Isolation and characterization of Bacillus megaterium mutants containing decreased levels of spore protease.

A proteolytic activity present in spores of Bacillus megaterium has previously been implicated in the initiation of hydrolysis of the A, B, and C proteins which are degraded during spore germination. Four mutants of B. megaterium containing 20 to 30% of the normal level of spore proteolytic activity have been isolated. Partial purification of the protease from wild-type spores by a reviewed procedure resulted in the resolution of spore protease activity on the A, B, and C proteins into two peaks--a major one (protease II) and a minor one (protease I). The protease mutants tested lacked active protease II. All of the mutants exhibited a decreased rate of degradation of the A, B, and C proteins during spore germination at 30 degrees C, but degradation of the proteins did occur. Degradation of the A, B, and C proteins during germination of the mutant spores was decreased neither by blockade of ATP production nor by germination at 44 degrees C. Initiation of spore germination was normal in all four mutants, and all four mutants went through outgrowth, grew, and sporulated normally in rich medium. Similarly, outgrowth of spores of two of the four mutants was normal in minimal medium at 30 degrees C. In the two mutants studied, the kinetics of loss of spore heat resistance and spore UV light resistance during germination were identical to those of wild-type spores. This indicates that the A, B, and C proteins alone are not sufficient to account for the heat or UV light resistance of the dormant spore.     

Modification of GerQ reveals a functional relationship between Tgl and YabG in the coat of Bacillus subtilis spores

Here we describe the functional relationship between YabG and transglutaminase (Tgl), enzymes that modify the spore coat proteins of Bacillus subtilis. In wild-type spores at 37 degrees C, Tgl mediates the crosslinking of GerQ into higher molecular mass forms; however, some GerQ multimers are found in tgl mutant spores, indicating that Tgl is not essential. Immunoblotting showed that spores isolated from a yabG mutant after sporulation at 37 degrees C contain only very low levels of GerQ multimers. Heat treatment for 20 min at 60 degrees C, which maximally activates the enzymatic activity of Tgl, caused crosslinking of GerQ in isolated yabG spores but not in tgl/yabG double-mutant spores. In addition, the germination frequency of the tgl/yabG spores in the presence of l-alanine with or without heat activation at 60 degrees C was lower than that of wild-type spores. These findings suggest that Tgl cooperates with YabG to mediate the temperature-dependent modification of the coat proteins, a process associated with spore germination in B. subtilis.     

Regulation of Extracellular Protease Production in Bacillus cereus T: Characterization of Mutants Producing Altered Amounts of Protease

Twenty-nine mutants of Bacillus cereus T were selected on casein agar for their inability to produce large amounts of extracellular protease. They all formed spores, and 27 were also auxotrophs for purines or pyrimidines. Upon reversion to prototrophy, a large fraction regained the capacity to produce protease. Conversely, reversion to normal protease production resulted in loss of the purine or pyrimidine requirement in a large fraction of the revertants. One spontaneous low-protease-producing pyrimidine auxotroph studied in detail grew as well as the wild type and produced spores which were identical to those produced by the wild type on the basis of heat resistance, dipicolinic acid content, density, and appearance in the electron microscope. The rate of protein turnover in the mutant was the same as the wild type. The mutant did grow poorly, however, when casein was the principal carbon source. A mutant excreting 5 to 10 times as much protease as the wild type was isolated as a secondary mutation from the hypoproducer discussed above. Loss of the pyrimidine requirement in this case did not alter the regulation of protease production. Although the secondary mutant grew somewhat faster in most media than the wild type, the final cell yield was lower. The spores of this mutant appeared to have excess coat on the basis of both electron microscopic and chemical studies. There appear to be closely related but distinct catabolic controls for both extracellular protease and spore formation. These controls can be dissociated as for the hypoproducers but can also appear integrated as for the hyperprotease producer.     

Properties of Bacillus cereus temperature-sensitive mutants altered in spore coat formation.

