Crystal Structure of the Catalytic Domain of the Bacillus cereus SleB Protein, Important in Cortex Peptidoglycan Degradation during Spore Germination

The SleB protein is one of two redundant cortex-lytic enzymes (CLEs) that initiate the degradation of cortex peptidoglycan (PG), a process essential for germination of spores of Bacillus species, including Bacillus anthracis. SleB has been characterized as a soluble lytic transglycosylase that specifically recognizes spore cortex PG and catalyzes the cleavage of glycosidic bonds between N-acetylmuramic acid (NAM) and N-acetylglucosamine residues with concomitant formation of a 1,6-anhydro bond in the NAM residue. We found that like the full-length Bacillus cereus SleB, the catalytic C-terminal domain (SleB^C) exhibited high degradative activity on cortex PG in vitro, although SleB''s N-terminal domain, thought to bind PG, was inactive. The 1.85-Å crystal structure of SleB^C reveals an ellipsoid molecule with two distinct domains dominated by either α helices or β strands. The overall fold of SleB closely resembles that of the catalytic domain of the family 1 lytic transglycosylases but with a completely different topological arrangement. Structural analysis shows that an invariant Glu157 of SleB is in a position equivalent to that of the catalytic glutamate in other lytic transglycosylases. Indeed, SleB bearing a Glu157-to-Gln mutation lost its cortex degradative activity completely. In addition, the other redundant CLE (called CwlJ) in Bacillus species likely has a three-dimensional structure similar to that of SleB, including the invariant putative catalytic Glu residue. SleB and CwlJ may offer novel targets for the development of anti-spore agents.     

Characterization of the germination of Bacillus megaterium spores lacking enzymes that degrade the spore cortex

Aims:  To determine roles of cortex lytic enzymes (CLEs) in Bacillus megaterium spore germination.
Methods and Results:  Genes for B. megaterium CLEs CwlJ and SleB were inactivated and effects of loss of one or both on germination were assessed. Loss of CwlJ or SleB did not prevent completion of germination with agents that activate the spore's germinant receptors, but loss of CwlJ slowed the release of dipicolinic acid (DPA). Loss of both CLEs also did not prevent release of DPA and glutamate during germination with KBr. However, cwlJ sleB spores had decreased viability, and could not complete germination. Loss of CwlJ eliminated spore germination with Ca²⁺ chelated to DPA (Ca-DPA), but loss of CwlJ and SleB did not affect DPA release in dodecylamine germination.
Conclusions:  CwlJ and SleB play redundant roles in cortex degradation during B. megaterium spore germination, and CwlJ accelerates DPA release and is essential for Ca-DPA germination. The roles of these CLEs are similar in germination of B. megaterium and Bacillus subtilis spores.
Significance and Impact of the Study:  These results indicate that redundant roles of CwlJ and SleB in cortex degradation during germination are similar in spores of Bacillus species; consequently, inhibition of these enzymes will prevent germination of Bacillus spores.     

Spore Germination Mediated by Bacillus megaterium QM B1551 SleL and YpeB

Previous work demonstrated that Bacillus megaterium QM B1551 spores that are null for the sleB and cwlJ genes, which encode cortex-lytic enzymes (CLEs), either of which is required for efficient cortex hydrolysis in Bacillus spores, could germinate efficiently when complemented with a plasmid-borne copy of ypeB plus the nonlytic portion of sleB encoding the N-terminal domain of SleB (sleB^N). The current study demonstrates that the defective germination phenotype of B. megaterium sleB cwlJ spores can partially be restored when they are complemented with plasmid-borne ypeB alone. However, efficient germination in this genetic background requires the presence of sleL, which in this species was suggested previously to encode a nonlytic epimerase. Recombinant B. megaterium SleL showed little, or no, activity against purified spore sacculi, cortical fragments, or decoated spore substrates. However, analysis of muropeptides generated by the combined activities of recombinant SleB and SleL against spore sacculi revealed that B. megaterium SleL is actually an N-acetylglucosaminidase, albeit with apparent reduced activity compared to that of the homologous Bacillus cereus protein. Additionally, decoated spores were induced to release a significant proportion of dipicolinic acid (DPA) from the spore core when incubated with recombinant SleL plus YpeB, although optimal DPA release required the presence of endogenous CLEs. The physiological basis that underpins this newly identified dependency between SleL and YpeB is not clear, since pulldown assays indicated that the proteins do not interact physically in vitro.     

Role of YpeB in Cortex Hydrolysis during Germination of Bacillus anthracis Spores

The infectious agent of the disease anthrax is the spore of Bacillus anthracis. Bacterial spores are extremely resistant to environmental stresses, which greatly hinders spore decontamination efforts. The spore cortex, a thick layer of modified peptidoglycan, contributes to spore dormancy and resistance by maintaining the low water content of the spore core. The cortex is degraded by germination-specific lytic enzymes (GSLEs) during spore germination, rendering the cells vulnerable to common disinfection techniques. This study investigates the relationship between SleB, a GSLE in B. anthracis, and YpeB, a protein necessary for SleB stability and function. The results indicate that ΔsleB and ΔypeB spores exhibit similar germination phenotypes and that the two proteins have a strict codependency for their incorporation into the dormant spore. In the absence of its partner protein, SleB or YpeB is proteolytically degraded soon after expression during sporulation, rather than escaping the developing spore. The three PepSY domains of YpeB were examined for their roles in the interaction with SleB. YpeB truncation mutants illustrate the necessity of a region beyond the first PepSY domain for SleB stability. Furthermore, site-directed mutagenesis of highly conserved residues within the PepSY domains resulted in germination defects corresponding to reduced levels of both SleB and YpeB in the mutant spores. These results identify residues involved in the stability of both proteins and reiterate their codependent relationship. It is hoped that the study of GSLEs and interacting proteins will lead to the use of GSLEs as targets for efficient activation of spore germination and facilitation of spore cleanup.     

