Effect of sporulation conditions on the resistance of Bacillus subtilis spores to heat and high pressure

Bacillus subtilis(B. subtilis) cells were placed in various environmental conditions to study the effects of aeration, water activity of the medium, temperature, pH, and calcium content on spore formation and the resulting properties. Modification of the sporulation conditions lengthened the growth period of B. subtilis and its sporulation. In some cases, it reduced the final spore concentration. The sporulation conditions significantly affected the spore properties, including germination capacity and resistance to heat treatment in water (30 min at 97°C) or to high pressure (60 min at 350 MPa and 40°C). The relationship between the modifications of these spore properties and the change in the spore structure induced by different sporulation conditions is also considered. According to this study, sporulation conditions must be carefully taken into account during settling sterilization processes applied in the food industry.     

Germination protein levels and rates of germination of spores of Bacillus subtilis with overexpressed or deleted genes encoding germination proteins

Deletion of Bacillus subtilis spores' GerA germinant receptor (GR) had no effect on spore germination via the GerB plus GerK GRs, and loss of GerB plus GerK did not affect germination via GerA. Loss of one or two GRs also did not affect levels of GRs that were not deleted. Overexpression of GRs 5- to 18-fold increased rates of germination via the overexpressed GR and slowed germination by other GRs up to 15-fold. However, overexpression of one or two GRs had no effect on levels of GRs that were not overexpressed. These results suggest that either interaction between different GRs reduces the activity of GRs in triggering spore germination or all GRs compete for interaction with a limiting amount of a downstream signaling molecule in the germination pathway. Overexpression or deletion of GRs also had no effect on spores' levels of the GerD protein needed for normal GR-dependent germination or of the SpoVAD protein likely involved in dipicolinic acid release early in germination. Loss of GerD also had no effect on levels of GRs or SpoVAD. Spores of a strain lacking the only B. subtilis prelipoprotein diacylglycerol transferase, GerF, also had no detectable GerD or the GerA's C subunit, both of which are most likely lipoproteins; GerA's A subunit was also absent. However, levels of GerB's C subunit, also almost certainly a lipoprotein, and GerK's A subunit were normal in gerF spores. These results with gerF spores were consistent with effects of loss of GerF on spore germination by different GRs.     

Effects of overexpression of nutrient receptors on germination of spores of Bacillus subtilis

The rates of germination of Bacillus subtilis spores with L-alanine were increased markedly, in particular at low L-alanine concentrations, by overexpression of the tricistronic gerA operon that encodes the spore's germinant receptor for L-alanine but not by overexpression of gerA operon homologs encoding receptors for other germinants. However, spores with elevated levels of the GerA proteins did not germinate more rapidly in a mixture of asparagine, glucose, fructose, and K(+) (AGFK), a germinant combination that requires the participation of at least the germinant receptors encoded by the tricistronic gerB and gerK operons. Overexpression of the gerB or gerK operon or both the gerB and gerK operons also did not stimulate spore germination in AGFK. Overexpression of a mutant gerB operon, termed gerB*, that encodes a receptor allowing spore germination in response to either D-alanine or L-asparagine also caused faster spore germination with these germinants, again with the largest enhancement of spore germination rates at lower germinant concentrations. However, the magnitudes of the increases in the germination rates with D-alanine or L-asparagine in spores overexpressing gerB* were well below the increases in the spore's levels of the GerBA protein. Germination of gerB* spores with D-alanine or L-asparagine did not require participation of the products of the gerK operon, but germination with these agents was decreased markedly in spores also overexpressing gerA. These findings suggest that (i) increases in the levels of germinant receptors that respond to single germinants can increase spore germination rates significantly; (ii) there is some maximum rate of spore germination above which stimulation of GerA operon receptors alone will not further increase the rate of spore germination, as action of some protein other than the germinant receptors can become rate limiting; (iii) while previous work has shown that the wild-type GerB and GerK receptors interact in some fashion to cause spore germination in AGFK, there also appears to be an additional component required for AGFK-triggered spore germination; (iv) activation of the GerB receptor with D-alanine or L-asparagine can trigger spore germination independently of the GerK receptor; and (v) it is likely that the different germinant receptors interact directly and/or compete with each other for some additional component needed for initiation of spore germination. We also found that very high levels of overexpression of the gerA or gerK operon (but not the gerB or gerB* operon) in the forespore blocked sporulation shortly after the engulfment stage, although sporulation appeared normal with the lower levels of gerA or gerK overexpression that were used to generate spores for analysis of rates of germination.     

Effects of temperature and heat activation on germination of individual spores of Bacillus subtilis

Phase intensity changes of individual germinating spores of Bacillus subtilis were determined by phase-contrast light microscopy and image analysis. Two germination phases were investigated. The length of the time period before a change in phase brightness was evident and the duration of the phase intensity change until a constant greylevel was maintained. The incubation temperature (37 and 20 °C) and heat activation (10 min at 65 °C) had a distinct effect on both phases. At 37 °C, spores of B. subtilis 604 started to show a decrease in brightness in l -alanine buffer after 3–39 min and needed 10–39 min to complete the phase change. At 20 °C, lag times of 10–100 min were observed and the spores needed 30–100 min to reach a constant greylevel. Heat activation and subsequently exposure to l -alanine buffer at 20 °C reduced the lag phase to 6–90 min and the phase change was finished after 30–60 min. Our results indicate enzymatic involvement before and during the phase intensity change of germinating spores.     

