Changes in wall and internal structure of allomyces-resistant sporangia during germination

The electron microscope was used to examine changes which take place in wall, as well as in internal, structure during germination of mature resistant sporangia of Allomyces neo-moniliformis. When the resistant sporangia are first placed in water to initiate germination, nuclei, mitochondria, and endoplasmic reticulum are not evident, though after the sporangia have been in water for more than 30 min all of these structures become visible. At this time no cracks are evident in the resistant sporangial wall and the cell membrane appears highly convoluted. Within the next 30 min the outer wall splits and the inner wall expands considerably as the protoplast increases in volume. At the same time the cell membrane straightens out, apparently in response to the protoplasmic expansion. The “cementing substances” begin to dissolve about this time so that 1 1/2 hr after placement in water the outer wall is completely separated from the inner wall which now acts as the cell wall. Cleavage appears to be initiated by the invagination of the cell membrane and by the appearance of segments of endoplasmic reticulum with filled vesicles at one end. Between 2 1/2 and 3 hr after placement in water zoospores are released.     

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.     

Germination of the resting sporangia ofPhysoderma maydis,the causal agent ofPhysoderma disease of maize

Summary The structural and developmental characteristics of the resting sporangium in uniflagellate phycomycetes, together with the type of zoospore, are of high taxonomic value. Among these fungi, however, only a few electron microscopic investigations have been published on this topic, mainly due to technical problems. In the present study ofPhysoderma maydis (Blastocladiales) these problems were overcome as the resting sporangia in this species are formed synchronously, in large numbers, the germination is readily induced and the impermeability of the resting sporangium wall can be circumvented by shaking the prefixed sporangia with glass beads.The germination of the resting sporangia ofP. maydis is described by correlative light and electron microscopic studies and discussed in relation to related investigations on sporogenesis: The germination process starts by a breakdown of large electron-dense accretions found in the resting stage. Simultaneously, the peripheral location of the lipid bodies is lost. The large operculum is pushed open by a protrusion of the inner sporangial wall; an additional wall layer is formed during this process. Synaptonemal complexes are found in the nuclei at this stage, as are nuclear division figures which suggests anEuallomyces type of life cycle for this fungus. Cleavage vesicles, formed from dictyosomes or endoplasmic reticulum, ultimately separate the sporangial content into meiospores. The sequential assembly of organelles into the side body complex is described. Sequestering of the ribosomes into a nuclear cap is interpreted as taking place immediately prior to zoospore discharge.     

The arrangement of microfibrils in sporangial walls of Allomyces

Summary The microfibrillar component of the walls of zoosporangia and resistant sporangia of the phycomycete Allomyces arbusculus has been studied in the electron microscope, after chemical removal of the amorphous wall materials. In the zoosporangium wall the microfibrils are randomly arranged, as in the outer layer of the hyphal walls, and the sporangial wall is of even thickness. In the resistant sporangia the microfibrillar layer of the wall is perforated by numerous pores 0.25 in diameter. The microfibrils are randomly arranged over much of the wall but tend to be concentrically arranged in the vicinity of the pores. On the inside of the wall the microfibrils form a thickened rim around the pore.     

ULTRASTRUCTURE OF DISPERSED AND IN SITU SPECIMENS OF THE DEVONIAN SPORE RHABDOSPORITES LANGII: EVIDENCE FOR THE EVOLUTIONARY RELATIONSHIPS OF PROGYMNOSPERMS

