Ultrastructure of spore development in <Emphasis Type="Italic">Scutellospora heterogama</Emphasis>

The ultrastructural detail of spore development in Scutellospora heterogama is described. Although the main ontogenetic events are similar to those described from light microscopy, the complexity of wall layering is greater when examined at an ultrastructural level. The basic concept of a rigid spore wall enclosing two inner, flexible walls still holds true, but there are additional zones within these three walls distinguishable using electron microscopy, including an inner layer that is involved in the formation of the germination shield. The spore wall has three layers rather than the two reported previously. An outer, thin ornamented layer and an inner, thicker layer are both derived from the hyphal wall and present at all stages of development. These layers differentiate into the outer spore layer visible at the light microscope level. A third inner layer unique to the spore develops during spore swelling and rapidly expands before contracting back to form the second wall layer visible by light microscopy. The two inner flexible walls also are more complex than light microscopy suggests. The close association with the inner flexible walls with germination shield formation consolidates the preferred use of the term ‘germinal walls’ for these structures. A thin electron-dense layer separates the two germinal walls and is the region in which the germination shield forms. The inner germinal wall develops at least two sub-layers, one of which has an appearance similar to that of the expanding layer of the outer spore wall. An electron-dense layer is formed on the inner surface of the inner germinal wall as the germination shield develops, and this forms the wall surrounding the germination shield as well as the germination tube. At maturity, the outer germinal wall develops a thin, striate layer within its substructure.     

Ultrastructure of developing basidiospores in <Emphasis Type="Italic">Rhizopogon roseolus</Emphasis> (= <Emphasis Type="Italic">R. rubescens</Emphasis>)

The ultrastructure of developing basidiospores in Rhizopogon roseolus is described. When viewed in the fruiting body chamber using scanning electron microscopy, basidiospores appear narrowly ellipsoid and have smooth walls. Eight basidiospores are usually produced on the apex of each sterigma on the basidium. Transmission electron micrographs showed that basidiospores formed by movement of cytoplasm (including the nuclei) via the sterigmata, and then each basidiospore eventually became separated from its sterigma by an electron-lucent septum. The sterigma and basidium subsequently collapsed, resulting in spore release. Freshly released spores retained the sterigmal appendage connected to the collapsed basidium. After spore release, the major ultrastructural changes in the spore concerned the lipid bodies and the spore wall. During maturation, lipid bodies formed and then expanded. Before release, the spore wall was homogeneous and electronlucent, but after release the spore wall comprised two distinct layers with electron-dense depositions at the inner wall, and the dense depositions formed an electron-dense third layer. The mature spore wall complex comprised at least four distinct layers: the outer electron-lucent thin double layers, the mottled electron-dense third layer, and the electron-lucent fourth layer in which electron-lucent granular substances were dispersed.     

Immunocytochemical localization of stachylysin in Stachybotrys chartarum

Stachylysin is a proteinaceous hemolytic agent that is produced by Stachybotrys chartarum. Stachylysin was found, using immunohistochemical and immunocytochemical methods, to be localized in S. chartarum spores/mycelia primarily in the inner wall suggesting that it is constitutively produced. Spores instilled in mouse or rat lung tissues resulted in granuloma formation, which showed the highest stachylysin concentration in the inner wall of the spore and near the spore, with less at distance indicating that it had diffused out from the spore. The in vitro high stachylysin producing strain (58-06) was also highest in vivo, based on immunohistochemistical staining. More stachylysin was observed in the mouse lung tissue at 72 h than at 24 h indicating that production/release is a relatively slow process. The localization of stachylysin in macrophage phagolysosomes suggests that these cells may be involved with hemolysin inactivation. This would be consistent with what is known about asp-hemolysin produced by Aspergillus fumigatus.This revised version was published online in October 2005 with corrections to the Cover Date.     

Ultrastructural changes in the spore and mycelia of Ascosphaera apis after treatment with benomyl (Benlate 50 W)

In Ascosphaera apis, after 8 days growth in darkness at 28° C, numerous sporocysts were observed, within which mature spores were seen aggregated into a spore ball. The mature spore of A. apis had a thick spore wall with an electron-opaque outer layer, a spore membrane with many depressions, and sporoplasm containing numerous ribosomes and mitochondria. In the cytoplasm of the mycelium, mitochondria with well-defined cristae and numerous ribosomes were observed. At a concentration of 1 g/ml of culture medium, benomyl appeared to inhibit colony growth of A. apis, but some sporocysts containing deformed spores were found. Deformed spores possessed a thick spore wall with a grainy matrix, and depressions were no longer detected in the spore membrane. Ribosomes were lacking in the sporoplasm and mitochondria appeared degenerate. The mycelium from the treated culture contained mitochondria with an electron-lucid matrix and no well defined cristae, while ribosomes were completely depleted. The significance of these observations in relation to the use of benomyl to control chalkbrood disease in the honey bee is discussed.     

