[Epidemiology of Streptococcus pyogenes invasive diseases in France (2007-2011)]

Group A Streptococcus (GAS) is a human pathogen responsible for a wide range of clinical manifestations. An increase of GAS invasive infections has been described since the mid 1980s. To study the French epidemiology of invasive infections (i) we characterized all GAS invasive strains received at the French National Reference Center for streptococci (CNR-Strep) between 2007 and 2011; (ii) we analyzed the epidemiological data on the corresponding strains. For each strain, emm genotype, superantigen genes and antibiotics susceptibility were determined. Among the 2 603 non redundant invasive GAS strains, 65.1 % (n=1 695) were isolated from blood culture. A streptococcal toxic shock syndrome (STSS) was described in 16.4 % (n=428) of cases, mostly associated with necrotizing fasciitis (NF), pleuropulmonary or osteoarticular infections (p ≤0.001). The case fatality rate was 10.6 %. A total of 102 different emm genotypes were identified. Three emm genotypes predominated, reaching nearly 60 % of the strains: emm 1 (26.7 %), emm 28 (16.4 %), and emm 89 (12.8 %). The proportion of each emm genotype varied according to the year and the age of patients. Among those < 15 years old, the three main genotypes were emm 1 (36.8 %), emm 12 (12.9 %) and emm 4 (9.5 %). The distribution of superantigen genes (SpeA, SpeC and Ssa) was restricted to several emm genotypes. Between 2007 and 2011, the rate of macrolides resistant GAS strains decreased from 7.8 to 5.5 %. emm 1 strains are still the most common especially in most severe clinical manifestations including STSS and NF.

Bacillus anthracis cell envelope components

Bacillus anthracis is a Gram-positive bacterium harboring a complex parietal architecture. The cytoplasmic membrane is surrounded by a thick peptidoglycan of the A1 gamma type. Only one associated polymer, a polysaccharide composed of galactose, N-acetylglucosamine, and N-acetylmannosamine, is covalently linked to the peptidoglycan. Outside the cell wall is an S-layer. Two proteins can each compose the S-layer. They are noncovalently anchored to the cell wall polysaccharide by their SLH N-terminal domain. The poly-gamma-D-glutamate capsule, which covers the S-layer, has an antiphagocytic role and its synthesis is dependent on environmental factors mimicking the mammalian host, such as bicarbonate and a temperature of 37 degrees C.

Anthrax

Bacillus anthracis was shown to be the etiological agent of anthrax by R. Koch and L. Pasteur at the end of the nineteenth century. The concepts on which medical microbiology are based arose from their work on this bacterium. The link between plasmids and major virulence factors of B. anthracis was not discovered until the 1980s. The three toxin components are organized in two A-B type toxins, and the bacilli are covered by an antiphagocytic polyglutamic capsule. Structure-function analysis of the toxins indicated that the common B-domain binds to a ubiquitous cell receptor and forms a heptamer after proteolytic activation. One enzyme moiety is an adenylate cyclase and the other is a Zn(2+) metalloprotease, which is able to cleave MAPKKs. The capsule covers an S-layer sequentially composed of two distinct proteins. Knowledge of the toxins facilitates the design of safer veterinary vaccines. Spore-structure analysis could contribute to the improvement of human nonliving vaccines. The phylogeny of B. anthracis within the Bacillus cereus group is also reviewed.

The incompatibility between the PlcR- and AtxA-controlled regulons may have selected a nonsense mutation in Bacillus anthracis