Three conditional Bacillus cereus mutants altered in the assembly or formation of spore coat layers were analyzed. They all grew as well as the wild type in an enriched or minimal medium but produced lysozyme and octanol-sensitive spores at the nonpermissive temperature (35 to 38 degrees C). The spores also germinated slowly when produced at 35 degrees C. Temperature-shift experiments indicated that the defective protein or regulatory signal is expressed at the time of formation of the outer spore coat layers. Revertants regained all wild-type spore properties at frequencies consistent with initial point mutations. Spore coat defects were evident in thin sections and freeze-etch micrographs of mutant spores produced at 35 degrees C. In addition, one mutant contained an extra surface deposit, perhaps unprocessed spore coat precursor protein. A prevalent band of about 65,000 daltons (the same size as the presumptive precursor) was present in spore coat extracts of this mutant and may be incorrectly processed to mature spore coat polypeptides. Another class of mutants was defective in the late uptake of half-cystine residues into spore coats. Such a defect could lead to improper formation of the outer spore coat layers.     

Involvement of the spore coat in germination of Bacillus cereus T spores

Bacillus cereus T spores were prepared on fortified nutrient agar, and the spore coat and outer membrane were extracted by 0.5% sodium dodecyl sulfate-100 mM dithiothreitol in 0.1 M sodium chloride (SDS-DTT) at pH 10.5 (coat-defective spores). Coat-defective spores in L-alanine plus adenosine germinated slowly and to a lesser extent than spores not treated with SDS-DTT, as determined by decrease in absorbance and release of dipicolinic acid and Ca2+. Spores germinated in calcium dipicolinate only after treatment with SDS-DTT. Biphasic and triphasic germination kinetics were observed with normal and coat-defective spores, respectively, in an environment with temperature increasing from 20 to 65 degrees C at a rate of 1 degree C/min. Therefore, the physical and biochemical processes involved in germination are modified by coat removal. The data suggest that a portion of the germination apparatus located interior to the coat may be protected by the coat and outer membrane or that the coat and outer membrane otherwise enhance germination in L-alanine plus adenosine. When coat-defective spores were heat activated with the dialyzed (12,000-Mr cutoff) components extracted from the spores, germination of the SDS-DTT-treated spores was enhanced; thus, one or more components located in the spore coat or outer membrane with a molecular weight greater than 12,000 were essential for fast germination.     

Involvement of the spore coat in germination of Bacillus cereus T spores.

Bacillus cereus T spores were prepared on fortified nutrient agar, and the spore coat and outer membrane were extracted by 0.5% sodium dodecyl sulfate-100 mM dithiothreitol in 0.1 M sodium chloride (SDS-DTT) at pH 10.5 (coat-defective spores). Coat-defective spores in L-alanine plus adenosine germinated slowly and to a lesser extent than spores not treated with SDS-DTT, as determined by decrease in absorbance and release of dipicolinic acid and Ca2+. Spores germinated in calcium dipicolinate only after treatment with SDS-DTT. Biphasic and triphasic germination kinetics were observed with normal and coat-defective spores, respectively, in an environment with temperature increasing from 20 to 65 degrees C at a rate of 1 degree C/min. Therefore, the physical and biochemical processes involved in germination are modified by coat removal. The data suggest that a portion of the germination apparatus located interior to the coat may be protected by the coat and outer membrane or that the coat and outer membrane otherwise enhance germination in L-alanine plus adenosine. When coat-defective spores were heat activated with the dialyzed (12,000-Mr cutoff) components extracted from the spores, germination of the SDS-DTT-treated spores was enhanced; thus, one or more components located in the spore coat or outer membrane with a molecular weight greater than 12,000 were essential for fast germination.     

spoVIC, a new sporulation locus in Bacillus subtilis affecting spore coats, germination and the rate of sporulation

A mutation near cysB on the Bacillus subtilis chromosome marks a new sporulation locus, spoVIC. It causes spores to germinate more slowly than those of the wild-type under all conditions and, from indirect evidence, it does not appear to alter the affinity for the germinant L-alanine. The mutant spores have some deficiency of coat proteins (particularly the alkalisoluble coat protein, Mr = 12 000) and the spore coat layers are disorganized. The mutant strain grows normally and sporulates normally until stage II, after which its sporulation is delayed by about 2 h compared to that of the wild-type. This delay results in the prolonged synthesis of some coat proteins and the late synthesis of others. The abnormal coat may be the cause of the germination deficiency. A double mutant strain carrying the spoVIC610 mutation together with gerE36 sporulates slowly. Its spores have very little coat protein, are sensitive to heat, lysozyme and organic solvents, but germinate as well as the strain carrying the spoVIC mutation alone. The role of the spore coat in germination is discussed in the light of these findings.     