Localization of the germination protein GerD to the inner membrane in Bacillus subtilis spores

GerD of Bacillus subtilis is a protein essential for normal spore germination with either L-alanine or a mixture of L-asparagine, D-glucose, D-fructose, and potassium ions. GerD's amino acid sequence suggests that it may be a lipoprotein, indicating a likely location in a membrane. Location in the spore's outer membrane seems unlikely, since removal of this membrane does not result in a gerD spore germination phenotype, suggesting that GerD is likely in the spore's inner membrane. In order to localize GerD within spores, FLAG-tagged GerD constructs were made, found to be functional in spore germination, and detected in immunoblots of spore extracts as not only monomers but also dimers and trimers. Upon fractionation of spore extracts, GerD-FLAG was found in the inner membrane fraction from dormant spores and was present at approximately 2,000 molecules/spore. GerD-FLAG in the inner membrane fraction was solubilized by Triton X-100, suggesting that GerD is a lipoprotein, and the protein was also solubilized by 0.5 M NaCl. GerD-FLAG was not processed proteolytically in a B. subtilis strain lacking gerF (lgt), which encodes prelipoprotein diacylglycerol transferase (Lgt), indicating that when GerD does not have a diacylglycerol moiety, signal sequence processing does not occur. However, unprocessed GerD-FLAG still gave bands corresponding to monomers and dimers of slightly higher molecular weight than that of GerD-FLAG from a strain with Lgt, further suggesting that GerD is a lipoprotein. Upon spore germination, much GerD became soluble and then appeared to be degraded as the germinated spores outgrew and initiated vegetative growth. All of these results suggest that GerD is a lipoprotein associated with the dormant spore's inner membrane that may be released in some fashion from this membrane upon spore germination.     

Role of GerD in germination of Bacillus subtilis spores

Spores of a Bacillus subtilis strain with a gerD deletion mutation (Delta gerD) responded much slower than wild-type spores to nutrient germinants, although they did ultimately germinate, outgrow, and form colonies. Spores lacking GerD and nutrient germinant receptors also germinated slowly with nutrients, as did Delta gerD spores in which nutrient receptors were overexpressed. The germination defect of Delta gerD spores was not suppressed by many changes in the sporulation or germination conditions. Germination of Delta gerD spores was also slower than that of wild-type spores with a pressure of 150 MPa, which triggers spore germination through nutrient receptors. Ectopic expression of gerD suppressed the slow germination of Delta gerD spores with nutrients, but overexpression of GerD did not increase rates of spore germination. Loss of GerD had no effect on spore germination induced by agents that do not act through nutrient receptors, including a 1:1 chelate of Ca2+ and dipicolinic acid, dodecylamine, lysozyme in hypertonic medium, a pressure of 500 MPa, and spontaneous germination of spores that lack all nutrient receptors. Deletion of GerD's putative signal peptide or change of its likely diacylglycerylated cysteine residue to alanine reduced GerD function. The latter findings suggest that GerD is located in a spore membrane, most likely the inner membrane, where the nutrient receptors are located. All these data suggest that, while GerD is not essential for nutrient germination, this protein has an important role in spores' rapid response to nutrient germinants, by either direct interaction with nutrient receptors or some signal transduction essential for germination.     

Effects of a gerF (lgt) mutation on the germination of spores of Bacillus subtilis

One of the proteins of the membrane-bound receptors that recognize individual nutrients that trigger germination of spores of Bacillus subtilis contains the recognition sequence for diacylglycerol addition to a cysteine residue near the protein's N terminus. B. subtilis spores lacking the gerF (lgt) gene that codes for prelipoprotein diacylglycerol transferase exhibited significantly slowed germination in response to nutrient germinants as found previously, but germination of gerF spores with a mixture of Ca2+ and dipicolinic acid or with dodecylamine was normal, as was the spontaneous germination of gerF spores lacking all nutrient germinant receptors. The deleterious effects of the gerF mutation on nutrient germination were highest on germination triggered by the GerA nutrient receptor and were less so (but still significant) on germination triggered by the GerB nutrient receptor. However, there was little, if any, effect on GerK nutrient receptor-mediated spore germination. As predicted from the latter results, replacement by alanine of the cysteine residue to which diacylglycerol is thought to be added to these nutrient receptors had a large effect on GerA receptor function, less effect on GerB receptor function, and little, if any, effect on GerK receptor function.     