Bacillus anthracis, Bacillus thuringiensis and Bacillus cereus are members of the Bacillus cereus group. These bacteria express virulence in diverse ways in mammals and insects. The pathogenic properties of B. cereus and B. thuringiensis in mammals results largely from the secretion of non-specific toxins, including haemolysins, the production of which depends upon a pleiotropic activator PlcR. In B. anthracis, PlcR is inactive because of a nonsense mutation in the plcR gene. This suggests that the phenotypic differences between B. anthracis on the one hand and B. thuringiensis and B. cereus on the other could result at least partly from loss of the PlcR regulon. We expressed a functional PlcR in B. anthracis. This resulted in the transcriptional activation of genes weakly expressed in the absence of PlcR. The transcriptional activation correlated with the induction of enzymatic activities and toxins including haemolysins. The toxicity of a B. anthracis PlcR+ strain was assayed in the mouse subcutaneous and nasal models of infection. It was no greater than that of the parental strain, suggesting that the PlcR regulon has no influence on B. anthracis virulence. The PlcR regulon had dramatic effects on the sporulation of a B. anthracis strain containing the virulence plasmid pXO1. This resulted from incompatible interactions with the major AtxA-controlled virulence regulon. We propose that the PlcR-controlled regulon in B. anthracis has been counterselected on account of its disadvantageous effects.

Distribution of S-layers on the surface of Bacillus cereus strains: phylogenetic origin and ecological pressure

Bacillus anthracis, Bacillus cereus and Bacillus thuringiensis have been described as members of the Bacillus cereus group but are, in fact, one species. B. anthracis is a mammal pathogen, B. thuringiensis an entomopathogen and B. cereus a ubiquitous soil bacterium and an occasional human pathogen. In two clinical isolates of B. cereus, in some B. thuringiensis strains and in B. anthracis, an S-layer has been described. We investigated how the S-layer is distributed in B. cereus, and whether phylogeny or ecology could explain its presence on the surface of some but not all strains. We first developed a simple biochemical assay to test for the presence of the S-layer. We then used the assay with 51 strains of known genetic relationship: 26 genetically diverse B. cereus and 25 non-B. anthracis of the B. anthracis cluster. When present, the genetic organization of the S-layer locus was analysed further. It was identical in B. cereus and B. anthracis. Nineteen strains harboured an S-layer, 16 of which belonged to the B. anthracis cluster. All 19 were B. cereus clinical isolates or B. thuringiensis, except for one soil and one dairy strain. These findings suggest a common phylogenetic origin for the S-layer at the surface of B. cereus strains and, presumably, ecological pressure on its maintenance.

Characterization of a plasmid region involved in Bacillus anthracis toxin production and pathogenesis

The germination of spores within the host is the initial step of anthrax infection. We have shown, using immunofluorescence staining, confocal scanning laser microscopy and image cytometry analysis, that the alveolar macrophage is the primary site of B. anthracis germination in a murine inhalation infection model. B. anthracis germinated inside macrophages, in vesicles derived from the phagosomal compartment. We have demonstrated that the toxin genes and their trans-activator, AtxA, are expressed within the macrophages after germination. It was also shown that the pXO1 plasmid strongly enhanced capsule formation and that this influence is mediated by AtxA. This indicates the existence of a regulon where AtxA is the regulatory protein acting on genes located on different plasmids. We identified a tricistronic germination operon gerX located between the pag and atxA genes on the 40-kb toxin-encoding fragment of pXO1 . Analysis of a gerX null mutant indicated that gerX-encoded proteins are involved in the virulence of B. anthracis.

Bacterial SLH domain proteins are non-covalently anchored to the cell surface via a conserved mechanism involving wall polysaccharide pyruvylation

Several bacterial proteins are non-covalently anchored to the cell surface via an S-layer homology (SLH) domain. Previous studies have suggested that this cell surface display mechanism involves a non-covalent interaction between the SLH domain and peptidoglycan-associated polymers. Here we report the characterization of a two-gene operon, csaAB, for cell surface anchoring, in Bacillus anthracis. Its distal open reading frame (csaB) is required for the retention of SLH-containing proteins on the cell wall. Biochemical analysis of cell wall components showed that CsaB was involved in the addition of a pyruvyl group to a peptidoglycan-associated polysaccharide fraction, and that this modification was necessary for binding of the SLH domain. The csaAB operon is present in several bacterial species that synthesize SLH-containing proteins. This observation and the presence of pyruvate in the cell wall of the corresponding bacteria suggest that the mechanism described in this study is widespread among bacteria.

