Infection of Onion by the White Rot Pathogen, Sclerotium cepivorum

Infection of onion tissue by Sclerotium cepivorum occurred from germ tubes penetrating between adjacent epidermal cell walls or directly, via penetration pegs produced from slightly swollen hyphal tips or from beneath dome shaped infection cushions. After passing through the cuticle, the infection peg enlarged to form an infection hypha within the primary cell wall. Extensive degradation of the epidermal cell wall occurred, often at a distance of 2–3 cells from the advancing hyphae. As infection advanced, hyphae spread rapidly from the epidermis to the cortex growing between and within dead/dying host cells. Extensive host cell death resulted in localized collapse of the tissue around infection points. Complete colonization of the internal tissues of the root and stem base occurred within 5–7 days of inoculation.     

Nucellar projection transfer cells in the developing wheat grain

Summary Transfer cells in the nucellar projection of wheat grains at 25 ±3 days after anthesis have been examined using light and electron microscopy. Within the nucellar tissue, a sequential increase in non-polarized wall ingrowth differentiation and cytoplasmic density was evident. Cells located near the pigment strand were the least differentiated. The degree of differentiation increased progressively in cells further removed from the pigment strand and the cells bordering the endosperm cavity had degenerated. Four stages of transfer cell development were identified at the light microscope level. Wall ingrowth differentiation followed a sequence from a papillate form through increased branching (antler-shaped ingrowths) which ultimately anastomosed to form a complex labyrinth. The final stage of wall ingrowth differentiation was compression which resulted in massive ingrowths. In parallel with wall ingrowth deposition cytoplasmic density increased. During wall deposition, paramural and multivesicular bodies were prominent and were in close association with the wall ingrowths. The degeneration phase involved infilling of cytoplasmic islets within the wall ingrowths. This was accompanied by complete loss of the protoplast. The significance of this transfer cell development for sucrose efflux to the endosperm cavity was assessed by computing potential sucrose fluxes across the plasma membrane surface areas of the nucellar projection cells. Transfer cell development amplified the total plasma membrane surface area by 22 fold. The potential sucrose flux, when compared with maximal rates of facilitated membrane transport of sugars, indicated spare capacity for sucrose efflux to the endosperm cavity. Indeed, when the total flux was partitioned between the nucellar projection cells at the three stages of transfer cell development, the fully differentiated stage III cells located proximally to the endosperm cavity alone exhibited spare transport capacity. Stage II cells could accommodate the total rate of sucrose transfer, but stage I cells could not. It is concluded that the nucellar projection tissue of wheat provides a unique opportunity to study transfer cell development and the functional role of these cells in supporting sucrose transport.Abbreviations CSPMSA cross sectional plasma membrane surface area - LPMSA longitudinal plasma membrane surface area - PTS tri-sodium 3-hydroxy-5,8,10-pyrenetrisulfonate     

Induction of wall ingrowths of transfer cells occurs rapidly and depends upon gene expression in cotyledons of developing Vicia faba seeds

Summary. Abaxial epidermal cells of developing faba bean (Vicia faba) cotyledons are modified to a transfer cell morphology and function. In contrast, the adaxial epidermal cells do not form transfer cells but can be induced to do so when excised cotyledons are cultured on an agar medium. The first fenestrated layer of wall ingrowths is apparent within 24 h of cotyledon exposure to culture medium. The time course of wall ingrowth formation was examined further. By 2 h following cotyledon excision, a 350 nm thick wall was deposited evenly over the outer periclinal walls of adaxial epidermal cells and densities of cytoplasmic vesicles increased. After 3 h in culture, 10% of epidermal cells contained small projections of wall material on their outer periclinal walls. Thereafter, this percentage rose sharply and reached a maximum of 90% by 15 h. Continuous culture of cotyledons on a medium containing 6-methyl purine (an inhibitor of RNA synthesis) completely blocked wall ingrowth formation. In contrast, if exposure to 6-methyl purine was delayed for 1 h at the start of the culture period, the adaxial epidermal cells were found to contain small wall ingrowths. Treating cotyledons for 1 h with 6-methyl purine at 15 h following cotyledon excision halted further wall ingrowth development. We conclude that transfer cell induction is rapid and that signalling and early events leading to wall ingrowth formation depend upon gene expression. In addition, these gene products have a high turnover rate. Correspondence and reprints: School of Environmental and Life Sciences, Biology Building, University of Newcastle, Callaghan, NSW 2308, Australia.     