The Germination-Specific Lytic Enzymes SleB,CwlJ1, and CwlJ2 Each Contribute to Bacillus anthracis Spore Germination and Virulence

The bacterial spore cortex is critical for spore stability and dormancy and must be hydrolyzed by germination-specific lytic enzymes (GSLEs), which allows complete germination and vegetative cell outgrowth. We created in-frame deletions of three genes that encode GSLEs that have been shown to be active in Bacillus anthracis germination: sleB, cwlJ1, and cwlJ2. Phenotypic analysis of individual null mutations showed that the removal of any one of these genes was not sufficient to disrupt spore germination in nutrient-rich media. This finding indicates that these genes have partially redundant functions. Double and triple deletions of these genes resulted in more significant defects. Although a small subset of ΔsleB ΔcwlJ1 spores germinate with wild-type kinetics, for the overall population there is a 3-order-of-magnitude decrease in the colony-forming efficiency compared with wild-type spores. ΔsleB ΔcwlJ1 ΔcwlJ2 spores are unable to complete germination in nutrient-rich conditions in vitro. Both ΔsleB ΔcwlJ1 and ΔsleB ΔcwlJ1 ΔcwlJ2 spores are significantly attenuated, but are not completely devoid of virulence, in a mouse model of inhalation anthrax. Although unable to germinate in standard nutrient-rich media, spores lacking SleB, CwlJ1, and CwlJ2 are able to germinate in whole blood and serum in vitro, which may explain the persistent low levels of virulence observed in mouse infections. This work contributes to our understanding of GSLE activation and function during germination. This information may result in identification of useful therapeutic targets for the disease anthrax, as well as provide insights into ways to induce the breakdown of the protective cortex layer, facilitating easier decontamination of resistant spores.Bacillus anthracis, a gram-positive spore-forming bacterium, is the causative agent of anthrax. The dormant spore form is the infectious particle and produces three different forms of the disease depending on the route of entry into a suitable host (8). When spores enter through a skin lesion and when they are ingested, they cause cutaneous and gastrointestinal anthrax, respectively. Spores entering through the lungs cause the most severe form of the disease, inhalation anthrax, which is often fatal even with aggressive antibiotic therapy (1, 8, 34). Because true pneumonias are rarely seen in victims, it is believed that inhaled spores do not germinate in the lung but are phagocytosed by alveolar macrophages and germinate intracellularly en route to the mediastinal lymph nodes, which leads to dissemination, septicemia, toxemia, and often death (1, 34). It has been shown that the spores are able to germinate and the bacteria are able to multiply inside macrophages both in cell culture and in the lungs of challenged animals (7, 11, 28, 29).Independent of the route of infection, spore germination inside a susceptible host is essential for disease. The highly stable spore form of the bacterium can remain viable under harsh environmental conditions for many decades (32). However, a spore can form a rapidly dividing vegetative cell upon entry into a host and recognition of specific chemical signals, or germinants, through specialized germinant receptors (32). The spore cortex, a thick layer of modified peptidoglycan (PG), contributes much of the spore''s environmental resistance as it is necessary to maintain dehydration of the spore core (25). This protective barrier is broken down following the activation of germination-specific lytic enzymes (GSLEs), allowing full core rehydration and cell outgrowth (32). Experimentally, germination can also be triggered by nongerminant treatments, such as lysozyme treatment, high pressure, exogenous Ca²⁺-dipicolinic acid treatment, and treatment with cationic surfactants (32). Several of these treatments likely cause spore cortex hydrolysis, triggering spore germination. This indicates the importance of cortex degradation in the spore germination process.Bacterial cell wall PG consists of polysaccharide chains of repeating N-acetylglucosamine and N-acetylmuramic acid, joined by β(1,4) glycosidic bonds (25). This basic structure is modified in several ways in spore cortex PG. In one major modification, 50% of the muramic acid residues (alternating every other residue) are converted to muramic-δ-lactam residues (25). This modification is essential for the specificity of GSLEs for degrading the cortex and prevents degradation of the bacterial cell wall during cortex hydrolysis (21).Previous work on the role of GSLEs in Bacillus subtilis and, recently, in B. anthracis has shown that the enzymes SleB and CwlJ have partially redundant roles and are necessary together for full cortex hydrolysis and spore germination (6, 14). SleB is a lytic transglycosylase that, when activated by an unknown mechanism, hydrolyzes the bond between N-acetylmuramic acid and N-acetylglucosamine (5). In both B. subtilis and B. anthracis, the sleB gene is found in a bicistronic operon with ypeB. Although the function of YpeB is not known, deletion of ypeB prevents SleB activity in spore germination, and sleB and ypeB mutants have similar phenotypes (5). Expression of both gene products is necessary for the presence of SleB in the cortex and inner membrane of mature spores (2, 5).Although no specific enzymatic activity has been attributed to CwlJ, it is required for full germination and it shares a homologous catalytic domain with SleB (20). In B. subtilis and Bacillus cereus, cwlJ is found in an operon with gerQ. Similar to the finding that ypeB is necessary for a functional SleB protein, gerQ is required for CwlJ activity (26). The B. anthracis genome contains two homologs of cwlJ (designated cwlJ1 and cwlJ2 [14]), whereas a single copy is present in B. subtilis and B. cereus. As it is in the related species, cwlJ1 is found in an operon with gerQ, but cwlJ2 is in a different locus and is not in an operon with a gerQ homolog (14). It has been shown that CwlJ is localized to the spore coat and that it is necessary for spore germination with exogenous Ca²⁺-dipicolinic acid treatment (3, 24).GSLE activation represents a critical step in the complex process of germination. The relatively small number of genes involved and the apparent essential nature of their activity make them attractive targets for new therapeutics, as well as environmental decontamination compounds. The objective of this study was to test by using genetic analysis the role of the GSLE genes sleB, cwlJ1, and cwlJ2 in B. anthracis spore germination. Mutants lacking these three genes were tested to determine their effects on in vitro germination kinetics and colony-forming efficiency. Additionally, the virulence of these mutant strains was examined by comparing mutant and wild-type spores in an in vivo mouse model of inhalational anthrax.     

