTAFCAGADLSGDAFAADYPDRLIELHKAMDASPMPVVGAINGPAIGAGLQLAMQCDLRVVAPDAFFQFPTSKYGLALDNWSIRRLSSLVGHGRARAMLLSAEKLTAEIALHTGMANRIGTLADAQAWAAEIARLAPLAIQHAKRVLNDDGAIEEAWPAHKELFDKAWGSQDVIEAQVARMEKRPPKFQGA

Bibliography

Mattow J, Schaible UE, Schmidt F, Hagens K, Siejak F, Brestrich G, Haeselbarth G, Muller EC, Jungblut PR and Kaufmann SH [2003]. Comparative proteome analysis of culture supernatant proteins from virulent Mycobacterium tuberculosis H37Rv and attenuated M. bovis BCG Copenhagen. Proteomics
Sassetti CM et al. [2003]. Genes required for mycobacterial growth defined by high density mutagenesis. Mutant
Gu S et al. [2003]. Comprehensive proteomic profiling of the membrane constituents of a Mycobacterium tuberculosis strain. Proteomics
Xiong Y, Chalmers MJ, Gao FP, Cross TA and Marshall AG [2005]. Identification of Mycobacterium tuberculosis H37Rv integral membrane proteins by one-dimensional gel electrophoresis and liquid chromatography electrospray ionization tandem mass spectrometry. Proteomics
Mawuenyega KG et al. [2005]. Mycobacterium tuberculosis functional network analysis by global subcellular protein profiling. Proteomics
Målen H et al. [2010]. Definition of novel cell envelope associated proteins in Triton X-114 extracts of Mycobacterium tuberculosis H37Rv. Proteomics
Kruh NA et al. [2010]. Portrait of a pathogen: the Mycobacterium tuberculosis proteome in vivo. Proteomics
Kelkar DS et al. [2011]. Proteogenomic analysis of Mycobacterium tuberculosis by high resolution mass spectrometry. Proteomics Sequence
de Souza GA et al. [2011]. Bacterial proteins with cleaved or uncleaved signal peptides of the general secretory pathway. Proteomics
Griffin JE et al. [2011]. High-resolution phenotypic profiling defines genes essential for mycobacterial growth and cholesterol catabolism. Mutant
de Souza GA et al. [2011]. Proteogenomic analysis of polymorphisms and gene annotation divergences in prokaryotes using a clustered mass spectrometry-friendly database. Proteomics Sequence
DeJesus MA et al. [2017]. Comprehensive Essentiality Analysis of the Mycobacterium tuberculosis Genome via Saturating Transposon Mutagenesis. Mutant
Minato Y et al. [2019]. Genomewide Assessment of Mycobacterium tuberculosis Conditionally Essential Metabolic Pathways. Mutant