Abstract
Bacillus thuringiensis, Bacillus cereus, and Bacillus anthracis are closely related species belonging to the Bacillus cereus group. B. thuringiensis and B. cereus generally produce extracellular proteins, including phospholipases and hemolysins. Transcription of the genes encoding these factors is controlled by the pleiotropic regulator PlcR. Disruption of plcR in B. cereus and B. thuringiensis drastically reduces the hemolytic, lecithinase, and cytotoxic properties of these organisms. B. anthracis does not produce these proteins due to a nonsense mutation in the plcR gene. We screened 400 B. thuringiensis and B. cereus strains for their hemolytic and lecithinase properties. Eight Hly− Lec− strains were selected and analyzed to determine whether this unusual phenotype was due to a mutation similar to that found in B. anthracis. Sequence analysis of the DNA region including the plcR and papR genes of these strains and genetic complementation of the strains with functional copies of plcR and papR indicated that different types of mutations were responsible for these phenotypes. We also found that the plcR genes of three B. anthracis strains belonging to different phylogenetic groups contained the same nonsense mutation, suggesting that this mutation is a distinctive trait of this species.
Bacillus thuringiensis, Bacillus cereus, and Bacillus anthracis are three closely related species belonging to the B. cereus group (20, 25, 48). These bacteria are gram-positive spore-forming microorganisms, the spores of which can be isolated from many sources, including insects, soils, dust, and foods (10, 11, 22). B. anthracis, the etiologic agent of anthrax, produces a capsule and toxins encoded by genes carried by the pXO1 and pXO2 plasmids (for a review see reference 35). The expression of these genes is under the control of the key regulator AtxA and the minor regulators AcpA and PagR (16, 24, 36). B. thuringiensis is an entomopathogenic bacterium that produces specific insecticidal toxins encoded by plasmid genes (45). These toxins, the Cry and Cyt proteins, are synthesized when the bacterium enters the stationary phase or the sporulation phase (2). B. cereus is an opportunistic pathogen that is responsible for food poisoning, pneumonia, and endophthalmitis, possibly due to production of an emetic toxin, enterotoxins, and degradative enzymes (3, 8, 15, 26, 34). B. cereus and B. thuringiensis generally produce extracellular proteins that are potentially involved in virulence. Transcription of the genes encoding these proteins is under control of the pleiotropic activator PlcR (1, 30, 38). These putative virulence factors include phospholipases (phosphatidylinositol-specific phospholipase C [PI-PLC], phosphatidylcholine-specific phospholipase C [PC-PLC], sphingomyelinase), cholesterol-dependent hemolysins (cereolysin Clo in B. cereus and thuringiolysin Tlo in B. thuringiensis), proteases (ColB, InhA, Sfp, NprB, NprP2), a cytotoxin (CytK), and hemolytic (Hbl) and nonhemolytic (Nhe) enterotoxins. Disruption of the plcR gene in B. cereus strain ATCC 14579 and B. thuringiensis strain 407 Cry− drastically reduces the hemolytic (Hly−) and cytotoxic properties (43) of these strains, decreases their motility, and attenuates the symptoms of endophthalmitis (9). Two-dimensional (2D) gel electrophoresis has shown that most of the proteins secreted by wild-type B. cereus ATTC 14579 (including phospholipases, hemolysins, enterotoxins, and proteases) are not secreted by the ΔplcR mutant strain (13). Opp, an oligopeptide permease, is necessary for plcR expression, suggesting that uptake of a small peptide is required to activate PlcR-regulated gene expression (14). PlcR activation requires a small peptide, designated PapR, which acts as a cell-cell signaling peptide. Agaisse and collaborators (1) showed that papR is a PlcR-regulated gene located 70 bp downstream from plcR and encoding a 48-amino-acid peptide. This peptide is secreted by the cell and then reimported via Opp, presumably as a pentapeptide. Intracellular PapR is required for binding of PlcR to its DNA targets and thus is required to trigger expression of the PlcR regulon (46).