Abstract: The spore Rhabdosporites (Triletes) langii (Eisenack) Richardson, 1960 is abundant and well preserved in Middle Devonian (Eifelian) ‘Middle Old Red Sandstone’ deposits from the Orcadian Basin, Scotland. Here it occurs as dispersed individual spores and in situ in isolated sporangia. This paper reports on a detailed light microscope (LM), scanning electron microscope (SEM) and transmission electron microscope (TEM) analysis of both dispersed and in situ spores. The dispersed spores are pseudosaccate with a thick walled inner body enclosed within an outer layer that was originally attached only over the proximal face. The inner body has lamellate/laminate ultrastructure consisting of fine lamellae that are continuous around the spore and parallel stacked. Towards the outer part of the inner body these group to form thicker laminate structures that are also continuous and parallel stacked. The outer layer has spongy ultrastructure. In situ spores preserved in the isolated sporangia are identical to the dispersed forms in terms of morphology, gross structure and wall ultrastructure. The sporangium wall is two‐layered. A thick coalified outer layer is cellular and represents the main sporangium wall. This layer is readily lost if oxidation is applied during processing. A thin inner layer is interpreted as a peritapetal membrane. This layer survives oxidation as a tightly adherent membranous covering of the spore mass. Ultrastructurally it consists of three layers, with the innermost layer composed of material similar to that comprising the outer layer of the spores. Based on the new LM, SEM and TEM information, consideration is given to spore wall formation. The inner body of the spores is interpreted as developing by centripetal accumulation of lamellae at the plasma membrane. The outer layer is interpreted as forming by accretion of sporopollenin units derived from a tapetum. The inner layer of the sporangium wall is considered to represent a peritapetal membrane formed from the remnants of this tapetum. The spore R. langii derives from aneurophytalean progymnosperms. In light of the new evidence on spore/sporangium characters, and hypotheses of spore wall development based on interpretation of these, the evolutionary relationships of the progymnosperms are considered in terms of their origins and relationship to the seed plants. It is concluded that there is a smooth evolutionary transition between Apiculiretusispora‐type spores of certain basal euphyllophytes, Rhabdosporites‐type spores of aneurophytalean progymnosperms and Geminospora‐/Contagisporites‐type spores of heterosporous archaeopteridalean progymnosperms. Prepollen of basal seed plants (hydrasperman, medullosan and callistophytalean pteridosperms) are easily derived from the spores of either homosporous or heterosporous progymnosperms. The proposed evolutionary transition was sequential with increasing complexity of the spore/pollen wall probably reflecting increasing sophistication of reproductive strategy. The pollen wall of crown group seed plants appears to incorporate a completely new developmental mechanism: tectum and infratectum initiation within a glycocalyx‐like Microspore Surface Coat. It is unclear when this feature evolved, but it appears likely that it was not present in the most basal stem group seed plants.     

Pollen morphology and structure of Zingiber (Zingiberaceae)

The aim of the present study is to describe the morphology and internal wall structure of Zingiber pollen. The pollen of 18 species of Zingiber was examined by light, scanning and transmission electron microscopy. In the sections Zingiber and Dymczewiczia (Horan.) Benth. the pollen grains are spherical with cerebroid sculpturing while in the section Cryptanthium Horan. the pollen is ellipsoid with spira-striate sculpturing. All species have a thin coherent exine and an intine consisting of a thick, radially channeled outer layer and a thin, finely granular inner layer. On the basis of pollen morphology it is proposed that the section Dymczeniczia is included in the section Zingiber. The structure of the pollen wall in Zingiber resembles that of Canna and Strelitzia in having a pollen wall offering an infinite number of germination sites.     

Comparative studies onChlorella cell walls: Induction of protoplast formation

Among 12 strains ofChlorella ellipsoidea, C. vulgaris, andC. saccharophila tested, 4 strains (1,C. ellpsoidea; 2,C. vulgaris; 1,C. saccharophila) formed osmotically labile protoplasts after treatment with mixtures of polysaccharide degrading enzymes. The relationship between enzymatical digestibility and structure or composition ofChlorella cell walls were studied by electron microscopy and staining techniques with some specific dyes. The cell wall structures of the 12Chlorella strains were grouped into three types: (1) with a trilaminar outer layer, (2) with a thin outer monolayer, and (3) without an outer layer. Protoplasts were formed only from the strains with a cell wall of Type 2. In the strains with a cell wall of Type 1, the outer layer protected the inner major microfibrillar layer against enzymatic digestion. The cell wall of Type 3 was totally resistant to the enzymes; the chemical composition of the cell wall would be somewhat different from that of other types.     

Electron microscopy of germinating ascospores ofSaccharomyces cerevisiae

The wall of mature ascospores ofSaccharomyces cerevisiae showed in sections under the electron microscope a dark outer layer and a lighter inner layer. The latter was composed of a greyish inner part and a light outer part. During germination, the spore grew out at one side and the dark outer layer was broken. Of the light inner layer, the inner greyish part became the wall of the vegetative cell, but the extented part of the cell had a new wall.     