Spore Adhesion and Cell Wall Formation in Gelidium Floridanum (Rhodophyta, Gelidiales)

The attachment of spores to a substratum is essential for their germination and, therefore, to the completion of the life cycle of the red algae. In most red algae, spores are liberated without a cell wall, within a sheath of mucilage which is responsible for their primary attachment. Utilizing fluorescent-labeled lectins, we identified carbohydrate residues and their locations in the mucilage and cell walls of spores of Gelidium floridanum. Cell wall formation and mucilage composition were studied with calcofluor, toluidine blue (AT-O), alcian blue (AB) and periodic acid-Schiff (PAS). In the mucilage we identified α-D mannose, α-D glucose, β-D-galactose, N-acetyl-glucosamine and N-acetyl-galactosamine. The first two sugar residues were not found in the cell wall of the germ tube but they were present on the rhizoid’s cell wall indicating their importance to substrate adhesion. A cell wall is produced soon after the spore’s attachment, beginning with a polar deposition of cellulose and its gradual spread around the spore as indicated by calcofluor. The cell wall matrix was positive to AB and metachromatic to AT-O, indicating acidic polysaccharides, while cellulose microfibrills were positive to PAS. A polar disorganization of the cell wall triggers the process of germination. As spores are the natural form of propagation of Gelidium, the understanding of the mechanisms of spore attachment may contribute to the cultivation of this valuable seaweed.     

Sporogenesis in Streptomyces melanochromogenes

The mode of spore differentiation in a strain of Streptomyces melanochromogenes was followed by analysis of ultrathin sections of sporulating aerial hyphae at various stages of sporogenesis. A special accent was laid on the formation of the sporulation septum and its alterations in the course of spore delimitation and separation. Distinct differences in formation and substructure have been observed between the cross walls of vegetative hyphae and the sporulation septa.Cross walls of vegetative hyphae are formed in a way typical for Gram-positive bacteria by a centripetal annular ingrowth of cytoplasmic membrane, on which wall material immediately is deposited. The development of the sporulation septa is characterized by the accumulation of amorphous material in addition to the newly synthesized wall layer inside the invaginating cytoplasmic membrane. This amorphous septal material will later be decomposed presumably by two lytic systems which cause the separation of the spores. The central region of the finished sporulation septum is perforated by microplasmodesmata. Spores are released by a break down of the surface sheath. The complete spores are enveloped by a twolayered cell wall and the spiny surface sheath.     

Spore ontogeny of the arbuscular mycorrhizal fungus<Emphasis Type="Italic"> Archaeospora trappei</Emphasis> (Ames &; Linderman) Morton &; Redecker (<Emphasis Type="Italic">Archaeosporaceae</Emphasis>)

Arbuscular mycorrhizal (AM) fungi in the genus Archaeospora (family Archaeosporaceae) contain both monomorphic and dimorphic species. The synanamorphism is often hard to discern without ontogenetic observations. Here, the spore ontogeny of Ar. trappei is reported from single species pot culture studies. The sporogenous hypha swelled up to a terminal sporiferous saccule and produced a lateral spore primordium on its neck. The saccule expanded fully before the spore primordium emerged. The saccule transferred its contents into the expanding spore and collapsed while wall differentiation continued inside the spore. The spore wall of Ar. trappei differentiated sequentially, in discrete steps, as in Acaulosporaceae members. In contrast, Ar. trappei produced a simplified spore wall in which the components differed in chemical and physical characteristics from those of the Acaulosporaceae members. Ontogenetic studies confirmed Ar. trappei to be monomorphic and producing acaulosporoid spores. The fungus is a new record to New Zealand.     

Spore formation in the Actinoplanaceae (Actinomycetales)

Spore development in four genera, Actinoplanes, Dactylosporangium, Planomonospora, and Streptosporangium, was studied by transmission and scanning electron microscopy. Actinoplanes and Streptosporangium formed spores by fragmentation of a hypha within its expanded outer sheath, as do many other actinomycetes. Dactylosporangium and Planomonospora formed spores endogenously by development of wall material within the parent hypha. In this respect, they resembled the genera Actinobifida and Thermoactinomyces. The term sporangium has therefore been used to describe structures which are not homologous. It was suggested that the term should be confined to structures in which endogenous spore formation occurs.     

