Changes of ultrastructure in spore coat of Bacillus thiaminolyticus during germination and outgrowth.

Electron microscopic observation showed that the spore coat of Bacillus thiaminolyticus consisted of at least four layers; a high electron dense outer spore coat layer with five prominent ridges, a middle spore coat layer including two layers of a high and a low electron density, and an inner spore coat layer composing six to seven laminated layers. Rapid breakdown of the cortex and swelling of the core occurred in spores which were allowed to germinate by L-alanine for 45 min, whereas no change of surface feature was observed by scanning electron microscopy. Germination and outgrowth of spores in nutrient broth proceeded, being accompanied by morphological changes, in three steps; the first is a rapid breakdown of the cortex and swelling of the core, the second degradation of the inner layer at prominent region of the spore coat, and the last rupture of the spore coat and emergence of a young vegetative cell.     

Changes of Ultrastructure in Spore Coat of Bacillus thiaminolyticus during Germination and Outgrowth

Electron microscopic observation showed that the spore coat of Bacillus thiaminolyticus consisted of at least four layers; a high electron dense outer spore coat layer with five prominent ridges, a middle spore coat layer including two layers of a high and a low electron density, and an inner spore coat layer composing six to seven laminated layers. Rapid breakdown of the cortex and swelling of the core occurred in spores which were allowed to germinate by L -alanine for 45 min, whereas no change of surface feature was observed by scanning electron microscopy. Germination and outgrowth of spores in nutrient broth proceeded, being accompanied by morphological changes, in three steps; the first is a rapid breakdown of the cortex and swelling of the core, the second degradation of the inner layer at a prominent region of the spore coat, and the last rupture of the spore coat and emergence of a young vegetative cell.     

Appendage Development in Clostridium bifermentans

The appendages of Clostridium bifermentans UK-A 1003 spores were shown to originate from a substance located just exterior to the outer forespore membrane. The dense spore coat develops along the periphery of this material, and, as the appendages develop in the cytoplasm, the coalescing spore coat intervenes between the appendages and their origin. Freeze etching revealed that the appendages are in the form of distinct fibers in proximity to the mature spore body. These fibers form a network around the spore, seemingly encasing it and insuring that the appendages remain attached to the mature, free spore. The inner wall of each appendage tubule is lined with fibers whereas the outer surface is smooth. The developing exosporium contained several layers consisting of small (3 nm) globular subunits; the outer exosporial surface is composed of relatively unstructured material.     

Ultrastructural Analysis During Germination and Outgrowth of Bacillus subtilis Spores

Electron microscopy of thin sections of dormant and germinating spores of Bacillus subtilis 168 revealed a progressive change in the structure of the cortex, outer spore coat, and inner spore coat. The initial changes were observed in the cortex region, which showed a loose fibrous network within 10 min of germination, and in the outer spore coat, which began to be sloughed off. The permeability of the complex outer spore layers was modified within 10 min, since, at this time, the internal structures of the spore coat were readily stainable. A nicking degradation action of the laminated inner spore coat began at 20 min, and this progressed for the next 20 min leading to the loosening of the inner spore coat. By 30 min, the outer spore coat showed signs of disintegration, and at 40 min, both the outer and inner spore coats were degraded extensively. At 30 to 40 min, a period just preceding net deoxyribonucleic acid synthesis, mesosomes became very prominent in the inner spore core and the cell wall began to thicken around the spore core. At 50 min, an emerging cell was observed, and by 60 min, there was clear evidence for elongation of the emerging cell and the presence of two nuclear bodies. At 90 min, elongation had been followed by the first cell division. There was evidence for spore coat fragments at the opposite poles of the dividing cell.     

Permeability of dormant spores of Bacillus subtilis to gramicidin S

Abstract Gramicidin S, dissolved in ethanol, penetrated into the inside of the dormant spores of Bacillus subtilis , had a partial inhibitory effect on l-alanine-initiated germination and completely inhibited their outgrowth and vegetative growth. The activity of particulate NADH oxidase of the antibiotic-treated dormant spores was also influenced significantly. Abnormal morphological changes were observed in germinated spores from gramicidin S-treated dormant spores. An immunoelectron microscopy method with colloidal gold-IgG complex showed that the penetration site of gramicidin S inside dormant spores was mainly the core region. These facts suggest that gramicidin S induces the damage of not only the outer membrane-spore coat complex but also the inner membrane surrounding the spore protoplast, and is able to penetrate into the core region of B. subtilis dormant spores.     

