Permeability of gentamicin and polymyxin B into the inside of Bacillus subtilis spores

The penetration of gentamicin and polymyxin B into the inside of Bacillus subtilis spores was examined by an immunoelectron microscopy method with colloidal gold--immunoglobulin G (IgG) complex. The colloidal gold particles were located predominantly in the coat region of both gentamicin-treated and polymyxin B-treated spores and were hardly observed in the other regions, i.e., the cortex and core regions. When these antibiotic-treated spores were subsequently treated with CaCl2, the number of gold particles bound to the coat region was greatly decreased. These results suggest that these two antibiotics are able to penetrate into the spore coat but not into the cortex or core, that is, the primary permeability barrier to them exists between the coat and the cortex regions.     

Effect of depletion of FtsY on spore morphology and the protein composition of the spore coat layer in Bacillus subtilis

Bacillus subtilis FtsY is a homolog of the alpha-subunit of mammalian signal recognition particle (SRP) receptor, and is essential for protein translocation and vegetative cell growth. An FtsY conditional null mutant (strain ISR39) can express ftsY during the vegetative stage but not during spore formation. Spores of ISR39 have the same resistance to heat and chloroform as the wild-type, while their resistance to lysozyme is reduced. Electron microscopy showed that the outer coat of spores was incompletely assembled. The coat protein profile of the ftsY mutant spores was different from that of wild-type spores. The amounts of CotA, and CotE were reduced in spore coat proteins of ftsY mutant spores and the molecular mass of CotB was reduced. In addition, CotA, CotB, and CotE are present in normal form at T(8) of sporulation in ftsY mutant cells. These results suggest that FtsY has a pivotal role in assembling coat proteins onto the coat layer during spore morphogenesis.     

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.     

The yabG gene of Bacillus subtilis encodes a sporulation specific protease which is involved in the processing of several spore coat proteins

The synthesis and proteolysis of the spore coat proteins, SpoIVA and YrbA, of Bacillus subtilis were analyzed using antisera. Almost no intact full-length proteins of either type were extracted from wild-type spores, while yabG mutant spores contained intact SpoIVA and YrbA proteins. We purified recombinant YrbA and YabG proteins from Escherichia coli transformants and found that YrbA was cleaved to the smaller moiety in the presence of YabG in vitro. These observations indicate that YabG is a protease involved in the proteolysis and maturation of SpoIVA and YrbA proteins, conserved with the cortex and/or coat assembly by B. subtilis.     

The Clostridium botulinum GerAB germination protein is located in the inner membrane of spores

Clostridium botulinum dormant spores germinate in presence of l-alanine via a specific receptor composed of GerAA, GerAB and GerAC proteins. In Bacillus subtilis spores, GerAA and GerAC proteins were located in the inner membrane of the spore. We studied the location of the GerAB protein in C. botulinum spore fractions by Western-blot analysis, using an antipeptidic antibody. The protein GerAB was in vitro translated and used to confirm the specificity of the antibodies. GerAB was not present in a coat and spore outer membrane fraction but was present in a fraction of decoated spores containing inner membrane. These results strongly suggest that the protein GerAB is located in the inner membrane of the spore.     

Ultrastructural localization of dipicolinic acid in dormant spores of Bacillus subtilis by immunoelectron microscopy with colloidal gold particles.

The localization of dipicolinic acid in dormant spores of Bacillus subtilis was examined by an immunoelectron microscopy method with colloidal gold-immunoglobulin G complex. The colloidal gold particles were distributed mainly in the core regions of dormant spores and were not observed in those of germinated or autoclaved spores. This result clearly demonstrates that dipicolinic acid is localized in the cores of dormant spores.     

Presence of proteins derived from the vegetative cell membrane in the dormant spore coat of Bacillus subtilis

To confirm the presence of the outer spore membrane in dormant spore coats of Bacillus subtilis, the proteins from vegetative cell membrane and dormant spore coat fractions were compared by immunoblot assay with antibodies prepared against both preparations. The spore coat fraction contained at least 11 proteins antigenically identical to those in the vegetative cell membranes. Further, the cytochemical localization of the proteins derived from vegetative cell membrane in dormant spores was examined by an immunoelectron microscopy method with a colloidal gold-immunoglobulin G complex. The colloidal gold particles were observed in the coat region and around the core region of dormant spore. These results have provided evidence that some proteins from vegetative cell membrane remain in the dormant spore coat region of B. subtilis, although it is not clear whether the outer membrane persists as an intact functional entity or not.     