The importance of the PlcR regulon in the B. cereus group was recently emphasized by the publication of the genome sequences of B. cereus ATCC 14579 and B. anthracis Ames (21, 42). More than 100 genes putatively belong to the PlcR regulon on the basis of the presence of a PlcR DNA-binding sequence upstream from these genes in B. cereus ATCC 14579. Most of these genes are also present in B. anthracis. However, B. anthracis does not produce the PlcR-regulated extracellular proteins even though the corresponding genes are present. Most B. cereus and B. thuringiensis strains are hemolytic on sheep blood agar plates, whereas B. anthracis is not hemolytic. This characteristic is commonly used to distinguish between B. anthracis and B. cereus or B. thuringiensis, although it is not considered to be a decisive criterion (29). B. anthracis Sterne does not produce PlcR-regulated proteins due to a nonsense mutation in the plcR gene (1). Mignot and collaborators (33) showed that this mutation in the plcR gene of B. anthracis might result from incompatibility between the PlcR and AtxA regulons. Indeed, B. anthracis is unable to sporulate when it is complemented with a functional plcR gene that restores expression of the PlcR regulon. Point mutations in regulators or in major virulence genes could be one of the mechanisms responsible for the genetic shaping and divergence of closely related populations (5). For example, there is genetic variability among different Clostridium difficile clinical isolates due to deletions in the tcdC gene, which is the putative transcriptional repressor of the A and B toxins and thus affects the toxicity of strains (47). Thus, a point mutation in a key regulator gene, in association with acquisition of mobile genetic elements harboring virulence factors (transposons, plasmids, bacteriophages), may result in distinctive differences between closely related species that may lead to a specialization, like multiplication in mammals for B. anthracis (for a review see reference 18, 19).
In this study, we first aimed to determine whether, because of their monomorphism, distinct B. anthracis strains had the same plcR mutation. We then sought B. thuringiensis and B. cereus strains that had lost phenotypic characteristics like hemolysis and lecithinase activity. We wanted to find out whether inactivation of a pleiotropic regulator, such as PlcR, was restricted to B. anthracis or if it was widespread in other species belonging to the B. cereus group.
MATERIALS AND METHODS
Bacterial strains and growth conditions.
The acrystalliferous strain B. thuringiensis 407 Cry−, which belongs to serotype 1 (31), and the B. cereus ATCC 14579 strain were used as reference strains throughout this study. The hemolysis assays were performed with B. cereus and B. thuringiensis strains originating from the Institut National de la Recherche Agronomique and Institut Pasteur collections. The type strain of each B. thuringiensis serotype was tested (28). Strains 05, 17, 26, and 45 are B. thuringiensis strains; the numbers indicate the serotypes. Bt1, Bt13, and Bt32 were identified as B. thuringiensis strains and LM112.3 was identified as a B. cereus strain on the basis of the presence or absence of crystal inclusions. These four strains, which have not been serotyped yet, were isolated from the environment; the B. thuringiensis strains were isolated from forest soils near Versailles (France), and the B. cereus strain was isolated from the coleopteran Otiorhynchus (Curculionidae). B. anthracis RA3R is a field strain cured for pXO2 (39). Escherichia coli strain ET 12567 (dam13::Tn9 dcm-6 hsdM hsdR recF143 zjj201::Tn10 galK2 galT22 ara-14 lacY1 xyl-5 leuB6 thi-1 tonA31 rpsL136 hisG4 tsx-78 mtlI glnV44 F−) (32) was used as a host for plasmid construction and for preparation of plasmid DNA for B. thuringiensis and B. cereus transformation. E. coli and B. thuringiensis cells were transformed by electroporation, as previously described (12, 31). E. coli strains were grown at 37°C in Luria-Bertani broth (LB) (1% tryptone, 0.5% yeast extract, 0.5% NaCl). B. thuringiensis and B. cereus strains were generally grown at 30 or 37°C in LB or in brain heart infusion (BHI) (Difco) broth. Specific media were used for the enzyme activity and motility assays (see below).