Electron microscopy of sexual reproduction in Nephroselmis olivacea (Prasinophyceae, Chlorophyta)

The electron microscopy of zygote formation and the early stages of zygote germination in Nephroselmis olivacea Stein are presented. Although the gametes differ behaviorally during the early stages of gamete fusion, the alga is isogamous. The minus gamete settled on the substrate, and attached with its left side. The plus gamete swam to the minus gamete, attached ventral to the right side of the minus gamete, while slightly on its left side, and plasmogamy started. No specialized organelle for gamete fusion was seen using either scanning or transmission electron microscopy. Gametic fusion was uniform; the right side of the minus gamete always fused with the ventral, slightly left side of the plus gamete, which suggests the participation of the d‐rootlets of the flagellar apparatus of the two gametes. Body scales were retained throughout the entire sexual process. Before karyogamy, a network of endoplasmic reticulum developed between the nuclei. This position corresponded to the contractile vacuole of the plus gamete. Fusion proceeded as the minus gamete was drawn to the plus gamete and resulted in a hemispherical zygote. Fibrous material appeared on the cell surface, embedding the body scales to form a layer that thickened and contributed to the strong adhesion of the zygote to the substrate. During this stage, karyogamy was completed. A thick zygotic wall composed of two layers, an electron‐dense outer layer and a straticulate electron‐lucent inner layer developed beneath the layer of fibrous material and scales. Zygote germination was induced. After the first meiotic division, the layer of fibrous material and scales ruptured and the inner layer of the zygotic wall thinned, allowing the emergence of two germ cells. They had newly formed scales and two starch grains, but no typical pyrenoid.     

Structural aspects of akinete germination in the cyanobacterium Anabaena variabilis

Electronmicroscopical investigations of light activated akinetes in different phases before outgrowth of the germinating cell showed two alterations in the akinete envelope, obviously in connection with the germination process. After induction of germination the akinetes show formation of an expanding more or less electron dense layer between the outer cell wall layer (outer membrane, L_IV) and the condensed part of the akinete coat (the transformed sheath of the vegetative cell). Between this new formed layer and the mentioned part of the akinete coat thick laminar layers are deposited which contain alternately electron dense and electron transparent strata. The expanding layer is assumed to be a mucous layer which acts as swelling body causing, after bursting of the layered shell, the expulsion of the germinating cell in the manner characteristic for Anabaena variabilis.     

Seed coat development, anatomy and scanning electron microscopy of Harpagophytum procumbens (Devil's Claw), Pedaliaceae

Seed coat development of Harpagophytum procumbens (Devil's Claw) and the possible role of the mature seed coat in seed dormancy were studied by light microscopy (LM), transmission electron microscopy (TEM) and environmental scanning electron microscopy (ESEM). Very young ovules of H. procumbens have a single thick integument consisting of densely packed thin-walled parenchyma cells that are uniform in shape and size. During later developmental stages the parenchyma cells differentiate into 4 different zones. Zone 1 is the multi-layered inner epidermis of the single integument that eventually develops into a tough impenetrable covering that tightly encloses the embryo. The inner epidermis is delineated on the inside by a few layers of collapsed remnant endosperm cell wall layers and on the outside by remnant cell wall layers of zone 2, also called the middle layer. Together with the inner epidermis these remnant cell wall layers from collapsed cells may contribute towards seed coat impermeability. Zone 2 underneath the inner epidermis consists of large thin-walled parenchyma cells. Zone 3 is the sub-epidermal layers underneath the outer epidermis referred to as a hypodermis and zone 4 is the single outer seed coat epidermal layer. Both zones 3 and 4 develop unusual secondary wall thickenings. The primary cell walls of the outer epidermis and hypodermis disintegrated during the final stages of seed maturation, leaving only a scaffold of these secondary cell wall thickenings. In the mature seed coat the outer fibrillar seed coat consists of the outer epidermis and hypodermis and separates easily to reveal the dense, smooth inner epidermis of the seed coat. Outer epidermal and hypodermal wall thickenings develop over primary pit fields and arise from the deposition of secondary cell wall material in the form of alternative electron dense and electron lucent layers. ESEM studies showed that the outer epidermal and hypodermal seed coat layers are exceptionally hygroscopic. At 100% relative humidity within the ESEM chamber, drops of water readily condense on the seed surface and react in various ways with the seed coat components, resulting in the swelling and expansion of the wall thickenings. The flexible fibrous outer seed coat epidermis and hypodermis may enhance soil seed contact and retention of water, while the inner seed coat epidermis maintains structural and perhaps chemical seed dormancy due to the possible presence of inhibitors.     

