Ultrastructure and composition of the conidial wall of Cladosporium cladosporioides

Cell wall of Aspergillus fumigatus: Variability and response to stress

The fungal cell is surrounded by a thick cell wall which obviously play an essential role in the protection of the fungus against external aggressive environments. In spite of 50 years of studies, the cell wall remains poorly known and especially its constant modifications during growth as well as environmental changes is not well appreciated. This review focus on the cell wall changes seen between different fungal stages and cell populations with a specific view to explain the resistance to stresses.

Fungal Spores Viability on the International Space Station

In this study we investigated the security of a spaceflight experiment from two points of view: spreading of dried fungal spores placed on the different wafers and their viability during short and long term missions on the International Space Station (ISS). Microscopic characteristics of spores from dried spores samples were investigated, as well as the morphology of the colonies obtained from spores that survived during mission. The selected fungal species were: Aspergillus niger, Cladosporium herbarum, Ulocladium chartarum, and Basipetospora halophila. They have been chosen mainly based on their involvement in the biodeterioration of different substrate in the ISS as well as their presence as possible contaminants of the ISS. From biological point of view, three of the selected species are black fungi, with high melanin content and therefore highly resistant to space radiation. The visual inspection and analysis of the images taken before and after the short and the long term experiments have shown that all biocontainers were returned to Earth without damages. Microscope images of the lids of the culture plates revealed that the spores of all species were actually not detached from the surface of the wafers and did not contaminate the lids. From the adhesion point of view all types of wafers can be used in space experiments, with a special comment on the viability in the particular case of iron wafers when used for spores that belong to B. halophila (halophilic strain). This is encouraging in performing experiments with fungi without risking contamination. The spore viability was lower in the experiment for long time to ISS conditions than that of the short experiment. From the observations, it is suggested that the environment of the enclosed biocontainer, as well as the species'specific behaviour have an important effect, reducing the viability in time. Even the spores were not detached from the surface of the wafers, it was observed that spores used in the long term experiment lost the outer layer of their coat without affecting the viability since they were still protected by the middle and the inner layer of the coating. This research highlights a new protocol to perform spaceflight experiments inside the ISS with fungal spores in microgravity conditions, under the additional effect of possible cosmic radiation. According to this protocol the results are expressed in terms of viability, microscopic and morphological changes.

In Situ Proximity Ligation Assay (PLA)

In situ proximity ligation assay (PLA) is a method to identify physical closeness of proteins, where a signal will only be produced if the two proteins are closer than 40 nm, in tissue section or cell cultures. Modifications of the PLA method can also be used to increase specificity or sensitivity of standard immunohistochemistry protocols.

Conidiation of Penicillium camemberti in submerged liquid cultures is dependent on the nitrogen source

OBJECTIVE

To study the ability of a commercial Penicillium camemberti strain, used for Camembert type cheese ripening, to produce conidia during growth in liquid culture (LC), in media containing different sources of nitrogen as, industrially, conidia are produced by growth at the surface of a solid state culture because conidiation in stirred submerged aerobic LC is not known.

RESULTS

In complex media containing peptic digest of meat, hyphae ends did not differentiate into phialides and conidia. Contrarily, in a synthetic media containing KNO3 as sole nitrogen source, hyphae ends differentiated into phialides producing 0.5 × 10(7) conidia/ml. Conidia produced in LC were 25 % less hydrophobic than conidia produced in solid culture, and this correlates with a seven-times-lower expression of the gene rodA encoding hydrophobin RodA in the mycelium grown in LC.

CONCLUSION

Conidiation of P. camembertii is stimulated in iquid medium containing KNO3 as sole source of nitrogen and therefore opens up opportunities for using liquid medium in commercial productions.

Production of conidia of Penicillium camemberti in liquid medium through microcycles of conidiation

Microcycle conidiation is a survival mechanism of fungi encountering unfavorable conditions. In this phenomenon, asexual spores germinate secondary spores directly without formation of mycelium. As Penicillium camemberti conidia have the ability to produce conidiophores after germination in liquid culture induced by a thermal stress (18 and 30 °C), our work has aimed at producing conidia through this mean. Incubation at 18 and 30 °C increased the swelling of conidia and their proportion thereby producing conidiophores. Our results showed that the microcycle of conidiation can produce 5 × 10(8) conidia ml(-1) after 7 days at 18 °C of culture. The activity of these conidia was checked through culture on a solid medium. Conidia produced by microcycle conidiation formed a normal mycelium on the surface of solid media and 25 % could still germinate after 5 months of storage.