Morphological and ultrastructural studies on protoplast production and reversion of the higher basidiomyceteAgaricus bisporus

Protoplasts have been isolated from young vegetative mycelia ofAgaricus bisporus by an enzyme mixture of novozym and chitinase. Protoplasts were released through ruptures in the wall, initially at the apices, but also later from older parts of the hyphae, indicating that they may lack the cell wall. The process of regeneration of these protoplasts has been investigated in liquid medium in which the protoplasts produced short chains of convoluted cells that finally produced a hypha. Electron microscopy has shown that at the start of regeneration two different kinds of fibrils were produced at the external surface of the protoplasts. Later, the thickness of the cell wall increased, and there was a deposit of amorphous material giving rise to a complete new wall.     

SECRETIONS FROM THE PISTIL OF LILIUM LONGIFLORUM

The pistil of Lilium longiflorum secretes two forms of exudate, one from the stigma surface and the other from the canal cavity. Electrophoretic studies of these exudates have revealed quantitative and qualitative differences in protein profiles. The exudatic components which are transferred to the cell wall by endoplasmic reticulum and Golgi vesicles, are stored within the cell wall of the secretive tissues and secreted from the cell walls directly. The cell wall structure of these secretive tissues differs. The canal cell wall has thick characteristic ingrowths that are supplied mainly from Golgi vesicles, while the papilla cell wall of the stigma is thinner, lacks ingrowths, and is supplied from ER vesicles.     

Ontogeny of external glands in the bladderwortUtricularia monanthos

Summary The development of external glands on traps and stolons ofU. monanthos has been studied using transmission electron microscopy. During early differentiation of the epidermis some cells remain narrow and develop a protuberance which subsequently divides into a terminal and a pedestal cell, with the remainder of the original cell forming the basal epidermal cell of the gland. The lateral wall of the pedestal cell soon becomes densely impregnated throughout its thickness, and this is followed by the formation of discontinuous cuticular deposits within the primary wall of the terminal cell. The outer wall of the terminal cell then usually undergoes extensive secondary wall thickening beginning with the formation of ingrowths which for a period characterize the cell as a transfer cell. Later, at the stage when traps begin capturing prey, these ingrowths are overlain by further layers of secondary wall material. Concomitantly, in the pedestal cell, wall ingrowths become fully differentiated on the outer transverse wall and persist throughout the remaining life of the gland.The function of external glands during early ontogeny is discussed. At the stage when the terminal cell is differentiated as a transfer cell it is suggested that the gland is mainly responsible for absorbing solutes from the external medium. Once traps commence capturing prey the gland may become modified for a rôle in water secretion, facilitated by the differentiation of the pedestal cell as a transfer cell, and by the formation of a thick outer wall in the terminal cell.     

Calcification and Decalcification During Epithallial Cell Turnover in Coralline Red Algae

Epithallial cells of the coralline red algae are characterized by unusual structural specialization, which include deep invaginations of the distal cell surface, and by unique development, which culminates in senescence, shedding, and replacement of the cells. Electron microscopic study of epithelial cell differentiation in morphologically and taxonomically disparate species suggests that the unusual features of epithelial cell structure and development stem from the fact that these dynamics occur within a calcified matrix. Distal wall ingrowths begin to form on the initial cells, cells whose cleavage eventually gives rise distally to new epithelial cells. After the distal wall ingrowths form, the overlying crosswall becomes rich in organic material. For this organic wall material to be deposited into the existing crosswall, the wall must first be decalcified; therefore, the presence of abundant organic material in the crosswall provides a marker of localized decalcification. We propose that the location and time of origin of distal wall ingrowths indicate a connection between the ingrowths and two coordinated processes: localized secretion of wall material, and decalcification of the overlying cell wall in preparation for the movement of the young epithelial cell into a new location relative to the surrounding calcified matrix. The large plasmalemmal surface area associated with the distal wall ingrowths allows for a greater abundance of membrane‐associated components, such as proton pumps, that could drive localized cell wall decalcification.     

