Your search keyword '"Commichau FM"' showing total 7 results

1. Aurantimycin resistance genes contribute to survival of Listeria monocytogenes during life in the environment.

Author

Hauf S, Herrmann J, Miethke M, Gibhardt J, Commichau FM, Müller R, Fuchs S, and Halbedel S

Subjects

Anti-Bacterial Agents pharmacology, Bacterial Proteins genetics, Gene Expression Regulation, Bacterial, Promoter Regions, Genetic, Streptomyces metabolism, Transcription Factors metabolism, ATP-Binding Cassette Transporters genetics, Depsipeptides pharmacology, Drug Resistance, Bacterial genetics, Listeria monocytogenes drug effects, Listeria monocytogenes genetics

Abstract

Bacteria can cope with toxic compounds such as antibiotics by inducing genes for their detoxification. A common detoxification strategy is compound excretion by ATP-binding cassette (ABC) transporters, which are synthesized upon compound contact. We previously identified the multidrug resistance ABC transporter LieAB in Listeria monocytogenes, a Gram-positive bacterium that occurs ubiquitously in the environment, but also causes severe infections in humans upon ingestion. Expression of the lieAB genes is strongly induced in cells lacking the PadR-type transcriptional repressor LftR, but compounds leading to relief of this repression in wild-type cells were not known. Using RNA-Seq and promoter-lacZ fusions, we demonstrate highly specific repression of the lieAB and lftRS promoters through LftR. Screening of a natural compound library yielded the depsipeptide aurantimycin A - synthesized by the soil-dwelling Streptomyces aurantiacus - as the first known naturally occurring inducer of lieAB expression. Genetic and phenotypic experiments concordantly show that aurantimycin A is a substrate of the LieAB transporter and thus, lftRS and lieAB represent the first known genetic module conferring and regulating aurantimycin A resistance. Collectively, these genes may support the survival of L. monocytogenes when it comes into contact with antibiotic-producing bacteria in the soil., (© 2019 John Wiley & Sons Ltd.)

Published

2019

2. ThrR, a DNA-binding transcription factor involved in controlling threonine biosynthesis in Bacillus subtilis.

Author

Rosenberg J, Müller P, Lentes S, Thiele MJ, Zeigler DR, Tödter D, Paulus H, Brantl S, Stülke J, and Commichau FM

Subjects

Aspartic Acid metabolism, Bacillus subtilis genetics, Base Sequence, Carbon-Oxygen Lyases metabolism, DNA genetics, DNA-Binding Proteins metabolism, Escherichia coli genetics, Genes, Bacterial, Mutation, Operon, Promoter Regions, Genetic, Threonine metabolism, Threonine Dehydratase genetics, Transcription Factors genetics, Bacillus subtilis metabolism, Threonine biosynthesis, Threonine Dehydratase metabolism

Abstract

The threonine dehydratase IlvA is part of the isoleucine biosynthesis pathway in the Gram-positive model bacterium Bacillus subtilis. Consequently, deletion of ilvA causes isoleucine auxotrophy. It has been reported that ilvA pseudo-revertants having a derepressed hom-thrCB operon appear in the presence of threonine. Here we have characterized two classes of ilvA pseudo-revertants. In the first class the hom-thrCB operon was derepressed unmasking the threonine dehydratase activity of the threonine synthase ThrC. In the second class of mutants, threonine biosynthesis was more broadly affected. The first class of ilvA pseudo-revertants had a mutation in the Phom promoter (P*hom ), resulting in constitutive expression of the hom-thrCB operon. In the second class of ilvA pseudo-revertants, the thrR gene encoding a putative DNA-binding protein was inactivated, also resulting in constitutive expression of the hom-thrCB operon. Here we demonstrate that ThrR is indeed a DNA-binding transcription factor that regulates the hom-thrCB operon and the thrD aspartokinase gene. DNA binding assays uncovered the DNA-binding site of ThrR and revealed that the repressor competes with the RNA polymerase for DNA binding. This study also revealed that ThrR orthologs are ubiquitous in genomes from the Gram-positive phylum Firmicutes and in some Gram-negative bacteria., (© 2016 John Wiley & Sons Ltd.)

