GerO,a Putative Na+/H+-K+ Antiporter,Is Essential for Normal Germination of Spores of the Pathogenic Bacterium Clostridium perfringens

The genome of the pathogen Clostridium perfringens encodes two proteins, GerO and GerQ, homologous to monovalent cation transporters suggested to have roles in the germination of spores of some Bacillus species. GerO and GerQ were able to transport monovalent cations (K⁺ and/or Na⁺) in Escherichia coli, and gerO and gerQ were expressed only in the mother cell compartment during C. perfringens sporulation. C. perfringens spores lacking GerO were defective in germination with a rich medium, KCl, l-asparagine, and a 1:1 chelate of Ca²⁺ and dipicolinic acid (DPA), but not with dodecylamine, and the defect was prior to DPA release in germination. All defects in gerO spores were complemented by ectopic expression of wild-type gerO. Loss of GerQ had much smaller effects on spore germination, and these effects were most evident in spores also lacking GerO. A modeled structure of GerO was similar to that of the E. coli Na⁺/H⁺ antiporter NhaA, and GerO, but not GerQ contained two adjacent Asp residues thought to be important in the function of this group of cation transporters. Replacement of these adjacent Asp residues in GerO with Asn reduced the protein''s ability to complement the germination defect in gerO spores but not the ability to restore cation transport to E. coli cells defective in K⁺ uptake. Together, these data suggest that monovalent cation transporters play some role in C. perfringens spore germination. However, it is not clear whether this role is directly in germination or perhaps in spore formation.Clostridium perfringens is a gram-positive, spore-forming anaerobic pathogen that causes diseases in animals and humans (13). C. perfringens spores are metabolically dormant, are resistant to many environmental insults, and can survive for long periods. Once conditions are favorable, these spores can germinate, outgrow, return to vegetative growth, and then release toxins and cause disease (14).Bacterial spores initiate germination when they sense a variety of compounds termed germinants, which include nutrients, a 1:1 chelate of Ca²⁺ and pyridine-2,6-dicarboxylic acid (dipicolinic acid [DPA]) (Ca-DPA) and cationic surfactants (21, 31). In spores of Bacillus species, nutrient germinants are sensed by specific germinant receptors located in the spore''s inner membrane, each generally encoded by tricistronic operons of the gerA family. In Bacillus megaterium spores, the interaction of nutrient germinants with their cognate receptors leads to an energy independent efflux of ∼80% of the spore''s depot of Na⁺ and K⁺, as well as much H⁺ efflux causing a rise of the spore core''s pH, all within the first 5 min of germination; this efflux is followed by reuptake of K⁺ by an energy-dependent system (33). The spores'' large depot of Ca-DPA is also released shortly after monovalent cation release. The mechanism of release of monovalent cations during spore germination is not known, but monovalent cation antiporters could be involved somehow in this event. Indeed, a member of the CPA-2 monovalent cation-proton antiporter family of membrane transport proteins (27), GrmA, is essential for germination of B. megaterium ATCC 12872 spores (34), since grmA inactivation makes spores unable to release their DPA and complete germination with a variety of germinants. Similarly, in Bacillus cereus ATCC 10876, a GrmA-type homologue, GerN, is essential for spore germination with inosine but not l-alanine (35), and studies with everted vesicles have shown that GerN possesses electrogenic Na⁺/H⁺-K⁺ antiporter activity (32). The GerN homolog, GerT, also plays a minor role in B. cereus spore germination with inosine, as well as a major role in spore outgrowth under some conditions (29). However, in contrast to these latter results, GrmA-like antiporters appear to have no role in the germination of spores of B. megaterium QM B1551 and Bacillus subtilis (3).In C. perfringens, there is no intact tricistronic gerA-like operon, and the only locus that encodes the three proteins (A, B, and C) of a likely germinant receptor is the gerK locus, comprising a bicistronic gerKA-gerKC operon, and a gerKB gene located just upstream of gerKA-gerKC but in the opposite orientation (16). However, GerKA and GerKC appear able to function in spore germination in the absence of GerKB (23). The lack of a classical GerA-type germinant receptor and the fact that C. perfringens spores germinate with K⁺ ions alone (21), raises the possibility that GrmA-like antiporters might also play some role in C. perfringens spore germination. The genome of C. perfringens strain SM101 has two genes encoding putative GrmA-like antiporters (see Fig. S1 in the supplemental material) that we have termed gerO (CPR0227) and gerQ (CPR1038). Orthologs of the gerO and gerQ genes are also present in the genomes of nine additional C. perfringens strains (http://www.ncbi.nlm.nih.gov/genomes/lproks.cgi). In present study we have constructed gerO, gerQ, and gerO gerQ strains of C. perfringens and have examined the roles of GerO and GerQ in spore germination. The results show that GerO is essential for normal germination of C. perfringens spores, whereas GerQ plays at most only a minor role.     