Transfer cell wall architecture: a contribution towards understanding localized wall deposition

Summary. A survey is presented of the architecture of secondary wall ingrowths in transfer cells from various taxa based on scanning electron microscopy. Wall ingrowths are a distinguishing feature of transfer cells and serve to amplify the plasma membrane surface area available for solute transport. Morphologically, two categories of ingrowths are recognized: reticulate and flange. Reticulate-type wall ingrowths are characterized by the deposition of small papillae that emerge from the underlying wall at discrete but apparently random loci, then branch and interconnect to form a complex labyrinth of variable morphology. In comparison, flange-type ingrowths are deposited as curvilinear ribs of wall material that remain in contact with the underlying wall along their length and become variously elaborate in different transfer cell types. This paper discusses the morphology of different types of wall ingrowths in relation to existing models for deposition of other secondary cell walls. Received July 20, 2001 Accepted November 29, 2001     

Elastic properties of the cell wall of Aspergillus nidulans studied with atomic force microscopy

Currently, little is known about the mechanical properties of filamentous fungal hyphae. To study this topic, atomic force microscopy (AFM) was used to measure cell wall mechanical properties of the model fungus Aspergillus nidulans. Wild type and a mutant strain (deltacsmA), lacking one of the chitin synthase genes, were grown in shake flasks. Hyphae were immobilized on polylysine-coated coverslips and AFM force--displacement curves were collected. When grown in complete medium, wild-type hyphae had a cell wall spring constant of 0.29 +/- 0.02 N/m. When wild-type and mutant hyphae were grown in the same medium with added KCl (0.6 M), hyphae were significantly less rigid with spring constants of 0.17 +/- 0.01 and 0.18 +/- 0.02 N/m, respectively. Electron microscopy was used to measure the cell wall thickness and hyphal radius. By use of finite element analysis (FEMLAB v 3.0, Burlington, MA) to simulate AFM indentation, the elastic modulus of wild-type hyphae grown in complete medium was determined to be 110 +/- 10 MPa. This decreased to 64 +/- 4 MPa for hyphae grown in 0.6 M KCl, implying growth medium osmotic conditions have significant effects on cell wall elasticity. Mutant hyphae grown in KCl-supplemented medium were found to have an elastic modulus of 67 +/- 6 MPa. These values are comparable with other microbial systems (e.g., yeast and bacteria). It was also found that under these growth conditions axial variation in elastic modulus along fungal hyphae was small. To determine the relationship between composition and mechanical properties, cell wall composition was measured by anion-exchange liquid chromatography and pulsed electrochemical detection. Results show similar composition between wild-type and mutant strains. Together, these data imply differences in mechanical properties may be dependent on varying molecular structure of hyphal cell walls as opposed to wall composition.     

Role of light and jasmonic acid signaling in regulating foliar phloem cell wall ingrowth development

Phloem cells adjacent to sieve elements can possess wall invaginations. The role of light and jasmonic acid signaling in wall ingrowth development was examined in pea companion cells (CCs), Arabidopsis thaliana phloem parenchyma cells (PCs), and in Senecio vulgaris (with ingrowths in both cell types). Features characterized included wall ingrowths (from electron microscopic images), foliar vein density and photosynthetic capacity. In Arabidopsis, wall ingrowths were bulky compared with finger-like invaginations in pea and S. vulgaris. Relative to low light (LL), wall invagination in both CCs and PCs was greater in high light (HL). Treatment with methyl jasmonate in LL had no effect on CCs, but increased PC wall ingrowths. LL-to-HL transfer resulted in significantly less wall ingrowth in the fad7-1 fad8-1 (jasmonate-deficient) Arabidopsis mutant relative to the wild type. These results suggest that chloroplast oxidative status, via chloroplast-derived jasmonates, may modulate phloem structure and function. While CC wall ingrowths facilitate phloem loading by expanding the membrane area available for active uptake, one can speculate that phloem PC ingrowths may have two potential roles: to increase the efflux of sugars and/or protons into the apoplast to augment phloem loading; and/or to protect the phloem against pathogens and/or insects.     

