Dominique Le Coq

The DNA sequence of the gene for the secreted Bacillus subtilis enzyme levansucrase and its genetic control sites

SummaryWe present the sequence of a 2 kb fragment of the Bacillus subtilis Marburg genome containing sacB, the structural gene of levansucrase, a secreted enzyme inducible by sucrose. The peptide sequence deduced for the secreted enzyme is very similar to that directly determined by Delfour (1981) for levansucrase of the non-Marburg strain BS5. The peptide sequence is preceded by a 29 amino acid signal peptide. Codon usage in sacB is rather different from that in the sequenced genes of other secreted enzymes in B. subtilis, especially α-amylase.Genetic evidence has shown that the sacB promotor is rather far from the beginning of sacB (200 bp or more). The 200 bp region preceding sacB shows some of the features of an attenuator. A preliminary discussion of the putative workings and roles of this attenuator-like structure is proposed. sacRc mutations, which allow constitutive expression of levansucrase, have been located within the 450 bp upstream of sacB. It is shown that sacRc and sacR+ alleles control in cis the expression of the adjacent sacB gene.

Multiple phosphorylation of SacY, a Bacillus subtilis transcriptional antiterminator negatively controlled by the phosphotransferase system.

The Bacillus subtilis SacY transcriptional antiterminator is a regulator involved in sucrose-promoted induction of the sacB gene. SacY activity is negatively controlled by enzyme I and HPr, the general energy coupling proteins of the phosphoenolpyruvate:sugar phosphotransferase system (PTS), and by SacX, a membranal protein homologous to SacP, theB. subtilis sucrose-specific PTS-permease. Previous studies suggested that the negative control exerted by the PTS on bacterial antiterminators of the SacY family involves phosphoenolpyruvate-dependent phosphorylation by the sugar-specific PTS-permeases. However, data reported herein show direct phosphorylation of SacY by HPr(His∼P) with no requirement for SacX. Experiments were carried out to determine the phosphorylatable residues in SacY. In silico analyses of SacY and its homologues revealed the modular structure of these proteins as well as four conserved histidines within two homologous domains (here designated P1 and P2), present in 14 distinct mRNA- and DNA-binding bacterial transcriptional regulators. Single or multiple substitutions of these histidyl residues were introduced in SacY by site-directed mutagenesis, and their effects on phosphorylation and antitermination activity were examined. In vitro phosphorylation experiments showed that SacY was phosphorylated on three of the conserved histidines. Nevertheless, in vivo studies using cells bearing asacB′-lacZ reporter fusion, as well as SacY mutants lacking the phosphorylatable histidyls, revealed that only His-99 is directly involved in regulation of SacY antitermination activity.

[Genetic analysis of sacB, the structural gene of a secreted enzyme, levansucrase of Bacillus subtilis Marburg].

The structural gene sacB encoding B. subtilis levansucrase, a secreted enzyme, expresses in E. coli. E. coli hosts of the sacB gene are poisoned by sucrose. This property allowed a powerful selection of mutants affected in the cloned gene. The plasmidic mutations were readily introduced in the B. subtilis chromosome. Using a collection of plasmids bearing various deletions extending in sacB we developed a technique of deletion mapping based on plasmid integration in the chromosome of B. subtilis. A generalization of this technique is discussed.

Crystal structure of an activated form of the PTS regulation domain from the LicT transcriptional antiterminator

The transcriptional antiterminator protein LicT regulates the expression of Bacillus subtilis operons involved in β‐glucoside metabolism. It belongs to a newly characterized family of bacterial regulators whose activity is controlled by the phosphoenolpyruvate:sugar phosphotransferase system (PTS). LicT contains an N‐terminal RNA‐binding domain (56 residues), and a PTS regulation domain (PRD, 221 residues) that is phosphorylated on conserved histidines in response to substrate availability. Replacement of both His207 and His269 with a negatively charged residue (aspartic acid) led to a highly active LicT variant that no longer responds to either induction or catabolite repression signals from the PTS. In contrast to wild type, the activated mutant form of the LicT regulatory domain crystallized easily and provided the first structure of a PRD, determined at 1.55 Å resolution. The structure is a homodimer, each monomer containing two analogous α‐helical domains. The phosphorylation sites are totally buried at the dimer interface and hence inaccessible to phosphorylating partners. The structure suggests important tertiary and quaternary rearrangements upon LicT activation, which could be communicated from the protein C‐terminal end up to the RNA‐binding domain.