Role of GerKB in Germination and Outgrowth of Clostridium perfringens Spores

Previous work indicated that Clostridium perfringens gerKA gerKC spores germinate significantly, suggesting that gerKB also has a role in C. perfringens spore germination. We now find that (i) gerKB was expressed only during sporulation, likely in the forespore; (ii) gerKB spores germinated like wild-type spores with nonnutrient germinants and with high concentrations of nutrients but more slowly with low nutrient concentrations; and (iii) gerKB spores had lower colony-forming efficiency and slower outgrowth than wild-type spores. These results suggest that GerKB plays an auxiliary role in spore germination under some conditions and is required for normal spore viability and outgrowth.Spores of Bacillus and Clostridium species can break dormancy upon sensing a variety of compounds (termed germinants), including amino acids, nutrient mixtures, a 1:1 chelate of Ca²⁺ and pyridine-2,6-dicarboxylic acid (dipicolinic acid [DPA]), and cationic surfactants such as dodecylamine (20). Nutrient germinants are sensed by their cognate receptors, located in the spore''s inner membrane (6), which are composed of proteins belonging to the GerA family (10, 11). In Bacillus subtilis, three tricistronic operons (gerA, gerB, and gerK) expressed uniquely during sporulation in the developing forespore each encode the three major germinant receptors, with different receptors responding to a different spectrum of nutrient germinants (5, 9, 20). Null mutations in any cistron in a gerA family operon inactivate the function of the respective receptor (9, 11). In contrast, Clostridium perfringens, a gram-positive, spore-forming, anaerobic pathogenic bacterium, has no tricistronic gerA-like operon but only a monocistronic gerAA that is far from a gerK locus. This locus contains a bicistronic gerKA-gerKC operon and a monocistronic gerKB upstream of and in the opposite orientation to gerKA-gerKC (Fig. ​(Fig.1A)1A) (16). GerAA has an auxiliary role in the germination of C. perfringens spores at low germinant concentrations, while GerKA and/or GerKC are required for l-asparagine germination and have partial roles in germination with KCl and a mixture of KCl and l-asparagine (AK) (16). In contrast to the situation with B. subtilis, where germinant receptors play no role in Ca-DPA germination (12, 13), GerKA and/or GerKC is required for Ca-DPA germination (16). The partial requirement for GerKA and/or GerKC in C. perfringens spore germination by KCl and AK suggests that the upstream gene product, GerKB, might also have some role in KCl and AK germination of C. perfringens spores. Therefore, in this study we have investigated the role of GerKB in the germination and outgrowth of C. perfringens spores.Open in a separate windowFIG. 1.Arrangement and expression of gerKB in C. perfringens SM101. (A) The arrangement of the gerK locus in C. perfringens SM101 is shown, and the locations of the primers used to amplify the upstream regions of the gerKB gene and the putative promoters of gerKB and gerKA are indicated. The gerKB promoter was predicted to be within the intergenic regions between gerKB and the gerK operon. (B) GUS specific activities from the gerKB-gusA fusion in strain SM101(pDP84) grown in TGY vegetative (filled squares) and DS sporulation (open squares) media were determined as described in the text. Data represent averages from three independent experiments with the error bars representing standard deviations, and time zero denotes the time of inoculation of cells into either TGY or DS medium.To determine if gerKB is expressed during sporulation, 485 bp upstream of the gerKB coding sequence, including DNA between gerKB and gerKA, was PCR amplified with primer pair CPP389/CPP391, which had SalI and PstI cleavage sites, respectively (see Table S2 in the supplemental material). The PCR fragment was cloned between SalI and PstI cleavage sites in plasmid pMRS127 (17) to create a gerKB-gusA fusion in plasmid pDP84 (see Table S1 in the supplemental material). This plasmid was introduced into C. perfringens SM101 by electroporation (3), and Em^r transformants were selected. The SM101 transformant carrying plasmid pDP84 was grown in TGY vegetative growth medium (3% Trypticase soy, 2% glucose, 1% yeast extract, 0.1% l-cysteine) (7) and in Duncan-Strong (DS) (4) sporulation medium and assayed for β-glucuronidase (GUS) activity as described previously (23). Vegetative cultures of strain SM101 carrying plasmid pMRS127 (empty vector) or pDP84 (gerKB-gusA) exhibited no significant GUS activity, and strain SM101 grown in DS medium also exhibited no significant GUS activity (Fig. ​(Fig.1B1B and data not shown). However, GUS activity was observed in sporulating cultures of SM101(pDP84) (Fig. ​(Fig.1B),1B), indicating that a sporulation-specific promoter is located upstream of gerKB. The expression of the gerKB-gusA fusion began ∼3 h after induction of sporulation and reached a maximum after ∼6 h of sporulation (Fig. ​(Fig.1B).1B). The decrease in GUS activity observed after ∼6 h is consistent with the GerKB-GusA protein being packaged into the dormant spore where it cannot be easily assayed and thus with gerKB being expressed in the forespore compartment of the sporulating cell (8). These results confirm that, as with the gerKA-gerKC operon (16), gerKB is also expressed only during sporulation.To investigate the role of GerKB in C. perfringens spore germination, we constructed a gerKB mutant strain (DPS108) as described previously (14-16). A 2,203-bp DNA fragment carrying 2,080 bp upstream of and 123 bp from the N-terminal coding region of gerKB was PCR amplified using primers CPP369 and CPP367, which had XhoI and BamHI cleavage sites at the 5′ ends of the forward and reverse primers, respectively (see Table S2 in the supplemental material). A 1,329-bp fragment carrying 134 bp from the C-terminal and 1,195 bp downstream of the coding region of gerKB was PCR amplified using primers CPP371 and CPP370, which had BamHI and KpnI cleavage sites at the 5′ ends of the forward and reverse primers, respectively (see Table S2 in the supplemental material). These PCR fragments were cloned into plasmid pCR-XL-TOPO, giving plasmids pDP67 and pDP69, respectively (see Table S1 in the supplemental material). An ∼2.2-kb BamHI-XhoI fragment from pDP67 was cloned into pDP1 (pCR-XL-TOPO carrying an internal fragment of gerAA), giving plasmid pDP68, and an ∼1.4-kb KpnI-BamHI fragment from pDP69 was cloned in pDP68, giving pDP73 (see Table S1 in the supplemental material). The latter plasmid was digested with BamHI, the ends were filled, and an ∼1.3-kb NaeI-SmaI fragment carrying catP from pJIR418 (1) was inserted, giving plasmid pDP74. Finally, an ∼4.8-kb KpnI-XhoI fragment from pDP74 (see Table S1 in the supplemental material) was cloned between the KpnI and SalI sites of pMRS104, giving pDP75, which cannot replicate in C. perfringens. Plasmid pDP75 was introduced into C. perfringens SM101 by electroporation (3), and the gerKB deletion strain DPS108 was isolated as described previously (18). The presence of the gerKB deletion in strain DPS108 was confirmed by PCR and Southern blot analyses (data not shown). Strain DPS108 gave ∼70% sporulating cells in DS sporulation medium, similar to results with the wild-type strain, SM101 (data not shown).Having obtained evidence for successful construction of the gerKB mutant, we compared the germinations of heat-activated (80°C; 10 min) gerKB and wild-type spores as previously described (16). Both the gerKB and wild-type spores germinated identically and nearly completely in 60 min at 40°C in brain heart infusion (BHI) broth as determined by the fall in optical density at 600 nm (OD₆₀₀) of germinating cultures and phase-contrast microscopy (data not shown). This result suggests that GerKB plays no essential role in spore germination in rich medium. The role of GerKB in C. perfringens spore germination was also assessed with individual germinants identified previously (16). Heat-activated wild-type and gerKB spores germinated similarly with high (100 mM) concentrations of KCl, l-asparagine, and AK, all in 25 mM sodium phosphate (pH 7.0), and in 50 mM Ca-DPA adjusted to pH 8.0 with Tris base (Fig. 2A to D). These results were also confirmed by phase-contrast microscopy (data not shown). However, with lower (10 to 20 mM) concentrations of KCl, l-asparagine, and AK, gerKB spore germination was very slightly (Fig. ​(Fig.2A)2A) to significantly (Fig. 2B and C) slower than that of wild-type spores. These results suggest that while GerKB is not essential for germination with high concentrations of KCl, l-asparagine, or AK, it plays a significant role in germination with low l-asparagine and AK concentrations and, further, that GerKB is not required for Ca-DPA germination. This latter finding is similar to the situation with B. subtilis spores where germinant receptors play no role in Ca-DPA germination (19, 20). However, in C. perfringens spores, GerKA and/or GerKC do play a significant role in Ca-DPA germination (16).Open in a separate windowFIG. 2.Germination of spores of C. perfringens strains with various germinants. Heat-activated spores of strains SM101 (wild type) (filled symbols) and DPS108 (gerKB) (open symbols) were incubated at an OD₆₀₀ of 1 at 40°C with high (squares) and low (triangles) germinant concentrations of 100 and 10 mM KCl (A), 100 and 20 mM l-asparagine (B), 100 and 10 mM AK (C), and 50 mM Ca-DPA (D) as described in the text, and at various times the OD₆₀₀ was measured. No significant germination was observed when heat-activated spores of SM101 and DPS108 were incubated for 60 min at 40°C in 25 mM sodium phosphate buffer (pH 7.0) (data not shown). The data shown are averages from duplicate determinations with two different spore preparations, and error bars represent standard deviations.Bacterial spores can also germinate with dodecylamine, a cationic surfactant (19). In B. subtilis spores, dodecylamine induces germination most likely by opening channels composed, at least in part, of SpoVA proteins (22), allowing release of the spores'' Ca-DPA (19). Spores of B. subtilis lacking all three functional germinant receptors release DPA, as do wild-type spores, upon incubation with dodecylamine (19), while C. perfringens spores lacking GerKA-GerKC incubated with dodecylamine release DPA slower than wild-type spores (16). However, when C. perfringens gerKB spores at an OD₆₀₀ of 1.5 were incubated with 1 mM dodecylamine in Tris-HCl (pH 7.4) at 60°C (2, 16), gerKB spores released their DPA slightly faster than wild-type spores (Fig. ​(Fig.3)3) when DPA release was measured as described previously (16). These results suggest that GerKB has no role in dodecylamine germination.Open in a separate windowFIG. 3.Germination of spores of C. perfringens strains with dodecylamine. Spores of strains SM101 (wild type) (filled squares) and DPS108 (gerKB) (open squares) were germinated with dodecylamine, and germination was monitored by measuring DPA release as described in the text. There was no significant DPA release in 60 min by spores incubated similarly but without dodecylamine (data not shown). Error bars represent standard deviations.Previous work (16) found that C. perfringens spores lacking GerKA-GerKC had lower viability than wild-type spores on rich medium plates, and it was thus of interest to determine gerKB spore viability, which was measured as previously described (14, 16). Strikingly, the colony-forming ability of gerKB spores was ∼7-fold lower (P < 0.01) than that of wild-type spores after 24 h on BHI plates (Table ​(Table1),1), and no additional colonies appeared when plates were incubated for up to 3 days (data not shown). The colony-forming ability of spores lacking GerKA and GerKC determined in parallel was ∼12-fold lower than that of wild-type spores (Table ​(Table1).1). Phase-contrast microscopy of C. perfringens spores incubated in BHI broth for 24 h under aerobic conditions to prevent vegetative cell growth indicated that >90% of wild-type spores not only had germinated but had also released the nascent vegetative cell, while >85% of gerKA gerKC and gerKB spores remained as only phase-dark germinated spores with no evidence of nascent cell release (data not shown), as found previously with gerKA gerKC spores (16). The fact that >85% of gerKB spores germinated in BHI medium in 24 h but most of these germinated spores did not progress further in development strongly suggests that GerKB is needed for normal spore outgrowth (and see below) as well as for normal spore germination.