The antibiotic concentrations used for bacterial selection were as follows: 100 μg of ampicillin ml−1 for E. coli; and 10 μg of erythromycin ml−1 and 200 μg of kanamycin ml−1 for B. thuringiensis. Bacteria with the Lac+ phenotype were identified on LB plates containing X-Gal (5-bromo-4-chloro-3-indolyl-d-galactoside) (80 μg ml−1).
Plasmid construction.
pHT304ΩplcR-papR was constructed by inserting a fragment containing the plcR and papR genes under control of their own promoter between the XbaI and HindIII sites of pHT304 (4). This fragment was amplified from chromosomal DNA of the B. thuringiensis 407 Cry− strain with primers S1X and S2H (Table 1).
TABLE 1.
Primer | Sequence (5′ −3′)a |
---|---|
26C200Y.2 | CTTTTGCATGATTATATCTTACCTTC |
26C200Y.3 | GAAGGTAAGATATAATCATGCAAAAG |
phind26 | CCCAAGCTTATATTTATCTACTGATT TTATTTACGAG |
S1 | CTATTATTATATGTGAGATGAATTGT ATG |
S1X | GCTCTAGACTATTATTATATGTGAGA TGAATTGTATG |
S2 | GTAAAGACGTTTGGATGTTACTCC |
S2H | CCCAAGCTTGTAAAGACGTTTGGAT GTTACTCC |
S3 | CGCAATTGCAAACATTTATGCTGA |
S3Bwei | TGCGATTGCAAATATTTATGCTGAAA AT |
S4 | CATTATCATGCAATGCCTCTAATTGT |
S4Bt1 | CTCTATATAAAGATTTTGGTATACATC |
S4Bt13 | TATTTTCAGGTAATGCCTCTAATTGC |
S4LM112.3 | GTTTTCGCATAATTATGTCTTACC TTCAC |
Restriction sites are underlined.
The plcR gene from strain 26 was amplified from chromosomal DNA by using primers S1X and phind26 (Table 1). The fragment was then inserted between the XbaI and HindIII sites of pHT304 to generate pHT304ΩplcR26wt.
The plasmid carrying the modified plcR gene from strain 26 (pHT304ΩplcR26mt) was constructed as follows. Chromosomal DNA from strain 26 was used as a template for PCR amplification with the S1X-26C200Y.2 and 26C200Y.3-phind26 primer pairs (Table 1). The two resulting fragments were mixed and PCR amplified with primers S1X and phind26. The fragment generated was inserted between the XbaI and HindIII sites of pHT304. In all the cases, the nucleotide sequences of the cloned DNA fragments were verified by sequencing.
DNA manipulations.
Plasmid DNA was extracted from E. coli by a standard alkaline lysis procedure by using Qiagen kits. Chromosomal DNA was extracted from B. thuringiensis and B. cereus cells grown to the mid-exponential phase in LB or BHI medium and was purified as previously described (37). Restriction enzymes and T4 DNA ligase were used as recommended by the manufacturers. The oligonucleotide primers used for PCR amplification were synthesized by Proligo (Paris, France). Primers S1 and S2 were used to amplify the plcR-papR region, and this region was sequenced by using the primers listed in Table 2. Primer sequences are shown in Table 1. PCR were carried out in 100-μl reaction mixtures containing each deoxynucleoside triphosphate at a concentration of 200 μM, 3.5 mM MgSO4, 50 pmol of each primer, 0.5 μg of chromosomal DNA, and 0.5 U of Pwo DNA polymerase (Roche Boehringer) in 1× reaction buffer. The PCR were performed with a GeneAmp PCR system 2400 thermal cycler (Perkin-Elmer). The reaction conditions were as follows: incubation for 5 min at 94°C, followed by 30 cycles of 30 s at 48 or 50°C for annealing, 1 min at 72°C for extension, and 30 s at 94°C for denaturation and then incubation at 72°C for 10 min. Nucleotide sequences were determined by Genome Express (Montreuil, France).