Isolation and Characterization of Microsporum gypseum Lysosomes: Role of Lysosomes in Macroconidia Germination

Three types of lysosomes containing either acid protease, alkaline protease, or phosphodiesterase were isolated from a Microsporum gypseum macroconidial homogenate on Ficoll gradients. The acid protease was contained in an assimilative lysosome since its activity was affected by the complexity of the exogenous nitrogen source. Ultracentrifugation and electron microscopy revealed that the alkaline protease-containing vesicles were associated with the spore coat material prior to macroconidial germination. During macroconidial germination, zones of spore coat hydrolysis were seen surrounding these vesicles. Other larger vesicles, believed to contain the phosphodiesterase, were also observed in the spore coat during macroconidial germination.     

CEMOVIS on a pathogen: analysis of Bacillus anthracis spores

Background information. Under conditions of starvation, bacteria of Bacillus ssp. are able to form a highly structured cell type, the dormant spore. When the environment presents more favourable conditions, the spore starts to germinate, which will lead to the release of the vegetative form in the life cycle, the bacillus. For Bacillus anthracis, the aetiological agent of anthrax, germination is normally linked to host uptake and represents an important step in the onset of anthrax disease. Morphological studies analysing the organization of the spore and the changes during germination at the electron microscopy level were only previously performed with techniques relying on fixation with aldehydes and osmium, and subsequent dehydration, which can produce artefacts. Results and conclusions. In the present study, we describe the morphology of dormant spores using CEMOVIS (Cryo‐Electron Microscopy of Vitreous Sections). Biosafety measures do not permit freezing of native spores of B. anthracis without chemical fixation. To study the influence of aldehyde fixation on the ultrastructure of the spore, we chose to analyse spores of the closely related non‐pathogen Bacillus cereus T. For none of the investigated structures could we find a difference in morphology induced by aldehyde fixation compared with the native preparations for CEMOVIS. This result legitimizes work with aldehyde‐fixed spores from B. anthracis. Using CEMOVIS, we describe two new structures present in the spore: a rectangular structure, which connects the BclA filaments with the basal layer of the exosporium, and a repetitive structure, which can be found in the terminal layer of the coat. We studied the morphological changes of the spore during germination. After outgrowth of the bacillus, coat and exosporium stay associated, and the layered organization of the coat, as well as the repetitive structure within it, remain unchanged.     

Changes in the hydrophobic characteristics of Clostridium perfringens spores and spore coats by heat

The hydrophobic characteristics of Clostridium perfringens NCTC 8679 spores were demonstrated by adherence to toluene in a toluene-aqueous partition system. Spores and spore coat preparations were hydrophobic. Vegetative cells and spores extracted with a dithiothreitol-sodium dodecyl sulfate treatment known to remove spore coats were not hydrophobic. A heat activation treatment (75 degrees C for 20 min) which promotes more rapid spore germination increased the hydrophobicity of intact spores and decreased that of isolated spore coats. The hydrophobic changes were reversed by washing and stabilized by 0.5% glutaraldehyde. Heat-induced hydrophobic changes were observed in spore coats prepared from spores that were preheated and washed before rupturing in a buffer containing glutaraldehyde. These results suggest the occurrence of a heat-induced change in the spore coat (possibly in the conformation of a macromolecule) which was stable only within the architectural confines of the intact spore.     

Spore coat is altered in modB glycosylation mutants of Dictyostelium discoideum.

The modB mutation eliminates specific carbohydrate epitopes from glycoproteins which are expressed primarily in prespore and spore cells of differentiating Dictyostelium discoideum. Spores formed by the mutant show several phenotypes. Whereas mutant spores germinate efficiently after heat activation, they germinate poorly after urea activation. Following germination, at least one glycosylation-defective glycoprotein is cleaved, and the larger fragment is released in soluble form from the spore coat. However, an earlier difference in the spore coat can be traced back to the nongerminated spore coat, as detected by the elutability of protein from intact spores by chemical extraction. An altered character of the pregermination spore coat is also suggested by increased labeling by a fluorescent lectin which binds to its interior. The findings are consistent with a change in the character of certain molecular contacts leading to altered characteristics of the mutant spore coat, which are specific because they are distinctive from changes observed in another glycosylation mutant which affects a different epitope.     

Spore coat architecture of Clostridium novyi NT spores

Spores of the anaerobic bacterium Clostridium novyi NT are able to germinate in and destroy hypoxic regions of tumors in experimental animals. Future progress in this area will benefit from a better understanding of the germination and outgrowth processes that are essential for the tumorilytic properties of these spores. Toward this end, we have used both transmission electron microscopy and atomic force microscopy to determine the structure of both dormant and germinating spores. We found that the spores are surrounded by an amorphous layer intertwined with honeycomb parasporal layers. Moreover, the spore coat layers had apparently self-assembled, and this assembly was likely to be governed by crystal growth principles. During germination and outgrowth, the honeycomb layers, as well as the underlying spore coat and undercoat layers, sequentially dissolved until the vegetative cell was released. In addition to their implications for understanding the biology of C. novyi NT, these studies document the presence of proteinaceous growth spirals in a biological organism.     