Characterization of the operon encoding the alternative sigma(B) factor from Bacillus anthracis and its role in virulence

The operon encoding the general stress transcription factor sigma(B) and two proteins of its regulatory network, RsbV and RsbW, was cloned from the gram-positive bacterium Bacillus anthracis by PCR amplification of chromosomal DNA with degenerate primers, by inverse PCR, and by direct cloning. The gene cluster was very similar to the Bacillus subtilis sigB operon both in the primary sequences of the gene products and in the order of its three genes. However, the deduced products of sequences upstream and downstream from this operon showed no similarity to other proteins encoded by the B. subtilis sigB operon. Therefore, the B. anthracis sigB operon contains three genes rather than eight as in B. subtilis. The B. anthracis operon is preceded by a sigma(B)-like promoter sequence, the expression of which depends on an intact sigma(B) transcription factor in B. subtilis. It is followed by another open reading frame that is also preceded by a promoter sequence similarly dependent on B. subtilis sigma(B). We found that in B. anthracis, both these promoters were induced during the stationary phase and induction required an intact sigB gene. The sigB operon was induced by heat shock. Mutants from which sigB was deleted were constructed in a toxinogenic and a plasmidless strain. These mutants differed from the parental strains in terms of morphology. The toxinogenic sigB mutant strain was also less virulent than the parental strain in the mouse model. B. anthracis sigma(B) may therefore be a minor virulence factor.

Bacillus anthracis, Bacillus cereus, and Bacillus thuringiensis--one species on the basis of genetic evidence

Bacillus anthracis, Bacillus cereus, and Bacillus thuringiensis are members of the Bacillus cereus group of bacteria, demonstrating widely different phenotypes and pathological effects. B. anthracis causes the acute fatal disease anthrax and is a potential biological weapon due to its high toxicity. B. thuringiensis produces intracellular protein crystals toxic to a wide number of insect larvae and is the most commonly used biological pesticide worldwide. B. cereus is a probably ubiquitous soil bacterium and an opportunistic pathogen that is a common cause of food poisoning. In contrast to the differences in phenotypes, we show by multilocus enzyme electrophoresis and by sequence analysis of nine chromosomal genes that B. anthracis should be considered a lineage of B. cereus. This determination is not only a formal matter of taxonomy but may also have consequences with respect to virulence and the potential of horizontal gene transfer within the B. cereus group.

Cell surface-exposed tetanus toxin fragment C produced by recombinant Bacillus anthracis protects against tetanus toxin

Bacillus anthracis, the causal agent of anthrax, synthesizes two surface layer (S-layer) proteins, EA1 and Sap, which account for 5 to 10% of total protein and are expressed in vivo. A recombinant B. anthracis strain was constructed by integrating into the chromosome a translational fusion harboring the DNA fragments encoding the cell wall-targeting domain of the S-layer protein EA1 and tetanus toxin fragment C (ToxC). This construct was expressed under the control of the promoter of the S-layer component gene. The hybrid protein was stably expressed on the cell surface of the bacterium. Mice were immunized with bacilli of the corresponding strain, and the hybrid protein elicited a humoral response to ToxC. This immune response was sufficient to protect mice against tetanus toxin challenge. Thus, the strategy developed in this study may make it possible to generate multivalent live veterinary vaccines, using the S-layer protein genes as a cell surface display system.

Bacillus anthracis surface: capsule and S-layer

Two abundant surface proteins, EA1 and Sap, are components of the Bacillus anthracis surface layer (S-layer). Their corresponding genes have been cloned, shown to be clustered on the chromosome and sequenced. EA1 and Sap each possess three 'S-layer homology' motifs. Single and double disrupted mutants were constructed. EA1 and Sap were co-localized at the cell surface of both the non-capsulated and capsulated bacilli. When present, the capsule is exterior to, and completely covers, the S-layer proteins, which form an array beneath it. Nevertheless, the presence of these proteins is not required for normal capsulation of the bacilli. Thus both structures are compatible, and yet neither is required for the correct formation of the other. Bacillus anthracis has, therefore, a very complex cell wall organization for a gram-positive bacterium.