Cladosporium cladosporioides LPSC 1088 produces the 1,8-dihydroxynaphthalene-melanin-like compound and carries a putative pks gene

Cladosporium cladosporioides is a dematiaceous fungus with coloured mycelia and conidia due to the presence of dark pigments. The purpose of this study was to characterize the dark pigments synthetized by Cladosporium sp. LPSC no. 1088 and also to identify the putative polyketide synthase (pks) gene that might be involved in the pigment biosynthesis. Morphological as well as molecular features like the ITS sequence confirmed that LPSC 1088 is Cladosporium cladosporioides. UV-visible, Fourier Transform Infrared (FTIR) and Electron Spin Resonance (ESR) spectroscopy analysis as well as melanin inhibitors suggest that the main dark pigment of the isolate was 1,8 dihydroxynaphthalene (DHN)-melanin-type compound. Two commercial fungicides, Difenoconazole and Chlorothalonil, inhibited fungal growth as well as increased pigmentation of the colonies suggesting that melanin might protect the fungus against chemical stress. The pigment is most probably synthetized by means of a pentaketide pathway since the sequence of a 651 bp fragment, coding for a putative polyketide synthase, is highly homologous to pks sequences from other fungi.

The influence of ortho- and para-diphenoloxidase substrates on pigment formation in black yeast-like fungi

Dothideaceous black yeast-like fungi (BYF) are known to synthesise DHN-melanin that is inhibited by the systemic fungicide tricyclazole. The final step of the DHN melanin pathway is the conjoining of 1,8-DHN molecules to form the melanin polymer. There are several candidate enzymes for this step, including phenoloxidases such as tyrosinase and laccases, peroxidases, and perhaps also catalases. We analysed the type polyphenoloxidases that are involved in biosynthesis of BYF melanins. For that purpose we used substrates of o-diphenoloxidases (EC 1.10.3.1.): 4-hydroxyphenyl-pyruvic acid, L-beta-phenyllactic acid, tyrosine, pyrocatechol, 3,4-dihydroxyphenylalanine and homogentisic acid, as well as substrates of p-diphenoloxidases (EC 1.10.3.2.): syringaldazine, resorcinol, p-phenylenediamine, phloroglucinol, guaiacol and pyrogallic acid. Fourteen strains of black yeasts originating from different natural biotopes were investigated. The tested strains could be divided into four groups based on their ability to produce dark pigments when cultivated on aromatic substrates of o- and on p-diphenoloxidases. It was established that syringaldazine, pyrogallic acid and 4-hydrophenyl-pyruvic acid, beta-phenyllactic acid optimally promote melanin biosynthesis. Average intensity of pigmentation of all strains studied was minimal when guaiacol was used as a substrate. The present investigation indicates that the melanisation process may involve more enzymes and more substrates than those commonly recognised. Black yeasts are likely to contain a multipotent polyphenoloxidase.

Surface hydrophobin prevents immune recognition of airborne fungal spores

The air we breathe is filled with thousands of fungal spores (conidia) per cubic metre, which in certain composting environments can easily exceed 10(9) per cubic metre. They originate from more than a hundred fungal species belonging mainly to the genera Cladosporium, Penicillium, Alternaria and Aspergillus. Although these conidia contain many antigens and allergens, it is not known why airborne fungal microflora do not activate the host innate immune cells continuously and do not induce detrimental inflammatory responses following their inhalation. Here we show that the surface layer on the dormant conidia masks their recognition by the immune system and hence prevents immune response. To explore this, we used several fungal members of the airborne microflora, including the human opportunistic fungal pathogen Aspergillus fumigatus, in in vitro assays with dendritic cells and alveolar macrophages and in in vivo murine experiments. In A. fumigatus, this surface 'rodlet layer' is composed of hydrophobic RodA protein covalently bound to the conidial cell wall through glycosylphosphatidylinositol-remnants. RodA extracted from conidia of A. fumigatus was immunologically inert and did not induce dendritic cell or alveolar macrophage maturation and activation, and failed to activate helper T-cell immune responses in vivo. The removal of this surface 'rodlet/hydrophobin layer' either chemically (using hydrofluoric acid), genetically (DeltarodA mutant) or biologically (germination) resulted in conidial morphotypes inducing immune activation. All these observations show that the hydrophobic rodlet layer on the conidial cell surface immunologically silences airborne moulds.