Sporulation temperature affects initiation of germination and inactivation by high hydrostatic pressure of Bacillus cereus

The influence of sporulation temperature (20, 30 and 37 °C) on the heat resistance and initiation of germination and inactivation by high pressure on Bacillus cereus ATCC 14579 spores was investigated. Spores sporulated at 37 °C were the most heat-resistant. However, spores sporulated at 20 °C were more resistant to the initiation of germination and inactivation by high pressure. Spores were more sensitive to pressure at higher treatment temperatures. At 25 °C, there was an optimum pressure (250 MPa) for the initiation of germination for the three suspensions; at higher temperatures an increase of pressure up to 690 MPa caused progressively more germination. Resistance to the germinability and inactivation by high pressure of the spore population was distributed heterogeneously. Semilogarithmic curves of the ungerminated and survival fraction of B. cereus spores were concave. The resistant fraction of the spore population was lower at higher treatment temperatures. At 60 °C after 30 s of treatment at 690 MPa almost 5 log cycles of the population of B. cereus sporulated at 20 °C was germinated, and more than 7 log cycles of the population of B. cereus sporulated at 30 and 37 °C. The same treatment inactivated 4, 6 and 7 log cycles of the population of B. cereus sporulated at 20, 30 and 37 °C, respectively.     

Properties of Bacillus megaterium and Bacillus subtilis mutants which lack the protease that degrades small, acid-soluble proteins during spore germination.

During germination of spores of Bacillus species the degradation of the spore's pool of small, acid-soluble proteins (SASP) is initiated by a protease termed GPR, the product of the gpr gene. Bacillus megaterium and B. subtilis mutants with an inactivated gpr gene grew, sporulated, and triggered spore germination as did gpr+ strains. However, SASP degradation was very slow during germination of gpr mutant spores, and in rich media the time taken for spores to return to vegetative growth (defined as outgrowth) was much longer in gpr than in gpr+ spores. Not surprisingly, gpr spores had much lower rates of RNA and protein synthesis during outgrowth than did gpr+ spores, although both types of spores had similar levels of ATP. The rapid decrease in the number of negative supertwists in plasmid DNA seen during germination of gpr+ spores was also much slower in gpr spores. Additionally, UV irradiation of gpr B. subtilis spores early in germination generated significant amounts of spore photoproduct and only small amounts of thymine dimers (TT); in contrast UV irradiation of germinated gpr+ spores generated almost no spore photoproduct and three to four times more TT. Consequently, germinated gpr spores were more UV resistant than germinated gpr+ spores. Strikingly, the slow outgrowth phenotype of B. subtilis gpr spores was suppressed by the absence of major alpha/beta-type SASP. These data suggest that (i) alpha/beta-type SASP remain bound to much, although not all, of the chromosome in germinated gpr spores; (ii) the alpha/beta-type SASP bound to the chromosome in gpr spores alter this DNA's topology and UV photochemistry; and (iii) the presence of alpha/beta-type SASP on the chromosome is detrimental to normal spore outgrowth.     

Mechanisms of killing of spores of Bacillus subtilis by dimethyldioxirane

AIMS: To determine the mechanisms of Bacillus subtilis spore resistance to and killing by a novel sporicide, dimethyldioxirane (DMDO) that was generated in situ from acetone and potassium peroxymonosulfate at neutral pH. METHODS AND RESULTS: Spores of B. subtilis were effectively killed by DMDO. Rates of killing by DMDO of spores lacking most DNA protective alpha/beta-type small, acid-soluble spore proteins (alpha- beta- spores) or the major DNA repair protein, RecA, were very similar to that of wild-type spore killing. Survivors of wild-type and alpha- beta- spores treated with DMDO also exhibited no increase in mutations. Spores lacking much coat protein due either to mutation or chemical decoating were much more sensitive to DMDO than were wild-type spores, but were more resistant than growing cells. Wild-type spores killed with this reagent retained their large pool of dipicolinic acid (DPA), and the survivors of spores treated with DMDO were sensitized to wet heat. The DMDO-killed spores germinated with nutrients, albeit more slowly than untreated spores, but germinated faster than untreated spores with dodecylamine. The killed spores were also germinated by very high pressures and by lysozyme treatment in hypertonic medium, but many of these spores lysed shortly after their germination, and none of these treatments were able to revive the DMDO-killed spores. CONCLUSIONS: DMDO is an effective reagent for killing B. subtilis spores. The spore coat is a major factor in spore resistance to DMDO, which does not kill spores by DNA damage or by inactivating some component needed for spore germination. Rather, this reagent appears to kill spores by damaging the spore's inner membrane in some fashion. SIGNIFICANCE AND IMPACT OF THE STUDY: This work demonstrates that DMDO is an effective decontaminant for spores of Bacillus species that can work under mild conditions, and the killed spores cannot be revived. Evidence has also been obtained on the mechanisms of spore resistance to and killing by this reagent.     