The S-layer homology domain as a means for anchoring heterologous proteins on the cell surface of Bacillus anthracis

Bacillus anthracis synthesizes two S-layer proteins, each containing three S-layer homology (SLH) motifs towards their amino-terminus. In vitro experiments suggested that the three motifs of each protein were organized as a structural domain sufficient to bind purified cell walls. Chimeric genes encoding the SLH domains fused to the levansucrase of Bacillus subtilis were constructed and integrated on the chromosome. Cell fractionation and electron microscopy studies showed that both heterologous polypeptides were targeted to the cell surface. In addition, surface-exposed levansucrase retained its enzymatic and antigenic properties. Preliminary results concerning applications of this work are presented.

Co-existence of clpB and clpC in the Bacillaceae

The gene encoding ClpC in Bacillus anthracis was amplified from the chromosome by polymerase chain reaction using degenerate oligonucleotide primers. These primers also amplified a second DNA fragment identified as a clpB homolog. Both genes were suggested to be functional. Contrary to Bacillus subtilis which possesses clpC but not clpB, many Bacillus species were found to harbor both clpC and clpB. We also found that Clostridium strains could possess clpB, clpC, or both. All the Gram-negative strains tested had clpB only.

Production and cell surface anchoring of functional fusions between the SLH motifs of the Bacillus anthracis S-layer proteins and the Bacillus subtilis levansucrase

Many surface proteins of Gram-positive bacteria contain motifs, about 50 amino acids long, called S-layer homology (SLH) motifs. Bacillus anthracis, the causal agent of anthrax, synthesizes two S-layer proteins, each with three SLH motifs towards the amino-terminus. We used biochemical and genetic approaches to investigate the involvement of these motifs in cell surface anchoring. Proteinase K digestion produced polypeptides lacking these motifs, and stable three-motif polypeptides were produced in Escherichia coli that were able to bind the B. anthracis cell walls in vitro, demonstrating that the three SLH motifs were organized into a cell surface anchoring domain. We also determined the function of these SLH domains by constructing chimeric genes encoding the SLH domains fused to the normally secreted levansucrase of Bacillus subtilis. Cell fractionation and electron microscopy studies showed that each three-motif domain was sufficient for the efficient anchoring of levansucrase onto the cell surface. Proteins consisting of truncated SLH domains fused to levansucrase were unstable and associated poorly with the cell surface. Surface-exposed levansucrase retained its enzymatic and antigenic properties.

The capsule and S-layer: two independent and yet compatible macromolecular structures in Bacillus anthracis

Bacillus anthracis, the etiological agent of anthrax, is a gram-positive spore-forming bacterium. Fully virulent bacilli are toxinogenic and capsulated. Two abundant surface proteins, including the major antigen, are components of the B. anthracis surface layer (S-layer). The B. anthracis paracrystalline S-layer has previously only been found in noncapsulated vegetative cells. Here we report that the S-layer proteins are also synthesized under conditions where the poly-gamma-D-glutamic acid capsule is present. Structural and immunological analyses show that the capsule is exterior to and completely covers the S-layer proteins. Nevertheless, analysis of single and double S-layer protein mutants shows that the presence of these proteins is not required for normal capsulation of the bacilli. Similarly, the S-layer proteins assemble as a two-dimensional crystal, even in the presence of the capsule. Thus, both structures are compatible, and yet neither is required for the correct formation of the other.

Molecular biology of S-layers

In this chapter we report on the molecular biology of crystalline surface layers of different bacterial groups. The limited information indicates that there are many variations on a common theme. Sequence variety, antigenic diversity, gene expression, rearrangements, influence of environmental factors and applied aspects are addressed. There is considerable variety in the S-layer composition, which was elucidated by sequence analysis of the corresponding genes. In Corynebacterium glutamicum one major cell wall protein is responsible for the formation of a highly ordered, hexagonal array. In contrast, two abundant surface proteins from the S-layer of Bacillus anthracis. Each protein possesses three S-layer homology motifs and one protein could be a virulence factor. The antigenic diversity and ABC transporters are important features, which have been studied in methanogenic archaea. The expression of the S-layer components is controlled by three genes in the case of Thermus thermophilus. One has repressor activity on the S-layer gene promoter, the second codes for the S-layer protein. The rearrangement by reciprocal recombination was investigated in Campylobacter fetus. 7-8 S-layer proteins with a high degree of homology at the 5' and 3' ends were found. Environmental changes influence the surface properties of Bacillus stearothermophilus. Depending on oxygen supply, this species produces different S-layer proteins. Finally, the molecular bases for some applications are discussed. Recombinant S-layer fusion proteins have been designed for biotechnology.