Mutual relationship between antibiotics and resting spores of Bacillus subtilis: morphological changes and macromolecular synthesis after germination of spores treated with cyclic polypeptide and aminoglycoside antibiotics

Morphological changes and synthesis of DNA, RNA, protein, and cell wall were investigated during germination of resting spores of Bacillus subtilis exposed transiently to the cyclic polypeptide antibiotics, polymyxin B and gramicidin S, and the aminoglycoside antibiotics, streptomycin, kanamycin, and gentamicin. Normal germinated spores showed breaks of the spore coat, a diminution in size and a fibrillar appearance of the cortex, a swelling core, a cell wall as thick as that of vegetable cells, some mesosomes and DNA fibrils. On the other hand, no breaks of the spore coat, a spore core with a slight swelling and irregular form, a thin cell wall, no demonstration of the nuclear material and no granularity in the cytoplasm were characteristic of the germinated spores derived from polymyxin B- and gramicidin S-treated resting spores. With gramicidin S-treated germinated spores a few vacuoles were formed in the cytoplasm. Both polymyxin B- and gramicidin S-treated germinated spores showed little or no synthesis of DNA, RNA, and protein. The vegetative cells derived from streptomycin-treated resting spores demonstrated several finely granular regions in the cytoplasm and a disorder of the fibrillar nucleoid, and their autolysis occurred early. Their DNA and RNA synthesis was normal, whereas protein synthesis was low. In spite of no occurrence of cell division and very low protein synthesis, the most striking characteristics of the outgrowing cells derived from kanamycin-treated resting spores were a markedly thickened cell wall and a continuous incorporation of labeled D-alanine suggesting cell wall synthesis; RNA synthesis was slightly lower and DNA synthesis was almost normal. The outgrowing cells from gentamicin-treated resting spores also revealed relatively thick cell walls and a very slight incorporation of labeled D-alanine. Their DNA and RNA synthesis was fairly low and protein synthesis was almost completely inhibited. These results coincide with the growth curves of individual antibiotic-treated resting spores.     

Immunoelectron microscopic localization of one of the spore germination proteins, GerAB, in Bacillus subtilis spores.

Ultrastructural localization of GerAB, one of the proteins of Bacillus subtilis spores related to L-alanine-initiated germination, was investigated by immunoelectron microscopy with antipeptide (residues 61 to 80 of GerAB) antiserum and a colloidal gold-immunoglobulin G complex. Immunogold particles were visualized in the boundary region between the cortex and coat of dormant spores, and they were broadly dispersed into the cortex region after germination.     

The source of the heat resistance of bacterial spores: Study of water in spores by NMR

It has been postulated that the heat stabilization of the essential macromolecules in the core of the spore may be produced by dehydration at two levels: (i) the spore is drier at high relative humidity than the vegetative cell and (ii) the core of the spore may be less hydrated than the cortex and the coat. The latter postulate was subjected to experimental testing by ¹H-NMR studies of the water signal in the five species of spores and coat and (coat + cortex) preparations. The transverse relaxation rate $\text{(}\text{1}\text{T}{}_2\text{)}$ was determined in samples equilibrated at constant relative humidity. To allow for the effect of paramagnetic ions on $\text{1}\text{T}{}_2$ a model system (wool keratin) was studied in the presence of known amounts of Ca(II), Mn(II), Cu(II), Ni(II) and Fe(III). Because of the dominant effect of Mn(II) on $\text{1}\text{T}{}_2$, the effect of small amounts of other metal ions in spores was neglected. The relaxation rate of water at a particular relative humidity and manganese concentration was consistently less for intact spores than for coat or coat + cortex, hence the water in the core is more mobile than in the outer integuments. Sorption isotherm studies have shown that at a particular relative humidity there is about as much water in the core as in the cortex and coat. These two results taken together indicate that the hypothesis that the core is drier than the cortex and coat is incorrect, hence the spore is not heat-stabilized in this way. A theory is proposed in which heat stabilization is attributed to immobilization of essential enzymes and nuclei acids by a solid support, calcium dipicolinate, in a similar fashion to the heat stabilization of enzymes in a charged polymer matrix. It is proposed that stabilization is effected by electrostatic and hydrogen bonds between the calcium dipicolinate and the essential macromolecules. Experiments in progress show that enzymes and DNA are heat-stabilized in vitro by calcium dipicolinate.     

Assembly of the CotSA coat protein into spores requires CotS in Bacillus subtilis

The CotSA protein, encoded by cotSA (ytxN) of Bacillus subtilis, was detected from the cells at 5 h after the onset of sporulation (T5) and in the spore coat of wild-type cells, but not in cotE, cotS, gerE, or cotSA mutant spores. CotSA was also detected in the sporangium at T5 to T7 but not in the sporangium at T18 of cotS mutant cells, while the incorporation of CotS into the coat was not dependent upon CotSA. These results suggested that CotSA was synthesized simultaneously with CotS during T5 to T7 of sporulation and assembled into the coat dependent upon CotS.     