Published

2016

3. Salt-sensitivity of σ(H) and Spo0A prevents sporulation of Bacillus subtilis at high osmolarity avoiding death during cellular differentiation.

Author

Widderich N, Rodrigues CD, Commichau FM, Fischer KE, Ramirez-Guadiana FH, Rudner DZ, and Bremer E

Subjects

DNA-Directed RNA Polymerases metabolism, Gene Expression Regulation, Bacterial, Mutation, Promoter Regions, Genetic, Protein Binding, Salinity, Transcription Factors genetics, Transcription Factors metabolism, Bacillus subtilis physiology, Bacterial Proteins genetics, Bacterial Proteins metabolism, Osmolar Concentration, Salt Tolerance genetics, Spores, Bacterial

Abstract

The spore-forming bacterium Bacillus subtilis frequently experiences high osmolarity as a result of desiccation in the soil. The formation of a highly desiccation-resistant endospore might serve as a logical osmostress escape route when vegetative growth is no longer possible. However, sporulation efficiency drastically decreases concomitant with an increase in the external salinity. Fluorescence microscopy of sporulation-specific promoter fusions to gfp revealed that high salinity blocks entry into the sporulation pathway at a very early stage. Specifically, we show that both Spo0A- and SigH-dependent transcription are impaired. Furthermore, we demonstrate that the association of SigH with core RNA polymerase is reduced under these conditions. Suppressors that modestly increase sporulation efficiency at high salinity map to the coding region of sigH and in the regulatory region of kinA, encoding one the sensor kinases that activates Spo0A. These findings led us to discover that B. subtilis cells that overproduce KinA can bypass the salt-imposed block in sporulation. Importantly, these cells are impaired in the morphological process of engulfment and late forespore gene expression and frequently undergo lysis. Altogether our data indicate that B. subtilis blocks entry into sporulation in high-salinity environments preventing commitment to a developmental program that it cannot complete., (© 2015 John Wiley & Sons Ltd.)

Published

2016

4. A jack of all trades: the multiple roles of the unique essential second messenger cyclic di-AMP.

Author

Commichau FM, Dickmanns A, Gundlach J, Ficner R, and Stülke J

Subjects

Bacteria enzymology, Bacteria metabolism, Bacterial Proteins metabolism, Phosphoric Diester Hydrolases metabolism, Pyruvate Carboxylase metabolism, Riboswitch, Dinucleoside Phosphates metabolism, Second Messenger Systems

Abstract

Second messengers are key components of many signal transduction pathways. In addition to cyclic AMP, ppGpp and cyclic di-GMP, many bacteria use also cyclic di-AMP as a second messenger. This molecule is synthesized by distinct classes of diadenylate cyclases and degraded by phosphodiesterases. The control of the intracellular c-di-AMP pool is very important since both a lack of this molecule and its accumulation can inhibit growth of the bacteria. In many firmicutes, c-di-AMP is essential, making it the only known essential second messenger. Cyclic di-AMP is implicated in a variety of functions in the cell, including cell wall metabolism, potassium homeostasis, DNA repair and the control of gene expression. To understand the molecular mechanisms behind these functions, targets of c-di-AMP have been identified and characterized. Interestingly, c-di-AMP can bind both proteins and RNA molecules. Several proteins that interact with c-di-AMP are required to control the intracellular potassium concentration. In Bacillus subtilis, c-di-AMP also binds a riboswitch that controls the expression of a potassium transporter. Thus, c-di-AMP is the only known second messenger that controls a biological process by interacting with both a protein and the riboswitch that regulates its expression. Moreover, in Listeria monocytogenes c-di-AMP controls the activity of pyruvate carboxylase, an enzyme that is required to replenish the citric acid cycle. Here, we review the components of the c-di-AMP signaling system., (© 2015 John Wiley & Sons Ltd.)

Published

2015

5. Control of glutamate homeostasis in Bacillus subtilis: a complex interplay between ammonium assimilation, glutamate biosynthesis and degradation.

