The fine structure of frozen-etched bacillus cereus spores

Summary The fine structure of Bacillus cereus spores was studied using the freeze-etching technique and compared with that already described in chemically fixed cells. Although the basic structures did not appear different, the freeze-etching technique permitted the examination of membrane surfaces and their involvement in sporulation. In this respect, some membranes were found to be covered with small 120 Å particles believed to represent multi-enzyme complexes, while other membranes appeared relatively smooth.One feature revealed by the freeze-etching technique and not demonstrated in chemically fixed cells, was the presence of relatively large (500 Å) vesicular structures. In many instances these vesicles were closely associated with different layers or membranes in the developing spore. While the role of these vesicular structures is as yet undetermined, their possible connection with the lytic process which liberates the spore from the sporangium, is discussed.     

Eukaryotic behaviour of a prokaryotic energy‐transducing membrane: fully detached vesicular organelles arise by budding from the Rhodobacter sphaeroides intracytoplasmic photosynthetic membrane

A major feature that distinguishes prokaryotic organisms from eukaryotes is their less complex internal structure, in which all membrane‐associated functions are thought to be present within a continuous lipid–protein bilayer, rather than with distinct organelles. Contrary to this notion, as described by Tucker and co‐workers in this issue of Molecular Microbiology, the application of cryo‐electron tomography to the purple bacterium Rhodobacter sphaeroides has demonstrated a heretofore unrecognized ultrastructural complexity within the intracytoplasmic membrane (ICM) housing the photosynthetic apparatus. In addition to distinguishing invaginations of the cytoplasmic membrane (CM) and interconnected vesicular structures still attached to the CM, a eukaryote‐like ICM budding process was revealed, which results in the formation of fully detached vesicular structures. These bacterial organelles are able to carry out both the light‐harvesting and light‐driven energy transduction activities necessary for the cells to assume a photosynthetic lifestyle. Their formation is shown to represent the final stage in a membrane invagination and growth process, originating with small CM indentations, which after cell disruption give rise to a membrane fraction that can be separated from mature ICM vesicles by rate‐zone sedimentation.     

Electron microscopy of spore germination and cell wall formation in Mucor rouxii

Summary The fine structure of ungerminated and aerobically germinated sporangiospores of Mucor rouxii was compared. The germination process may be divided into two stages: I, spherical growth; II, emergence of a germ tube. In both stages, germination is growth in its strictest sense with overall increases in cell organelles; e.g., the increase in mitochondria is commensurate with the overall increase in protoplasmic mass. Noticeable changes occurring during germination are the disappearance of electron-dense lipoid bodies, formation of a large central vacuole and, most strikingly, formation of a new cell wall. Unlike many other fungi, M. rouxii does not germinate by converting the spore wall into a vegetative wall. Instead, as in other Mucorales, a vegetative wall is formed de novo under the spore wall during germination stage I. This new wall grows out, rupturing the spore wall, to become the germ tube wall. Associated with the apical wall of the germ tube is an apical corpuscle previously described. The vegetative wall exhibits a nonlayered, uniformly microfibrillar appearance in marked distinction to the spore wall which is triple-layered, with two thin electron dense outer layers, and a thick transparent inner stratum. The lack of continuity between the spore and vegetative walls is correlated with marked differences in wall chemistry previously reported. A separate new wall is also formed under the spore wall during anaerobic germination leading to yeast cell formation. On the other hand, in the development of one vegetative cell from another, such as in the formation of hyphae from yeast cells, the cell wall is structurally continuous. This continuity is correlated with a similarity in chemical composition of the cell wall reported earlier.     

Composition and Ultrastructure of Streptomyces venezuelae

Streptomyces venezuelae is a filamentous bacterium with branching vegetative hyphae embedded in the substrate and aerial hyphae bearing spores. The exterior of the spore is inlaid with myriads of tiny rods which can be removed with xylene. The spore wall is approximately 30 nanometers thick. Occasionally, it can be seen that the plasma membrane and the membranous bodies within a spore are connected. The spore's germ plasm is not separated from the cytoplasm by a nuclear envelope. The cell walls of the vegetative hyphae, which are about 15 nanometers thick, are structurally and chemically similar to those of gram-positive bacteria. The numerous internal membranous bodies, some of which arise from the plasma membrane of the vegetative hypha, may be vesicular, whirled, or convoluted. Membranous bodies are usually prominent at the hyphal apices and are associated with septum formation. The germ plasm is an elongate, contorted, centrally placed area of lower electron density than the hyphal cytoplasm. The spores differ from the vegetative hyphae, not only in fine structure, but also in the arginine and leucine contents of their total cellular proteins.     