TABLE 2.
Strain | Primers used for sequencing |
---|---|
B. anthracis RA3R | S1, S2, S3, S4 |
B. thuringiensis strains | |
407 Cry− | S1, S2, S3, S4 |
05 | S1, S2, S3, S4 |
17 | S1, S2, S3, S4 |
26 | S1, S2, S3, S4 |
45 | S1, S2, S3, S4 |
Bt1 | S1, S2, S3, S4Bt1 |
Bt13 | S1, S2, S3, S4Bt13 |
Bt32 | S1, S2, S3Bwei, S4Bt13 |
B. cereusLM112.3 | S1, S2, S3, S4LM112.3 |
Enzyme activity assays.
Columbia agar plates containing 5% sheep blood (BioMérieux) were used to assay the hemolytic activity of the B. thuringiensis and B. cereus strains. The hemolytic activity was also evaluated on agar plates containing washed human erythrocytes (5%). Erythrocytes from defibrinated human blood were washed twice in phosphate-buffered saline (44) before they were added to the medium.
The lecithinase activity was assayed on BHI agar plates containing 5% egg yolk (Difco). The plates were checked after 24 and 48 h, and the assays were repeated at least twice.
2D-PAGE.
For preparation of samples for 2D polyacrylamide gel electrophoresis (2D-PAGE) cells were grown in 50 ml of LB at 30°C in 500-ml flasks with rotation at 175 rpm, harvested 2 h after they entered the stationary phase, and centrifuged at 5,000 × g for 10 min at 4°C. The supernatant was rapidly filtered through a membrane (pore size, 0.2 μm). Proteins were precipitated twice by using the deoxycholate-tetrachloroacetic acid method (41). The pellet was washed twice with ethanol-ether (1:1), dried, and stored at −80°C until it was used. The protein content of the pellet was quantified by the Bradford method (7).
2D-PAGE was performed as described previously (13). For gel analysis gels were scanned at 300 dpi and 8-bit depth by using a SHARP JX-330 scanner equipped with a film-scanning unit and were analyzed with the ImageMaster 2D program from Amersham BioScience. The spots were identified on the basis of mobility and by comparison with a reference gel as described previously (13).
Nucleotide sequence accession numbers.
plcR nucleotide sequences have been deposited in the EMBL database under the following accession numbers: serotypes 1 to 14, AJ582632 to AJ582638 and AJ582669 to AJ582675; serotypes 17 and 26, AJ583460 and AJ583461; isolates Bt13, Bt32, and LM112.3, serotype 45, and isolate Bt1, AJ583463 to AJ583467; and B. anthracis RA3R, AJ585425.
The accession numbers of the papR sequences of the nonhemolytic strains are AJ586123 to AJ586131. The accession numbers of the papR sequences of B. cereus ATCC 14579 and B. thuringiensis 407 Cry− (serotype 1) have been given previously (46).
RESULTS
Comparison and analysis of the PlcR sequences from various B. anthracis, B. cereus, and B. thuringiensis strains.
We analyzed the hemolytic properties of 400 B. thuringiensis and B. cereus strains (from the Institut Pasteur and the Institut National de la Recherche Agronomique collections) on sheep blood agar plates. The Hly− strains were subsequently screened for lecithinase activity on egg yolk agar plates. Eight Hly− Lec− strains were found and selected. The plcR-papR regions of these strains and of the B. anthracis RA3R strain were sequenced and aligned with those of B. cereus ATCC 14579, B. thuringiensis 407 Cry−, B. anthracis Sterne, and B. anthracis Ames (Fig. 1A). The B. anthracis RA3R strain was chosen because phylogenetically it is distantly related to the B. anthracis Ames and Sterne strains. The latter strains both belong to the A3b group, whereas B. anthracis RA3R is in the B2 group (23). Although the three B. anthracis strains belong to different phylogenetic groups, they all have the same point mutation leading to the same truncated PlcR.