Lectin mapping reveals stage-specific display of surface carbohydrates in in vitro and haemolymph-derived cells of the entomopathogenic fungus Beauveria bassiana

The entomopathogenic fungus Beauveria bassiana and its insect host target represent a model system with which to examine host–pathogen interactions. Carbohydrate epitopes on the surfaces of fungal cells play diverse roles in processes that include adhesion, non-self recognition and immune invasion with respect to invertebrate hosts. B. bassiana produces a number of distinct cell types that include aerial conidia, submerged conidia, blastospores and haemolymph-derived cells termed in vivo blastospores or hyphal bodies. In order to characterize variations in the surface carbohydrate epitopes among these cells, a series of fluorescently labelled lectins, combined with confocal microscopy and flow cytometry to quantify the response, was used. Aerial conidia displayed the most diverse lectin binding characteristics, showing reactivity against concanavalin A (ConA), Galanthus nivalis (GNL), Griffonia simplicifolia (GSII), Helix pomatia (HPA), Griffonia simplicifolia isolectin (GSI), peanut agglutinin (PNA), Ulex europaeus agglutinin I (UEAI) and wheatgerm agglutinin (WGA), and weak reactivity against Ricinus communis I (RCA), Sambucus nigra (SNA), Limax flavus (LFA) and Sophora japonica (SJA) lectins. Lectin binding to submerged conidia was similar to that to aerial conidia, except that no reactivity against UEAI, HPA and SJA was noted, and WGA appeared to bind strongly at specific polar spots. In contrast, the majority of in vitro blastospores were not bound by ConA, GNL, GSII, GSI, SNA, UEAI, LFA or SJA, with PNA binding in large patches, and some polarity in WGA binding noted. Significant changes in lectin binding also occurred after aerial conidial germination and in cells grown on either lactose or trehalose. For germinated conidia, differential lectin binding was noted between the conidial base, the germ tube and the hyphal tip. Fungal cells isolated from the haemolymph of the infected insect hosts Manduca sexta and Heliothis virescens appeared to shed most carbohydrate epitopes, displaying binding only to the GNL, PNA and WGA lectins. Ultrastructural examination of the haemolymph-derived cells revealed the presence of a highly ordered outermost brush-like structure not present on any of the in vitro cells. Haemolymph-derived hyphal bodies placed into rich broth medium showed expression of several surface carbohydrate epitopes, most notably showing increased PNA binding and strong binding by the RCA lectin. These data indicate robust and diverse production of carbohydrate epitopes on different developmental stages of fungal cells and provide evidence that surface carbohydrates are elaborated in infection-specific patterns.

Functional analysis of the Alternaria brassicicola non-ribosomal peptide synthetase gene AbNPS2 reveals a role in conidial cell wall construction

SUMMARY Alternaria brassicicola is a necrotrophic pathogen causing black spot disease on virtually all cultivated Brassica crops worldwide. In many plant pathosystems fungal secondary metabolites derived from non-ribosomal peptide synthetases (NPSs) are phytotoxic virulence factors or are antibiotics thought to be important for niche competition with other micro-organisms. However, many of the functions of NPS genes and their products are largely unknown. In this study, we investigated the function of one of the A. brassicicola NPS genes, AbNPS2. The predicted amino acid sequence of AbNPS2 showed high sequence similarity with A. brassicae, AbrePsy1, Cochliobolus heterostrophus, NPS4 and a Stagonospora nodorum NPS. The AbNPS2 open reading frame was predicted to be 22 kb in length and encodes a large protein (7195 amino acids) showing typical NPS modular organization. Gene expression analysis of AbNPS2 in wild-type fungus indicated that it is expressed almost exclusively in conidia and conidiophores, broadly in the reproductive developmental phase. AbNPS2 gene disruption mutants showed abnormal spore cell wall morphology and a decreased hydrophobicity phenotype. Conidia of abnps2 mutants displayed an aberrantly inflated cell wall and an increase in lipid bodies compared with wild-type. Further phenotypic analyses of abnps2 mutants showed decreased spore germination rates both in vitro and in vivo, and a marked reduction in sporulation in vivo compared with wild-type fungus. Moreover, virulence tests on Brassicas with abnps2 mutants revealed a significant reduction in lesion size compared with wild-type but only when aged spores were used in experiments. Collectively, these results indicate that AbNPS2 plays an important role in development and virulence.