Regulation and Characterization of a Newly Deduced Cell Wall Hydrolase Gene (cwlJ) Which Affects Germination of Bacillus subtilis Spores

The predicted amino acid sequence of Bacillus subtilis ycbQ (renamed cwlJ) exhibits high similarity to those of the deduced C-terminal catalytic domain of SleBs, the specific cortex-hydrolyzing enzyme of B. cereus and the deduced one of B. subtilis. We constructed a cwlJ::lacZ fusion in the B. subtilis chromosome. The β-galactosidase activity and results of Northern hybridization and primer extension analyses of the cwlJ gene indicated that it is transcribed by Eς^E RNA polymerase. cwlJ-deficient spores responded to both l-alanine and AGFK, the A₅₈₀ values of spore suspensions decreased more slowly than in the case of the wild-type strain, and the mutant spores released less dipicolinic acid than did those of the wild-type strain during germination. However, the mutant spores released only slightly less hexosamine than did the wild-type spores. In contrast, B. subtilis sleB spores did not release hexosamine at a significant level. While cwlJ and sleB spores were able to germinate, CJSB (cwlJ sleB) spores could not germinate but exhibited initial germination reactions, e.g., partial decrease in A₅₈₀ and slow release of dipicolinic acid. CJSB spores became slightly gray after 6 h in the germinant, but their refractility was much greater than that of sleB mutant spores. The roles of the sleB and cwlJ mutations in germination and spore maturation are also discussed.During sporulation and germination of Bacillus subtilis, the action of autolysins is assumed to be required for asymmetric septum peptidoglycan hydrolysis, engulfment, cortex maturation, mother cell lysis, and cortex hydrolysis during germination (28, 33). Mother cell lysis depends on the compensatory effect of cell wall hydrolases CwlB (LytC) and CwlC (11, 13, 34). For cortex maturation, a defect in the cwlD gene leads to a lack of germination and blocking of the formation of muramic acid lactam structure in the cortex (2, 26, 31). Recently, Makino and colleagues reported that the B. cereus sleB gene encodes a 24-kDa mature germination-specific N-acetylmuramoyl-l-alanine amidase which degrades decoated spores from various organisms (18, 22). B. subtilis sleB is homologous to B. cereus sleB, and B. subtilis sleB mutant spores are able to germinate and form colonies. However, B. subtilis SleB showed no activity against degraded decoated spores or other substrates (21).Our work on the B. subtilis genome sequencing project has revealed the ycbQ gene, which is homologous with the cortex-hydrolyzing sleB genes (22, 25). In this study, we describe the regulation and function of the cwlJ (ycbQ) gene and the compensatory effect of the CwlJ and B. subtilis SleB proteins on germination.     

HtrC Is Involved in Proteolysis of YpeB during Germination of Bacillus anthracis and Bacillus subtilis Spores

Bacterial endospores can remain dormant for decades yet can respond to nutrients, germinate, and resume growth within minutes. An essential step in the germination process is degradation of the spore cortex peptidoglycan wall, and the SleB protein in Bacillus species plays a key role in this process. Stable incorporation of SleB into the spore requires the YpeB protein, and some evidence suggests that the two proteins interact within the dormant spore. Early during germination, YpeB is proteolytically processed to a stable fragment. In this work, the primary sites of YpeB cleavage were identified in Bacillus anthracis, and it was shown that the stable products are comprised of the C-terminal domain of YpeB. Modification of the predominant YpeB cleavage sites reduced proteolysis, but cleavage at other sites still resulted in loss of full-length YpeB. A B. anthracis strain lacking the HtrC protease did not generate the same stable YpeB products. In B. anthracis and Bacillus subtilis htrC mutants, YpeB was partially stabilized during germination but was still degraded at a reduced rate by other, unidentified proteases. Purified HtrC cleaved YpeB to a fragment similar to that observed in vivo, and this cleavage was stimulated by Mn²⁺ or Ca²⁺ ions. A lack of HtrC did not stabilize YpeB or SleB during spore formation in the absence of the partner protein, indicating other proteases are involved in their degradation during sporulation.     

Crystal structure of the PepSY‐containing domain of the YpeB protein involved in germination of bacillus spores

The crystal structure of the C‐terminal domain of the Bacillus megaterium YpeB protein has been solved by X‐ray crystallography to 1.80‐Å resolution. The full‐length protein is essential in stabilising the SleB cortex lytic enzyme in Bacillus spores, and may have a role in regulating SleB activity during spore germination. The YpeB‐C crystal structure comprises three tandemly repeated PepSY domains, which are aligned to form an extended laterally compressed molecule. A predominantly positively charged region located in the second PepSY domain may provide a site for protein interactions that are important in stabilising SleB and YpeB within the spore. Proteins 2015; 83:1914–1921. © 2015 Wiley Periodicals, Inc.     