Molecular characterization of the Bacillus anthracis main S-layer component: evidence that it is the major cell-associated antigen

Bacillus anthracis, the aetiological agent of anthrax, is a Gram-positive spore-forming bacterium. The cell wall of vegetative cells of B. anthracis is surrounded by an S-layer. An array remained when sap, a gene described as encoding an S-layer component, was deleted. The remaining S-layer component, termed EA1, is chromosomally encoded. The gene encoding EA1 (eag) was obtained on two overlapping fragments in Escherichia coli and shown to be continuous to the sap gene. The EA1 amino acid sequence, deduced from the eag nucleotide sequence, shows classical S-layer protein features (no cysteine, only 0.1% methionine, 10% lysine, and a weakly acidic pl). Similar to Sap and other Gram-positive surface proteins, EA1 has three 'S-layer-homology' motifs immediately downstream from a signal peptide. Single- and double-disrupted mutants were constructed. EA1 and Sap were co-localized at the cell surface of the wild-type bacilli. However, EA1 was more tightly bound than Sap to the bacteria. Electron microscopy studies and in vivo experiments with the constructed mutants showed that EA1 constitutes the main lattice of the B. anthracis S-layer, and is the major cell-associated antigen.

AtxA activates the transcription of genes harbored by both Bacillus anthracis virulence plasmids

Fully virulent Bacillus anthracis bacilli are encapsulated and toxinogenic. These bacteria carry two plasmids, pXO1, and pXO2, encoding toxins and capsule synthetic-enzymes (capB, C, A, dep), respectively. The PXO1 plasmid strongly enhances capsule formation. This influence was studied by analysing the expression of a capB-lacZ fusion in various backgrounds. The beta-galactosidase activities were similar in a delta atxA strain and a pXO1 cured strain. Moreover, the capB-lacZ expression level could be restored, in a pXO1 cured strain, by addition of atxA in trans. Thus, we conclude that the pX01 influence on capsule synthesis is mediated by AtxA, the pXO1-encoded trans-activator of the toxin gene expression.

Differential influence of the two Bacillus anthracis plasmids on regulation of virulence gene expression

Fully virulent Bacillus anthracis bacilli are encapsulated and toxinogenic. These bacteria contain two plasmids, pXO1 and pXO2, carrying genes coding for toxins (pag, lef, and cya) and for capsule synthetic enzymes (capB, capC, capA, and dep), respectively. A transcriptional fusion between the capB regulatory region and the lacZ reporter gene was constructed to study the regulation of capsule synthesis. A single copy of this fusion was inserted into the cap region of pXO2. The influence of environmental factors on the capB-lacZ fusion expression was initially analyzed in a pXO1-negative background: bicarbonate but not temperature induced the transcription from the capB promoter. A strain carrying the recombinant pXO2 and (delta)pag pXO1 was constructed for transregulatory studies. The pXO1 plasmid strongly enhanced capsule formation without modifying the bicarbonate-dependent induction level. A (delta)cap pXO2 was transduced into a strain containing pXO1 harboring a pag-lacZ transcriptional fusion (19). pXO2 showed no influence on the toxin gene transcription.

Molecular tools for the study of transcriptional regulation in Bacillus anthracis

Bacillus anthracis produces two toxins composed of three proteins. Genetic tools were constructed to study the regulation of toxin synthesis. They included transcriptional fusions with various reporter genes, in replicative and integrative vectors. The reporter gene xylE, encoding catechol 2,3-dioxygenase, may be valuable for screening of strong promoters, as expression of the gene can be visualized directly and the studies of regulation in B. anthracis. Therefore, transcriptional fusions between a lacZ reporter gene and the toxin genes were constructed. Experiments with a multicopy plasmid in trans suggested that the transcriptional activator(s) of the toxin genes were not titrated. B. anthracis strains, which contain pXO1 carrying multiple copies of fusions, were analysed. Expression of the reporter gene was proportional to the fusion copy number. Indeed, single integration of a suicide plasmid can be distinguished from multiple integration according to the level of resistance to an appropriate antibiotic. Finally, recombination in B. anthracis was found to be very efficient (approximately 10(-2) recombinants per transconjugant cell.

