Expression levels of transcription factors in Escherichia coli: growth phase- and growth condition-dependent variation of 90 regulators from six families

Abstract: The expression pattern of the genome in Escherichia coli is controlled by regulating the utilization of a limited number of RNA polymerases between a total of 4600 genes on its genome. The distribution pattern of RNA polymerase on the genome changes after two steps of protein-protein interaction with seven sigma subunits and about 300 transcription factors (TFs). Based on a systematic search for the regulation target promoters recognized by each TF, we propose two novel concepts: each TF regulates a number of … Show more

“…Previous studies involving E. coli have demonstrated important transcriptomic differences between mid-exponential and stationary growth phase cultures (Yamamoto et al 2014). These transcriptomic differences likely alter the bacterial proteome, which in turn could alter both the soluble and volatile metabolomes, accounting for the growth phase-specific appearance, and subsequent disappearance, of a subset of molecules.…”

Expanding theKlebsiella pneumoniaevolatile metabolome using advanced analytical instrumentation for the detection of novel metabolites

“…Previous studies involving E. coli have demonstrated important transcriptomic differences between mid-exponential and stationary growth phase cultures (Yamamoto et al 2014). These transcriptomic differences likely alter the bacterial proteome, which in turn could alter both the soluble and volatile metabolomes, accounting for the growth phase-specific appearance, and subsequent disappearance, of a subset of molecules.…”

Expanding theKlebsiella pneumoniaevolatile metabolome using advanced analytical instrumentation for the detection of novel metabolites

“…If the functional forms of both TFs exist at high concentrations, they should compete with each other, but both belong to the low-abundance TF group in WT E. coli Yamamoto et al, 2014). Under steady-state growth in the absence of external Cu 2+ and H 2 O 2 , both should remain as nonphosphorylated non-functional forms.…”

Cooperative regulation of the common target genes between H2O2-sensing YedVW and Cu2+-sensing CusSR in Escherichia coli

“…Excluding the high-abundance nucleoid proteins, the estimated concentrations of regulatory proteins range between v50 and *1500 molecules per genome in exponentially growing cells . Measurements of protein-GFP fusions suggest a concentration range of three orders of magnitude for different regulatory proteins in growing cells (Yamamoto et al, 2014). Note that NsrR concentration was not measured in these studies, and we have been unable to detect NsrR by Western blotting (using a strain with a GTG start codon), which is consistent with a low cellular abundance.…”

“…The seven proteins with very low concentrations (v50 molecules per genome) have between one and five regulatory targets . In this paper, we show with a translational fusion [a technique similar to that used by Yamamoto et al (2014)] that the abundance of NsrR is below the detection limit of the reporter enzyme assay. NsrR appears to be unusual in being a low-abundance regulatory protein with a relatively large number (w10) of target promoters.…”

“…Yet, until recently, measurements of concentrations were available for only a very small number of proteins. This knowledge gap has now been partially filled for E. coli, by high-throughput measurements of regulator abundances using immunological and fluorescence-based (Yamamoto et al, 2014) methods. Excluding the high-abundance nucleoid proteins, the estimated concentrations of regulatory proteins range between v50 and *1500 molecules per genome in exponentially growing cells .…”

Inefficient translation of nsrR constrains behaviour of the NsrR regulon in Escherichia coli