TABLE 1.

Colony formation by spores of C. perfringens strains^a

The Effects of Heat Activation on Bacillus Spore Germination,with Nutrients or under High Pressure,with or without Various Germination Proteins

Nutrient germination of spores of Bacillus species occurs through germinant receptors (GRs) in spores'' inner membrane (IM) in a process stimulated by sublethal heat activation. Bacillus subtilis spores maximum germination rates via different GRs required different 75°C heat activation times: 15 min for l-valine germination via the GerA GR and 4 h for germination with the l-asparagine–glucose–fructose–K⁺ mixture via the GerB and GerK GRs, with GerK requiring the most heat activation. In some cases, optimal heat activation decreased nutrient concentrations for half-maximal germination rates. Germination of spores via various GRs by high pressure (HP) of 150 MPa exhibited heat activation requirements similar to those of nutrient germination, and the loss of the GerD protein, required for optimal GR function, did not eliminate heat activation requirements for maximal germination rates. These results are consistent with heat activation acting primarily on GRs. However, (i) heat activation had no effects on GR or GerD protein conformation, as probed by biotinylation by an external reagent; (ii) spores prepared at low and high temperatures that affect spores'' IM properties exhibited large differences in heat activation requirements for nutrient germination; and (iii) spore germination by 550 MPa of HP was also affected by heat activation, but the effects were relatively GR independent. The last results are consistent with heat activation affecting spores'' IM and only indirectly affecting GRs. The 150- and 550-MPa HP germinations of Bacillus amyloliquefaciens spores, a potential surrogate for Clostridium botulinum spores in HP treatments of foods, were also stimulated by heat activation.     

Analysis of the Dynamics of a Bacillus subtilis Spore Germination Protein Complex during Spore Germination and Outgrowth

Germination of Bacillus subtilis spores is normally initiated when nutrients from the environment interact with germinant receptors (GRs) in the spores'' inner membrane (IM), in which most of the lipids are immobile. GRs and another germination protein, GerD, colocalize in the IM of dormant spores in a small focus termed the “germinosome,” and this colocalization or focus formation is dependent upon GerD, which is also essential for rapid GR-dependent spore germination. To determine the fate of the germinosome and germination proteins during spore germination and outgrowth, we employed differential interference microscopy and epifluorescence microscopy to track germinating spores with fluorescent fusions to germination proteins and used Western blot analyses to measure germination protein levels. We found that after initiation of spore germination, the germinosome foci ultimately changed into larger disperse patterns, with ≥75% of spore populations displaying this pattern in spores germinated for 1 h, although >80% of spores germinated for 30 min retained the germinosome foci. Western blot analysis revealed that levels of GR proteins and the SpoVA proteins essential for dipicolinic acid release changed minimally during this period, although GerD levels decreased ∼50% within 15 min in germinated spores. Since the dispersion of the germinosome during germination was slower than the decrease in GerD levels, either germinosome stability is not compromised by ∼2-fold decreases in GerD levels or other factors, such as restoration of rapid IM lipid mobility, are also significant in germinosome dispersion as spore germination proceeds.     

Summer meeting 2013 – when the sleepers wake: the germination of spores of Bacillus species

Spores of Bacillus species can remain dormant and resistant for years, but can rapidly ‘come back to life’ in germination triggered by agents, such as specific nutrients, and non‐nutrients, such as CaDPA, dodecylamine and hydrostatic pressure. Major events in germination include release of spore core monovalent cations and CaDPA, hydrolysis of the spore cortex peptidoglycan (PG) and expansion of the spore core. This leads to a well‐hydrated spore protoplast in which metabolism and macromolecular synthesis begin. Proteins essential for germination include the GerP proteins that facilitate germinant access to spores' inner layers, germinant receptors (GRs) that recognize and respond to nutrient germinants, GerD important in rapid GR‐dependent germination, SpoVA proteins important in CaDPA release and cortex‐lytic enzymes that degrade cortex PG. Rates of germination of individuals in spore populations are heterogeneous, and methods have been developed recently to simultaneously analyse the germination of multiple individual spores. Spore germination heterogeneity is due primarily to large variations in GR levels among individual spores, with spores that germinate extremely slowly and termed superdormant having very low GR levels. These and other aspects of spore germination will be discussed in this review, and major unanswered questions will also be discussed.     