Development of natto with germination-defective mutants of <Emphasis Type="Italic">Bacillus subtilis</Emphasis> (<Emphasis Type="Italic">natto</Emphasis>)

The effects of cortex-lysis related genes with the pdaA, sleB, and cwlD mutations of Bacillus subtilis (natto) NAFM5 on sporulation and germination were investigated. Single or double mutations did not prevent normal sporulation, but did affect germination. Germination was severely inhibited by the double mutation of sleB and cwlD. The quality of natto made with the sleB cwlD double mutant was tested, and the amounts of glutamic acid and ammonia were very similar to those in the wild type. The possibility of industrial development of natto containing a reduced number of viable spores is presented.     

The Products of the spoVA Operon Are Involved in Dipicolinic Acid Uptake into Developing Spores of Bacillus subtilis

Bacillus subtilis cells with mutations in the spoVA operon do not complete sporulation. However, a spoVA strain with mutations that remove all three of the spore's functional nutrient germinant receptors (termed the ger3 mutations) or the cortex lytic enzyme SleB (but not CwlJ) did complete sporulation. ger3 spoVA and sleB spoVA spores lack dipicolinic acid (DPA) and have lower core wet densities and levels of wet heat resistance than wild-type or ger3 spores. These properties of ger3 spoVA and sleB spoVA spores are identical to those of ger3 spoVF and sleB spoVF spores that lack DPA due to deletion of the spoVF operon coding for DPA synthetase. Sporulation in the presence of exogenous DPA restored DPA levels in ger3 spoVF spores to 53% of the wild-type spore levels, but there was no incorporation of exogenous DPA into ger3 spoVA spores. These data indicate that one or more products of the spoVA operon are involved in DPA transport into the developing forespore during sporulation.     

Mutational Analysis of Bacillus megaterium QM B1551 Cortex-Lytic Enzymes

Molecular-genetic and muropeptide analysis techniques have been applied to examine the function in vivo of the Bacillus megaterium QM B1551 SleB and SleL proteins. In common with Bacillus subtilis and Bacillus anthracis, the presence of anhydromuropeptides in B. megaterium germination exudates, which is indicative of lytic transglycosylase activity, is associated with an intact sleB structural gene. B. megaterium sleB cwlJ double mutant strains complemented with engineered SleB variants in which the predicted N- or C-terminal domain has been deleted (SleB-ΔN or SleB-ΔC) efficiently initiate and hydrolyze the cortex, generating anhydromuropeptides in the process. Additionally, sleB cwlJ strains complemented with SleB-ΔN or SleB-ΔC, in which glutamate and aspartate residues have individually been changed to alanine, all retain the ability to hydrolyze the cortex to various degrees during germination, with concomitant release of anhydromuropeptides to the surrounding medium. These data indicate that while the presence of either the N- or C-terminal domain of B. megaterium SleB is sufficient for initiation of cortex hydrolysis and the generation of anhydromuropeptides, the perceived lytic transglycosylase activity may be derived from an enzyme(s), perhaps exclusively or in addition to SleB, which has yet to be identified. B. megaterium SleL appears to be associated with the epimerase-type activity observed previously in B. subtilis, differing from the glucosaminidase function that is apparent in B. cereus/B. anthracis.Spores of the genera Bacillus and Clostridium emerge from dormancy via the process of germination. The germination process comprises a series of sequential biophysical and biochemical reactions that result irreversibly in the spore losing its properties of metabolic dormancy and extreme resistance to various chemical and physical treatments (24, 34). Germination is initiated by the presumed binding of small molecular germinants, commonly amino acids or sugars, to cognate receptors located within the spore inner membrane (25, 28). In a process that is poorly understood at the molecular level, this interaction leads to a change in the permeability of the inner membrane, resulting in the release of various solutes from the spore core, including metal ions, calcium dipicolinate (Ca-DPA), and some amino acids (32, 33, 35). A degree of rehydration of the core is evident at or around the same time, although this is insufficient to permit a significant degree of vegetative metabolism (9, 31). These events, which appear common to all Bacillus species where examined, comprise stage I of germination (31, 32, 34).The major event in stage II of the germination process from a biochemical perspective involves depolymerization of the spore cortex. The spore cortex is a thick layer of peptidoglycan, characterized by the spore-specific muramic acid lactam (MAL) moiety (37, 38), which, together with the thin inner layer of germ cell wall peptidoglycan (36), forms contiguous layers that entirely envelope the spore protoplast. While the germ cell wall forms the initial cell wall during vegetative outgrowth, the spore cortex serves primarily to maintain the relatively dehydrated status of the spore protoplast during dormancy (13). Dissolution of the cortex permits complete hydration of the spore core and resumption of vegetative metabolism, leading ultimately to shedding of the spore coat and the emergence of a new vegetative cell (34).A number of studies have indicated that spores of various Bacillus species employ two