FORMATION AND STRUCTURE OF THE SPORE OF BACILLUS COAGULANS

Spore formation in Bacillus coagulans has been studied by electron microscopy using an epoxy resin (Araldite) embedding technique. The developmental stages from the origin of the initial spore septum to the mature spore were investigated. The two forespore membranes developed from the double layer of cytoplasmic membrane. The cortex was progressively deposited between these two membranes. The inner membrane finally became the spore protoplasmic membrane, and the outer membrane part of the inner spore coat or the outer spore coat itself. In the mature spore the completed integuments around the spore protoplasm consisted of the cortex, a laminated inner coat, and a dense outer coat. No exosporium was observed. The method of formation of the cortex and the spore coats is discussed.     

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.     

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.     

Fine Structure of Bacillus megaterium during Microcycle Sporogenesis

Ultrathin sections were prepared from cultures of Bacillus megaterium QM B1551 undergoing microcycle sporogenesis (initial spore to primary cell to second-stage spore without intervening cell division) on a chemically defined medium. The cytoplasmic core of the dormant spore was surrounded by plasma membrane, cell-wall primordium, cortex, outer cortical layer, and spore coats. Early in the cycle, the coat opened at the germinal groove, the cortex swelled, ribosomes and a chromatinic area associated with large mesosomes (which may later be incorporated into the expanding plasma membrane) appeared in the core, and the cell wall became defined at the site of the cell wall primordium. Poly-β-hydroxybutyrate granules began to appear in the primary cell at about 3 hr. By 7 hr, the forespore of the second-stage spore was delineated by typical double membranes. Between 7 and 12 hr, second-stage cell-wall primordium and cortex developed between the separating forespore membranes. The inner membrane became the plasma membrane of the second-stage spore, and the outer membrane eventually disintegrated within the second-stage spore cortex. A densely staining double layer (spore-coat primordium) developed external to the outer forespore membrane. The inner spore coat and the outer cortical layer of the second-stage spore developed from this primordium. The outer part of the spore coat, probably of sporangial origin, was laid down on the external surface of the inner spore coat. By 12 hr, second-stage spores were almost mature. By 20 hr, the mature endospores, with a thickened outer coat, were often still enclosed by degenerate primary cell wall and by the outer cortical layer and spore coat of the initial spore.     

The fine structure of the frozen-etched spore of Nosema apis Zander

The mature spore of Nosema apis possesses a thick spore coat and a particle-bearing spore membrane. Within the spore membrane, in the anterior portion of the spore, is the highly laminated polaroplast. The fractured face of the lamella is granular. The convex face of the polar filament membrane carries few particles, while the concave face bears many densely packed particles. The nucleus of the mature spore is centrally located, and pores were observed on the nuclear envelope.     

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.     

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.     

DIVISION IN THE DINOFLAGELLATE GYRODINIUM COHNII (SCHILLER) : A New Type of Nuclear Reproduction

Dinoflagellates are of interest because their chromosomes resemble the nucleoplasm of prokaryotes both chemically and ultrastructurally. We have studied nuclear division in the dinoflagellate Gyrodinium cohnii (Schiller), using cells obtained from cultures undergoing phasic growth. Electron micrographs of serial sections were used to prepare three-dimensional reconstructions of nuclei and chromosomes at various stages of nuclear division. During division, a complex process of invagination of the intact nuclear envelope takes place at one side of the nucleus and results in the formation of parallel cylindrical cytoplasmic channels through the nucleus. These invaginations contain bundles of microtubules, and each of the bundles comes to lie in the cytoplasm of a cylindrical channel. Nuclear constriction occurs perpendicular to these channels without displacement of the microtubules. There are no associations between chromosomes and the cytoplasmic microtubules. In dividing cells most chromosomes become V-shaped, and the apices of the V's make contact with the membrane surrounding cytoplasmic channels. It is proposed that the membrane surrounding cytoplasmic channels in the dividing nucleus may be involved in the separation of daughter chromosomes. Thus, dinoflagellates may resemble prokaryotes in the manner of genophore separation as well as in genophore chemistry and ultrastructure.     