Sites of positive and negative regulation in the Bacillus subtilis antiterminators LicT and SacY

The Bacillus subtilis homologous transcriptional antiterminators LicT and SacY control the inducible expression of genes involved in aryl β‐glucoside and sucrose utilization respectively. Their RNA‐binding activity is carried by the N‐terminal domain (CAT), and is regulated by two similar C‐terminal domains (PRD1 and PRD2), which are the targets of phosphorylation reactions catalysed by the phosphoenolpyruvate: sugar phosphotransferase system (PTS). In the absence of the corresponding inducer, LicT is inactivated by BglP, the PTS permease (EII) specific for aryl β‐glucosides, and SacY by SacX, a negative regulator homologous to the EII specific for sucrose. LicT, but not SacY, is also subject to a positive control by the general PTS components EI and HPr, which are thought to phosphorylate LicT in the absence of carbon catabolite repression. Construction of SacY/LicT hybrids and mutational analysis enabled the location of the sites of this positive regulation at the two phosphorylatable His207 and His269 within LicT‐PRD2, and suggested that the presence of negative charges at these sites is sufficient for LicT activation in vivo. The BglP‐mediated inhibition process was found to essentially involve His100 of LicT‐PRD1, with His159 of the same domain playing a minor role in this regulation. In vitro experiments indicated that His100 could be phosphorylated directly by the general PTS proteins, this phosphorylation being stimulated by P∼BglP. We confirmed that, similarly, the corresponding conserved His99 residue in SacY is the major site of the negative control exerted by SacX on SacY activity. Thus, for both antiterminators, the EII‐mediated inhibition process seems to rely primarily on the presence of a negative charge at the first conserved histidine of the PRD1.

Reconciling molecular regulatory mechanisms with noise patterns of bacterial metabolic promoters in induced and repressed states

Assessing gene expression noise in order to obtain mechanistic insights requires accurate quantification of gene expression on many individual cells over a large dynamic range. We used a unique method based on 2-photon fluorescence fluctuation microscopy to measure directly, at the single cell level and with single-molecule sensitivity, the absolute concentration of fluorescent proteins produced from the two Bacillus subtilis promoters that control the switch between glycolysis and gluconeogenesis. We quantified cell-to-cell variations in GFP concentrations in reporter strains grown on glucose or malate, including very weakly transcribed genes under strong catabolite repression. Results revealed strong transcriptional bursting, particularly for the glycolytic promoter. Noise pattern parameters of the two antagonistic promoters controlling the nutrient switch were differentially affected on glycolytic and gluconeogenic carbon sources, discriminating between the different mechanisms that control their activity. Our stochastic model for the transcription events reproduced the observed noise patterns and identified the critical parameters responsible for the differences in expression profiles of the promoters. The model also resolved apparent contradictions between in vitro operator affinity and in vivo repressor activity at these promoters. Finally, our results demonstrate that negative feedback is not noise-reducing in the case of strong transcriptional bursting.

13C-flux analysis reveals NADPH-balancing transhydrogenation cycles in stationary phase of nitrogen-starving Bacillus subtilis

Background: Metabolic pathway operation and NAPDH homeostasis in non-growing bacteria is unknown. Results: Jointly with known metabolic reactions newly discovered metabolic cycles balance the catabolic NADPH production. Conclusion: We propose the first quantitative NADPH balancing model under non-growing conditions. Significance: NADPH balancing is significantly different between resting and growing bacteria, reflecting microbial survival strategies during environmental challenges. In their natural habitat, microorganisms are typically confronted with nutritional limitations that restrict growth and force them to persevere in a stationary phase. Despite the importance of this phase, little is known about the metabolic state(s) that sustains it. Here, we investigate metabolically active but non-growing Bacillus subtilis during nitrogen starvation. In the absence of biomass formation as the major NADPH sink, the intracellular flux distribution in these resting B. subtilis reveals a large apparent catabolic NADPH overproduction of 5.0 ± 0.6 mmol·g−1·h−1 that was partly caused by high pentose phosphate pathway fluxes. Combining transcriptome analysis, stationary 13C-flux analysis in metabolic deletion mutants, 2H-labeling experiments, and kinetic flux profiling, we demonstrate that about half of the catabolic excess NADPH is oxidized by two transhydrogenation cycles, i.e. isoenzyme pairs of dehydrogenases with different cofactor specificities that operate in reverse directions. These transhydrogenation cycles were constituted by the combined activities of the glyceraldehyde 3-phosphate dehydrogenases GapA/GapB and the malic enzymes MalS/YtsJ. At least an additional 6% of the overproduced NADPH is reoxidized by continuous cycling between ana- and catabolism of glutamate. Furthermore, in vitro enzyme data show that a not yet identified transhydrogenase could potentially reoxidize ∼20% of the overproduced NADPH. Overall, we demonstrate the interplay between several metabolic mechanisms that concertedly enable network-wide NADPH homeostasis under conditions of high catabolic NADPH production in the absence of cell growth in B. subtilis.