The PlcR sequences of the B. cereus and B. thuringiensis strains differ essentially in the carboxy-terminal part of the protein. Strain LM112.3 (B. cereus) has a truncated PlcR, but the mutation is located at a different place in the sequence than the mutation in B. anthracis. The Bt32 protein lacks two residues in the middle of the protein. PlcR from strain Bt1 is 15 residues longer than PlcR from strain 407 Cry−. Mutations that could potentially affect PlcR activity were less obvious in the other Hly− Lec− strains. PlcR from strain 45 has two more residues than PlcR from strain 407 Cry−, but it is also divergent throughout the sequence. We compared the PlcR sequences of strains 05, 17, 26, and Bt13 to those of hemolytic strains belonging to serotypes 1 to 14 (data not shown) (see Materials and Methods for the accession numbers of the nucleotide sequences). The PlcR sequence of strain 17 differed at five positions, positions 8, 15, 154, 207, and 244 (Fig. 1A). PlcR from strain 26 differed at two sites, E186D and H/Y200C; the latter difference presumably had a drastic effect. No mutations were detected in strains 05 and Bt13.
Alignment of the predicted PapR polypeptide sequence of each nonhemolytic strain with the sequences of the hemolytic strains revealed no obvious mutations, except in B. thuringiensis serotype 17 (Fig. 1B). Indeed, the PapR pentapeptide, which is located at the carboxy terminus of the PapR protein and is required for PlcR activation, contains an isoleucine at position 1. When the first residue of the pentapeptide is an isoleucine, PlcR is not activated in B. thuringiensis 407 Cry− (46). However, addition of synthetic pentapeptides (with a leucine, a valine, or an isoleucine at position 1 of the pentapeptide) on sheep blood agar plates did not restore the hemolytic activity in strain 17 (data not shown). The absence of hemolysis and lecithinase activity might be due to the absence of the genes conferring these phenotypes or to the absence of a functional PlcR protein. This is discussed below.
Together, our results indicate that the possible causes for PlcR inactivity can be summarized as follows: (i) a nonsense mutation leading to a truncated protein (B. cereus LM112.3 and B. anthracis), (ii) deletions (Bt32) or additions (Bt1), (iii) divergence throughout the sequence (B. thuringiensis serotype 45), (iv) point mutations (B. thuringiensis serotype 17 and serotype 26), and (v) mutations in genes required for PlcR expression or activity (e.g., papR, opp, gene coding for a protease responsible for PapR maturation).
Point mutation in PlcR restores activity in B. thuringiensis serotype 26.
We next tested the hypothesis that a point mutation could be sufficient to explain the loss of PlcR activity in nonhemolytic strains. This hypothesis was examined by using strain 26; we hypothesized that a cysteine at position 200 may have a drastic effect on PlcR activity in this strain. We constructed pHT304ΩplcR26mt, in which the cysteine codon was replaced by a tyrosine codon. This plasmid and pHT304ΩplcR26wt (carrying the wild-type plcR gene from strain 26) were introduced into strain 26, which had two potential mutations (Fig. 1A). We then assayed the enzymatic activities of the transformants (Fig. 2). Both the lecithinase and hemolytic activities were fully restored when strain 26 was complemented with pHT304ΩplcR26mt, whereas no lecithinase activity and only weak hemolysis were detected when it was complemented with pHT304ΩplcR26wt. Similarly, the protease activity of strain 26 on BHI milk agar plates was also restored when the strain was complemented with pHT304ΩplcR26mt (data not shown).