A Highly Redundant Gene Network Controls Assembly of the Outer Spore Wall in S. cerevisiae

The spore wall of Saccharomyces cerevisiae is a multilaminar extracellular structure that is formed de novo in the course of sporulation. The outer layers of the spore wall provide spores with resistance to a wide variety of environmental stresses. The major components of the outer spore wall are the polysaccharide chitosan and a polymer formed from the di-amino acid dityrosine. Though the synthesis and export pathways for dityrosine have been described, genes directly involved in dityrosine polymerization and incorporation into the spore wall have not been identified. A synthetic gene array approach to identify new genes involved in outer spore wall synthesis revealed an interconnected network influencing dityrosine assembly. This network is highly redundant both for genes of different activities that compensate for the loss of each other and for related genes of overlapping activity. Several of the genes in this network have paralogs in the yeast genome and deletion of entire paralog sets is sufficient to severely reduce dityrosine fluorescence. Solid-state NMR analysis of partially purified outer spore walls identifies a novel component in spore walls from wild type that is absent in some of the paralog set mutants. Localization of gene products identified in the screen reveals an unexpected role for lipid droplets in outer spore wall formation.     

Rhinosporidium seeberi: Light,phase contrast,fluorescent and scanning electron microscopic study

Phase contrast microscopic study indicated the multilayered structure of the sporangial wall of R. seeberi while the scanning electronmicroscopic study revealed a trilaminated wall compared to a thick double walled light microscopic structure. The scanning electronmicroscopy revealed the spores of varying sizes which were found either discretely or in groups interconnected and seen attached to the inner aspect of the sporangial wall. Autofluorescence of sporangia and spores was observed under microscope. Acridine orange staining revealed the presence of DNA materials in the spore and sporangia.     

The role of fungal proteinases in pathophysiology of <Emphasis Type="Italic">Stachybotrys chartarum</Emphasis>

The adverse health effects of Stachybotrys chartarum have often been linked to exposure to the trichothecene mycotoxins. Recent studies have shown that in addition to mycotoxins this fungus is capable of producing and secreting in vivo proteins such as hemolysins and proteinases. Spore extracts obtained from a high trichothecene producing isolate JS 58-17 exhibited a significantly lower proteolytic activity compared to the low trichothecene producer, JS 58-06. Growing isolates on rice or potato dextrose agar results in higher proteolytic activity of the spores compared to those grown on drywall. Proteinases in the spore extracts can hydrolyze gelatin and collagen I and IV. Analysis of zymograms shows the presence of several proteins with proteolytic activity in the spores of S. chartarum. Human tracheal epithelial cells exposed to spore extracts produced significantly higher levels of IL-6, IL-8, and TNF-α than control cells. This stimulation of cytokine production was completely abolished by Pefabloc, a serine protease inhibitor. Neutrophil numbers and proinflammatory cytokine (IL1-β and TNF-α) concentrations were highly elevated in the lungs of 7 day old rat pups exposed intratracheally to 4 × 10⁴ spores/gm body weight compared to control. No significant differences in those inflammatory indices in vivo were noted between the treatments with the high trichothecene producer, isolate JS 58-17 and JS 58-06, which does not produce macrocyclic trichothecenes. Immunohistochemistry revealed reduced collagen IV labeling in spore-induced lung granulomas in rat pups exposed to both isolates. These results suggest that proteinases from S. chartarum spores significantly contribute to lung inflammation and injury.     

Effects of meteorological factors on airborne bracken (<Emphasis Type="Italic">Pteridium aquilinum</Emphasis> (L.) Kuhn.) spores in Salamanca (middle-west Spain)

Temporal variation of airborne bracken (Pteridium aquilinum) spores concentration in Salamanca during 10 years from January 1998 to December 2007 were studied by using a Burkard spore trap, and correlations with some meteorological parameters were analyzed. The number of spores that were counted was very low, due probably to the distance between the spore trap and the main bracken populations which were located 70 km away from the city. Long-range transport caused by winds coming from the Second Quadrant (IIQ) is supposed to be responsible for the appearance of bracken spores in Salamanca. The season period from August to late October shows the most intense spore dispersal process, with an early morning distribution along the day. Years 2002 and 2007 with a low quantity of airborne spores were also characterized by low mean temperatures, always under 18°C from May to June. Daily spore concentration shows positive correlation with temperature and sun hours but negative with IVQ winds and with relative humidity. No correlation between daily spore concentration and rainfall was found. Also, a positive correlation between number of spores and IIQ winds was observed during the main spore season (MSS) and prepeak period (PRE).     