Hypersaline conditions induce changes in cell-wall melanization and colony structure in a halophilic and a xerophilic black yeast species of the genus Trimmatostroma

Melanized yeast-like meristematic fungi are characteristic inhabitants of highly stressed environments and are rare eukaryotic extremophiles. Therefore, they are attractive organisms for studies of adaptations. In this study we compared two meristematic species of the genus Trimmatostroma on media of differing water potentials isolated from distinct water-stressed environments: T. salinum from the hypersaline water of a solar saltern, and T. abietis from a marble monument in Crimea. The morphology and melanization of both isolates in response to sodium chloride-induced water stress were investigated by means of light and electron microscopy. We describe and compare the colony form and structure, ultrastructure, and degree of cell-wall melanization of both species in reaction to salinity and to inhibited melanin synthesis. The halophilic T. salinum responded to changed salinity conditions on the level of individual cell ultrastructure and degree of cell wall melanization, whereas the xerophilic rock-inhabiting T. abietis responded with modification of its colony structure. Surprisingly, both the halophilic and the xerophilic Trimmatostroma species were able to adapt to hypersaline growth conditions, although their growth patterns show distinct adaptation of each species to their natural ecological niches.

Evidence for 1,8-dihydroxynaphthalene melanin in three halophilic black yeasts grown under saline and non-saline conditions

The ascomycetous black yeasts Hortaea werneckii, Phaeotheca triangularis, and Trimmatostroma salinum are halophilic fungi that inhabit hypersaline water of solar salterns. They are characterized by slow, meristematic growth and very thick, darkly pigmented cell walls. The dark pigment, generally thought to be melanin, is consistently present in their cell walls when they grow under saline and non-saline conditions. We used the inhibitor tricyclazole to test the fungi in this study for the presence of 1,8-dihydroxynaphthalene (DHN)-melanin biosynthesis, since fungal melanins reportedly are derived either from DHN, tyrosine via 3,4-dihydroxyphenylalanine, gamma-glutaminyl-3,4-dihydroxybenzene, or catechol. Tricyclazole-treated cultures of the fungi were reddish-brown in color and contained typical intermediates of the DHN-melanin pathway, as demonstrated by high-performance liquid chromatography. This investigation showed that the three fungi synthesized DHN-melanin under saline and non-saline growth conditions.

The role of the rodlet structure on the physicochemical properties of Aspergillus conidia

Physico-chemical properties of Aspergillus conidia rely on their outer cell-wall rodlet layer. In A. fumigatus and A. nidulans, the rodlet structure is due to an hydrophobin encoded by homologous rodA genes. To evaluate the role of the rodlet structure on the physico-chemical properties of conidia, we compared hydrophobicity, Lewis acid-base (i.e. electron donor/acceptor) characteristics and electrostatic charge of hydrophobin-less (rodletless) mutant and wild-type conidia of A. fumigatus and A. nidulans. The results obtained by aqueous-solvent partitioning assays, microsphere adhesion assays and microelectrophoresis showed that the disruption of the rodA gene modifies surface properties of A. fumigatus and A. nidulans conidia, and confirmed that the rodlet layer plays a key role in their physico-chemical behaviour. The absence of this layer on A. fumigatus spores led to the appearance of weakly basic and acidic characteristics, and had a slight effect on the hydrophobicity of conidia. Whereas in A. nidulans, it induced a basic character, a marked decrease in hydrophobicity and in the polarization capacity (electronegativity) of conidia. These physico-chemical differences between A. fumigatus and A. nidulans rodletless conidia may be attributed to differences in the composition of the conidial outer cell-wall of the two species.

Conidial surface ultrastructure of human-pathogenic and saprobic Cladosporium species

Freeze-fracturing of outer wall layers of Cladosporium conidia revealed two types of ultrastructure, coinciding with taxonomic characteristics. The outer conidial layers were essentially smooth in the human pathogenic species, C. bantianum, C. carrionii, and C. trichoides. In contrast, mosaic arrays of rodlets on conidia were observed with freeze-fracturing in the saprobic species, C. cladosporioides, C. coralloides, C. herbarum, C. sphaerospermum, and C. variabile. Conidia of C. elatum were an exception among the saprobic species as they had smooth surfaces. The present study supports the suggestion that the human pathogenic Cladosporium species should be transferred to another genus.

The existence of a dispensable fibrillar layer on the wall surface of mycelial but not yeast cells of Aureobasidium pullulans

Wall surface ultrastructure of Aureobasidium pullulans was studied by freeze-etching. Yeast cells had a smooth wall surface as in typical yeast species. Mycelial cells and chlamydospores had an extra layer on the wall surface made mostly of fibrils. The fibrils were 20 nm in diameter, and thicker than typical major fungal wall skeletal fibrils of beta-glucan and chitin. This layer was apparently easily detached from the wall proper, presumably as a result of enzymic activity or by physical means, suggesting that it is a physiologically dispensable wall component.