Ascospores of large-spored Metschnikowia species are genuine meiotic products of these yeasts

The asci of Metschnikowia species normally contain two ascospores (never more), raising the question of whether these spores are true meiotic products. We investigated this problem by crossing genetically-marked strains of the haploid, heterothallic taxa Metschnikowia hawaiiensis, Metschnikowia continentalis var. continentalis, and M. continentalis var. borealis. Asci were dissected and the segregation patterns for various phenotypes analyzed. In all cases (n = 47) both mating types (h+ and h-) were recovered in pairs of sister spores, casting further uncertainty as to whether normal meiosis takes place. However, the segregation patterns for cycloheximide resistance and several auxotrophic markers were random, suggesting that normal meiosis indeed occurs. To explain the lack of second-division segregation of mating types, we concluded that crossing-over does not occur between the mating-type locus and the centromere, and that meiosis I is tied to spore formation, which explains why the number of spores is limited to two. The latter assumption was also supported by fluorescence microscopy. The second meiotic division takes place inside the spores and is followed by the resorption of two nuclei, one in each spore.     

Early events of Bacillus anthracis germination identified by time-course quantitative proteomics

Germination of Bacillus anthracis spores involves rehydration of the spore interior and rapid degradation of several of the protective layers, including the spore coat. Here, we examine the temporal changes that occur during B. anthracis spore germination using an isobaric tagging system. Over the course of 17 min from the onset of germination, the levels of at least 19 spore proteins significantly decrease. Included are acid-soluble proteins, several known and predicted coat proteins, and proteins of unknown function. Over half of these proteins are small (less than 100 amino acids) and would have been undetectable by conventional gel-based analysis. We also identified 20 proteins, whose levels modestly increased at the later time points when metabolism has likely resumed. Taken together, our data show that isobaric labeling of complex mixtures is particularly effective for temporal studies. Furthermore, we describe a rigorous statistical approach to define relevant changes that takes into account the nature of data obtained from multidimensional protein identification technology coupled with the use of isobaric tags. This study provides an expanded list of the proteins that may be involved in germination of the B. anthracis spore and their relative levels during germination.     

Fungal injury to seed tissues of Norway spruce,Picea abies (L.) Karst.

Norway spruce bore an abundance of cones in Finland in 2000, but these cones were often fungal-infected. The seeds had structural injuries that were revealed when seed samples were examined using light (LM) and a field emission scanning electron microscope (FESEM). Two main types of spores were found either in the tissues inside the seed coat or on the sarcotesta, the outermost layer of seed coat. The spores of Chrysomyxa pirolata appeared particularly in the nucellar tissue, where the cell walls were disintegrated at the middle lamellae and cytoplasm was disrupted. Degenerated remnants of fungal structures resembling aecial peridium were found close to aeciospores. The tissue of the megagametophyte differed also from that of a normal mature seed. Conidia of Thysanophora penicillioides were often encountered on the sarcotesta where the ordinary wax cover was missing. Fungal injury occurred in the nucellar layers that shelter the embryo and megagametophyte from desiccation and oxidation. Destruction of these structures together with rapid opening of the seed coat advance deterioration of seeds during storage and may cause unexpected economic losses in forest plant production.     

Soil burrowing Muscina angustifrons (Diptera: Muscidae) larvae excrete spores capable of forming mycorrhizae underground

Muscina angustifrons (Diptera: Muscidae) is a mycophagous species that exploits a variety of fungi, including ectomycorrhizal fungi. Larvae of this species have been shown to feed on sporocarps (including spores), and full-grown larvae leave sporocarps and pupate 0–6?cm below the soil surface. In this study, we examined whether M. angustifrons larvae are capable of transporting ectomycorrhizal fungal spores and enhancing ectomycorrhiza growth on host-plant roots. Full-grown larvae were found to move horizontally 10–20?cm from their feeding sites and burrow underground. These wandering larvae retained ectomycorrhizal fungal spores in their intestines, which were excreted following relocation to underground pupation sites. Excreted spores retained germination and infection capacities to form ectomycorrhiza on host-plant roots. In the infection experiments, ectomycorrhizal fungal spores applied in the vicinity of underground host-plant roots were more effective in forming ectomycorrhiza than those applied to the ground surface, suggesting that belowground transportation of spores by M. angustifrons larvae could enhance ectomycorrhizal formation. These results suggested that M. angustifrons larvae act as a short-distance spore transporter of ectomycorrhizal fungi.     

Immunological detection of the GerA spore germination proteins in the spore integuments of Bacillus subtilis using scanning electron microscopy

Abstract To clarify the molecular mechanisms that trigger spore germination of Bacillus subtilis , the location of GerA proteins (GerAA, GerAB and GerAC), which were reported to be putative gene products of a receptor for one of the germinants, l-alanine, was investigated by immunological techniques using anti-GerA peptide antibodies. Four antibodies were raised against the corresponding epitopes, two in GerAA, one in GerAB and the other in GerAC molecules. The binding of all four antibodies to the inner surface of the cortex-less spore coat fragments could be seen by scanning immunoelectron microscopy with colloidal gold particles. The result agreed with the fact, previously reported, that the colloidal gold particles were visualized just inside the spore coat layer by transmission immunoelectron microscopy using another anti-GerAB peptide antibody.