Zostera capensis setchell: III. Some aspects of wall ingrowth development in leaf blade epidermal cells

Summary The development of wall ingrowths in leaf blade epidermal cells of the marine angiospermZostera capensis was studied by electron microscopy. Prior to the appearance of ingrowths long profiles of endoplasmic reticulum cisternae become arranged peripherally closely following the contours of the walls. The plasmalemma assumes a wavy appearance and in regions where wall ingrowths first start forming (i.e., along the radial, inner tangential and transverse walls) the plasmalemma becomes separated from the walls by an undulating extracytoplasmic space. Small, irregular projections of secondary wall material make their appearance here. Paramural bodies, dictyosomes, endoplasmic reticulum (ER) and possibly also microtubules seem to be closely associated with the initiation and subsequent development of wall projections. As the cells mature, new ingrowths arise in a centrifugal direction along the radial and transverse walls. When wall ingrowths reach a certain stage of their development, mitochondria become strongly polarized towards them and become closely associated with the plasmalemma which ensheaths the ingrowths. There is often also a close association between ER cisternae and the involuted plasmalemma of the wall projections. Initially ingrowths are slender, curved structures, but become more complex as the cells mature. Ingrowths are most extensively developed along the inner tangential and transverse walls. As epidermal cells age there is a loss of wall material from the ingrowths. The probable significance of the formation of wall ingrowths in the epidermal cells is also discussed.     

The leaf internal morphology and ultrastructure of Zostera muelleri irmisch ex aschers. (Zosteraceae): a comparative study of the intertidal and subtidal forms

The leaf anatomy, histochemistry and ultrastructure of the intertidal and subtidal seagrass Zostera muelleri Irmish ex Aschers. from Westernport Bay, Victoria were studied. Unusual anatomical and ultrastructural features are compared with other seagrasses and their functional significance is assessed. Subcuticular cavities are present in the young blade, but not observed in the older blade nor young and old leaf sheath. Wall ingrowths occur in the blade epidermal cells particularly on the inner tangential walls and the lower portions of the radial walls. Plasmodesmata are present between adjacent epidermal cells and between the epidermal and mesophyll cells, suggesting that solutes could transfer between these tissues both symplastically and apoplastically. Each leaf has three longitudinally aligned vascular bundles, each of which comprises a single xylem element isolated from the phloem tissue. The phloem consists of nacreous-walled sieve elements accompanied by phloem parenchyma cells which also process wall ingrowths. The xylem walls are completely hydrolysed and the middle lamella borders directly on the xylem lumen. Leaves have prominent air lacunae bisected transversely by septa at regular intervals along their length. Each septum consists of a file of small parenchyma cells with wall protuberances projecting into intercellular space. There are no major structural differences between the subtidal and intertidal plants, but the former have larger leaves and more leaves per shoot than the latter. In addition, a network of unusual reticulated fungal hyphae is present in the leaf intercellular spaces of the subtidal form and this network may facilitate solute transfer in these plants.     

一株马桑根瘤内生菌纯培养物的分类鉴定

从尼泊尔马桑(Coriaria nepalensis)根瘤中分离到一株内生菌纯培养物Cs146,它能使生长在半固体琼脂斜面和珍珠岩上的原寄主植物结瘤。该纯培养物具有Frankia属典型的形态和培养特征。在放线菌样的菌丝体上着生有泡囊和孢囊。在28～30℃下均能在液体和固体培养基上缓慢生长。菌丝呈橙黄色,产淡黄色可溶性色素,无气丝。但是,菌株Cs146的生理类型;细胞壁氨基酸组分和全细胞糖型等均与已知弗兰克氏菌有明显差别。因此认为,马桑根瘤内生菌Cs146应为Frankia类群中一个与其他弗兰克氏菌不同的新成员。     

Wall ingrowth formation in transfer cells: novel examples of localized wall deposition in plant cells

The formation of wall ingrowths increases plasma membrane surface areas of transfer cells involved in membrane transport of nutrients in plants. Construction of these ingrowths provides intriguing and diverse examples of localized wall deposition. Flange wall ingrowths resemble secondary wall thickenings of tracheary elements in morphology and probable mechanisms of deposition. By contrast, reticulate wall ingrowths, deposited as discrete papillate projections, branch and fuse to create a fenestrated wall labyrinth representing a novel form of localized wall deposition. Papillate wall ingrowths are initiated as patches of disorganized cellulosic material and are compositionally similar to primary walls, except for a surrounding layer of callose and enhanced levels of arabinogalactan proteins at the ingrowth/membrane interface. How this unusual form of localized wall deposition is constructed is unknown but may involve constraining cellulose-synthesizing rosette complexes at their growing tips.     