Numbers of Individual Nutrient Germinant Receptors and Other Germination Proteins in Spores of Bacillus subtilis

Germination of dormant Bacillus subtilis spores with specific nutrient germinants is dependent on a number of inner membrane (IM) proteins, including (i) the GerA, GerB, and GerK germinant receptors (GRs) that respond to nutrient germinants; (ii) the GerD protein, essential for optimal GR function; and (iii) SpoVA proteins, essential for the release of the spore-specific molecule dipicolinic acid (DPA) during spore germination. Levels of GR A and C subunit proteins, GerD, and SpoVAD in wild-type spores were determined by Western blot analysis of spore fractions or total disrupted spores by comparison with known amounts of purified proteins. Surprisingly, after disruption of decoated B. subtilis spores with lysozyme and fractionation, ∼90% of IM fatty acids and GR subunits remained with the spores'' insoluble integument fraction, indicating that yields of purified IM are low. The total lysate from disrupted wild-type spores contained ∼2,500 total GRs/spore: GerAA and GerAC subunits each at ∼1,100 molecules/spore and GerBC and GerKA subunits each at ∼700 molecules/spore. Levels of the GerBA subunit determined previously were also predicted to be ∼700 molecules/spore. These results indicate that the A/C subunit stoichiometry in GRs is most likely 1:1, with GerA being the most abundant GR. GerD and SpoVAD levels were ∼3,500 and ∼6,500 molecules/spore, respectively. These values will be helpful in formulating mathematic models of spore germination kinetics as well as setting lower limits on the size of the GR-GerD complex in the spores'' IM, termed the germinosome.     

Germination of Spores of Bacillus Species: What We Know and Do Not Know

Spores of Bacillus species can remain in their dormant and resistant states for years, but exposure to agents such as specific nutrients can cause spores'' return to life within minutes in the process of germination. This process requires a number of spore-specific proteins, most of which are in or associated with the inner spore membrane (IM). These proteins include the (i) germinant receptors (GRs) that respond to nutrient germinants, (ii) GerD protein, which is essential for GR-dependent germination, (iii) SpoVA proteins that form a channel in spores'' IM through which the spore core''s huge depot of dipicolinic acid is released during germination, and (iv) cortex-lytic enzymes (CLEs) that degrade the large peptidoglycan cortex layer, allowing the spore core to take up much water and swell, thus completing spore germination. While much has been learned about nutrient germination, major questions remain unanswered, including the following. (i) How do nutrient germinants penetrate through spores'' outer layers to access GRs in the IM? (ii) What happens during the highly variable and often long lag period between the exposure of spores to nutrient germinants and the commitment of spores to germinate? (iii) What do GRs and GerD do, and how do these proteins interact? (iv) What is the structure of the SpoVA channel in spores'' IM, and how is this channel gated? (v) What is the precise state of the spore IM, which has a number of novel properties even though its lipid composition is very similar to that of growing cells? (vi) How is CLE activity regulated such that these enzymes act only when germination has been initiated? (vii) And finally, how does the germination of spores of clostridia compare with that of spores of bacilli?     

Analysis of the Effects of a gerP Mutation on the Germination of Spores of Bacillus subtilis

As previously reported, gerP Bacillus subtilis spores were defective in nutrient germination triggered via various germinant receptors (GRs), and the defect was eliminated by severe spore coat defects. The gerP spores'' GR-dependent germination had a longer lag time between addition of germinants and initiation of rapid release of spores'' dipicolinic acid (DPA), but times for release of >90% of DPA from individual spores were identical for wild-type and gerP spores. The gerP spores were also defective in GR-independent germination by DPA with its associated Ca²⁺ divalent cation (CaDPA) but germinated better than wild-type spores with the GR-independent germinant dodecylamine. The gerP spores exhibited no increased sensitivity to hypochlorite, suggesting that these spores have no significant coat defect. Overexpression of GRs in gerP spores did lead to faster germination via the overexpressed GR, but this was still slower than germination of comparable gerP⁺ spores. Unlike wild-type spores, for which maximal nutrient germinant concentrations were between 500 μM and 2 mM for l-alanine and ≤10 mM for l-valine, rates of gerP spore germination increased up to between 200 mM and 1 M l-alanine and 100 mM l-valine, and at 1 M l-alanine, the rates of germination of wild-type and gerP spores with or without all alanine racemases were almost identical. A high pressure of 150 MPa that triggers spore germination by activating GRs also triggered germination of wild-type and gerP spores identically. All these results support the suggestion that GerP proteins facilitate access of nutrient germinants to their cognate GRs in spores'' inner membrane.     

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.     