Effect of temperature on spore germination and vegetative cell growth of Clostridium botulinum.

Spore germination and vegetative growth of Clostridium botulinum type E strain VH at 2 to 50 degrees C were studied. At all of these temperatures, germination began immediately after the addition of the spores to the germination medium. Microscopic observations during germination revealed three types of spores: phase bright (ungerminated), phase variable (partially germinated), and phase dark (fully germinated). At all temperatures except 50 degrees C, there was a pronounced lag between the initial appearance of phase-variable spores and their eventual conversion to phase-dark spores. The number of partially germinated spores increased steadily, reaching 40 to 60% by 18 to 21 h of incubation. During this time, phase-dark, fully germinated spores developed slowly and did not exceed 28% in any of the samples. At 18 to 26 h of incubation, the rate of full germination increased abruptly four-fold. There was extensive and relatively rapid germination at 2 degrees C, the lowest temperature tested, yielding about 60% phase-variable spores by 18 h, which became phase-dark by 26 h of incubation. The optimum temperature for partial and full germination was consistently 9 degrees C. Germination at 50 degrees C was exceptionally rapid and was completed within 1 to 2 h, although 40% remained phase bright. Vegetative cells showed detectable growth at 6 to 41 degrees C, with a distinct optimum at 32.5 degrees C. No growth occurred at 50 degrees C, and only marginal growth was observed at 6 to 14 degrees C. The psychrophilic nature of the germination process coupled with the cold tolerance of vegetative growth appears to give C. botulinum type E an advantage in cold climates as well as in cold-stored foods.     

Germination properties of a spore coat-defective mutant of Bacillus subtilis.

The presence of the gerE36 mutation in strains of Bacillus subtilis 168 resulted in poor germination of their spores in a range of germinants, as measured by the fall in absorbance of spore suspensions. Although resistant to heat and organic solvents, spores were sensitive to lysozyme; electron microscopy revealed that their coat structure was incomplete. These spores responded to germinants by losing heat resistance and changing from phase bright to phase gray. The release of dipicolinic acid and the fall in absorbance of spore suspensions reached only 75 and 50% of wild-type levels, respectively, but followed the same time course as the loss of heat resistance. Although the germination response was incomplete, the concentration of L-alanine required to elicit it was the same for the mutant as for the wild type. The properties of mutant spores suggest that an intact spore coat is not required for the initial interaction between germinant and spore, but that the coat layers may contain molecules important in later stages of germination. In transduction with phage SPP1, the gerE36 mutation mapped between citF and ilvB and was 90% cotransduced with citF2. The gerE mutation identifies the location of a gene important for the progress of late stages of spore formation.     

The effect of acid shock on sporulating Bacillus subtilis cells

AIMS: To study the effect of acid shock in sporulation on the production of acid-shock proteins, and on the heat resistance and germination characteristics of the spores formed subsequently. METHODS AND RESULTS: Bacillus subtilis wild-type (SASP-alpha+beta+) and mutant (SASP-alpha-beta-) cells in 2 x SG medium at 30 degrees C were acid-shocked with HCl (pH 4, 4.3, 5 and 6 against a control pH of 6.2) for 30 min, 1 h into sporulation. The D85-value of B. subtilis wild-type (but not mutant) spores formed from sporulating cells acid-shocked at pH 5 increased from 46.5 min to 78.8 min, and there was also an increase in the resistance of wild-type acid-shocked spores at both 90 degrees C and 95 degrees C. ALA- or AGFK-initiated germination of pH 5-shocked spores was the same as that of non-acid-shocked spores. Two-dimensional gel electrophoresis showed only one novel acid-shock protein, identified as a vegetative catalase 1 (KatA), which appeared 30 min after acid shock but was lost later in sporulation. CONCLUSIONS: Acid shock at pH 5 increased the heat resistance of spores subsequently formed in B. subtilis wild type. The catalase, KatA, was induced by acid shock early in sporulation, but since it was degraded later in sporulation, it appears to act to increase heat resistance by altering spore structure. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first proteomic study of acid shock in sporulating B. subtilis cells. The increasing spore heat resistance produced by acid shock may have significance for the heat resistance of spores formed in the food industry.     