Polarized microtubule deposition coincides with wall ingrowth formation in transfer cells ofVicia faba L. cotyledons

Summary The epidermal transfer cells in developingVicia faba L. cotyledons are highly polarized. Extensive wall ingrowths occur on their outer periclinal walls and extend part way down both anticlinal walls. This ingrowth development serves to increase the surface area of the plasma membrane and thus maximize porter-dependent uptake of sugars from the seed apoplasm. In contrast, the inner periclinal walls of these transfer cells do not form wall ingrowths. We have commenced a study of the mechanisms responsible for establishing this polarity by first analysing the microtubule (MT) cytoskeleton in developing transfer cells. Thin sections of fixed cotyledons embedded in methacrylate resin were processed for immunofluorescence microscopy using monoclonal anti--tubulin and counterstained with Calcofluor White to visualize wall ingrowths. In epidermal cells of young cotyledons where wall ingrowths were yet to develop, MT labelling was detected around all cortical regions of the cell. However, in cells where wall ingrowths were clearly established, MT labelling was detected almost exclusively in cortical regions adjacent to the wall ingrowths. Little, if any, MT labelling was detected on the anticlinal or inner periclinal walls of these cells. This distribution of MTs was most prominent in cells with well developed wall ingrowths. In these cells, a subpopulation of MTs were also detected emanating from the subcortex and extending towards the wall ingrowth region. The possible role of MT distribution in establishing transfer cell polarity and wall ingrowth formation is discussed.Abbreviations MT microtubule     

Transfer Cells in Suspensur and Endosperm during Early Embryogeny of Vigna sinensis

During early embryogeny, structural differentiation of the suspensor and endosperm can be observed with the formation of cells with wall ingrowths. In the early proembryo stage, wall ingrowths are seen only on the boundary walls of the embryo sac around the proembryo and at the chalazal end. Later, ingrowths appear in the outer walls of the basal suspensor cells and some wall ingrowths also begin to develop in the outer walls of cellular endospermic cells adjacent to the nucellar cap and the inner integumentary tissues. The suspensor appears to remain active throughout the differentiation stages. Two regions can be clearly distinguished in the suspensor: a basal region and a neck region. Wall ingrowths appear to form only in the cells of the basal region. During the development of the cellular endospermic sheath, its cell number and size both increase slightly. Later, these cells rapidly become separated from each other. Those endospermic cells that abut directly onto the integumentary tissues also develop wall ingrowths. In the region of the fluid endosperm, wall ingrowths are especially abundant in the boundary walls on the ventral side of the embryo sac. The possible pathway of nutrient flow to the developing embryo is discussed.     

Isolation of an effective strain of Frankia from nodules of Discaria trinervis (Rhamnaceae)

Frankia strain BCU110501 was isolated from root nodules of the native Patagonian actinorhizal plant Discaria trinervis. The strain was grown on BAP medium with sodium propionate or glucose as carbon sources. Colonies grown in nitrogen-free medium showed branched hyphae bearing polymorphic sporangia and vesicles, which were capable of nitrogen fixation. Old cultures produced a red pigment. The infectivity and effectivity of a Frankia strain isolated from Discaria on its own host, D. trinervis and also in D. chacaye, is reported for the first time. Frankia BCU110501 has physiological properties that are intermediate between categories proposed by Lechevalier et al. (1983) to classify Frankia.     