Complementation of the Hly− Lec− strains with functional plcR and papR genes.
pHT304 and pHT304ΩplcR-papR were introduced into each Hly− Lec− strain except the B. anthracis strain. The transformants were then assayed on sheep blood agar plates, human blood agar plates, and egg yolk agar plates. In parallel, the extracellular proteomes of each wild-type strain and the corresponding complemented strain were analyzed by 2D-PAGE, and the presence of the potential virulence factors belonging to the PlcR regulon was determined for each strain (Table 3). An example of each assay for strain LM112.3 is shown in Fig. 3, and an example of 2D-PAGE of the extracellular proteome of strain LM112.3 is shown in Fig. 4. All the results are summarized in Table 3. Hemolysis, both of sheep blood and of human blood, and lecithinase activity were restored when strains 17, 26, Bt32, and LM112.3 were complemented with pHT304ΩplcR-papR. Bt13(pHT304ΩplcR-papR) exhibited hemolytic activity with human blood and lecithinase activity, whereas only the latter was observed in the case of Bt1(pHT304ΩplcR-papR). The phenotypes of strains 05 and 45, which were hemolytic on human blood agar plates, did not change on blood agar and egg yolk agar plates when the strains were complemented with papR and plcR. Similarly, 2D-PAGE analysis of these two strains revealed no difference between the extracellular proteomes of the wild-type strains and those of the corresponding complemented strains. The extracellular proteome of strain 05 with or without plcR and papR (data not shown) was considerably different from that of B. cereus ATCC 14579 described previously (13). The former lacked almost all the major proteins of the PlcR regulon except CytK, sphingomyelinase, and Tlo. Both wild-type and complemented strain 45 produced Sfp, NheA, NheB, NprP2, Tlo, HblL2, PI-PLC, and sphingomyelinase. Wild-type strain Bt1 produced Sfp, NheA, NprP2, NprB, and sphingomyelinase, and it produced ColB, NheB, Tlo, HblL2, and PC-PLC when it was complemented with plcR and papR. CytK, NheA, NheB, NprP2, NprB, and HblL2 were produced by both wild-type strain Bt13 and the complemented Bt13 strain, but Tlo was only weakly produced by the wild-type strain. The amount of Tlo was greater in Bt13(pHT304ΩplcR-papR) than in Bt13. ColB, Sfp, sphingomyelinase, and PC-PLC were found only in the extracellular proteome of Bt13(pHT304ΩplcR-papR). Wild-type Bt32 and Bt32(pHT304ΩplcR-papR) both expressed Sfp, but NprB, Tlo, HblB, L1, L2, PI-PLC, and PC-PLC were found only in Bt32(pHT304ΩplcR-papR). None of these proteins were present in wild-type strains 17, 26, and LM112.3, but all were present when these strains were complemented with plcR and papR.
TABLE 3.
Straina | 2D-PAGE analysisb
|
Agar plates assaysc
|
|||||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
ColB | Sfp | CytK | NheB | NheA | NprP2 | NprB | Tlo; Clo | HbIL2 | HbIL1 | HBlB | PI-PLC | Smase | PC-PLC | Sheep blood | Human blood | Egg yolk | |
05 wt | −d | − | + | − | − | − | − | + | − | − | − | − | + | − | − | + | − |
05 plcR-papR | − | − | + | − | − | − | − | + | − | − | − | − | + | − | − | + | − |
17 wt | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − |
17 plcR-papR | + | + | + | + | + | + | + | + | + | + | + | + | + | + | + | + | + |
26 wt | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − |
26 plcR-papR | + | + | + | + | + | + | + | + | + | + | + | + | + | + | + | + | + |
45 wt | − | + | − | + | + | + | − | + | + | − | − | + | + | − | − | + | − |
45 plcR-papR | − | + | − | + | + | + | − | + | + | − | − | + | + | − | − | + | − |
Bt1 wt | − | + | − | − | + | + | + | − | − | − | − | − | + | − | − | − | − |
Bt1 plcR-papR | + | + | − | + | + | + | + | + | + | − | − | − | + | + | − | − | + |
Bt13 wt | − | − | + | + | + | + | + | + | + | − | − | − | − | − | − | − | − |
Bt13 plcR-papR | + | + | + | + | + | + | + | —e | + | − | − | − | + | + | − | + | + |
Bt32 wt | − | + | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − |
Bt32 plcR-papR | − | + | − | − | − | − | + | + | + | + | + | + | − | + | + | + | + |
LM112.3 wt | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − | − |
LM112.3 plcR-papR | + | + | + | + | + | + | + | + | + | + | + | + | + | + | + | + | + |
wt, wild type; plcR-papR, PHT304ΩplcR-papR.