Characterization of the Bacillus anthracis S-layer: cloning and sequencing of the structural gene

Bacillus anthracis, a gram-positive, spore-forming bacterium, is the etiological agent of anthrax. The gene coding for the S-layer protein (sap) was cloned on two contiguous fragments in Escherichia coli, and the complete sequence of the structural gene was determined. The protein, Sap, is composed of 814 residues, including a classical prokaryotic 29-amino-acid signal peptide. The mature form has a calculated molecular mass of 83.7 kDa and a molecular mass of 94 kDa on a sodium dodecyl sulfate-polyacrylamide gel. Sap possesses many charged residues, is weakly acidic, and contains only 0.9% methionine and no cysteine residues. The N-terminal region of Sap shares sequence similarities with the Acetogenium kivui S-layer protein, the Bacillus brevis middle wall protein, the Thermotoga maritima Omp alpha protein, and the Bacillus thuringiensis S-layer protein. Electron microscopy observations showed that this S-layer is not observed on B. anthracis cells in which sap has been deleted.

The three Bacillus anthracis toxin genes are coordinately regulated by bicarbonate and temperature

The two Bacillus anthracis toxins are composed of three proteins, protective antigen, lethal factor, and edema factor. The structural genes for these three components are located on the virulence plasmid pXO1. We constructed transcriptional fusions between the regulatory region of each of these genes and lacZ. Each construct was then inserted as a single copy at the corresponding toxin gene locus on pXO1, resulting in three isogenic strains. Two environmental factors, bicarbonate and temperature, were found to induce beta-galactosidase synthesis in each recombinant strain. Furthermore, the transcription of the three toxin genes appears to be coordinately regulated.

Bacillus anthracis pXO1 virulence plasmid encodes a type 1 DNA topoisomerase

The virulence plasmid pXO1 is responsible for toxin production in Bacillus anthracis. A DNA fragment from pXO1 was isolated and was shown, by sequence analysis, to contain part of a type 1 DNA topoisomerase gene. Attempts to clone the entire wild-type gene, designated topX, in Escherichia coli, were unsuccessful. In order to obtain the complete gene, it was first insertionally inactivated and then cloned in the mutated form. The deduced amino acid sequence of Topo X1 shows similarities to that of the two E. coli type 1 DNA topoisomerases. The N-terminal two-thirds of the putative B. anthracis protein exhibits strongest sequence similarity to topoisomerase III, whereas the C-terminal portion contains cysteine residues that could form three zinc-binding domains, as they do in topoisomerase I. The suggested active-site tyrosine is conserved in all three proteins. The regulation of expression from the topX promoter is modified by addition of a gyrase inhibiting antibiotic. The Topo X1 protein is likely to be involved in the stability of pXO1.

Regulation of pag gene expression in Bacillus anthracis: use of a pag-lacZ transcriptional fusion

The production of protective antigen (PA), the common component of the two anthrax toxins, is influenced by the environment. In order to examine factors involved in its regulation, a transcriptional fusion between the promoter region of the PA gene (pag) and the lacZ gene was constructed and introduced into Bacillus anthracis Sterne. Activity of the pag promoter was followed by measuring beta-galactosidase activities under various growth and medium conditions. Expression from the pag promoter was observed throughout exponential-phase and was maximal in early stationary phase. The activity of the pag promoter was stimulated by the addition of glucose in the medium.