Fine structure of sporulation in Bacillus cereus grown in a chemically defined medium

Ellar, D. J. (Syracuse University, Syracuse, N.Y.), and D. G. Lundgren. Fine structure of sporulation in Bacillus cereus grown in a chemically defined medium. J. Bacteriol. 92:1748-1764. 1966.-A study was made of the fine structure of sporulating cells of Bacillus cereus grown in a chemically defined medium. The developmental stages of sporulation occurred in a fairly synchronous manner and were complete by 14 hr. This time period was shortened when spore wall peptide components were added to the medium, but the addition had no effect upon fine structure except to thicken the cell wall. Sporulation could be separated into six morphological stages which generally agreed with those published for other sporulating bacteria. The initiation of the spore (forespore) septum takes the form of an inward folding of the cytoplasmic membrane toward the pole of the cell. The inward folding forms a characteristic Y-shaped membrane structure enclosing an area within which vesicles are found. These vesicles comprise the perisporal mesosome of the cell. The membranes on opposite sides of the cell progress toward the cell center where they fuse to form the double unit membrane of the spore septum. As the proliferation of the spore septum continues, the vesicular areas move towards the pole. The end result is a double forespore membrane which completely encloses a part of the vegetative cell's chromatin. Sporal mesosomes, as well as membrane vesicles, are involved in the proliferation of the forespore. Vesicles are generally bounded by a single unit membrane, whereas in the sporal mesosomes several unit membranes are arranged concentrically. The latter become associated with the segregation of a portion of the nuclear material into the forespore region of the cell.     

槲蕨配子体形态发育的扫描电镜观察

该研究以水龙骨科(Polypodiaceae)槲蕨(Drynaria roosii Nakaike)为研究对象,在人工培养条件下,采用扫描电镜观察其配子体发育的全过程,以期从三维立体角度揭示槲蕨配子体各发育阶段中的一些精细结构,为进一步补充部分经典形态学理论提供依据。结果显示:(1)槲蕨孢子萌发过程中原叶体母细胞的初生假根存在两条同时生长的现象。(2)槲蕨配子体的假根膨大及分叉现象普遍,且具有2层细胞壁,基部呈圆孔状结构。(3)槲蕨的原叶体腹面及边缘处毛状体非常发达,且乳突状单细胞毛状体和针状单细胞毛状体混生。(4)精子器释放精子时,盖细胞前后呈不同开裂状态。(5)发现精细胞向游动精子转化可能的限制性结构是细胞膜,细胞膜表面附着有碎屑状物质。(6)观察到腹沟细胞的解体过程是从近颈卵器开口处的细胞膜开始逐渐向四周及其后下方扩展。(7)发现了颈壁细胞在排列顺序和数量上都不稳定的畸形颈卵器、体积正常但无法区分雌雄的性器及体积显著增大呈锥形的泡状败育性器。     

Studies on the Fine Structure of Microorganisms : V. Morphogenesis of Nuclear and Membrane Structures during Ascospore Formation in Yeast

The fine structure of cells of Saccharomyces cerevisiae engaged in the formation of ascospores was studied in electron micrographs of ultrathin sections. Although the mode of the first reduction division could not be clearly determined, the second nuclear division appeared to proceed in a manner similar to that observed previously during vegetative division. That is, division by constriction of the existing nucleus occurs without dissolution of the nuclear membrane and without involvement of discrete chromosomes. Variously shaped areas of low electron density were discerned within the nucleoplasm; these had not been previously seen in the vegetative nucleus. The significance of this nuclear differentiation and its possible similarity to nuclear structures reported in bacteria and an imperfect fungus are discussed. The cytoplasmic membrane appears first in the developing ascospore. The formation of an outer coat and an inner coat then follows. The cytoplasmic vacuole was observed not to be incorporated into the spore. An unusual intracytoplasmic membrane was observed in the spore and appeared to be at least temporarily continuous with the nuclear membrane.     

