Cell wall analysis

The cell wall is a rigid structure essential for survival of the fungal cell. Because of its absence in mammalian cells, the cell wall is an attractive target for antifungal agents. Thus, for different reasons, it is important to know how the cell wall is synthesized and how different molecules regulate that synthesis. The Schizosaccharomyces pombe cell wall is mainly formed by glucose polysaccharides and some galactomannoproteins. Here, we describe a fast and reliable method to analyze changes in S. pombe cell wall composition by using specific enzymatic degradation and chemical treatment of purified cell walls. This approach provides a powerful means to analyze changes in (1,3)beta-glucan and (1,3)alpha-glucan, two main polysaccharides present in fungal cell walls. Analysis of cell wall polymers will be useful to search for new antifungal drugs that may inhibit cell wall biosynthesis and/or alter cell wall structure.     

Trifluoromethanesulfonic acid-based proteomic analysis of cell wall and secreted proteins of the ascomycetous fungi Neurospora crassa and Candida albicans

Cell wall proteins from purified Candida albicans and Neurospora crassa cell walls were released using trifluoromethanesulfonic acid (TFMS) which cleaves the cell wall glucan/chitin matrix and deglycosylates the proteins. The cell wall proteins were then characterized by SDS–PAGE and identified by proteomic analysis. The analyses for C. albicans identified 15 cell wall proteins and six secreted proteins. For N. crassa, the analyses identified 26 cell wall proteins and nine secreted proteins. Most of the C. albicans cell wall proteins are found in the cell walls of both yeast and hyphae cells, but some cell type-specific cell wall proteins were observed. The analyses showed that the pattern of cell wall proteins present in N. crassa vegetative hyphae and conidia (asexual spores) are quite different. Almost all of the cell wall proteins identified in N. crassa have close homologs in the sequenced fungal genomes, suggesting that these proteins have important conserved functions within the cell wall.     

Loss of pectin is an early event during infection of cocoyam roots by Pythium myriotylum

Cocoyam (Xanthosoma sagittifolium) is an important tuber crop in most tropical zones of Africa and America. In Cameroon, its cultivation is hampered by a soil-borne fungus Pythium myriotylum which is responsible for root rot disease. The mechanism of root colonisation by the fungus has yet to be elucidated. In this study, using microscopical and immunocytochemical methods, we provide a new evidence regarding the mode of action of the fungus and we describe the reaction of the plant to the early stages of fungal invasion. We show that the fungal attack begins with the colonisation of the peripheral and epidermal cells of the root apex. These cells are rapidly lost upon infection, while cortical and stele cells are not. Labelling with the cationic gold, which binds to negatively charged wall polymers such as pectins, is absent in cortical cells and in the interfacial zone of the infected roots while it is abundant in the cell walls of stele cells. A similar pattern of labelling is also found when using the anti-pectin monoclonal antibody JIM5, but not with anti-xyloglucan antibodies. This suggests that early during infection, the fungus causes a significant loss of pectin probably via degradation by hydrolytic enzymes that diffuse and act away from the site of attack. Additional support for pectin loss is the demonstration, via sugar analysis, that a significant decrease in galacturonic acid content occurred in infected root cell walls. In addition, we demonstrate that one of the early reactions of X. sagittifolium to the fungal invasion is the formation of wall appositions that are rich in callose and cellulose.     

Irregular growth forms and cell wall modifications,polygalacturonase detection,and endocell formation in <Emphasis Type="Italic">Fusarium oxysporum</Emphasis> f. sp. <Emphasis Type="Italic">radicis-lycopersici</Emphasis> infecting tomato plants,as studied ultrastructurally and cytochemically