ON A RETICULAR DERIVATIVE FROM GOLGI BODIES IN THE MERISTEM OF Anthoceros

Micrographs of dictyosomes in face view and in profile, together with serial sections representing both these planes, are reproduced from three sample cells at different developmental stages in the meristem of Anthoceros. The stages are: a vegetative cell at anaphase of a mitotic division, a vegetative cell in an early stage of postmitotic extension growth, and a young spore mother cell in the act of rounding up before the onset of meiosis. The observations suggest that proliferation of tubules from the edges of the dictyosomal cisternae into the cytoplasm is occurring with varying intensity and with slightly different morphological expression in all three cells. In all, the tubules are joined into a reticulum which exhibits local swellings at varying distances from the unfenestrated part of the subtending cisterna. A comparison is suggested between the observed reticulum and "smooth" endoplasmic reticulum of animals but it is not claimed that all the cytoplasmic tubules detectable in Anthoceros need have arisen in this way. Morphological differences discernible between tubules near their point of attachment to dictyosomes and others apparently involved in the formation of the new nuclear membrane at the end of a cell division could mean that more than one category of tube may exist in these cells. A plea is registered for restraint in the formulation of far reaching theories until more facts are available on unequivocal evidence.     

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.     

CRUCIFORM NUCLEAR DIVISION IN WORONINA PYTHII (PLASMODIOPHOROMYCETES)

Somatic nuclear divisions in sporangiogenous plasmodia of Woronina pythii Goldie-Smith were studied with transmission electron microscopy. During metaphase, each nucleus formed a cruciform configuration as chromatin became aligned at the equatorial plate perpendicular to the persistent nucleolus. Except for polar fenestrations, the original nuclear envelope remained intact throughout the mitotic division. Intranuclear membranous vesicles appeared to bleb off the inner membrane of the original nuclear envelope, adhered to the surfaces of the separating chromatin, and eventually formed new daughter nuclear envelope within the original nuclear envelope. During the first 24 hr of vegetative plasmodial growth, each telophase nucleus exhibited an obvious constriction of the original nuclear envelope in the interzonal region. Similar constrictions were not evident in telophase nuclei found in 24–36-hr-old plasmodia. This variation in the ultrastructural morphology of cruciform division appears to be related to the age and size of each sporangiogenous plasmodium, and is the first to be documented within this group of fungal pathogens.     

Morphogenesis of Ascospores in Saccharomyces cerevisiae

Ultrastructural changes associated with ascospore formation in Saccharomyces cerevisiae were investigated by using freeze-etching and thin-sectioning techniques. The first nuclear division (meiosis I) is indicated by the appearance of spindle fibers within the nucleus. The nucleus subsequently elongates and eventually assumes a barbell shape; the second nuclear division (meiosis II) occurs before nuclear separation. The spindle fibers involved in meiosis II appear to be oriented perpendicular to those observed in meiosis I. A discrete bilaminar structure (forespore wall) progressively delineates each ascospore nucleus and encloses cytoplasmic material including mitochondria and endoplasmic reticulum. The forespores then elongate, close off, and become separated from the ascus cytoplasm by membranes. The ascospores assume a spherical shape as spore coat material is laid down; the latter stages of ascospore formation are characterized by thickening of the ascospore wall and disintegration of the ascus cytoplasm. No structures which could be identified as chromosomes were observed.     

The fission yeast spore is coated by a proteinaceous surface layer comprising mainly Isp3

The spore is a dormant cell that is resistant to various environmental stresses. As compared with the vegetative cell wall, the spore wall has a more extensive structure that confers resistance on spores. In the fission yeast Schizosaccharomyces pombe, the polysaccharides glucan and chitosan are major components of the spore wall; however, the structure of the spore surface remains unknown. We identify the spore coat protein Isp3/Meu4. The isp3 disruptant is viable and executes meiotic nuclear divisions as efficiently as the wild type, but isp3∆ spores show decreased tolerance to heat, digestive enzymes, and ethanol. Electron microscopy shows that an electron-dense layer is formed at the outermost region of the wild-type spore wall. This layer is not observed in isp3∆ spores. Furthermore, Isp3 is abundantly detected in this layer by immunoelectron microscopy. Thus Isp3 constitutes the spore coat, thereby conferring resistance to various environmental stresses.     

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.     