Inorganic Phosphate and Sodium Ions Are Cogerminants for Spores of Clostridium perfringens Type A Food Poisoning-Related Isolates

Clostridium perfringens type A isolates carrying a chromosomal copy of the enterotoxin (cpe) gene are involved in the majority of food poisoning (FP) outbreaks, while type A isolates carrying a plasmid-borne cpe gene are involved in C. perfringens-associated non-food-borne (NFB) gastrointestinal diseases. To cause diseases, C. perfringens spores must germinate and return to active growth. Previously, we showed that only spores of FP isolates were able to germinate with K⁺ ions. We now found that the spores of the majority of FP isolates, but none of the NFB isolates, germinated with the cogerminants Na⁺ and inorganic phosphate (NaP_i) at a pH of ∼6.0. Spores of gerKA-KC and gerAA mutants germinated to a lesser extent and released less dipicolinic acid (DPA) than did wild-type spores with NaP_i. Although gerKB spores germinated to a similar extent as wild-type spores with NaP_i, their rate of germination was lower. Similarly, gerO and gerO gerQ mutant spores germinated slower and released less DPA than did wild-type spores with NaP_i. In contrast, gerQ spores germinated to a slightly lesser extent than wild-type spores but released all of their DPA during NaP_i germination. In sum, this study identified NaP_i as a novel nutrient germinant for spores of most FP isolates and provided evidence that proteins encoded by the gerKA-KC operon, gerAA, and gerO are required for NaP_i-induced spore germination.Clostridium perfringens is a gram-positive, anaerobic, spore-forming, pathogenic bacterium that causes a wide array of gastrointestinal (GI) diseases in both animals and humans (14, 15). However, Clostridium perfringens type A food poisoning (FP) is the most common C. perfringens-associated illness among humans and is currently ranked as the third most commonly reported food-borne disease (14). Mostly type A isolates that produce the C. perfringens enterotoxin have been associated with C. perfringens-related GI illnesses (14). C. perfringens cpe-positive isolates can carry the cpe gene on either the chromosome or a plasmid (3, 4). Interestingly, the majority of C. perfringens type A FP isolates carry a chromosomal copy of the cpe gene, while all non-food-borne (NFB) GI disease isolates carry a plasmid copy of cpe (3, 4, 11, 29). The genetic differences involved in the pathogenesis differences between C. perfringens FP and NFB isolates seem to involve more factors than the simple location of the cpe gene. For example, spores of FP isolates are strikingly more resistant than spores of NFB isolates to heat (100°C) (27), cold (4°C), and freezing (−20°C) temperatures (12) and to chemicals used in food industry settings (13), making FP spores more suited for FP environments. Under favorable environmental conditions, these dormant spores germinate to return to active growth, proliferate to high numbers, and then produce toxins to cause disease (14).Bacterial spores germinate when they sense the presence of nutrients (termed germinants) in the environment through their cognate receptors located in the spore inner membrane (18). For C. perfringens, some nutrients that initiate germination include l-asparagine, KCl, a mixture of l-asparagine and KCl, and a 1:1 chelate of Ca²⁺ and dipicolinic acid (DPA) (Ca-DPA) (20). The main receptor(s) involved in sensing these compounds is the GerKA and/or GerKC receptor(s), which is required for l-asparagine and Ca-DPA and only partially required for KCl and an l-asparagine-KCl mixture (20, 21). Upon binding of the germinant to its cognate receptor, a variety of biophysical events take place, including the release of monovalent ions (i.e., Na⁺, K⁺, and Li⁺) followed by the release of the spore''s large depot of Ca-DPA (28). In Bacillus subtilis, release of Ca-DPA acts as a signal for activation of the cortex-lytic enzyme CwlJ (17). In contrast, Ca-DPA release from the spore core has no role in triggering cortex hydrolysis during C. perfringens spore germination (19, 22, 23); instead, Ca-DPA induces germination via the GerKA and/or GerKC receptor(s) (20, 21). Degradation of the cortex in both species leads to hydration of the spore core up to levels found in growing bacteria, allowing resumption of enzymatic activity and metabolism, and consequently outgrowth (22, 28).The ability of bacterial spores to sense different nutrients appears to be tightly regulated by their adaptation to different environmental niches. For example, spores of FP isolates, but not NFB isolates, are capable of germinating with KCl (20), an intrinsic mineral of meats that are most commonly associated with FP, suggesting an adaptation of FP isolates to FP environments. In addition, the level of inorganic phosphate (P_i) is also significant in meat products (42 to 60 mM) (USDA [http://fnic.nal.usda.gov/nal_display/index.php?info_center=4&tax_level=1&tax_subject=242]). Similarly, sodium ions are also present in meats (∼30 mM), especially in processed meat products (∼300 to 400 mM) (USDA). Consequently, in this study we found that Na⁺ and P_i at ∼100 mM and pH 6.0 are unique cogerminants for spores of C. perfringens type A FP isolates, act through the GerKA and/or GerKC and GerAA receptors, and also require the presence of the putative Na⁺/K⁺-H⁺ antiporter, GerO, for normal germination.     

Analysis of the Loss in Heat and Acid Resistance during Germination of Spores of Bacillus Species

A major event in the nutrient germination of spores of Bacillus species is release of the spores'' large depot of dipicolinic acid (DPA). This event is preceded by both commitment, in which spores continue through germination even if germinants are removed, and loss of spore heat resistance. The latter event is puzzling, since spore heat resistance is due largely to core water content, which does not change until DPA is released during germination. We now find that for spores of two Bacillus species, the early loss in heat resistance during germination is most likely due to release of committed spores'' DPA at temperatures not lethal for dormant spores. Loss in spore acid resistance during germination also paralleled commitment and was also associated with the release of DPA from committed spores at acid concentrations not lethal for dormant spores. These observations plus previous findings that DPA release during germination is preceded by a significant release of spore core cations suggest that there is a significant change in spore inner membrane permeability at commitment. Presumably, this altered membrane cannot retain DPA during heat or acid treatments innocuous for dormant spores, resulting in DPA-less spores that are rapidly killed.     