Pathogen cells of Fusarium oxysporum f.sp. radicis-lycopersici infecting container-grown tomato plants were characterized ultrastructurally, using gold-complexed probes, chitinase and wheat germ agglutinin to localize chitin, and polyclonal antibodies to a polygalacturonase to localize this enzyme. It was isolated and purified from the pathogen growing in culture. Many fungal cells were of irregular forms (microhyphal, frondose) with modified, thin or imperceptible lucent wall layers, in which were often included components seemingly of host origin. Gold particles of the polygalacturonase probe were concentrated on portions of penetration hyphae and in areas of associated altered host wall. Fine filamentous-like structures, often linked to fungal cells, reached into extracellular matter and into host walls. Examination of 0.2–0.25 μm-thick sections at 120 kV, and tilted at various angles, indicated that fungal cells frequently had a pronounced wavy contour. Labelling of thin walls for chitin was mostly nil, particularly in contact with host walls, as of also thicker walls in similar situations, or it was then associated with the outside opaque layer. Cells of diverse dimensions with thin or thicker walls and with altered or normal content, contained endocells. Walls of the encodcells and of the enclosing cells often labelled differently for chitin with both probes. Endocells mostly did not originate from proliferation of a living into a dead cell but often ensuing as an apparent fragmentation of the cell content or following its retraction. The bearing of these observations on the host-pathogen relationship, particularly concerning the role of thin-walled hyphae and irregular forms, is discussed.     

Ultrastructure at the Host-Parasite Interface of Phytophthora capsici in Roots and Stems of Capsicum annuum

The infecting hyphae of Phytophthora capsici grew intercellularly in infected tissues of roots and stems of pepper (Capsicum annuum). The vascular tissues were not markedly disorganized even when heavily infected. Intercellularly growing hyphae penetrated the host cells by forming haustorium-like bodies. The consistent features of ultrastructural changes in infected tissues of pepper roots and stems were degeneration of cell organelles and dissolution of host cell walls. The cytoplasm detached from the cell wall aggregated abundantly around some haustorium-like bodies or the penetration sites of fungal hyphae. The host cell walls were palely stained, thinned and swollen, possibly being biochemically altered by the action of fungal macerating enzymes. Electron-dense, wall-like material was apposed on the outer wall of xylem vessel contacted by fungal hyphae. The infecting hyphae were also surrounded by granular, dark-staining cytoplasm. Characteristics of host cell responses to the invading P. capsici were the deposition of papilla-like material on host cell walls next to hyphae and the encasement of haustorium-like bodies with wall appositions.     

Deciphering the uniqueness of Mucoromycotina cell walls by combining biochemical and phylogenomic approaches

Most fungi from the Mucoromycotina lineage occur in ecosystems as saprobes, although some species are phytopathogens or may induce human mycosis. Mucoromycotina represent early diverging models that are most valuable for understanding fungal evolution. Here we reveal the uniqueness of the cell wall structure of the Mucoromycotina Rhizopus oryzae and Phycomyces blakesleeanus compared with the better characterized cell wall of the ascomycete Neurospora crassa. We have analysed the corresponding polysaccharide biosynthetic and modifying pathways, and highlight their evolutionary features and higher complexity in terms of gene copy numbers compared with species from other lineages. This work uncovers the presence in Mucoromycotina of abundant fucose‐based polysaccharides similar to algal fucoidans. These unexpected polymers are associated with unusually low amounts of glucans and a higher proportion of chitin compared with N. crassa. The specific structural features are supported by the identification of genes potentially involved in the corresponding metabolic pathways. Phylogenomic analyses of genes encoding carbohydrate synthases, polysaccharide modifying enzymes and enzymes involved in nucleotide‐sugar formation provide evidence for duplication events during evolution of cell wall metabolism in fungi. Altogether, the data highlight the specificity of Mucoromycotina cell walls and pave the way for a finer understanding of their metabolism.     

Multinucleate transfer cells induced in coleus roots by the root-knot nematode,Meloidogyne arenaria

Summary The occurrence and position of wall protuberances in giant cells induced in coleus roots by the root-knot nematodeMeloidogyne arenaria is described, and the structure and function of giant cells is compared with that of syncytia induced by cyst-nematodes.Extensive protuberance development occurs on walls of giant cells adjacent to xylem vessels. Protuberances are less well developed next to sieve elements, and almost absent next to parenchyma cells. On walls between giant cells they occur on both sides or only one side. The formation of protuberances indicates that giant cells are multinucleate transfer cells. The position of protuberances marks the wall area where solutes enter the cell. Solutes are obtained from xylem and phloem elements, and the position of protuberances at the junction between giant cells and vascular elements indicates an extensive flow of solutes along cell walls. The observations support the hypothesis that wall protuberances form as a result of selective solute flow across the plasmalemma.No cell wall dissolution was observed, although wall gaps may occur between giant cells as a result of breakage during rapid cell expansion.     