A 2D-PAGE analysis of the extracellular proteomes of the wild-type and the plcR-papR-complemented strains was performed. Co1B, collagenase; Sfp, subtilase family protein; CytK, hemolysin cytolysin K; NheB, enterotoxin Nhe component B; NheA, enterotoxin Nhe component A; NprP2, neutral protease; NprB, neutral protease; Tlo/Clo, hemolysin thuringiolysin O/cereolysin O; HbIL2, enterotoxin Hbl lytic component L2; HbIL1, enterotoxin Hbl lytic component L1; HblB, enterotoxin Hbl binding component B; PI-PLC, phosphatidylinositol-specific phospholipase C; Smase, sphingomyelinase; PC-PLC, phosphatidylcholine-specific phospholipase C.
Enzymatic activities were determined on sheep blood agar plates, human blood agar plates, and egg yolk agar plates.
−, negative (protein or activity absent); +, positive (protein or activity present). A spot was considered positive if its volume was equal to or greater than 0.1% of the total spot volume (pixel density × area).
—, There was an increase in the amount of protein.
DISCUSSION
Eight of the 400 B. thuringiensis and B. cereus strains screened in this study displayed a nonhemolytic phenotype on sheep blood agar plates and were also lecithinase negative on egg yolk agar plates, like B. anthracis. These two characteristics are known to depend on the presence of PlcR-regulated proteins (43). Sequence analysis of three B. anthracis strains belonging to the A3b and B2 phylogenetic groups (23) indicated that these strains have identical plcR sequences and harbor the same nonsense mutation in the plcR gene. This is in agreement with the monomorphism of B. anthracis and strongly suggests that the nonsense mutation is a distinctive feature of this species. This is emphasized by the fact that all of the B. cereus and B. thuringiensis mutations that led to an inactive PlcR polypeptide differed from the mutation found in B. anthracis. Thus, the point mutation in the plcR gene of B. anthracis might be used to design specific primers to detect B. anthracis strains.
Analysis of the PlcR sequences of the eight Hly− Lec− strains revealed that the amino-terminal part of the protein, which is the putative helix-turn-helix DNA-binding domain, is very well conserved. In contrast, the region located downstream of the 75th residue, which contains the tetratricopeptide repeat domain region (40), is highly variable. These domains are involved in protein-protein interactions or protein-peptide interactions (6, 27). Thus, the loss of PlcR activity in these strains might be due to a failure to form multimers or to the lack of an interaction with the activating peptide PapR rather than to an inability to bind DNA.
B. cereus LM112.3 had a truncated, presumably inactive PlcR. In this strain, PlcR is 169 residues long, whereas the PlcR proteins of hemolytic strains are 285 residues long. Analysis of the extracellular proteome of strain LM112.3 showed that the PlcR-regulated proteins examined in this study were not produced in the wild-type strain and that production of these proteins was restored in the plcR-papR-complemented strain. Furthermore, the enzymatic activities tested were restored in the complemented strain. B. thuringiensis serotypes 17 and 26 responded in a similar manner to complementation. For these three strains, complementation with plcR and papR completely restored the enzymatic activities tested. This was not the case with strains Bt1, Bt13, and Bt32. The enzymatic activities of Bt32 were restored, but about one-half of the PlcR-regulated proteins were absent from the complemented secretome and Sfp seemed to be regulated independently of PlcR. The genes encoding the proteins that were not induced after PlcR complementation might be absent from the Bt32 strain, as is the case for a large number of B. cereus strains (17). However, mutations in the coding sequences of these genes or in the PlcR boxes upstream of these genes might also explain the absence of these proteins in the secretome. One-half of the PlcR-controlled proteins examined were present in wild-type strains Bt13 and Bt1, suggesting either that they are not under control of PlcR or that PlcR is not totally inactive in these strains. The latter hypothesis might be in agreement with the mutation found in the PlcR sequence of Bt1 (addition of 15 residues at