Clostridium perfringens spore germination: characterization of germinants and their receptors

Clostridium perfringens food poisoning is caused by type A isolates carrying a chromosomal enterotoxin (cpe) gene (C-cpe), while C. perfringens-associated non-food-borne gastrointestinal (GI) diseases are caused by isolates carrying a plasmid-borne cpe gene (P-cpe). C. perfringens spores are thought to be the important infectious cell morphotype, and after inoculation into a suitable host, these spores must germinate and return to active growth to cause GI disease. We have found differences in the germination of spores of C-cpe and P-cpe isolates in that (i) while a mixture of L-asparagine and KCl was a good germinant for spores of C-cpe and P-cpe isolates, KCl and, to a lesser extent, L-asparagine triggered spore germination in C-cpe isolates only; and (ii) L-alanine or L-valine induced significant germination of spores of P-cpe but not C-cpe isolates. Spores of a gerK mutant of a C-cpe isolate in which two of the proteins of a spore nutrient germinant receptor were absent germinated slower than wild-type spores with KCl, did not germinate with L-asparagine, and germinated poorly compared to wild-type spores with the nonnutrient germinants dodecylamine and a 1:1 chelate of Ca2+ and dipicolinic acid. In contrast, spores of a gerAA mutant of a C-cpe isolate that lacked another component of a nutrient germinant receptor germinated at the same rate as that of wild-type spores with high concentrations of KCl, although they germinated slightly slower with a lower KCl concentration, suggesting an auxiliary role for GerAA in C. perfringens spore germination. In sum, this study identified nutrient germinants for spores of both C-cpe and P-cpe isolates of C. perfringens and provided evidence that proteins encoded by the gerK operon are required for both nutrient-induced and non-nutrient-induced spore germination.     

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.     

Slow Leakage of Ca-Dipicolinic Acid from Individual Bacillus Spores during Initiation of Spore Germination

When exposed to nutrient or nonnutrient germinants, individual Bacillus spores can return to life through germination followed by outgrowth. Laser tweezers, Raman spectroscopy, and either differential interference contrast or phase-contrast microscopy were used to analyze the slow dipicolinic acid (DPA) leakage (normally ∼20% of spore DPA) from individual spores that takes place prior to the lag time, T_lag, when spores begin rapid release of remaining DPA. Major conclusions from this work with Bacillus subtilis spores were as follows: (i) slow DPA leakage from wild-type spores germinating with nutrients did not begin immediately after nutrient exposure but only at a later heterogeneous time T₁; (ii) the period of slow DPA leakage (ΔT_leakage = T_lag − T₁) was heterogeneous among individual spores, although the amount of DPA released in this period was relatively constant; (iii) increases in germination temperature significantly decreased T₁ times but increased values of ΔT_leakage; (iv) upon germination with l-valine for 10 min followed by addition of d-alanine to block further germination, all germinated spores had T₁ times of less than 10 min, suggesting that T₁ is the time when spores become committed to germinate; (v) elevated levels of SpoVA proteins involved in DPA movement in spore germination decreased T₁ and T_lag times but not the amount of DPA released in ΔT_leakage; (vi) lack of the cortex-lytic enzyme CwlJ increased DPA leakage during germination due to longer ΔT_leakage times in which more DPA was released; and (vii) there was slow DPA leakage early in germination of B. subtilis spores by the nonnutrients CaDPA and dodecylamine and in nutrient germination of Bacillus cereus and Bacillus megaterium spores. Overall, these findings have identified and characterized a new early event in Bacillus spore germination.     

Functional Characterisation of Germinant Receptors in Clostridium botulinum and Clostridium sporogenes Presents Novel Insights into Spore Germination Systems

Clostridium botulinum is a dangerous pathogen that forms the highly potent botulinum toxin, which when ingested causes a deadly neuroparalytic disease. The closely related Clostridium sporogenes is occasionally pathogenic, frequently associated with food spoilage and regarded as the non-toxigenic equivalent of Group I C. botulinum. Both species form highly resistant spores that are ubiquitous in the environment and which, under favourable growth conditions germinate to produce vegetative cells. To improve the control of botulinum neurotoxin-forming clostridia, it is imperative to comprehend the mechanisms by which spores germinate. Germination is initiated following the recognition of small molecules (germinants) by a specific germinant receptor (GR) located in the spore inner membrane. The present study precisely defines clostridial GRs, germinants and co-germinants. Group I C. botulinum ATCC3502 contains two tricistronic and one pentacistronic GR operons, while C. sporogenes ATCC15579 has three tricistronic and one tetracistronic GR operons. Insertional knockout mutants, allied with characterisation of recombinant GRs shows for the first time that amino acid stimulated germination in C. botulinum requires two tri-cistronic encoded GRs which act in synergy and cannot function individually. Spore germination in C. sporogenes requires one tri-cistronic GR. Two other GRs form part of a complex involved in controlling the rate of amino-acid stimulated germination. The suitability of using C. sporogenes as a substitute for C. botulinum in germination studies and food challenge tests is discussed.     