The Pathway of Golgi Cluster Formation in Okadaic Acid-Treated Cells

Using stereology and immunoelectron microscopy we examined the pathway of Golgi duster formation during treatment with the phosphatase inhibitor okadaic acid. During the first hour the Golgi stack of suspension HeLa cells lost 90% of its membrane without appreciable reduction in the number of cisternae. During this time clusters of tubules and vesicles (Golgi clusters) appeared and these contained only a fraction of the Golgi membrane present in untreated cells. Despite the overall reduction in membrane the total amount of immunolabeling for galactosyltransferase over the Golgi clusters of a typical cell was maintained, indicating that galactosyltransferase had been retained in Golgi membranes. The observation that, after 40 min okadaic acid treatment, labeling density for galactosyltransferase within trans Golgi cisternae increased 1.6-fold (n = 3, CE 10%) suggests that membrane loss from trans cisternae was selective. Careful evaluation of immunolabeled clusters showed that most of the galactosyltransferase labeling was located over complex tubular profiles and not vesicular profiles. Tubular structures were also observed during disassembly and these were found both connected to disassembling cisternae and within forming Golgi clusters, indicating that they were intermediates in cluster formation. We also investigated the role of vesicular transport in cluster formation. During disassembly we found no accumulation of COP-coated buds and vesicles over Golgi membrane. However, aluminium fluoride, previously found to arrest transport in the Golgi stack, completely inhibited membrane depletion and stack disassembly. Taken together, our results indicate that during Golgi cluster formation, membrane leaves the Golgi but galactosyltransferase is retained within a tubular reticulum which is a direct descendant of trans-Golgi cisternae. Membrane depletion may require ongoing vesicular transport and we postulate that it arises because of an imbalance in membrane traffic into and out of the Golgi apparatus.     

The induction of spore cells in vitro by membranes of Dictyostelium discoideum

A mutant of Dictyostelium discoideum, HM18, will differentiate into both stalk and spore cells when plated at high cell density (10⁵ cells/cm²) as a monolayer on non-nutrient agar containing 5 mM cAMP [6]. At low cell density (10³ cells/cm²) neither stalk nor spore cells are produced, but the addition of a cytosol fraction leads to stalk cell formation, and the addition of a membrane fraction leads to spore cell formation. The spore cell-inducing activity of the cell membranes is developmentally regulated; it is first detectable during late aggregation and increases to a maximum level in the pseudoplasmodial stage of development. The activity is sensitive to proteolysis and insensitive to periodate treatment. It is partially inactivated by incubation at 100 °C for 5 min. Variable amounts of the activity can be removed from the membrane by washing, suggesting that at least part of the activity is loosely membrane-bound. Activity is enriched in plasma membrane fractions, suggesting that the inducing factor is located at the cell surface. It is possible that the membranes are replacing a cell-cell contact requirement for spore formation.     

MORPHOLOGY OF SPORE DEVELOPMENT IN CLOSTRIDIUM PECTINOVORUM.

Fitz-James, Philip C. (University of Western Ontario, London, Ont., Canada). Morphology of spore development in Clostridium pectinovorum. J. Bacteriol. 84:104-114. 1962-The process of spore formation in Clostridium pectinovorum was followed by phase-contrast microscopy and by thin-section electron microscopy employing a polyester plastic for embedding. The development of the forespore membrane was found to be similar to that already described for the genus Bacillus, being, in addition, accompanied by considerable cell enlargement. The cortex, as in the bacilli, was found between the apposed layers of the double forespore membrane. The spore coat was laid down in the narrow zone of cytoplasm peripheral to the outer forespore membrane. As these layers formed, striking changes occurred in the fine structure of the spore nuclear material, mesosomes and ribosomes, reflecting the marked alterations in physical environment known to occur in a developing spore.     