Multiple regulatory sites in the Bacillus subtilis citB promoter region

The aconitase (citB) gene of Bacillus subtilis is repressed during growth in a medium that contains a rapidly metabolizable carbon source and a source of 2-ketoglutarate. It is derepressed when either of these nutrient sources becomes limiting. Repression by rapidly metabolizable carbon sources was shown previously to depend at least in part on a DNA sequence located 67 to 84 base pairs upstream of the start point of citB transcription. In the present work, this region and surrounding DNA were mutagenized to identify more precisely the target for carbon catabolite repression. Mutations in a symmetric sequence located between positions -73 and -59 led to constitutive transcription from the citB promoter in media that normally provoke catabolite repression. By gel mobility shift assays, it was shown that at least one protein in extracts of B. subtilis binds to the symmetric sequence and that DNA of constitutive mutants binds to this protein much less effectively. A second sequence located near position -45 was also implicated in this regulation. A second form of regulation of citB was also investigated. This gene is known to be derepressed when cells are induced to sporulate by exhaustion of a nutrient broth medium or limitation of guanine nucleotide synthesis. The mutations that led to constitutivity with respect to the carbon source had no effect on citB expression in nutrient broth medium, indicating that control by catabolite repression and control by components of nutrient broth (presumably amino acids) act by different mechanisms.

The sacT gene regulating the sacPA operon in Bacillus subtilis shares strong homology with transcriptional antiterminators

The expression of the Bacillus subtilis sacPA operon is induced by sucrose. A DNA fragment containing the upstream region of this operon was cloned. This fragment contains a promoter from which the operon is expressed. This upstream region also contains a palindromic DNA sequence very similar to the transcriptional terminator which regulates the induction of the B. subtilis sacB gene. Of 37 nucleotides in a region partially overlapping the sacP palindromic sequence, 34 were identical to the corresponding region of the sacB gene. A similar motif is also present in the bgl operon of Escherichia coli. The sacT locus controlling sacPA expression had been identified by a single constitutive mutation sacT30 which mapped close to the sacPA operon. DNA fragments containing the sacT+ and sacT30 alleles were cloned and sequenced. The sacT gene product is very similar to the B. subtilis sacY and to the E. coli bglG gene products. The constitutive sacT30 mutation was identified. It corresponds to a Asp-96-to-Tyr missense mutation located in a highly conserved region in SacT and SacY. These results strongly suggest that sacT is a specific regulatory gene of the sacPA operon.

A target for carbon source-dependent negative regulation of the citB promoter of Bacillus subtilis

Expression of the aconitase (citB) gene of Bacillus subtilis is subject to catabolite repression in cells grown in minimal media. In nutrient broth medium, citB expression is low in growing cells but is induced when cells enter sporulation. A 600-base-pair DNA fragment that extends from positions -400 through +200, relative to the transcription start site, was shown to include all of the cis-acting sequences necessary for catabolite repression and sporulation-associated regulation. This was demonstrated by fusing this DNA fragment to the Escherichia coli lacZ gene, integrating the fusion in the amyE locus of the B. subtilis chromosome, and measuring the regulation of expression of beta-galactosidase. By creating a series of deletions from either end of the 600-base-pair fragment, it was possible to define a target for catabolite repression; at least part of this target lies within the sequence between positions -84 and -68. DNA fragments that included positions -84 through +36, when carried on high-copy plasmids, caused derepression of aconitase synthesis, as if a negative regulator were being titrated. The same plasmids caused derepression of citrate synthase activity as well. Deletion of the sequence between positions -84 and -67 abolished this titration effect for both enzymes. Mutations that altered the target for catabolite repression also affected the inducibility of citB at the onset of sporulation, at least when sporulation was induced by the addition of decoyinine, an inhibitor of guanine nucleotide synthesis. When sporulation was induced by exhaustion of nutrient broth, there was no detectable difference in expression of citB-lacZ fusions whether or not they had the citB sequence from positions -84 to -67, suggesting that the mechanisms of regulation of citB in minimal medium and nutrient broth are different.