cortex-lytic enzymes (CLEs), SleB and CwlJ, to initiate hydrolysis of the cortex during stage II of the germination process (16, 19, 32). These enzymes are semiredundant; hence, strains bearing null mutations in either structural gene can still degrade the cortex sufficiently to complete germination, whereas double mutant strains do not appear capable of degrading the cortex at all, resulting typically in a decrease of several orders of magnitude in colony-forming ability (15, 19, 32). Other enzymes, including Bacillus cereus/Bacillus anthracis SleL, are also involved in stage II of germination, apparently hydrolyzing peptidoglycan products of SleB and/or CwlJ to smaller peptidoglycan fragments that can more easily permeate through the spore coats to the surrounding germination medium (21).Studies with SleB and SleL purified from dormant and germinating spores indicate that whereas the latter enzyme degrades only cortical fragments of peptidoglycan (7), SleB has a requirement for intact peptidoglycan that has adopted the precise architecture present within the spore (12, 22). These substrate requirements appear to be important in maintenance of the respective autolysins, which are present in the spore in a mature form, in an inactive state during dormancy. Additionally, whereas the molecular mechanism of activation of SleB remains unclear—a change in cortical stress/architecture induced by stage I events has been hypothesized (12)—the efflux of Ca-DPA from the spore core to the cortex/coat boundary where CwlJ is localized (5) appears to be the mechanism by which this CLE is activated. CwlJ can also be activated by high concentrations of exogenous Ca-DPA, presenting an alternative germination pathway that bypasses the germinant receptors (27).The hydrolytic bond specificity of various CLEs has been examined by both direct and indirect biochemical means. Direct assays are typically conducted by incubation of purified or recombinant enzymes with peptidoglycan fragments or suspensions of spores in which the cortex is rendered accessible by first chemically compromising the permeability of the spore coats (7, 12, 22). Subsequent assays for the generation of reducing groups and/or free amino groups can yield information on the probable hydrolytic bond specificity of the respective enzyme(s) being assayed.More recently, the high-performance liquid chromatography/mass spectrometry (HPLC/MS)-based muropeptide analysis technique has been applied to characterize CLE activity during germination of various spore-forming species (2, 4, 10). This methodology has the resolution to reveal fine structural changes that occur to the peptidoglycan in vivo during germination, and when used in combination with CLE null mutant strains, it can be used to indirectly correlate the generation of certain classes of muropeptides, and therefore the hydrolytic bond specificity, with defined CLEs. Muropeptide analysis has revealed, for example, that an intact copy of the sleB gene in B. subtilis and B. anthracis is required for the presence of anhydromuropeptides in the germination exudates of these respective species, indicating that SleB is a lytic transglycosylase or generates substrate for subsequent lytic transglycosylase activity (6, 16). Conversely, B. cereus SleB was characterized as a probable amidase after enzyme purified from germinating spores was found to liberate a large amount of free amino groups when incubated with coat-stripped spores as a substrate (22). The hydrolytic bond specificity of SleB therefore remains ambiguous and perhaps varies between different species.Contrary to these observations, the overall structural architecture of SleB appears to be well conserved between different Bacillus species. Alignment of the primary amino acid sequence from different species indicates that the mature protein comprises an N-terminal domain that is connected to the C-terminal domain by a linker region that is variable in length and amino acid composition (Fig. ​(Fig.1).1). The N-terminal domain is thought to comprise the peptidoglycan binding domain by virtue of two direct sequence repeats that are reminiscent of cell wall-binding motifs observed in other proteins (26). The C-terminal domain shows homology with that of the other major Bacillus CLE, CwlJ, which lacks a corresponding peptidoglycan binding domain and is therefore thought to comprise the catalytic domain (19), although there is as yet no experimental evidence to substantiate this idea.Open in a separate windowFIG. 1.ClustalW alignment of SleB from various Bacillus species. Residues predicted to comprise putative structural domains are denoted. Stars indicate charged residues that were subjected to amino acid substitution in this work. BM, B. megaterium QM B1551; BC, B. cereus W; BCl, B. clausii KSM-K16; BS, B. subtilis 168.In the current study, we have investigated the molecular function of SleB during germination of Bacillus megaterium QM B1551 spores, employing engineered SleB N- and C-terminal deletion strains, site-directed mutagenesis (SDM), and muropeptide analyses. In addition to revealing several cortex-modifying activities during germination of this species, the presented data indicate that while the presence of either the N- or C-terminal domain of SleB is sufficient for the generation of anhydromuropeptides during germination, this may be an indirect effect, and at least a degree of lytic transglycosylase activity may result from the activity of another as yet unidentified enzyme.     