Role of glucose dehydrogenase in germination of Bacillus subtilis spores

Abstract A mutant of Bacillus subtilis has been isolated which is devoid of glucose dehydrogenase. This mutant is unable to germinate on a mix of glucose, fructose, asparagine, and KCl, which is a normal germination trigger for wild-type strains. Transfer of the genotype by transformation to isogenic strains confers the same properties on these transformed strains. These observations strongly implicate glucose dehydrogenase in germination.     

Comparative study of pressure- and nutrient-induced germination of Bacillus subtilis spores

Germination experiments with specific germination mutants of Bacillus subtilis, including a newly isolated mutant affected in pressure-induced germination, suggest that a pressure of 100 MPa triggers the germination cascades that are induced by the nutrient germinant alanine (Ala) and by a mixture of asparagine, glucose, fructose, and potassium ions (AGFK), by activating the receptors for alanine and asparagine, GerA and GerB, respectively. As opposed to germination at 100 MPa, germination at 600 MPa apparently short-cuts at least part of the Ala- and AGFK-induced germination pathways. Inhibitors of nutrient-induced germination (HgCl(2) and Nalpha-P-tosyl-L-arginine methyl ester) also inhibit pressure-induced germination at 600 MPa, suggesting that germination at 600 MPa involves activation of a true physiological germination pathway and is therefore not merely a physico-chemical process in which water is forced into the spore protoplast.     

Synergism between different germinant receptors in the germination of Bacillus subtilis spores

Rates of commitment to germinate and germination of Bacillus subtilis spores with mixtures of low concentrations of germinants acting on different germinant receptors (GRs) were much higher than the sums of the rates of commitment and germination with individual germinants alone. This synergism with mixtures of nutrient germinants was not seen with spores lacking GRs responsible for recognizing one or several components of the germinant mixtures and was not eliminated by either a gerD mutation or overexpression of one of the GRs involved in this synergism. This synergism was also not seen between the germinant L-valine, which acts via a GR, and the germinant dodecylamine, which does not act via any GR. These results indicate that spores not only integrate but can also amplify signals from multiple germinants and multiple GRs in determining rates of commitment and overall spore germination. This amplification can be explained by a simple mechanism in which a single signal integrator triggers germination above an accumulation threshold. Direct cooperative action between GRs may further add to the synergism seen in germination triggered by multiple GRs. Further experiments and modeling are required to determine the relative contributions of these different mechanisms.     

Revival of Bacillus subtilis spores from biocide-induced injury in the germination process

Spores of Bacillus subtilis NCTC 8236 were treated with glutaraldehyde, Lugol's iodine, polyvinylpyrrolidone-iodine (PVP-I), sodium hypochlorite or sodium dichloroisocyanurate (NaDCC). After exposure survivors were enumerated on nutrient agar containing potential revival agents (subtilisin, lysozyme, calcium dipicolinate, calcium lactate). Of these, only calcium lactate had any significant enhancing effect and then only with iodine-treated spores. Calcium lactate (9 mmol 1⁻¹) in nutrient broth enhanced the rate and extent of germination of iodine-treated spores but not of spores previously subjected to glutaraldehyde, hypochlorite or NaDCC.     

Levels of germination proteins in dormant and superdormant spores of Bacillus subtilis

Bacillus subtilis spores that germinated poorly with saturating levels of nutrient germinants, termed superdormant spores, were separated from the great majority of dormant spore populations that germinated more rapidly. These purified superdormant spores (1.5 to 3% of spore populations) germinated extremely poorly with the germinants used to isolate them but better with germinants targeting germinant receptors not activated in superdormant spore isolation although not as well as the initial dormant spores. The level of β-galactosidase from a gerA-lacZ fusion in superdormant spores isolated by germination via the GerA germinant receptor was identical to that in the initial dormant spores. Levels of the germination proteins GerD and SpoVAD were also identical in dormant and superdormant spores. However, levels of subunits of a germinant receptor or germinant receptors activated in superdormant spore isolation were 6- to 10-fold lower than those in dormant spores, while levels of subunits of germinant receptors not activated in superdormant spore isolation were only ≤ 2-fold lower. These results indicate that (i) levels of β-galactosidase from lacZ fusions to operons encoding germinant receptors may not be an accurate reflection of actual germinant receptor levels in spores and (ii) a low level of a specific germinant receptor or germinant receptors is a major cause of spore superdormancy.     

Non-variable sources of pure water and the germination and outgrowth of Bacillus subtilis spores

Variable germination and outgrowth occurred when Bacillus subtilis NCTC 8236 spores were inoculated into nutrient broth prepared with distilled water. More reproducible findings were achieved when the medium was prepared with Elgastat water and the greatest reproducibility occurred with Elgastat water as vehicle combined with a rigorous acid-washing of all glassware. This combined procedure also produced optimum and reproducible results for the synchronous growth of two B. subtilis 168 strains in casein medium supplemented with appropriate amino acids, a technique of value in monitoring the development of resistance to antibacterial agents during sporulation. The levels of aluminium in distilled water were higher than those of other elements; however, the incorporation of aluminium sulphate into broth prepared with Elgastat water had no effect on germination, and outgrowth was reduced (but not eliminated) only at high concentrations of this salt.