Effect of choline deprivation on the growth, morphology and ultrastructure of a choline-requiring mutant of Aspergillus nidulans

Abstract On minimal medium in the absence of added choline, conidiospores of the cho C3 choline-requiring mutant of Aspergillus nidulans germinated and grew normally for approximately 17 h at 37°C. After this period a characteristic aberant morphology was produced by the swelling of small regions at or close to the majority of hyphal apices, creating spherical structures up to 10 μm in diameter from hyphae which were typically 1–2 μm in diameter. During the swelling of these structures, apical extension showed and stopped. This apparently indicated a switch from polarised to unpolarised growth. Electron microscopic examination of ultrathin sections of the swellings indicated that they had thicker walls (158.2 ± 42.1 nm) than the immediately adjacent hyphae (88.0 ± 17.6 nm) and that wall thickness of the swellings increased with increasing age and size. However, the absence of any accumulation of cytoplasmic vesicles within the swellings indicated that they were not simply produced by diversion that they normal polarised flow of vesicles from the tip to the side walls of hyphae.     

Wall ingrowths in epidermal transfer cells of Vicia faba cotyledons are modified primary walls marked by localized accumulations of arabinogalactan proteins

Despite the importance of transfer cells in enhancing nutrient transport in plants, little is known about how deposition of the complex morphology of their wall ingrowths is regulated. We probed thin sections of mature cotyledon epidermal transfer cells of Vicia faba with affinity probes and antibodies specific to polysaccharides and glycoproteins, to determine the distribution of these components in their walls. Walls of these transfer cells consist of the pre-existing primary wall, a uniformly deposited wall layer and wall ingrowths which are comprised of two regions; an electron-opaque inner region and an electron-translucent outer region. The primary wall reacted strongly with antibodies against esterified pectin, xyloglucan, the side chains of rhamnogalaturonan-1 and a cellulase-gold affinity probe. The electron-opaque inner region of wall ingrowths displayed a similar labeling pattern to that of the primary wall, showing strong cross-reactivity with all antibodies tested, except those reacting against highly de-esterified pectins. The electron-opaque outer layer of developmentally more mature wall ingrowths reacted strongly with anti-callose monoclonal and polyclonal antibodies, but showed no reaction for pectin or xyloglucan antibodies or the cellulase-gold affinity probe. The plasma membrane-wall interface was labeled strongly with anti-arabinogalactan protein (AGP) antibodies, with some AGP-reactive antibodies also labeling the electron-translucent zone. Nascent wall ingrowths were labeled specifically with AGPs but not anti-callose. A reduction in wall ingrowth density was observed when developing transfer cells were exposed to beta-d-glucosyl Yariv reagent compared with controls. Our results indicate that wall ingrowths of transfer cells are primary wall-like in composition and probably require AGPs for localized deposition.     

Immunogold-cytochemical labelling of β-glucosidase in the white-rot fungus Coriolus versicolor

Summary Immunogold cytochemical labelling of hyphal sections of Coriolus versicolor showed that -glucosidase was localised in the extracellular mucilage, cell wall layers and cell interior in hyphae grown on glucose-rich malt extract medium whereas in hyphae grown with carboxymethylcellulose (CMC) as sole carbon source, most labelling was in the cell wall layers and cell interior. Little mucilage was visible around hyphae from these cultures. Hyphae from beechwood cultures showed gold labelling of -glucosidase in mucilage and fungal cell walls with some intracellular labelling. Biochemical studies of enzyme activity showed that similar amounts of enzyme were detected in the growth medium when cultures were grown on CMC medium, in agitated liquid cultures or in stationary cultures. In agitated cultures grown on glucose-rich malt extract, the activity of -glucosidase in the medium was 100 times less than that detected in stationary cultures on the same medium. However activity in the hyphae of stationary CMC-grown cultures was similar to that in hyphae from stationary glucose-rich cultures. These data confirm the patterns of gold labelling observed in hyphae from stationary cultures on glucose-rich malt extract when -glucosidase was immobilised in the extracellular mucilage layer around the hyphae. In this paper we propose that a primary function of the extracellular mucilage produced by hyphae of C. versicolor in vivo is to serve as a matrix for immobilisation of -glucosidase. Its substrate, cellobiose, which is released as a result of endo-and exoglucanase hydrolysis of cellulose, is absorbed and retained by the gel filtration properties of the mucilage, so encountering the immobilised -glucosidase. Glucose produced by this reaction is retained within the mucilage matrix around the hyphae before intracellular absorption.Offprint requests to: C. S. Evans