Altered arrangement of proteins in the spore coat of a germination mutant of Bacillus subtilis

Spores produced by a mutant of Bacillus subtilis were slow to develop their resistance properties during sporulation, and were slower to germinate than were wild-type spores. The coat protein composition of the mutant spores, as analysed by SDS-PAGE, was similar to that of the wild-type spores. However, one of the proteins (mol. wt 12000) which is normally present in the outer-most layers of mature wild-type spores and which is surface-exposed, was assembled abnormally into the coat of the mutant spores and not surface-exposed. The mutation responsible for this phenotype (spo-520) has been mapped between pheA and leuB on the B. subtilis chromosome, and was 47% cotransformable with leuB16. This mutation, and three others closely linked to it, define a new sporulation locus, spoVIB, which is involved in spore coat assembly. The phenotype of the mutant(s) supports the contention that spore germination and resistance properties may be determined by the assembly of the coat.     

Changes in Microsporum gypseum Mycelial Wall and Spore Coat Glycoproteins During Sporulation and Spore Germination

Ethylenediamine-soluble glycoproteins were extracted from isolated Microsporum gypseum hyphal walls during sporulation and from spore coats before and after germination. This study was carried out to identify a sporulation-specific cell wall protein that possibly served as a substrate for the alkaline protease which initiated the macroconidial germination of this fungus. Analyses revealed that water-insoluble glycoprotein accounted for 10% of the ungerminated spore coat but only for 4 to 5% of the mycelial wall dry weight. This fraction was modified in its amino acid composition during sporulation, and it decreased in protein content during spore germination. Water-soluble glycoprotein, which accounted for approximately 3 to 3.5% of either the spore coat or mycelial wall dry weight, was of similar amino acid composition from both sources and did not decrease in protein content upon spore germination. The water-insoluble glycoprotein was found to be rich in leucine, aspartic acid, glycine, glutamic acid, and phenylalanine residues. The water-soluble glycoprotein was rich in proline, threonine, glycine, serine, glutamic acid, and alanine.     

Isolation and Partial Chemical Characterization of the Spore Appendages of Clostridium taeniosporum

The spore appendages of Clostridium taeniosporum NI were removed from the spores by sonic treatment and were isolated by using discontinuous sucrose gradients. The amino acid composition of the appendages, which are elaborations of the spore coat, was similar to but not identical with the amino acid composition of the coats. Approximately 80% of the appendage dry weight was composed of 17 common amino acids, whereas 68% of the spore coat dry weight was amino acids. Mole ratios of the amino acids differed between the appendages and spore coats. The appendages contained neither diaminopimelic acid nor hydroxyproline. Glucosamine was an abundant constituent but muramic acid was absent. Approximately 10% of appendage dry weight consisted of three sugars, one of which was glucose. Phosphorus content was high and dipicolinic acid was absent. Appendage fine structure was not affected by common buffers, dilute acids and bases, hydrogen bond-breaking agents, certain proteolytic enzymes, or lysozyme.     

Carbohydrate Composition during Germination and Outgrowth of Ascospores of Saccharomyces cerevisiae

Single spores of Saccharomyces cerevisiae were examined to distinguish changes in the synthesis and degradation of intracellular and wall carbohydrates during germination and outgrowth. Intracellular carbohydrate was fractionated into trehalose and glycogen. Trehalose degradation occurred during germination and outgrowth. The intracellular glycogen was degraded during germination and then synthesized during outgrowth. Wall carbohydrate was fractionated into glycogen, glucan and mannan. The wall glycogen and the KOH-soluble glucan were degraded during germination and then synthesized prior to and during outgrowth, respectively. The major component of the KOH-insoluble glucan in the wall is β-1,3-glucan. The glucan and mannan were synthesized during outgrowth.

The study revealed that the development of a vegetative cell from a spore follows rapid decreases in the amounts of trehalose, glycogen and KOH-soluble glucan during germination, and great increases in the amounts of glycogen, β-1,3-glucan and mannan during outgrowth.     