Studies of the Commitment Step in the Germination of Spores of Bacillus Species

Spores of Bacillus species are said to be committed when they continue through nutrient germination even when germinants are removed or their binding to spores'' nutrient germinant receptors (GRs) is both reversed and inhibited. Measurement of commitment and the subsequent release of dipicolinic acid (DPA) during nutrient germination of spores of Bacillus cereus and Bacillus subtilis showed that heat activation, increased nutrient germinant concentrations, and higher average levels of GRs/spore significantly decreased the times needed for commitment, as well as lag times between commitment and DPA release. These lag times were also decreased dramatically by the action of one of the spores'' two redundant cortex lytic enzymes (CLEs), CwlJ, but not by the other CLE, SleB, and CwlJ action did not affect the timing of commitment. The timing of commitment and the lag time between commitment and DPA release were also dependent on the specific GR activated to cause spore germination. For spore populations, the lag times between commitment and DPA release were increased significantly in spores that germinated late compared to those that germinated early, and individual spores that germinated late may have had lower appropriate GR levels/spore than spores that germinated early. These findings together provide new insight into the commitment step in spore germination and suggest several factors that may contribute to the large heterogeneity among the timings of various events in the germination of individual spores in spore populations.Spores of Bacillus species can remain dormant for long times and are extremely resistant to a variety of environmental stresses (26). However, under appropriate conditions, normally upon the binding of specific nutrients to spores'' nutrient germinant receptors (GRs), spores can come back to active growth through a process called germination followed by outgrowth (19, 20, 25, 26). Germination of Bacillus subtilis spores can be triggered by l-alanine or l-valine or a combination of l-asparagine, d-glucose, d-fructose, and K⁺ (AGFK). These nutrient germinants trigger germination by binding to and interacting with GRs that have been localized to the spore''s inner membrane (12, 20). l-Alanine and l-valine bind to the GerA GR, while the AGFK mixture triggers germination by interacting with both the GerB and GerK GRs (25). Normally, l-asparagine alone does not trigger B. subtilis spore germination. However, a mutant form of the GerB GR, termed GerB*, displays altered germinant specificity such that l-asparagine alone will trigger the germination of gerB* mutant spores (1, 18).A number of events occur in a defined sequence during spore germination. Initially, exposure of spores to nutrient germinants causes a reaction that commits spores to germinate, even if the germinant is removed or displaced from its cognate GR (7, 10, 21, 27, 28). This commitment step is followed by release of monovalent cations, as well as the spore core''s large pool of pyridine-2,6-dicarboxylic acid (dipicolinic acid [DPA]) along with divalent cations, predominantly Ca²⁺, that are chelated with DPA (Ca-DPA). In Bacillus spores, the release of Ca-DPA triggers the hydrolysis of spores'' peptidoglycan cortex by either of two cortex lytic enzymes (CLEs), CwlJ and SleB (11, 16, 23). CwlJ is activated during germination by Ca-DPA as it is being released from individual spores, while SleB activation requires that most Ca-DPA be released (14, 16, 17). Cortex hydrolysis, in turn, allows the spore core to expand and fully hydrate, which leads to activation of enzymes and initiation of metabolism in the spore core (21, 25).As noted above, commitment is the first event that can be assessed during spore germination, although the precise mechanism of commitment is not known. Since much has been learned about proteins important in spore germination in the many years since commitment was last studied (25, 26), it seemed worth reexamining commitment, with the goal of determining those factors that influence this step in the germination process. Knowledge of factors important in determining kinetics of commitment could then lead to an understanding of what is involved in this reaction.Kinetic analysis of spore germination, as well as commitment, has mostly been based on the decrease in optical density at 600 nm (OD₆₀₀) of spore suspensions, which monitors a combination of events that occur well after commitment, including DPA release, cortex hydrolysis, and core swelling (25-27). In the current work, we have used a germination assay that measures DPA release, an early event in spore germination, and have automated this assay to allow routine measurement of commitment, as well as DPA release from large numbers of spore samples simultaneously. This assay has allowed comparison of the kinetics of DPA release and commitment during germination and study of the effects of heat activation, germinant concentration, GR levels, and CLEs on commitment.     

Involvement of Coat Proteins in Bacillus subtilis Spore Germination in High-Salinity Environments

The germination of spore-forming bacteria in high-salinity environments is of applied interest for food microbiology and soil ecology. It has previously been shown that high salt concentrations detrimentally affect Bacillus subtilis spore germination, rendering this process slower and less efficient. The mechanistic details of these salt effects, however, remained obscure. Since initiation of nutrient germination first requires germinant passage through the spores'' protective integuments, the aim of this study was to elucidate the role of the proteinaceous spore coat in germination in high-salinity environments. Spores lacking major layers of the coat due to chemical decoating or mutation germinated much worse in the presence of NaCl than untreated wild-type spores at comparable salinities. However, the absence of the crust, the absence of some individual nonmorphogenetic proteins, and the absence of either CwlJ or SleB had no or little effect on germination in high-salinity environments. Although the germination of spores lacking GerP (which is assumed to facilitate germinant flow through the coat) was generally less efficient than the germination of wild-type spores, the presence of up to 2.4 M NaCl enhanced the germination of these mutant spores. Interestingly, nutrient-independent germination by high pressure was also inhibited by NaCl. Taken together, these results suggest that (i) the coat has a protective function during germination in high-salinity environments; (ii) germination inhibition by NaCl is probably not exerted at the level of cortex hydrolysis, germinant accessibility, or germinant-receptor binding; and (iii) the most likely germination processes to be inhibited by NaCl are ion, Ca²⁺-dipicolinic acid, and water fluxes.     

Monitoring Rates and Heterogeneity of High-Pressure Germination of Bacillus Spores by Phase-Contrast Microscopy of Individual Spores

Germination of Bacillus spores with a high pressure (HP) of ∼150 MPa is via activation of spores'' germinant receptors (GRs). The HP germination of multiple individual Bacillus subtilis spores in a diamond anvil cell (DAC) was monitored with phase-contrast microscopy. Major conclusions were that (i) >95% of wild-type spores germinated in 40 min in a DAC at ∼150 MPa and 37°C but individual spores'' germination kinetics were heterogeneous; (ii) individual spores'' HP germination kinetic parameters were similar to those of nutrient-triggered germination with a variable lag time (T_lag) prior to a period of the rapid release (ΔT_release) of the spores'' dipicolinic acid in a 1:1 chelate with Ca²⁺ (CaDPA); (iii) spore germination at 50 MPa had longer average T_lag values than that at ∼150 MPa, but the ΔT_release values at the two pressures were identical and HPs of <10 MPa did not induce germination; (iv) B. subtilis spores that lacked the cortex-lytic enzyme CwlJ and that were germinated with an HP of 150 MPa exhibited average ΔT_release values ∼15-fold longer than those for wild-type spores, but the two types of spores exhibited similar average T_lag values; and (v) the germination of wild-type spores given a ≥30-s 140-MPa HP pulse followed by a constant pressure of 1 MPa was the same as that of spores exposed to a constant pressure of 140 MPa that was continued for ≥35 min; (vi) however, after short 150-MPa HP pulses and incubation at 0.1 MPa (ambient pressure), spore germination stopped 5 to 10 min after the HP was released. These results suggest that an HP of ∼150 MPa for ≤30 s is sufficient to fully activate spores'' GRs, which remain activated at 1 MPa but can deactivate at ambient pressure.     