Cytochemical and biochemical observations on the cell wall of the spore ofGlomus epigaeum

Summary The cell wall of the spore ofGlomus epigaeum Daniels and Trappe, which has fibrillar subunits regularly arranged in arcs, was studied ultrastructurally and biochemically.The periodic acid/thiocarbohydrazide/silver proteinate (PATAg) reaction for polysaccharide location (Thiéry 1967) and the silver methenamine reaction for protein location (Swift 1968) were performed on whole spores, progressively alkaline-extracted and autoclaved spores, and untreated and alkaline-extracted cell wall fractions. The cytochemical results and those obtained from frozen sections indicated that the fibrils forming the main structure of the outer and inner wall consist of chitin. Quantitative determinations showed that chitin is the most important component (47%) of the alkali-insoluble residue and represents 27.2% of the whole cell wall fraction. It occurs predominantly as the acetylated form. Cytochemical and biochemical observations showed that the matrix surrounding the fibrils is made of alkali-soluble, PATAg positive polysaccharides (4.98% of the whole cell wall fraction). Monomers were identified by gas liquid chromatography as being -lactone of glucuronic acid, and glucose, rhamnose and mannose. Alkali-soluble proteins are an important part of the matrix, being spread mostly throughout the inner wall and constituting a large portion (55.1 %) of the alkali-soluble fraction.From the results we derive a model in which the chemical components are interconnected to build up a macromolecular network, in agreement with electron-microscopic observations.     

适用于双向电泳的米曲霉孢子破壁方法研究

为探究米曲霉(Aspergillus oryzae)孢子适用于双向电泳的最佳破壁方法,采用5种不同的破壁方法对米曲霉孢子进行破壁,用血球计数板进行破壁率计算,Bradford方法测定释出的可溶性蛋白含量,并进行双向电泳可行性验证。结果表明,在普通光学显微镜下,破壁后的米曲霉孢子多为碎片,极少数为孢壁内空圆球。5种破壁方法中石英砂研磨+超声、液氮研磨、MP·Fast-prep均质器法在孢子浓度较低(107个/m L)时破壁效果较佳,但是随着孢子浓度的不断提升(109个/m L),只有均质器法能保证较高的破壁率,破壁率高达90%,且适用于双向电泳的蛋白质提取。     

Immunocytochemical staining of Histoplasma capsulatum at the electron microscopic level

Summary Rabbits were immunized with histoplasmin emulsified in Freund's complete adjuvant. Antibody raised in these rabbits was exposed to Histoplasma capsulatum yeast cells, either in tissue culture medium, or after in vitro or in vivo phagocytosis by mouse macrophages. The sites of antibody binding were identified using an immunoperoxidase technique. At least two sites of antibody binding were identified, one to the fungal cell wall and the other to the outer cell membrane. Within 6 h after phagocytosis by macrophages, fungal cell walls appeared roughened, with what appeared to be cell wall antigen released into the phagolysosome, appearing associated with the phagolysosome membrane, and possibly adjacent macrophage cytoplasm. Similar staining of fungal antigen was noted in alveolar macrophages which had ingested Histoplasma capsulatum after a respiratory challenge. This method may be useful in detailing the host/pathogen interactions which occur in human pulmonary histoplasmosis.     

The tapetum inSchizaea pectinata (Schizaeaceae) and a comparison with the tapetum inPsilotum nudum (Psilotaceae)

A combination tapetum consisting of a cellular, parietal component and a plasmodial component occurs inSchizaea pectinata. A single, tapetal initial layer divides to form an outer parietal layer which maintains its cellular integrity until late in spore wall development. The inner tapetal layer differentiates into a plasmodium which disappears after the outer exospore has developed. In the final stages of spore wall development, granular material occurs in large masses and is dispersed as small granules throughout the sporangial loculus. No tapetal membrane develops. Comparisons are drawn with the combination tapetum found inPsilotum nudum.     

Ultrastructural study of spore wall morphogenesis inOphioglossum thermale kom. var.nipponicum (Miyabe et Kudo) nishida

Spore wall morphogenesis ofOphioglossum thermale var.nipponicum was examined by transmission electron microscopy. The spore wall of this species consists of three layers: endospore, exospore, and perispore. The spore wall development begins at the tetrad stage. At first, the outer undulating lamellar layer of the exospore (Lo) is formed on the spore plasma membrane in advance of the inner accumulating lamellar layer (Li) of the exospore. Next, the homogeneous layer of the exospore (H) is deposited on the outer lamellar layer. Both lamellar layers may be derived from spore cytoplasm; and the homogeneous layer, from the tapetum. Then the endospore (EN) is formed. It may be derived from spore cytoplasm. The membranous perispore (PE), derived from the tapetum, covers the exospore surface as the final layer. Though the ornamentation of this species differs distinctly from that ofO. vulgatum, the results mentioned above are fundamentally in accordance with the data obtained fromO. vulgatum (Lugardon, 1971). Therefore, the pattern of spore wall morphogenesis appears to be very stable in the genusOphioglossum.     