Bacillus subtilis sucrose-specific enzyme II of the phosphotransferase system: expression in Escherichia coli and homology to enzymes II from enteric bacteria

Sucrose is transported into Bacillus subtilis cells by way of a phosphotransferase system, which consists of a specific enzyme II, a nonspecific enzyme I, and a histidine-containing phosphocarrier protein. Mutations in the sacP locus abolish the specific transport of sucrose. The B. subtilis sacP gene was cloned and expressed in Escherichia coli, and transformed cells could transport and phosphorylate sucrose. This indicates that the sacP gene product is enzyme II of the sucrose phosphotransferase system of B. subtilis. The nucleotide sequence of the sacP gene was determined and was found to overlap with the sacA gene at the tetranucleotide ATGA, which may allow a translational coupling between sacP and sacA. The two genes are therefore probably organized in an operon structure with the promoter located 5' to sacP gene. The deduced amino acid sequence gave a Mr of 48,945 for the sucrose-specific enzyme II polypeptide. The amino acid sequence was compared to that of three other known enteric bacterial enzymes II (beta-glucoside-specific enzyme II, mannitol-specific enzyme II, and glucose-specific enzyme II). Homology was found with beta-glucoside enzyme II, and well conserved regions were identified through the comparison of the proteins.

Distinct control sites located upstream from the levansucrase gene of Bacillus subtilis

The sacR regulatory region, which modulates the expression of sacB, the structural gene for levansucrase, was separated into two parts: an upstream region which carries a constitutive promoter and a downstream region which carries a palindromic structure. Three types of fusions were constructed in which the aphA3 gene coding for kanamycin resistance of Streptococcus faecalis was placed downstream from different deleted sacR regions. Other fusions were constructed by inserting a promoter from phage SPO1 upstream from the sacB gene and part of the sacA region. A third kind of fusion was constructed in which the palindromic structure was flanked by a heterologous promoter and a heterologous structural gene. After introduction of these fusions into the chromosomal DNA of mutants affected in sacB regulation, it was possible to reveal different targets for the regulatory genes sacU, sacQ and sacS: the sacU and sacQ genes act on a region located near or just upstream from the promoter, and the sacS gene, which is involved in the induction process, acts on the palindromic structure.

Nucleotide sequence of the sucrase gene of Bacillus subtilis

The sucrase gene (sacA) and part of the sacP locus, which corresponds to a membrane component of the phosphotransferase system (PTS) of sucrose transport of Bacillus subtilis, were previously cloned on a 2.1-kb EcoRI DNA fragment. Genes sacA and sacP were localized on this DNA fragment and the nucleotide sequence of the 2.1-kb DNA fragment was determined. A 1440-bp open reading frame (480 codons) was identified coding for a deduced polypeptide of Mr54827, which corresponds to that of purified sucrase. The amino acid sequence shares homology with that of yeast invertase (SUC2 gene product). The sacA gene and the preceding sacP gene seem to belong to the same operon.

Characterization of the precursor form of the exocellular levansucrase from Bacillus subtilis

Expression of the cloned levansucrase gene (sacB) was demonstrated in E. coli minicells by assay of the enzyme in crude extracts, SDS-polyacrylamide gel electrophoresis and immunoblotting. The existence of a precursor form of the enzyme of MW 53000 was also demonstrated and confirmed by the DNA sequence corresponding to the NH2 terminal region of the protein.

Cloning and expression in Escherichia coli of the sucrase gene from Bacillus subtilis

A recombinant cosmid carrying the sucrase gene (sacA) was obtained from a colony bank of E. coli harboring recombinant cosmids representative of the B. subtilis genome. It was shown that the sacA gene is located in a 2kb EcoRI fragment and that the cloned sequence is homologous to the corresponding chromosomal DNA fragment. A fragment of 2kb containing the gene was subcloned in both orientations in the bifunctional vector pHV33 and expression was further looked for in B. subtilis and E. coli. Complementation of a sacA mutation was observed in Rec+ and REc- strains of B. subtilis. Expression of sucrase was also demonstrated in E. coli, which is normally devoid of this activity, by SDS-polyacrylamide gel electrophoresis, specific immunoprecipitation and assay of the enzyme in crude extracts. The specific activity of the enzyme depended on the orientation of the inserted fragment. The saccharolytic activity was found to be cryptic in E. coli since the presence of the recombinant plasmids did not allow the transport of [U14C] sucrose and the growth of the cells. It was shown also that the recombinant cosmid contained part of the neighboring locus (sacP) which corresponds to a component of the PEP-dependent phosphotransferase system of sucrose transport of B. subtilis.