Microscopic observations of germination and septum formation in pycnidiospores of Botryodiplodia theobromae

A population of aseptate pycnidiospores of the fungus Botryodiplodia theobromae can be induced to germinate or to form septa delimiting two cells; this developmental process is dependent upon nutritional and environmental factors. Transmission electron microscope investigations indicate that during germination of the aseptate spore, a new inner wall layer is synthesized de novo at the site of germ tube emergence. Formation of the septum also involves the de novo synthesis of an inner wall layer which comprises the majority of the septum and completely surrounds the spore. The wall of the germ tube emerging from the septate spore is a direct extension of this inner layer deposited during the formation of the septum. Although the early stages of spore germination may involve localized enzymatic degradation of the internal layers of the spore wall, transmission and scanning electron micrographs of germinating spores show that the outer wall layers are physically fractured by the emerging germ tube. It is suggested that spore germination and septum formation are initially similar processes regarding cell wall genesis but that some mechanism responsive to environmental and nutritional conditions determines the course of development.     

STRUCTURE AND COMPOSITION OF THE RESISTANT SPORANGIAL WALL IN THE FUNGUS ALLOMYCES

The fine structure and chemical composition of the wall of resistant sporangia of Allomyces neo-moniliformis were investigated. Studies with the electron microscope showed that the wall is approximately 1.3 μ in thickness and is of complex construction. It consists essentially of three parts: a five-layered outer wall, two layers of “cementing substances,” and a single-layered inner wall. The presence of a highly convoluted cell membrane was also demonstrated. Six structural components were found to make up the walls of the resistant sporangia: glucose, glucosamine, chitin, melanin, protein, and lipids. Comparison of the structure and composition of the walls of resistant sporangia with the walls of hyphae and zoospores of Allomyces as reported by other investigators showed that, while the structure is very different, the composition is quite similar with only melanin and lipids apparently being absent from the zoospore and hyphal walls.     

Ultrastructure of freeze-substitutedFrankia strain HFPCcI 3, the actinomycete isolated from root nodules ofCasuarina cunninghamiana

Summary Frankia strain HFPCcI 3 is an actinomycete isolated from root nodules ofCasuarina cunninghamiana. In culture it exhibits typicalFrankia morphology and may produce three distinct morphological forms: branching septate hyphae, terminal or intercalary sporangia, and specialized structures termed vesicles which are the purported site of nitrogenase activity. An examination of the ultrastructure of all three morphological forms using both conventional chemical fixation (CF) and quick-freezing followed by freeze-substitution (FS) reveals some interesting differences between the two fixation methods. Unique to FS material are: 1. smooth membrane profiles; 2. lack of mesosomes; 3. lack of discernible nucleoid regions with condensed chromatin; 4. clarity of cytoplasmic elements such as ribosomes and granular bodies; 5. large cytoplasmic tubules in hyphae and young sporangia; 6. outer wall layer not widely separated from the spherical portion of the vesicle, and 7. bundles of microfilaments in vesicles. The quality of preservation after FS appears to be far superior to that obtained with CF. Accordingly the structures observed after FS are thought to represent more faithfully the structure of the living cell.     

THE CELL WALL OF PYROCYSTIS SPP. (DINOCOCCALES)1,2

The cell of Pyrocystis spp. is covered by an outer layer of material resistant to strong acids and bases. Internal to this layer much of the cell wall is composed of cellulose fibrils. The presence of cellulose fibrils was established by staining raw and ultra-violet–peroxide-cleaned cell walls and by combining X-ray diffraction spectroscopy with electron microscope observation. Carbon replicas of freeze-etched preparations and thin sections of P. lunula walls show outer layers, inside them ca. 24 layers of crossed parallel cellulose fibrils (4–5 nm thick, ca. 12 nm wide), then a region of smaller (ca. 6–12 nm diameter) fibrils in a disperse texture, and then the plasma membrane. Cellulose fibrils in the parallel texture are constructed of 3–5 elementary fibrils ca. 3 nm in diameter. Walls of P. fusiformis and P. pseudonctiluca also have cellulose fibrils in a crossed parallel texture similar to those of P. lunula. The Gymnodinium-type swarmer from lunate P. lunula appears to have a cell wall ultrastructure typical of other “naked” dinoflagellates.     

