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32 Publications visible to you, out of a total of 32
Depletion of thiol-containing proteins in response to quinones in Bacillus subtilis

Abstract (Expand)

SUMMARY: Quinones are highly toxic naturally occurring thiol-reactive compounds. We have previously described novel pathways for quinone detoxification in the Gram-positive bacterium Bacillus subtilis. In this study, we have investigated the extent of irreversible and reversible thiol modifications caused in vivo by electrophilic quinones. Exposure to toxic benzoquinone (BQ) concentrations leads to depletion of numerous Cys-rich cytoplasmic proteins in the proteome of B. subtilis. Mass spectrometry and immunoblot analyses demonstrated that these BQ-depleted proteins represent irreversibly damaged BQ aggregates that escape the two-dimensional gel separation. This enabled us to quantify the depletion of thiol-containing proteins which are the in vivo targets for thiol-(S)-alkylation by toxic quinone compounds. Metabolomic approaches confirmed that protein depletion is accompanied by depletion of the low-molecular-weight (LMW) thiol cysteine. Finally, no increased formation of disulphide bonds was detected in the thiol-redox proteome in response to sublethal quinone concentrations. The glyceraldehyde-3-phosphate dehydrogenase (GapA) was identified as the only new target for reversible thiol modifications after exposure to toxic quinones. Together our data show that the thiol-(S)-alkylation reaction with protein and non-protein thiols is the in vivo mechanism for thiol depletion and quinone toxicity in B. subtilis and most likely also in other bacteria.

Authors: Manuel Liebeke, Dierk-Christoph Pöther, Nguyen van Duy, Dirk Albrecht, Dörte Becher, Falko Hochgräfe, , , Haike Antelmann

Date Published: 30th Jul 2008

Publication Type: Not specified

Trigger enzymes: bifunctional proteins active in metabolism and in controlling gene expression

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All regulatory processes require components that sense the environmental or metabolic conditions of the cell, and sophisticated sensory proteins have been studied in great detail. During the last few years, it turned out that enzymes can control gene expression in response to the availability of their substrates. Here, we review four different mechanisms by which these enzymes interfere with regulation in bacteria. First, some enzymes have acquired a DNA-binding domain and act as direct transcription repressors by binding DNA in the absence of their substrates. A second class is represented by aconitase, which can bind iron responsive elements in the absence of iron to control the expression of genes involved in iron homoeostasis. The third class of these enzymes is sugar permeases of the phosphotransferase system that control the activity of transcription regulators by phosphorylating them in the absence of the specific substrate. Finally, a fourth class of regulatory enzymes controls the activity of transcription factors by inhibitory protein-protein interactions. We suggest that the enzymes that are active in the control of gene expression should be designated as trigger enzymes. An analysis of the occurrence of trigger enzymes suggests that the duplication and subsequent functional specialization is a major pattern in their evolution.

Authors: Fabian M Commichau,

Date Published: 11th Dec 2007

Publication Type: Not specified

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