Author

Gunka K and Commichau FM

Subjects

Bacillus subtilis enzymology, Bacillus subtilis genetics, Gene Expression Regulation, Bacterial, Gene Expression Regulation, Enzymologic, Metabolic Networks and Pathways genetics, Models, Biological, Bacillus subtilis metabolism, Glutamic Acid metabolism, Homeostasis, Quaternary Ammonium Compounds metabolism

Abstract

Glutamate, the major amino group donor in anabolism, is synthesized by the combined action of the glutamine synthetase (GS) and the glutamate synthase (GOGAT) in Bacillus subtilis. The glutamate dehydrogenase (GDH) exclusively degrades glutamate. GS and GDH are both trigger enzymes, active in nitrogen metabolism and in controlling gene expression. Feedback-inhibited GS (FBI-GS) controls DNA-binding activities of two transcription factors, the repressor GlnR and TnrA, the global regulator of nitrogen metabolism. FBI-GS binds to and activates GlnR. This protein complex inhibits GS formation and thus glutamine synthesis. Moreover, FBI-GS inhibits DNA-binding activity of TnrA. Glutamate biosynthesis, the reaction linking carbon with nitrogen metabolism, is controlled by GDH. Together with glutamate GDH inhibits GltC, the transcription factor that activates expression of the GOGAT genes. Thus, GS and GDH control glutamine and glutamate synthesis, respectively, depending on the nitrogen status of the cell. B. subtilis lacking a functional GDH show a severe growth defect. Interestingly, the growth defect is suppressed by the rapid activation of an inactive GDH. Thus, maintenance of glutamate homeostasis is crucial for cellular vitality. This review covers the recent work on the complex control of glutamine and glutamate metabolism in the Gram-positive model organism B. subtilis., (© 2012 Blackwell Publishing Ltd.)

Published

2012

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

Author

Commichau FM and Stülke J

Subjects

Bacteria genetics, Bacteria metabolism, Metabolic Networks and Pathways, Phosphorylation, Repressor Proteins metabolism, Signal Transduction, Bacteria enzymology, Bacterial Proteins metabolism, Enzymes metabolism, Gene Expression Regulation, Bacterial, Transcription Factors metabolism

Abstract

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.

Published

2008

7. A regulatory protein-protein interaction governs glutamate biosynthesis in Bacillus subtilis: the glutamate dehydrogenase RocG moonlights in controlling the transcription factor GltC.

Author

Commichau FM, Herzberg C, Tripal P, Valerius O, and Stülke J

Subjects

Bacterial Proteins isolation & purification, Base Sequence, Glutamate Dehydrogenase isolation & purification, Models, Biological, Molecular Sequence Data, Mutation genetics, Operon genetics, Promoter Regions, Genetic genetics, Protein Binding, Recombinant Fusion Proteins metabolism, Repressor Proteins isolation & purification, Trans-Activators isolation & purification, Bacillus subtilis enzymology, Bacterial Proteins metabolism, Glutamate Dehydrogenase metabolism, Glutamic Acid biosynthesis, Repressor Proteins metabolism, Trans-Activators metabolism

Abstract

Glutamate synthesis is the link between carbon and nitrogen metabolism. In Bacillus subtilis, glutamate is exclusively synthesized by the glutamate synthase encoded by the gltAB operon. The glutamate dehydrogenase RocG from B. subtilis is exclusively devoted to glutamate degradation rather than to its synthesis. The expression of the gltAB operon is induced by glucose and ammonium and strongly repressed by arginine. Regulation by glucose and arginine depends on the transcriptional activator protein GltC. The gltAB operon is constitutively expressed in a rocG mutant strain, but the molecular mechanism of negative control of gltAB expression by RocG has so far remained unknown. We studied the role of RocG in the intracellular accumulation of GltC. Furthermore, we considered the possibility that RocG might act as a transcription factor and be able to inhibit the expression of gltAB either by binding to the mRNA or to the promoter region of the gltAB operon. Finally, we asked whether a direct binding of RocG to GltC could be responsible for the inhibition of GltC. The genetic and biochemical data presented here show that the glutamate dehydrogenase RocG is able to bind to and concomitantly inactivate the activator protein GltC. This regulatory mechanism by the bifunctional enzyme RocG allows the tight control of glutamate metabolism by the availability of carbon and nitrogen sources.

Published

2007