Ultrastructure of the ascospores of some species of the Torulaspora group

Development and germination of the ascospores in species of the Torulaspora group of yeasts have been described. Most species had warty spores which, in sections, showed a dark outer layer consisting of the outer unit membrane of the prospore wall and a layer underneath formed at an early stage of development of the spores. In mature spores the light inner layer of the wall was delimited at the outside by a thin dark layer. The warts often contained dark material. The ascospores of two Pichia and three Debaryomyces species were studied for comparison; they differed in sections from the Torulaspora spores. The taxonomic implications of the ultrastructural observations have been discussed.     

SPORE WALL DEVELOPMENT IN ANDREAEA (MUSCI: ANDREAEOPSIDA)

The spore wall of Andreaea rothii (Andreaeopsida) is unique among mosses studied by transmission electron microscopy. The exine of other mosses is typically initiated on trilaminar structures of near unit membrane dimensions just outside the plasma membrane. The exine of Andreaea is initiated in the absence of such structures as discrete globules within the coarsely fibrillar network of the sporocyte wall. The sequence of wall layer development, nevertheless, is essentially like that of other mosses. The intine is deposited within the exine and the perine accumulates on the surface of the exine during the latter stages of spore maturation. The mature spore is weakly trilete and inaperturate. The wall consists of three layers, the inner intine, the spongy exine consisting of loosely compacted irregular globules of sporopollenin, and an outer layer of perine. The perine differs ultrastructurally from the exine only in its greater degree of electron opacity. This ultrastructural evidence of departure from the fundamental pattern of exine development in mosses supports the taxonomic isolation of Andreaea from mosses of the Sphagnopsida and Bryopsida.     

Electron Microscopic Studies on the Outer Layers of Staphylococcus aureus Using a Lytic Enzyme from Flavobacterium

The structure of the outer layers (cell wall and membrane) of Staphylococcus aureus was studied by electron microscope using a bacteriolytic enzyme from Flavobacterium sp. called the L-11 enzyme. Comparative studies on the morphology of bacteria before and after treatment with this enzyme and cell wall and membrane fractions obtained from bacteria after the enzyme treatment led to the following conclusions. (1) The cell wall of S. aureus is composed of morphologically distinct two layers which are both susceptible to the L-11 enzyme. (2) Between the cell wall and membrane, there is an electron opaque region which could not be stained using any of the methods tested. (3) Before treatment of bacteria with the enzyme the cell membrane could not be seen clearly. However, after enzyme treatment the membrane was clearly seen. (4) The infolding of the inner layer of the cell wall, forming a structure like a mesosome, was liberated by extensive enzyme treatment.     

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.     

Embryology of the dioecious Woonyoungia septentrionalis (Magnoliaceae)

The embryological characteristics and ovular integument development of the dioecious species Woonyoungia septentrionalis (Dandy) Law (Magnoliaceae), which are poorly understood, were investigated under laser scanning confocal microscope (LSCM) and light microscope (LM). The embryological characteristics conform to most of the previously studied species in Magnoliaceae. The anther has 4 microsporangia, and the anther wall develops according to the dicotyledonous type. Cytokinesis at meiosis of the microspore mother cells follows a modified simultaneous type, giving rise to isobilateral or decussate tetrads, and a cell plate is absent, but a membrane was observed. Mature pollen grains are 2‐cellular and have high germination rates. The ovule is anatropous, crassinucellate and bitegmic, and meiotic result in linear tetrads of megaspores, the one at the chalazal end functions directly as an embryo‐sac cell. The development of the embryo sac is of the Polygonum‐type and endosperm formation is of the nuclear type. The outer integument of the ovule differentiates into an outer fleshy and an inner stony layer while the inner integument is reduced to a tanniniferous layer. The normal embryological development, high germination rates of pollen and high seed set indicate that the primary reason for the decline of the species is not to be found in these developmental processes.