Properties of spores of Bacillus subtilis blocked at an intermediate stage in spore germination

Germination of mutant spores of Bacillus subtilis unable to degrade their cortex is accompanied by excretion of dipicolinic acid and uptake of some core water. However, compared to wild-type germinated spores in which the cortex has been degraded, the germinated mutant spores accumulated less core water, exhibited greatly reduced enzyme activity in the spore core, synthesized neither ATP nor reduced pyridine or flavin nucleotides, and had significantly higher resistance to heat and UV irradiation. We propose that the germinated spores in which the cortex has not been degraded represent an intermediate stage in spore germination, which we term stage I.     

Effects of minerals on resistance of Bacillus subtilis spores to heat and hydrostatic pressure

Among Bacillus subtilis IFO13722 spores sporulated at 30, 37, and 44 degrees C, those sporulated at 30 degrees C had the highest resistance to treatments with high hydrostatic pressure (100 to 300 MPa, 55 degrees C, 30 min). Pressure resistance increased after demineralization of the spores and decreased after remineralization of the spores with Ca(2+) or Mg(2+), whereas the resistance did not change when spores were remineralized with Mn(2+) or K(+), suggesting that former two divalent ions were involved in the activation of cortex-lytic enzymes during germination.     

Factors Affecting the Rate of Heat-induced Spore Germination in Dictyostelium discoideum

Washed spores of Dictyostelium discoideum, strains NC-4H, NC-4D, and V-12, germinated rapidly after being heat shocked at or near 45.0 C for 30 min. Cultures of the slime molds were grown in association with Escherichia coli B/r as the host bacterium; spores taken from plates of synthetic medium had a higher final germination value than spores from complex medium containing peptone and yeast extract. Young spores germinated more rapidly than older spores. Optimal germination occurred between pH 6.0 and 7.0, and, of the buffers tested, potassium phosphate allowed the most rapid germination. After heat shocking, spores were diluted into fresh oxygenated buffer to provide enough oxygen for completion of germination. Germination occurred most rapidly between incubation temperatures of 22 and 25 C.     

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.     

Selective Process for Efficient Isolation of Soil Bacillus spp

We were able to isolate Bacillus thuringiensis from environmental samples with a background of 10 bacteria per g of soil. Our selection process differed significantly from classical selection methods which permit only the desired organism to grow. In our process, germination of B. thuringiensis spores was selectively inhibited by sodium acetate, while most of the undesired sporeformers germinated. Next, all of the nonsporulated microbes were eliminated by heat treatment at 80 degrees C for 3 min. The surviving spores were then plated on a rich agar medium and allowed to grow until they sporulated. Of random colonies picked from agar, 20 to 96% were crystal-forming Bacillus species. B. thuringiensis and B. sphaericus were routinely selected by this method.     

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.     

Thermal analysis of the spores of Bacillus cereus with special reference to heat activation.

The heat activation of bacterial spores was studied by means of differential thermal analysis in the temperature range 30-110 degrees C using the spores of Bacillus cereus. The thermogram showed three endothermic peaks at 56, 95, and 103 degrees C with one exothermic peak at 105 degrees C during the heating process. The spore coat separated from the native spores also showed a peak at 56 degrees C on its heating thermogram. The peak at 56 degrees C was reversible for both native spores and the spore coat. It was suggested that this peak at 56 degrees C might be related to the heat-activation process that takes place in the spore-coat region. It seems that the peak is due to the denaturation or the structural change of the spore-coat protein that might facilitate either the permeation of germination stimulators or the release of some germination inhibitor into or out of the spores.