the carboxy-terminal end) and with the apparent absence of mutations in the PlcR sequence of Bt13. Tlo, which confers the ability to lyse human blood (33), was present in wild-type strain Bt13. However, probably because of the small amount of Tlo, this strain was nonhemolytic on human blood agar plates. Strain Bt1(pHT304ΩplcR-papR) was also nonhemolytic on human erythrocytes even though expression of Tlo was induced, suggesting that Tlo was inactive. In this strain, only lecithinase activity, corresponding to PC-PLC activity, was restored. In B. cereus ATCC 14579 and B. thuringiensis 407 Cry−, NheA, NheB, HblL1, hb1L2, and HblB are expressed from two operons (1, 38). These proteins were produced in strain Bt1(pHT304ΩplcR-papR) as they are independently regulated. The fact that the complemented strain displayed no hemolytic activity with sheep erythrocytes is compatible with the absence of two of the Hbl components as determined by 2D-PAGE. Neither the enzymatic activities nor the secretome profiles of B. thuringiensis strains 05 and 45 were changed by complementation (both strains were hemolytic on human blood). Various PlcR-regulated proteins were present in both B. thuringiensis serotype 05 and 45 wild-type strains and in these strains transformed with pHT304ΩplcR-papR. This strongly suggests that the plcR and papR genes are functional in these two strains. To verify this hypothesis, we transformed the 05 and 45 wild-type strains with the pHT304ΩplcA′-lacZ plasmid. This plasmid carries a transcriptional fusion between the promoter of the plcA gene (belonging to the PlcR regulon) and the reporter gene lacZ (30). This fusion has been shown to reflect plcR expression or PlcR activity. The plcA′-lacZ fusion was expressed when it was introduced into strains 05 and 45 (results not shown), confirming that PlcR is produced and functional in these two strains. The Hly− phenotype on sheep blood agar plates and the Lec− phenotype are likely due to the absence or inactivity of the genes encoding the Hbl components and PC-PLC.
In conclusion, the work described here showed that inactivation of the plcR gene is not restricted to B. anthracis, but none of the B. cereus and B. thuringiensis strains contained the nonsense mutation found in B. anthracis. Three strains contained mutations that could be predicted to affect PlcR activity (truncations, deletions, and insertions). The other strains either contained no mutations in PlcR or had sequence variations that may or may not have affected their activity. However, one point mutation was confirmed to be responsible for the loss of PlcR activity. Thus, about 1% (4 of 400) of the strains belonging to the B. cereus group were deficient for expression of the PlcR regulon due to mutations in PlcR. The causes of these mutations are unknown. It has been shown that in B. anthracis incompatibility with the AtxA regulon results in a drastic reduction in sporulation, and it was suggested previously that the mutation in plcR occurred after the acquisition of plasmid pXO1 carrying atxA (33). In the four strains with an inactive PlcR regulon which we identified, complementation with a functional plcR gene did not affect growth and sporulation (results not shown), suggesting that in these strains counterselection of PlcR did not result from an incompatibility event. The latter hypothesis might be true for B. anthracis, but we cannot exclude the possibility that the plcR mutation occurred prior to acquisition of the AtxA regulon. Inactivation of PlcR might have been caused by the biological cost of the useless PlcR regulon in some ecosystems and the resulting reduction in fitness of the bacterium.
Acknowledgments
We thank Catherine Braun-Breton for the gift of human blood for the hemolytic assays. We also thank Arnaud Chastanet and Julien Brillard for critical reading of the manuscript.
This work was supported by the Institut Pasteur, by the Institut National de la Recherche Agronomique, by the Centre National de Recherche Scientifique, and by a grant from the Délégation Générale de l'Armement (contract 99.34.032). Leyla Slamti received a Ph.D. grant from the Ministère de la Recherche and a Pasteur-Weizmann fellowship from The Institut Pasteur, Paris, France.
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