Secondary spore formation in <Emphasis Type="Italic">Orchesellaria mauguioi</Emphasis> (Asellariales,Trichomycetes) and its taxonomic and ecological implications

Orchesellaria (Orc.) mauguioi (Asellariales) was detected from the hindguts of Isotomurus palustris (Collembola, Hexapoda) collected in Japan. The secondary spore formation on the exuviae of its host is described. When the host molted, its exoskelton including the ectoderm-originated hindgut cuticle to which Orc. mauguioi mycelia attaches was shed. Arthrospores of Orc. mauguioi germinated and penetrated the molt skin and produced secondary spores terminally. The secondary spore is a narrowly ovoid monosporangious sporangium accompanied by a capitate-lageniform terminal cell; these fall off together as a dispersive unit. The terminal cell is sterile and bears one to three fine filamentous extensions seven times as long as the length of the cell. In contrast to the appendages produced endogenously by other harpellids, the filament is produced exogenously and is similar to those of the genus Orphella (Harpellales). The taxonomic and ecological implications of the secondary spore formation of Orc. mauguioi are discussed by comparison with those of other Trichomycetes.     

Manipulation of Major Membrane Lipid Synthesis and Its Effects on Sporulation in Saccharomyces cerevisiae

During the sporulation process of Saccharomyces cerevisiae, meiotic progression is accompanied by de novo formation of the prospore membrane inside the cell. However, it remains to be determined whether certain species of lipids are required for spore formation in yeast. In this study, we analyzed the requirement of the synthesis of phosphatidylethanolamine (PE), phosphatidylcholine (PC), and ergosterol for spore formation using strains in which the synthesis of these lipids can be controlled. When synthesis of PE and PC was repressed, sporulation efficiency decreased. This suggests that synthesis of these phospholipids is vital to proper sporulation. In addition, sporulation was also impaired in cells with a lowered sterol content, raising the possibility that sterol content is also important for spore formation.     

The gamma body: A vesicle generating structure

Gamma bodies, which are present in the sporangia and gametangia of Allomyces and in its spores, are interpreted as constituting vesicle generating structures. During spore cleavage the mobilization–decay of the gamma bodies leads to vesicle formation; the vesicles appear to fuse to form the axonemal and plasma membrane of the spore. Vesicle formation by the gamma bodies during spore cleavage can be perturbed by phosphate buffer which leads to the formation of myelin–figure arrays of membranes, or by colchicine and benomyl which give rise to large vacuolar structures after gamma body decay. During the motile period of the spores of Allomyces , mobilization of the gamma bodies leads to vacuole formation and the resulting vacuoles fuse with the plasma membrane of the spore and by this means maintain the osmotic balance of the spore. During spore encystment the gamma body decays and forms vesicles which fuse with the plasma membrane of the cyst; these vesicles appear to be instrumental in chitin wall synthesis.     

Effect of lipopolysaccharides on the morphology of erythrocyte membranes

The effect of lipopolysaccharide (LPS) isolated from Gram-negative bacteriaSalmonella typhi on erythrocyte membranes was investigated by electron microscopy. The LPS was found to be irregularly distributed on the surface of erythrocytes and their envelopes. It caused the formation of short bilayer rods associated at one end with the erythrocyte membrane of vesicular formations localized horizontally on or in the membrane, and of lamellar structures.     

Aspects of spore production in the red algaCeramium

Summary Tetraspore development from the post-meiotic to the mature stage has been studied using light and electron microscopy and histochemistry. The structure of the mature carpospore is identical to that of the tetraspore suggesting a similar developmental sequence.The tetrasporangial wall consists of 3 main fibrillar layers, the origin of the inner of which appears to be the wall-plasmalemma interface. The development of furrows cleaving the protoplast into 4 results in the formation of new plasmalemma and subsequently new wall fibrils. The Golgi apparatus is important in the formation of two well-defined substances. The first is fibrillar and is secretedvia vacuole-like structures into the sporangial wall. After spore release, this functions as a protective mucilaginous layer. The second has a distinctive fine structural morphology and probably functions as an adhesive.Observations on spore releasein vivo reveals a similar process for both types of spore. Each spore is surrounded by mucilage which may assist in initial attachment prior to the secretion of the adhesive.     

Ultrastructural pathology of the compound eye and optic neuropiles of the retinal degeneration mutant (w rdgB KS222) Drosophila melanogaster

Summary Lanthanum, applied to the outside of the fixed sciatic nerve of Rana pipiens, did not enter the endoneurium, but was halted by functionally tight junctions at the inner layers of the perineurium. This component of the bloodnerve barrier consists of several concentric layers of cells interspersed with an extracellular matrix of amorphous ground substance, collagen fibrils, and fine filaments. Numerous vesicular profiles are closely associated with the surface membranes of all the cells. The application of lanthanum to fixed tissue revealed that these profiles are attached to the cell surface by narrow necks, and open to the extracellular space. The attenuated cells are filled by the vesicular structures, which often appear to overlap. Stereoscopic electron microscopy showed that these vesicles did not fuse with each other or with the apposing cell surface to form transcellular channels. Channel formation does not appear to contribute significantly to the permeability of any of the perineurial layers.     