STRUCTURE AND REPRODUCTION OF THE ALGAL SYMBIONTS OF HYDRA VIRIDIS1

The algal symbionts of Hydra viridis are found within vacuoles of the gastrodermal digestive cells of the host. Electron microscopy reveals that the symbionts possess cell walls, and that their reproductive cycle follows the general pattern of free-living Chlorella. Nuclear and chloroplast divisions arc followed by formation of new cell walls, the Golgi apparatus being quite active during cell wall synthesis. Autospores are released when the parent wall ruptures. The autospores are then usually segregated into separate animal vacuoles. Remnants of the ruptured parent wall persist in the vacuoles for an indefinite period. The ruptured parent walls curl at the breakage clefts, forming double-layered scroll-like structures. The fate of these wall remnants has not been firmly established. Long-term starvation of the animals does not result in a detectable change in the structure of the symbionts, and they continue to divide and to store carbohydrate as starch grains.     

Attempted localization of a substrate for chitinases in plant cells reveals abundant N-acetyl-d-glucosamine residues in secondary walls

Ultrathin sections of healthy and fungus-infected plant tissue were treated with either wheat-germ agglutinin (WGA) ovomucoid-gold complex or microbial chitinase-gold complexes for localizing putative chitin-like macromolecules. Fungal cell walls, known to contain chitin, were labeled with both probes and were considered as positive controls. Plant secondary cell walls of both healthy and infected tissues were also intensely labeled whereas compound middle lamella-primary walls and cell cytoplasm were free of labeling. Enzymatic digestion of plant tissues with chitinase from Streptomyces griseus abolished the fungal cell wall labeling but did not interfere with that of plant secondary cell walls. This suggests that polymers analogous to fungal chitin are absent in plant cell walls. Tissue digestions with either proteinase K or lipase led to surprising results as far as the possible nature of N-acetylglucosamine-containing molecules is concerned. The loss of labeling over plant secondary walls following lipase digestion suggests that N-acetylglucosamine residues may be linked to lipids to form glycolipids. However, these results have to be viewed with caution since the possibility that peptides may be present but inacessible to proteinase K should be considered. The role of the detected N-acetylglucosamine containing molecules as possible substrates for plant chitinases is discussed.     

Ultrastructural studies on the cell walls in Fusarium sulphureum.

The cell walls of Fusarium sulphureum have a microfibrillar component that is randomly arranged. X-ray-diffraction diagrams of the microfibrils are consistent with a high degree of crystallinity and show that they are chitin. The chitin microfibrils of the peripheral walls envelop the hyphal apex and extend across the septae. During the first 8h in culture, the conversion of conidial cells to chlamydospores is evidenced by a swelling of the cells and the original microfibrils remain randomly arranged. Within 24h new wall material is deposited as the cells expand and the wall thickens. The new microfibrils are indistinguishable from those of the original conidial cells. After 3 days in culture, the chlamydospores are fully developed and have the characteristic thick wall which is a continuous layer of randomly arranged microfibrils. Chlamydospores maintained in a conversion medium for 8 days have microfibrils identical with those in 3-day-old cultures; thus a further change in the microfibril orientation did not occur during that period. Alkaline hydrolysis of the walls removes most of the electron-dense staining constituents from the inner wall layer and leaves the outer wall layer intact. This treatment also reveals some of the wall microfibrils. An additional treatment of the walls with HAc/H2O2 completely removes the wall components that react positively to heavy metal stains. The results are discussed in relation to the structure of other fungal cell walls.     