Characterization of Clostridium perfringens spores that lack SpoVA proteins and dipicolinic acid

Spores of Clostridium perfringens possess high heat resistance, and when these spores germinate and return to active growth, they can cause gastrointestinal disease. Work with Bacillus subtilis has shown that the spore's dipicolinic acid (DPA) level can markedly influence both spore germination and resistance and that the proteins encoded by the spoVA operon are essential for DPA uptake by the developing spore during sporulation. We now find that proteins encoded by the spoVA operon are also essential for the uptake of Ca(2+) and DPA into the developing spore during C. perfringens sporulation. Spores of a spoVA mutant had little, if any, Ca(2+) and DPA, and their core water content was approximately twofold higher than that of wild-type spores. These DPA-less spores did not germinate spontaneously, as DPA-less B. subtilis spores do. Indeed, wild-type and spoVA C. perfringens spores germinated similarly with a mixture of l-asparagine and KCl (AK), KCl alone, or a 1:1 chelate of Ca(2+) and DPA (Ca-DPA). However, the viability of C. perfringens spoVA spores was 20-fold lower than the viability of wild-type spores. Decoated wild-type and spoVA spores exhibited little, if any, germination with AK, KCl, or exogenous Ca-DPA, and their colony-forming efficiency was 10(3)- to 10(4)-fold lower than that of intact spores. However, lysozyme treatment rescued these decoated spores. Although the levels of DNA-protective alpha/beta-type, small, acid-soluble spore proteins in spoVA spores were similar to those in wild-type spores, spoVA spores exhibited markedly lower resistance to moist heat, formaldehyde, HCl, hydrogen peroxide, nitrous acid, and UV radiation than wild-type spores did. In sum, these results suggest the following. (i) SpoVA proteins are essential for Ca-DPA uptake by developing spores during C. perfringens sporulation. (ii) SpoVA proteins and Ca-DPA release are not required for C. perfringens spore germination. (iii) A low spore core water content is essential for full resistance of C. perfringens spores to moist heat, UV radiation, and chemicals.     

Role of the gerP Operon in Germination and Outgrowth of Bacillus anthracis Spores

Germination of Bacillus anthracis spores occurs when nutrients such as amino acids or purine nucleosides stimulate specific germinant receptors located in the spore inner membrane. The gerP_ABCDEF operon has been suggested to play a role in facilitating the interaction between germinants and their receptors in spores of Bacillus subtilis and Bacillus cereus. B. anthracis mutants containing deletions in each of the six genes belonging to the orthologue of the gerP_ABCDEF operon, or deletion of the entire operon, were tested for their ability to germinate. Deletion of the entire gerP operon resulted in a significant delay in germination in response to nutrient germinants. These spores eventually germinated to levels equivalent to wild-type, suggesting that an additional entry point for nutrient germinants may exist. Deletions of each individual gene resulted in a similar phenotype, with the exception of ΔgerPF, which showed no obvious defect. The removal of two additional gerPF-like orthologues was necessary to achieve the germination defect observed for the other mutants. Upon physical removal of the spore coat, the mutant lacking the full gerP operon no longer exhibited a germination defect, suggesting that the GerP proteins play a role in spore coat permeability. Additionally, each of the gerP mutants exhibited a severe defect in calcium-dipicolinic acid (Ca-DPA)–dependent germination, suggesting a role for the GerP proteins in this process. Collectively, these data implicate all GerP proteins in the early stages of spore germination.     

Interaction of Apurinic/Apyrimidinic Endonucleases Nfo and ExoA with the DNA Integrity Scanning Protein DisA in the Processing of Oxidative DNA Damage during Bacillus subtilis Spore Outgrowth

Oxidative stress-induced damage, including 8-oxo-guanine and apurinic/apyrimidinic (AP) DNA lesions, were detected in dormant and outgrowing Bacillus subtilis spores lacking the AP endonucleases Nfo and ExoA. Spores of the Δnfo exoA strain exhibited slightly slowed germination and greatly slowed outgrowth that drastically slowed the spores'' return to vegetative growth. A null mutation in the disA gene, encoding a DNA integrity scanning protein (DisA), suppressed this phenotype, as spores lacking Nfo, ExoA, and DisA exhibited germination and outgrowth kinetics very similar to those of wild-type spores. Overexpression of DisA also restored the slow germination and outgrowth phenotype to nfo exoA disA spores. A disA-lacZ fusion was expressed during sporulation but not in the forespore compartment. However, disA-lacZ was expressed during spore germination/outgrowth, as was a DisA-green fluorescent protein (GFP) fusion protein. Fluorescence microscopy revealed that, as previously shown in sporulating cells, DisA-GFP formed discrete globular foci that colocalized with the nucleoid of germinating and outgrowing spores and remained located primarily in a single cell during early vegetative growth. Finally, the slow-outgrowth phenotype of nfo exoA spores was accompanied by a delay in DNA synthesis to repair AP and 8-oxo-guanine lesions, and these effects were suppressed following disA disruption. We postulate that a DisA-dependent checkpoint arrests DNA replication during B. subtilis spore outgrowth until the germinating spore''s genome is free of damage.     

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.     

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.