Role of dipicolinic acid in the germination, stability, and viability of spores of Bacillus subtilis

Spores of Bacillus subtilis spoVF strains that cannot synthesize dipicolinic acid (DPA) but take it up during sporulation were prepared in medium with various DPA concentrations, and the germination and viability of these spores as well as the DPA content in individual spores were measured. Levels of some other small molecules in DPA-less spores were also measured. These studies have allowed the following conclusions. (i) Spores with no DPA or low DPA levels that lack either the cortex-lytic enzyme (CLE) SleB or the receptors that respond to nutrient germinants could be isolated but were unstable and spontaneously initiated early steps in spore germination. (ii) Spores that lacked SleB and nutrient germinant receptors and also had low DPA levels were more stable. (iii) Spontaneous germination of spores with no DPA or low DPA levels was at least in part via activation of SleB. (iv) The other redundant CLE, CwlJ, was activated only by the release of high levels of DPA from spores. (v) Low levels of DPA were sufficient for the viability of spores that lacked most alpha/beta-type small, acid-soluble spore proteins. (vi) DPA levels accumulated in spores prepared in low-DPA-containing media varied greatly between individual spores, in contrast to the presence of more homogeneous DPA levels in individual spores made in media with high DPA concentrations. (vii) At least the great majority of spores of several spoVF strains that contained no DPA also lacked other major spore small molecules and had gone through some of the early reactions in spore germination.     

Effects of cortex peptidoglycan structure and cortex hydrolysis on the kinetics of Ca(2+)-dipicolinic acid release during Bacillus subtilis spore germination

The kinetic parameters of the release of Ca(2+)-dipicolinic acid (CaDPA) during germination of spore populations and multiple individual spores of Bacillus subtilis strains with major alterations in the structure of the spore peptidoglycan (PG) cortex or lacking one or both of the two redundant enzymes involved in cortex hydrolysis (cortex-lytic enzymes [CLEs]) were determined. The lack of the CLE CwlJ greatly slowed CaDPA release with a germinant receptor (GR)-dependent germinant, l-valine, or a non-GR-dependent germinant, dodecylamine. The absence of the cortex-specific PG modification muramic acid-δ-lactam also increased the time needed for full CaDPA release during germination with both types of germinants. In contrast, increased cortex PG cross-linking was associated with faster times for initiation of CaDPA release with both l-valine and dodecylamine but not with faster CaDPA release once this release had been initiated. These data suggest that the precise structure of the spore cortex plays a significant role in determining the timing and the rate of CaDPA release during B. subtilis spore germination and, further, that this effect is independent of effects of GRs.     

SleC Is Essential for Germination of Clostridium difficile Spores in Nutrient-Rich Medium Supplemented with the Bile Salt Taurocholate