Low-molecular-weight precursors for defense-related cell wall hydroxycinnamoyl esters in elicited parsley suspension cultures

Cell walls from suspension cultures of parsley (Petroselinum crispum L.) induced with a fungal elicitor contained hydroxycinnamoyl ester groups presumably not bound to pectic polysaccharides. Extracts from these cells were separated into a range of low-molecular-weight compounds containing esterified ferulic and p-coumaric acid as well as glucose and some arabinose. Similar compounds also accumulated extracellularly in elicited cultures but only in the presence of the peroxidase inhibitor ascorbate, suggesting that they may represent the exported precursors for cell wall hydroxycinnamic acids. From cultures elicited in the presence of ascorbate, alkali released from the cell walls more ferulic, p-coumaric and p-hydroxybenzoic acid, as well as p-hydroxybenzaldehyde and vanillin, indicating that the corresponding wall phenolics can all become further cross-linked. Received: 6 September 1996 / Revision received: 10 March 1997 / Accepted: 10 April 1997     

Specific localization of inorganic polyphosphate (poly P) in fungal cell walls by selective extraction and immunohistochemistry

Inorganic polyphosphate (poly P) is a linear polymer of phosphoanhydride-linked phosphate residues that occurs in all organisms and cells. It was found in all organelles and is particularly abundant in fungal vacuoles. The fungal cell wall also contains poly P, but very little is known about the nature and functions of poly P in this compartment. Here, we describe a novel method for the specific quantification and visualization of poly P in fungal cell walls. Selective extraction in high salt buffer revealed large poly P stores in cell walls of Mucorales and lower amounts in most other fungi tested. Staining with specific poly P binding proteins (PBPs) enabled the visualization of poly P in cell walls of selected species from all fungal phyla. The presence of an extracellular phosphate pool in the form of a strongly negatively charged polymer is suggested to have important functions as a phosphate source in mycorrhizal interactions, an antimicrobial compound or protection against toxicity of heavy metals.     

Immunocytochemical staining of Histoplasma capsulatum at the electron microscopic level

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

Morphology and ultrastructure of Interfilum and Klebsormidium (Klebsormidiales,Streptophyta) with special reference to cell division and thallus formation

Representatives of the closely related genera, Interfilum and Klebsormidium, are characterized by unicells, dyads or packets in Interfilum and contrasting uniseriate filaments in Klebsormidium. According to the literature, these distinct thallus forms originate by different types of cell division, sporulation (cytogony) versus vegetative cell division (cytotomy), but investigations of their morphology and ultrastructure show a high degree of similarity. Cell walls of both genera are characterized by triangular spaces between cell walls of neighbouring cells and the parental wall or central space among the walls of a cell packet, exfoliations and projections of the parental wall and cap-like and H-like fragments of the cell wall. In both genera, each cell has its individual cell wall and it also has part of the common parental wall or its remnants. Therefore, vegetative cells of Interfilum and Klebsormidium probably divide by the same type of cell division (sporulation-like). Various strains representing different species of the two genera are characterized by differences in cell wall ultrastructure, particularly the level of preservation, rupture or gelatinization of the parental wall surrounding the daughter cells. The differing morphologies of representatives of various lineages result from features of the parental wall during cell separation and detachment. Cell division in three planes (usual in Interfilum and a rare event in Klebsormidium) takes place in spherical or short cylindrical cells, with the chloroplast positioned perpendicularly or obliquely to the filament (dyad) axis. The morphological differences are mainly a consequence of differing fates of the parental wall after cell division and detachment. The development of different morphologies within the two genera mostly depends on characters such as the shape of cells, texture of cell walls, mechanical interactions between cells and the influence of environmental conditions.     

3,4-Dehydroproline inhibits cell wall assembly and cell division in tobacco protoplasts.