A novel small protein of Bacillus subtilis involved in spore germination and spore coat assembly

Two small genes named sscA (previously yhzE) and orf-62, located in the prsA-yhaK intergenic region of the Bacillus subtilis genome, were transcribed by SigK and GerE in the mother cells during the later stages of sporulation. The SscA-FLAG fusion protein was produced from T(5) of sporulation and incorporated into mature spores. sscA mutant spores exhibited poor germination, and Tricine-SDS-PAGE analysis showed that the coat protein profile of the mutant differed from that of the wild type. Bands corresponding to proteins at 59, 36, 5, and 3 kDa were reduced in the sscA null mutant. Western blot analysis of anti-CotB and anti-CotG antibodies showed reductions of the proteins at 59 kDa and 36 kDa in the sscA mutant spores. These proteins correspond to CotB and CotG. By immunoblot analysis of an anti-CotH antibody, we also observed that CotH was markedly reduced in the sscA mutant spores. It appears that SscA is a novel spore protein involved in the assembly of several components of the spore coat, including CotB, CotG, and CotH, and is associated with spore germination.     

How do spores germinate?

Spore germination, as defined as those events that result in the loss of the spore-specific properties, is an essentially biophysical process. It occurs without any need for new macromolecular synthesis, so the apparatus required is already present in the mature dormant spore. Germination in response to specific chemical nutrients requires specific receptor proteins, located at the inner membrane of the spore. After penetrating the outer layers of spore coat and cortex, germinant interacts with its receptor: one early consequence of this binding is the movement of monovalent cations from the spore core, followed by Ca2(+) and dipicolinic acid (DPA). In some species, an ion transport protein is also required for these early stages. Early events - including loss of heat resistance, ion movements and partial rehydration of the spore core - can occur without cortex hydrolysis, although the latter is required for complete core rehydration and colony formation from a spore. In Bacillus subtilis two crucial cortex lytic enzymes have been identified: one is CwlJ, which is DPA-responsive and is located at the cortex-coat junction. The second, SleB, is present both in outer layers and at the inner spore membrane, and is more resistant to wet heat than is CwlJ. Cortex hydrolysis leads to the complete rehydration of the spore core, and then enzyme activity within the spore protoplast resumes. We do not yet know what activates SleB activity in the spore, and neither do we have any information at all on how the spore coat is degraded.     

Ultrastructural changes occurring during germination and outgrowth of spores of the thermophile Bacillus acidocaldarius.

Spores of the thermophilic, acidophilic, Bacillus acidocaldarius were covered by a thick outer coat and a laminated inner coat (5.5 nm periodicity). Small membranous vesicles were present in the spore core and they disappeared as germination proceeded. After depolymerization of the cortex, and a 30% increase in spore diameter a localized gap appeared in the laminated inner coat only. This inner coat gap was narrow and could be the whole length of the spore. The germ cell appeared to grow, or to be pushed towards the inner coat gap, at which stage the outer coat disappeared in the same localized area. As the vegetative cell grew out the spore coat fell away, with loose cortical material still attached to it. The young germ cell developed a large spherical electron dense inclusion body in the cytoplasm, at the same time as the ribosomal and nuclear areas became distinct.     

Localization of the Cortex Lytic Enzyme CwlJ in Spores of Bacillus subtilis

The enzyme CwlJ is involved in the depolymerization of cortex peptidoglycan during germination of spores of Bacillus subtilis. CwlJ with a C-terminal His tag was functional and was extracted from spores by procedures that remove spore coat proteins. However, this CwlJ was not extracted from disrupted spores by dilute buffer, high salt concentrations, Triton X-100, Ca(2+)-dipicolinic acid, dithiothreitol, or peptidoglycan digestion, disappeared during spore germination, and was not present in cotE spores in which the spore coat is aberrant. These findings indicate the following: (i) the reason decoated and cotE spores germinate poorly with dipicolinic acid is the absence of CwlJ from these spores; and (ii) CwlJ is located in the spore coat, presumably tightly associated with one or more other coat proteins.     

Biochemical Studies on Germination of Bacterial Spores

The initiating mechanism in the germination of Bacillus thiaminolyticus spores was studied with ¹⁴C-L -alanine. A characteristic pattern of incorporation of L -alanine into the spores was observed during the early stages of germination with two incorporation peaks, one occurred just after contact with L -alanine (first incorporation) and the other 5 min later (second incorporation). L -Glutamine, L -valine, or L -serine substituted for the incorporation of L -alanine during the first stage of germination. Although, L -alanine taken up during the first incorporation phase was extractable with trichloroacetic acid (TCA), that taken up during the second incorporation phase was not extractable. The distribution of radioactivity showed that incorporated L -alanine was located in the spore coat, mainly in the paracrystal fraction. The radioactive material which remained in the germination medium or was extractable from the spore coat fraction with TCA treatment or pronase digestion was identified as alanine. Significance of incorporation of L -alanine and its location in the spore in reference to the initiation of germination is discussed.