Clostridium difficile is the major cause of infectious diarrhea and a major burden to health care services. The ability of this organism to form endospores plays a pivotal role in infection and disease transmission. Spores are highly resistant to many forms of disinfection and thus are able to persist on hospital surfaces and disseminate infection. In order to cause disease, the spores must germinate and the organism must grow vegetatively. Spore germination in Bacillus is well understood, and genes important for this process have recently been identified in Clostridium perfringens; however, little is known about C. difficile. Apparent homologues of the spore cortex lytic enzyme genes cwlJ and sleB (Bacillus subtilis) and sleC (C. perfringens) are present in the C. difficile genome, and we describe inactivation of these homologues in C. difficile 630Δerm and a B1/NAP1/027 clinical isolate. Spores of a sleC mutant were unable to form colonies when germination was induced with taurocholate, although decoated sleC spores formed the same number of heat-resistant colonies as the parental control, even in the absence of germinants. This suggests that sleC is absolutely required for conversion of spores to vegetative cells, in contrast to CD3563 (a cwlJ/sleB homologue), inactivation of which had no effect on germination and outgrowth of C. difficile spores under the same conditions. The B1/NAP1/027 strain {"type":"entrez-nucleotide","attrs":{"text":"R20291","term_id":"774925","term_text":"R20291"}}R20291 was found to sporulate more slowly and produce fewer spores than 630Δerm. Furthermore, fewer {"type":"entrez-nucleotide","attrs":{"text":"R20291","term_id":"774925","term_text":"R20291"}}R20291 spores germinated, indicating that there are differences in both sporulation and germination between these epidemic and nonepidemic C. difficile isolates.The Gram-positive anaerobe Clostridium difficile causes diarrheal diseases ranging from asymptomatic carriage to a fulminant, relapsing, and potentially fatal colitis (8, 30). This organism is resistant to various broad-spectrum antibiotics and capitalizes on disruption of the normal intestinal flora to colonize and cause disease symptoms through the action of toxins A and B (16, 40). While these toxins are the principal virulence factors, the ability of the organism to produce endospores is necessary for disease transmission.Clostridial spores are extremely resistant to all kinds of chemical and physical agents and provide the mechanism by which C. difficile can evade the potentially fatal consequences of exposure to heat, oxygen, alcohol, and certain disinfectants (35). Thus, the spores shed in fecal matter are very difficult to eradicate and can persist on contaminated surfaces in health care facilities for extended periods of time (35). This leads to infection or reinfection of cohabitating individuals through inadvertent ingestion of infected material (10, 32). Once in the anaerobic environment of the gut, spores presumably germinate to form toxin-producing vegetative cells and, in susceptible individuals, diarrheal disease.Spore germination is defined as the events that result in the irreversible loss of spore characteristics. However, current mechanistic knowledge of the germination process is based principally on data derived from studying Bacillus subtilis. Little is known about spore germination in clostridia and, in particular, in C. difficile. Germination is initiated when the bacterial spore senses specific effectors, termed germinants. These effectors can include nutrients, cationic surfactants, peptidoglycan, and a 1:1 chelate of pyridine-2,6-dicarboxylic acid (dipicolinic acid) and Ca²⁺ (CaDPA) (23, 34, 36). Spores of B. subtilis can germinate in response to nutrients through the participation of three sensory receptors located in the spore inner membrane, GerA, GerB, and GerK (23). After activation, the events include the release of monovalent cations (H⁺, K⁺, and Na⁺) and CaDPA (accounting for approximately 10% of the spore dry weight) (36). The third major step in germination involves hydrolysis of the spore peptidoglycan (PG) cortex. It is during this hydrolysis that the previously low water content of the spore is restored to the water content of a normal vegetative cell and the core is able to expand, which in turn allows enzyme activity, metabolism, and spore outgrowth (36).CwlJ and SleB are two specific spore cortex-lytic enzymes (SCLEs) involved in Bacillus cortex hydrolysis, which break down PG containing muramic-δ-lactam (28). SleB has been shown to localize in both the inner and outer layers of B. subtilis spores through interaction of the enzyme peptidoglycan-binding motif and the δ-lactam structure of the cortex (7, 19) and in association with YpeB, which is required for sleB expression during sporulation (4, 7). SleB is a lytic transglycosylase muramidase, but so far its mode of activation is unknown (21). CwlJ is localized to the spore coat during sporulation (3) and is required for CaDPA-induced germination in B. subtilis. Activation can be due to either CaDPA released from the spore core at the onset of germination or exogenous CaDPA (22). Neither enzyme is individually essential for complete cortex hydrolysis during nutrient germination, although inactivation of both cwlJ and sleB in B. subtilis results in a spore unable to complete this process (15). The role of SleL has recently been studied in Bacillus anthracis. Mutants unable to produce this enzyme are still able to germinate, but the process is retarded (18).The SCLEs of Clostridium are less well studied than those of Bacillus. The SCLEs SleC (20) and SleM (6) have been identified in Clostridium perfringens, and a recent study demonstrated that SleC is required during germination for complete cortex hydrolysis (26). Although SleM can degrade spore cortex peptidoglycan and inactivation of both sleC and sleM decreased the ability of spores to germinate more than inactivation of sleC alone did, SleM was not essential (26). It has also been shown that the germination-specific serine protease CspB is essential for cortex hydrolysis and converts the inactive pro-SleC found in dormant spores to an active enzyme (24). So far, there has been no detailed study of any gene responsible for spore germination in C. difficile, although genes showing homology to cwlJ and sleB of B. subtilis (CD3563) and sleC of C. perfringens (CD0551) have now been identified in the C. difficile 630 genome (33).With germinant receptors in C. difficile yet to be identified, the mechanism by which the spores sense a suitable environment for germination is unclear. Recent studies have suggested that this process may involve the interaction of C. difficile with bile. Taurocholate has been shown to enhance recovery of C. difficile spores in nutrient-rich medium (42), and it has been proposed that glycine and taurocholate act as cogerminants (38), while chenodeoxycholate inhibits C. difficile spore germination (39).The emergence of C. difficile B1/NAP1/027 strains has increased the burden on health care services worldwide. Such strains have been shown to produce higher levels of toxin in the laboratory than many other types of strains (41), although the mechanism behind this production is not fully understood. However, while the observed higher levels of toxin production is doubtless important, perhaps the recent attention given to B1/NAP1/027 strains has focused too much on toxins. As spores represent the infectious stage of C. difficile, processes such as spore germination may also contribute to the greater virulence of these strains. In this study we evaluated the sporulation and germination efficiencies of an “epidemic” B1/NAP1/027 C. difficile strain ({"type":"entrez-nucleotide","attrs":{"text":"R20291","term_id":"774925","term_text":"R20291"}}R20291, isolated from the Stoke Mandeville outbreak in 2004 and 2005) and the “nonepidemic” strain 630Δerm (14). We then constructed strains with mutations in CD3563 (a cwlJ/sleB homologue) and a sleC homologue to analyze the role of these genes in the germination of C. difficile spores.     

Levels of Germination Proteins in Bacillus subtilis Dormant,Superdormant, and Germinating Spores

Bacterial endospores exhibit extreme resistance to most conditions that rapidly kill other life forms, remaining viable in this dormant state for centuries or longer. While the majority of Bacillus subtilis dormant spores germinate rapidly in response to nutrient germinants, a small subpopulation termed superdormant spores are resistant to germination, potentially evading antibiotic and/or decontamination strategies. In an effort to better understand the underlying mechanisms of superdormancy, membrane-associated proteins were isolated from populations of B. subtilis dormant, superdormant, and germinated spores, and the relative abundance of 11 germination-related proteins was determined using multiple-reaction-monitoring liquid chromatography-mass spectrometry assays. GerAC, GerKC, and GerD were significantly less abundant in the membrane fractions obtained from superdormant spores than those derived from dormant spores. The amounts of YpeB, GerD, PrkC, GerAC, and GerKC recovered in membrane fractions decreased significantly during germination. Lipoproteins, as a protein class, decreased during spore germination, while YpeB appeared to be specifically degraded. Some protein abundance differences between membrane fractions of dormant and superdormant spores resemble protein changes that take place during germination, suggesting that the superdormant spore isolation procedure may have resulted in early, non-committal germination-associated changes. In addition to low levels of germinant receptor proteins, a deficiency in the GerD lipoprotein may contribute to heterogeneity of spore germination rates. Understanding the reasons for superdormancy may allow for better spore decontamination procedures.