We investigated the function of cell wall hydroxyproline-rich glycoproteins by observing the effects of a selective inhibitor of prolyl hydroxylase, 3,4-dehydro-L-proline (Dhp), on wall regeneration by Nicotiana tabacum mesophyll cell protoplasts. Protoplasts treated with micromolar concentrations of Dhp do not develop osmotic stability and do not initiate mitosis. The architecture of regenerated cell walls was examined using deep-etch, freeze-fracture electron microscopy of rapidly frozen tobacco cells. Untreated protoplasts assemble a dense fibrillar cell wall consisting of laterally associating subelementary fibrils. In contrast, treatment of protoplasts with Dhp alters the structure of the regenerated wall fibrils in several ways: first, the microfibrils are coated with globular knobs; second, some larger fiber bundles have an open ribbon-like appearance; and third, the smallest subelementary fibrils were not visible. Tobacco cells develop an abnormal morphology as a consequence of this abnormal cell wall structure. Thus, inhibition of prolyl hydroxylase results in the regeneration of a cell wall with abnormal structural and functional properties. These data provide experimental evidence that hydroxyproline-rich glycoproteins are important for the structural integrity of primary cell walls and for the correct assembly of other wall polymers, and that wall structure is an important regulator of cell division and cell morphology.     

Characterization of the cell wall of the ubiquitous plant pathogen Botrytis cinerea

The ascomycete Botrytis cinerea is a destructive and ubiquitous plant pathogen and represents a model organism for the study of necrotrophic fungal pathogens. Higher fungi possess a complex and dynamic multilayer cell wall involved in crucial aspects of fungal development, growth and pathogenicity. Plant resistance to microbial pathogens is determined often by the capacity of the plant to recognize molecular patterns associated with the surface of an interacting microbe. Here we report the chemical characterization of cell walls from B. cinerea during axenic growth. Neutral sugars and proteins constituted most of the mass of the B. cinerea cell walls, although chitin and uronic acids were detected. Glucose was the most abundant neutral sugar, but arabinose, galactose, xylose and mannose also were present. Changes in cell wall composition during culture were observed. As the culture developed, protein levels declined, while chitin and neutral sugars increased. Growth of B. cinerea was associated with a remarkable decline in the fraction of its cell wall material that was soluble in hot alkali. These results suggest that the cell wall of B. cinerea undergoes significant modifications during growth, possibly becoming more extensively covalently cross-linked, as a result of aging of mycelia or in response to decreasing nutrient supply or as a consequence of increasing culture density.     

Aspergillus as a versatile cell factory for organic acid production

Filamentous fungi from the genus Aspergillus are of high importance for biobased organic acid production. So far, a number of Aspergillus strains belonging to phylogenetically distantly related species have been successfully applied in industrial production of organic acids due to their excellent capabilities of secreting high amounts of desired organic acids. For the past decades, numerous efforts have been made to reveal the mechanisms of organic acid biosynthesis in several Aspergillus species and to improve the production of desired organic acids via genetic engineering. This review summarizes the recent breakthroughs in the fundamental understanding of physiological aspects of organic acid accumulation by fungal biocatalysts and highlights the progress in genetic engineering of aspergilli for organic acid production. The challenges for the future applications of aspergilli as commercial cell factories for organic acid production are also discussed.     

The fungal cell wall and the mechanism of action of anidulafungin

The fungal cell wall is a structure with a high plasticity that protects the cell from different types of environmental stresses including changes in osmotic pressure. In addition to that, the cell wall allows the fungal cell to interact with its environment, since some of its proteins are adhesins and receptors. Some of its components are highly immunogenic. The structure of the fungal cell wall is unique to the fungi, and it is composed of glucan, chitin and glycoproteins. Since humans lack the components present in the cell walls of fungi, this structure is an excellent target for the development of antifungal drugs. Anidulafungin, like the rest of echinocandins acts on beta-1,3-D-glucan synthase inhibiting the formation of beta-1,3-D-glucan and causing, depending on the type of fungus, a fungicidal or either a fungistatic effect.     

Studies onArtemisia afra Jacq.: The phloem in stem and leaf

Summary The structure of the phloem was studied in stem and leaf ofArtemisia afra Jacq., with particular attention being given to the sieve element walls. Both primary and secondary sieve elements of stem and midvein have nacreous walls, which persist in mature cells. Histochemical tests indicated that the sieve element wall layers contained some pectin. Sieve element wall layers lack lignin. Sieve elements of the minor veins (secondary and tertiary veins) lack nacreous thickening, although their walls may be relatively thick. These walls and those of contiguous transfer cells are rich in pectic substances. Transfer cell wall ingrowths are more highly developed in tertiary than in secondary veins.