Biofilms of a 'Bacillus subtilis' hospital isolate protect 'Staphylococcus aureus' from biocide action

The development of a biofilm constitutes a survival strategy by providing bacteria a protective environment safe from stresses such as microbicide action and can thus lead to important health-care problems. In this study, biofilm resistance of a Bacillus subtilis strain (called hereafter NDmedical) recently isolated from endoscope washer-disinfectors to peracetic acid was investigated and its ability to protect the pathogen Staphylococcus aureus in mixed biofilms was evaluated. Biocide action within Bacillus subtilis biofilms was visualised in real time using a non-invasive 4D confocal imaging method. The resistance of single species and mixed biofilms to peracetic acid was quantified using standard plate counting methods and their architecture was explored using confocal imaging and electronic microscopy. The results showed that the NDmedical strain demonstrates the ability to make very large amount of biofilm together with hyper-resistance to the concentration of PAA used in many formulations (3500 ppm). Evidences strongly suggest that the enhanced resistance of the NDmedical strain was related to the specific three-dimensional structure of the biofilm and the large amount of the extracellular matrix produced which can hinder the penetration of peracetic acid. When grown in mixed biofilm with Staphylococcus aureus, the NDmedical strain demonstrated the ability to protect the pathogen from PAA action, thus enabling its persistence in the environment. This work points out the ability of bacteria to adapt to an extremely hostile environment, and the necessity of considering multi-organism ecosystems instead of single species model to decipher the mechanisms of biofilm resistance to antimicrobials agents.

CcpN Controls Central Carbon Fluxes in Bacillus subtilis

The transcriptional regulator CcpN of Bacillus subtilis has been recently characterized as a repressor of two gluconeogenic genes, gapB and pckA, and of a small noncoding regulatory RNA, sr1, involved in arginine catabolism. Deletion of ccpN impairs growth on glucose and strongly alters the distribution of intracellular fluxes, rerouting the main glucose catabolism from glycolysis to the pentose phosphate (PP) pathway. Using transcriptome analysis, we show that during growth on glucose, gapB and pckA are the only protein-coding genes directly repressed by CcpN. By quantifying intracellular fluxes in deletion mutants, we demonstrate that derepression of pckA under glycolytic condition causes the growth defect observed in the ccpN mutant due to extensive futile cycling through the pyruvate carboxylase, phosphoenolpyruvate carboxykinase, and pyruvate kinase. Beyond ATP dissipation via this cycle, PckA activity causes a drain on tricarboxylic acid cycle intermediates, which we show to be the main reason for the reduced growth of a ccpN mutant. The high flux through the PP pathway in the ccpN mutant is modulated by the flux through the alternative glyceraldehyde-3-phosphate dehydrogenases, GapA and GapB. Strongly increased concentrations of intermediates in upper glycolysis indicate that GapB overexpression causes a metabolic jamming of this pathway and, consequently, increases the relative flux through the PP pathway. In contrast, derepression of sr1, the third known target of CcpN, plays only a marginal role in ccpN mutant phenotypes.

Pathogens protection against the action of disinfectants in multispecies biofilms.

Biofilms constitute the prevalent way of life for microorganisms in both natural and man-made environments. Biofilm-dwelling cells display greater tolerance to antimicrobial agents than those that are free-living, and the mechanisms by which this occurs have been investigated extensively using single-strain axenic models. However, there is growing evidence that interspecies interactions may profoundly alter the response of the community to such toxic exposure. In this paper, we propose an overview of the studies dealing with multispecies biofilms resistance to biocides, with particular reference to the protection of pathogenic species by resident surface flora when subjected to disinfectants treatments. The mechanisms involved in such protection include interspecies signaling, interference between biocides molecules and public goods in the matrix, or the physiology and genetic plasticity associated with a structural spatial arrangement. After describing these different mechanisms, we will discuss the experimental methods available for their analysis in the context of complex multispecies biofilms.