Sporulation and regeneration efficiency of phosphobacteria (<Emphasis Type="Italic">Bacillus megaterium</Emphasis> var <Emphasis Type="Italic">phosphaticum</Emphasis>)

Sporulation in Bacillus megaterium var phosphaticum (PB — 1) was induced using modified nutrient media. This modified medium induced sporulation within 36 h. After spore induction the spores were kept under refrigerated (5°C) and room temperature (32°C) for five months and survival of spores was studied at 15 days intervals by plating them in nutrient agar medium. It was observed that there was not much variation in the storage temperature (5°C & 32°C). The spore cells of Bacillus megaterium var phosphaticum (PB — 1) were observed up to five months of storage under refrigerated (5°C) and room temperature (32°C). Regeneration of spore cells into vegetative cells was studied in tap water, rice gruel, nutrient broth, sterile lignite and sterile water at different concentrations of spore inoculum. The multiplication of sporulated Bacillus megaterium var phosphaticum culture was fast and reached its maximum (29.5 × 10⁸ cfu ml⁻¹) in nutrient broth containing 5 per cent inoculum level.     

Effects of media composition on submerged culture spores of the entomopathogenic fungus,Metarhizium anisopliae var. acridum Part 2: Effects of media osmolality on cell wall characteristics,carbohydrate concentrations,drying stability,and pathogenicity

This study evaluates osmolality of a submerged conidia-producing medium in relation to the following spore characteristics: yield, morphology (dimensions and cell wall structure), chemical properties of cell wall surfaces (charge, hydrophobicity, and lectin binding), cytoplasmic polyols and trehalose, and performance (drying stability and pathogenicity). Spore production was increased by the addition of up to 150 g l^?1 polyethylene glycol 200 (PEG). Spores from high osmolality medium (HOM spores) containing 100 g l^?1 PEG had thin cell walls and dimensions more similar to blastospores than submerged conidia or aerial conidia. However, a faint electron-dense layer separating primary and secondary HOM spores’ cell walls was discernable by transmission electron microscopy as found in aerial and submerged conidia but not found in blastospores. HOM spores also appeared to have an outer rodlet layer, unlike blastospores, although it was thinner than those observed in submerged conidia. HOM spores’ surfaces possessed hydrophobic microsites, which was further evidence of the presence of a rodlet layer. In addition, HOM spores had concentrations of exposed N-acetyl-β-d-glucosaminyl residues intermediate between blastospores and submerged conidia potentially indicating a masking of underlying cell wall by a rodlet layer. All spore types had exposed α-d-mannosyl and/or α-d-glucosyl residues, but lacked oligosaccharides. Similar to blastospores, HOM spores were less anionic than submerged conida. Although HOM spores had thin cell walls, they were more stable to drying than blastospores and submerged conidia. Relative drying stability did not appear to be the result of differences in polyol or trehalose concentrations, since trehalose concentrations were lower in HOM spores than submerged conidia and polyol concentrations were similar between the two spore types. HOM spores had faster germination rates than submerged conidia, similar to blastospores, and they were more pathogenic to Schistocerca americana than submerged conidia and aerial conidia.     

The response to a specific germinant by <Emphasis Type="Italic">Bacillus anthracis</Emphasis> spores in primary mouse macrophages is modulated by a protein encoded on the pXO1 plasmid

A Bacillus anthracis Sterne pXO1 plasmid-encoded protein designated Cot43 was found in coat extracts of purified spores. Cot43 is a tetratricopeptide repeat domain protein related to those which function as phosphatases in the sporulation phosphorelay and as regulators of competence and pathogenic factors. The synthesis of Cot43 began in the late exponential phase downstream from a sigmaA promoter (as mapped by RACE) and it was present at least until the formation of phase white endospores. There was specificity in the association of Cot43 with B. anthracis spores since Bacillus cereus producing Cot43 from a cloned gene had very little of this protein in spore coat extracts. In addition, Cot43 was synthesized by B. anthracis cells to the same extent in glucose-yeast extract and nutrient sporulation media, but was essentially absent from spores formed in the former. l-histidine is an important germinant for B. anthracis spores in macrophages, Spores produced by a mutant with a disruption of cot43 germinated in response to l-histidine both in vitro and within primary mouse macrophages earlier and more extensively than Sterne strain spores. The germination delay due to the presence of Cot43 would enhance spore survival and thus increase the chances for a successful infection. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.