Formation of multinuclear cells induced by dimethyl sulfoxide: inhibition of cytokinesis and occurrence of novel nuclear division in Dictyostelium cells

Our previous studies showed that 10 percent dimethyl sulfoxide (DMSO) induces the formation of actin microfilament bundles in the cell nucleus together with the dislocation of cortical microfilaments from the plasma membrane. The present study investigated the effects of DMSO on diverse activities mediated by cellular microfilaments as the second step toward assessing potential differences between nuclear and cytoplasmic actins of dictyostelium mucoroides. DMSO was found to reversibly inhibit cell-to- glass as well as cell-to-cell adhesion, cell locomotion, and cell multiplication, whereas cytoplasmic streaming and phagocytosis were not obviously inhibited. Also, 5 percent DMSO inhibited cytokinesis but did not totally inhibit cell growth thus leading to the development of giant cells more than 10 times larger than normal cells. Transmission electron microscopy using serial thin sections showed the occurrence of multinucleation in the DMSO- induced giant cells. After the removal of DMSO, the giant multinuclear cells underwent multiple cytoplasmic cleavage producing normal-sized mononuclear cells. The nuclear division in the DMSO-induced giant cells was unique in that no spindle microtubules were formed, and vesicles appeared inside the nucleus forming a transverse partition of the nuclear envelope. The presence of actin filaments in those nuclei was demonstrated by a binding study with skeletal muscle myosin subfragment-1, and their possible involvement in this mode of nuclear division is discussed.     

COLONY DEVELOPMENT IN EUDORINA ELEGANS (CHLOROPHYTA,VOLVOCALES)1

A detailed ultrastructure study was made of cell division and colony development in Eudorina elegans Ehrenberg. At the onset of cell division and prior to nuclear division the nucleus moved from the cell center to the cell surface. During nuclear division the nuclear membrane remained intact, except for openings occurring at the nuclear poles. The spindle microtubules appeared to arise from a MTOC-like (microtubule organizing centers) structure, while centrioles were absent from the nuclear poles. Following telophase, daughter nuclei formed which were separated by several distinct bands of endoplasmic reticulum. Cytokinesis occurred with formation of a cleavage furrow, associated with a typical phycoplast band of microtubules. However, cytokinesis was incomplete, resulting in formation of cytoplasmic bridges between the plakeal cells. Upon completion of up to five successive cell divisions, the plakea underwent inversion, which appeared to involve the production of colonial envelope material and rearrangement of cytoplasmic bridges. A new hypothesis concerning inversion is postulated based on these observations.     

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.     

Abnormal spore cleavage: Abnormal spores of Allomyces macrogynus

In the aquatic phycomycete Allomyces macrogynus abnormal spore cleavage takes place in the presence of colchicine or benomyl resulting in multinucleate–multiflagellate spores due to failure in the formation of cytoplasmic microtubules after the induction of zoosporogenesis. The 27 cytoplasmic microtubules which normally surround the nucleus and nuclear cap of the mature spore are not formed in the presence of colchicine or benomyl. At high concentrations of colchicine (4–8 mg/ml) the spores do not have a flagellum. Colchicine or benomyl inhibit microtubule formation during zoosporogenesis and also appear to perturb the mobilization of the gamma bodies which are believed to be the source of the vesicles which form the axonemal membrane and cleavage furrows. These observations are discussed in relation to the hypothesis of Heath that cytoplasmic microtubules formed during zoosporogenesis determine cytoplasmic domains which will delimit the spore initials at cleavage. The observations presented here appear to confirm this hypothesis.     

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.     

An investigation of membrane fluidity changes during sporulation and germination of Bacillus megaterium K.M. measured by electron spin and nuclear magnetic resonance spectroscopy

Changes in membrane and macromolecular fluidity which may accompany the differentiation processes of sporulation and germination in Bacillus megaterium K.M. are examined by electron spin and nuclear magnetic resonance spectroscopy. No change in membrane lipid fluidity is observed in isolated forespores up to stage VI. Between stage VI and release of mature spores, the ESR spectrum of doxylstearic acid spin labels becomes polycrystalline. This change in spectral fluidity is completely reversed during germination and is paralleled by the rapid release of Ca²⁺ from the spore. NMR studies also show that the mature spore has reduced macromolecular mobility and an increased non-exchangeable water pool compared with vegetative cells.