Ultrastructure of basidiospores and mycelium of Lenzites saepiaria

Hyde, James M. (University of Mississippi Medical School, Jackson), and Charles H. Walkinshaw. Ultrastructure of basidiospores and mycelium of Lenzites saepiaria. J. Bacteriol. 92:1218-1227. 1966.-Ungerminated and germinated basidiospores and 2-day-old mycelial cultures of Lenzites saepiaria were similar in their fine structure. Fixation with glutaraldehyde, followed by osmium tetroxide, was far superior to permanganate. Cell organelles were seen in cytoplasm of spores and hyphae, and clamp connections were abundant in hyphal elements. Numerous lomasomes, vesicular bodies, and complex concentric membranes occurred in the cytoplasm and were often associated with the cell membrane or the dolipore membrane (parenthesome) of the septum. Endoplasmic reticulum was not found, but numerous ribosomes were seen; polyribosome groupings were frequently noted. The nucleus was bounded by a double membrane which contained few pores. Germinating spores exhibited one or more large osmiophilic bodies in association with a vacuole and membranous elements. Other than possessing a thin wall, the emerging germ tube was similar in structure to the parent spore.     

Spore production and mycorrhizal development in various tropical crop hosts infected with Glomus clarum

Plant growth, mycorrhizal development and vesicular arbuscular spore production were examined in five tropical crop host species inoculated with Glomus clarum and grown in a glasshouse. In one of the two experiments, sequential harvests of maize, sorghum and chickpea were made in order to study spore production in relation to plant growth and mycorrhizal development. Spore numbers in each of these hosts increased at a fairly constant rate until maximum plant dry weight, when spore production ceased. Sorghum and maize produced considerably more spores than chickpea, with spore numbers being closely correlated with mycorrhizal root length. In the second experiment, Glomus clarum was cultured on each of maize, millet, sorghum, groundnut and chickpea for three consecutive generations before cross-inoculation of the spores from each host onto all five hosts. Sporulation with respect to host size was generally greatest when the inoculum used to infect a host had been produced on that host. The growth-promoting effects of the fungus were not influenced by the source of the inoculum. More spores were produced on the cereals than the legumes. Differences in spore numbers amongst hosts and plant generations were apparently influenced mainly by infected root length and by the growth period.     

PARTICIPATION OF THE CYTOPLASMIC MEMBRANE IN THE GROWTH AND SPORE FORMATION OF BACILLI

A polyester embedding technique was used to study the early stages of spore formation in members of the genus Bacillus in order to investigate further the origin and nature of the initial spore septum and the resulting forespore envelope. Whereas previously, with a methacrylate procedure, this layer had appeared to be continuous with the cell wall, this study reveals it as a double layer of cytoplasmic membrane. Perisporal, membranous organelles connected both to the developing forspore envelope and to the cytoplasmic membrane were encountered in the four species studied. Similar organelles were prominent during growth at the sites of transverse septa formation. These were connected to, or continuous with, the cytoplasmic membrane and often adherent to the chromatin bodies of the dividing bacilli.     

Fine structure of the developing spore of Nosema apis zander

Summary The mature spore possesses a thick spore coat and a particle-bearing spore membrane. The highly laminated polaroplast membranes are located at the anterior pole of the spore. Close to its base, the polar filament is surrounded by the polaroplast membrane. The polar filament runs spirally towards the posterior pole of the spore. A large portion of the polar filament is arranged in two layers. A similar arrangement was also observed in immature spores and in the sporoblast stage, although it was not so orderly arranged in the latter. The developing polaroplast membrane was observed in the immature spore, but not in the sporoblast. The sporoblast wall is much thinner than the spore coat, but has the same texture. Endoplasmic reticulum is the most prominent cytoplasmic organelle in the developing stages of Nosema apis. Porous nuclear envelopes are also observed in developing stages. The role of the endoplasmic reticulum in the formation of the polar filament, polaroplast and spore coat, and the function of the spore membrane, are discussed.