Mapping and manipulating the Mycobacterium tuberculosis transcriptome using a transcription factor overexpression-derived regulatory network.

Publication Type:

Journal Article

Source:

Genome Biol, Volume 15, Issue 11, p.502 (2014)

Keywords:

Cloning, Molecular, Gene Expression Regulation, Bacterial, Gene Regulatory Networks, Humans, Isoniazid, Mycobacterium tuberculosis, Promoter Regions, Genetic, Regulon, Transcription Factors, Transcription, Genetic, Transcriptome, Tuberculosis

Abstract:

<p><b>BACKGROUND: </b>Mycobacterium tuberculosis senses and responds to the shifting and hostile landscape of the host. To characterize the underlying intertwined gene regulatory network governed by approximately 200 transcription factors of M. tuberculosis, we have assayed the global transcriptional consequences of overexpressing each transcription factor from an inducible promoter.</p><p><b>RESULTS: </b>We cloned and overexpressed 206 transcription factors in M. tuberculosis to identify the regulatory signature of each. We identified 9,335 regulatory consequences of overexpressing each of 183 transcription factors, providing evidence of regulation for 70% of the M. tuberculosis genome. These transcriptional signatures agree well with previously described M. tuberculosis regulons. The number of genes differentially regulated by transcription factor overexpression varied from hundreds of genes to none, with the majority of expression changes repressing basal transcription. Exploring the global transcriptional maps of transcription factor overexpressing (TFOE) strains, we predicted and validated the phenotype of a regulator that reduces susceptibility to a first line anti-tubercular drug, isoniazid. We also combined the TFOE data with an existing model of M. tuberculosis metabolism to predict the growth rates of individual TFOE strains with high fidelity.</p><p><b>CONCLUSION: </b>This work has led to a systems-level framework describing the transcriptome of a devastating bacterial pathogen, characterized the transcriptional influence of nearly all individual transcription factors in M. tuberculosis, and demonstrated the utility of this resource. These results will stimulate additional systems-level and hypothesis-driven efforts to understand M. tuberculosis adaptations that promote disease.</p>

Supplementary Files: 

TFOE Expression Data Records

Title Gene BioProject GEO Series Platform Accession Sample Method Sample Type References Release Date Repository
TFOE_2229_1219c
Transcriptional regulator, TetR family
PRJNA254351 GSE59086 GPL14824 GSM1426637 Tiling Array RNA 25232098 4-Jul-14 GEO
TFOE_5098_1219c
Transcriptional regulator, TetR family
PRJNA254351 GSE59086 GPL14824 GSM1426638 Tiling Array RNA 25232098 4-Jul-14 GEO
TFOE_6617_1219c
Transcriptional regulator, TetR family
PRJNA254351 GSE59086 GPL14824 GSM1426639 Tiling Array RNA 25232098 4-Jul-14 GEO
TFOE_8236_1176c
Transcriptional regulator, PadR family
PRJNA254351 GSE59086 GPL14824 GSM1426629 Tiling Array RNA 25232098 4-Jul-14 GEO
TFOE_7962_1167c
Transcriptional regulator, TetR family
PRJNA254351 GSE59086 GPL14824 GSM1426627 Tiling Array RNA 25232098 4-Jul-14 GEO
TFOE_6929_1167c
Transcriptional regulator, TetR family
PRJNA254351 GSE59086 GPL14824 GSM1426626 Tiling Array RNA 25232098 4-Jul-14 GEO
TFOE_4839_1129c
Transcriptional regulator, XRE family
PRJNA254351 GSE59086 GPL14824 GSM1426616 Tiling Array RNA 25232098 4-Jul-14 GEO
TFOE_1203_1151c
NAD-dependent protein deacetylase of SIR2 family
PRJNA254351 GSE59086 GPL14824 GSM1426617 Tiling Array RNA 25232098 4-Jul-14 GEO
TFOE_4316_1151c
NAD-dependent protein deacetylase of SIR2 family
PRJNA254351 GSE59086 GPL14824 GSM1426618 Tiling Array RNA 25232098 4-Jul-14 GEO
TFOE_7811_1151c
NAD-dependent protein deacetylase of SIR2 family
PRJNA254351 GSE59086 GPL14824 GSM1426619 Tiling Array RNA 25232098 4-Jul-14 GEO