Association of melanin content with conidiogenesis in Bipolaris Sorokiniana of barley (Hordeum vulgare L.)

Sixty-seven isolates of Bipolaris sorokiniana of barley, belonging to three groups (black, white and mixed) were studied to find an association of melanin with the spore production of the fungus. Conidiogenesis in black, white and mixed subpopulation of B. sorokiniana was positively correlated with melanin content/g of mycelium. Primary hyphae of black and mixed subpopulation differentiated into secondary hyphal structures which subsequently produced conidiophores and conidia. Primary hyphae could not differentiate into secondary hyphae and subsequently conidiophores and conidia in white subpopulation. A melanin containing mutant developed from white subpopulation regained its ability to differentiate into secondary hyphae, conidiophores and conidia. Results showed that melanization of mycelia B. sorokiniana mycelia is an important factor for conidia production.     

Disposition of Mycophenolic Acid, Brevianamide A, Asperphenamate, and Ergosterol in Solid Cultures of Penicillium brevicompactum

When Penicillium brevicompactum was grown between layers of dialysis membrane on Czapek-Dox agar for 3 days, no synthesis of mycophenolic acid, brevianamide A, asperphenamate, or ergosterol occurred. After removal of the uppermost membrane layer, aerial mycelium developed and all four metabolites were formed. The bulk of the mycophenolic acid that was formed was excreted into the medium, the bulk of the brevianamide A and asperphenamate was found in the aerial hyphae, and ergosterol was found in both vegetative and aerial mycelia.     

Lack of evidence for a role of hydrophobins in conferring surface hydrophobicity to conidia and hyphae of Botrytis cinerea

Background  

Hydrophobins are small, cysteine rich, surface active proteins secreted by filamentous fungi, forming hydrophobic layers on the walls of aerial mycelia and spores. Hydrophobin mutants in a variety of fungi have been described to show 'easily wettable' phenotypes, indicating that hydrophobins play a general role in conferring surface hydrophobicity to aerial hyphae and spores.     

Surface Ultrastructural Studies on the Germination,Penetration and Conidial Development of Aspergillus Flavus Link : Fries Infecting Silkworm,Bombyx Mori Linn

Aspergillosis is a common disease of the silkworm Bombyx mori Linn., caused by an insect mycopathogen Aspergillus flavus Link:Fries. The present study reveals the germination, penetration and conidial development of A. flavus on the larval integument of B. mori under SEM. Four different strains (NB18, KA, NB4D2 and NB7) of B. mori was surface inoculated with ca. of 1 x 10(6) conidia/ml. Each conidium germinated on the cuticle approximately 6 h after inoculation, forming a humpy or suctorial appressoria within 24 h. The hyphae which entered into haemocoel 2 day post-inoculation, grew and multiplied extensively, forming a mycelial complex, causing death of the host larva in about 4-5 days. This occurred with minimal breakdown of the internal tissues. Death of the host was followed by ramification of the fungus through the mesodermal and epidermal tissues, leading to larval mummification about 5-6 days after inoculation. Extensive fungal growths on the entire larval body followed, consisting of aerial hyphae, which developed branched conidiophores. The aerial hyphae with abundant conidiophores formed a confluent yellowish green fungal mat over the entire larval body in 6-7 days of post-inoculation. The tip of each emerging conidiophores gradually dilated and developed to become a bulbous head known as the vesicle. A large number of conidiogenous cells were produced over the entire surface of vesicle, which later developed into finger-like projections termed as sterigmata or phialides. The phialides matured within 2 days after the aerial hyphae emerged as evidenced by chains of conidia at their tips. The conidia were globose with externally roughened walls. The life cycle of the fungus on B. mori was completed in six to seven days.     

Structural Proteins Involved in Emergence of Microbial Aerial Hyphae

Filamentous fungi and filamentous bacteria (i.e., the streptomycetes) belong to different kingdoms that diverged early in evolution. Yet, they adopted similar lifestyles. After a submerged feeding mycelium has been established, hyphae grow into the air and form aerial structures from which (a)sexual spores can develop. These spores are dispersed and can give rise to a new mycelium. Some of the key processes involved in the formation of aerial hyphae by these microbes appear to be very similar. In both cases molecules that lower the surface tension are secreted into the aqueous environment, thereby enabling hyphae to grow into the air. Aerial hyphae are then covered with a hydrophobic film. In fungi, this film is characterized by a mosaic of parallel rodlets, while similar rodlets have also been observed on aerial structures of filamentous bacteria. Although the erection of aerial hyphae in both filamentous fungi and filamentous bacteria is dependent upon (poly)peptides that are structurally unrelated, they can, at least partially, functionally substitute for each other.     

Extracellular complementation of a developmental mutation implicates a small sporulation protein in aerial mycelium formation by S. coelicolor

The filamentous bacterium S. coelicolor differentiates by forming aerial hyphae, which protrude into the air and metamorphose into chains of spores. Aerial hyphae formation is associated with the production of a small, abundant protein, SapB, which is present in a zone around colonies of differentiating bacteria. Production of SapB is impaired in bld mutants, which are blocked in aerial hyphae formation, but not in whi mutants in which spore formation is prevented. We report that aerial hyphae formation by a newly identified bld mutant is restored by juxtaposition of the mutant near colonies of SapB-producing bacteria or by the application of the purified protein near mutant colonies. These observations implicate SapB in aerial mycelium formation and suggest that SapB is a morphogenetic protein that enables hyphae on the surface of colonies to grow into the air.     

The formation of the rodlet layer of streptomycetes is the result of the interplay between rodlins and chaplins

Streptomycetes form hydrophobic aerial hyphae that eventually septate into hydrophobic spores. Both aerial hyphae and spores possess a typical surface layer called the rodlet layer. We present here evidence that rodlet formation is conserved in the streptomycetes. The formation of the rodlet layer is the result of the interplay between rodlins and chaplins. A strain of Streptomyces coelicolor in which the rodlin genes rdlA and/or rdlB were deleted no longer formed the rodlet layer. Instead, these surfaces were decorated with fine fibrils. Deletion of all eight chaplin genes (strain DeltachpABCDEFGH) resulted in the absence of the rodlet layer as well as the fibrils at surfaces of aerial hyphae and spores. Apart from coating these surfaces, chaplins are involved in the escape of hyphae into the air, as was shown by the strong reduction in the number of aerial hyphae in the DeltachpABCDEFGH strain. The decrease in the number of aerial hyphae correlated with a lower expression of the rdl genes in the colony. Yet, expression per aerial hypha was similar to that in the wild-type strain, indicating that expression of the rdl genes is initiated after the hypha has sensed that it has grown into the air.     

The effect of low temperatures on ultrastructure of hyphae and young zygospores ofRhizopus sexualis (Smith) Callen

Summary Aerial hyphae and young zygospores ofR. sexualis were exposed to a temperature of 7 °C for periods of 6 to 72 hours. The zonation of organelles seen in the apices of hyphae grown at 20 °C was lost by treatment at 7 °C. In particular the small vesicles normally present at the apex were absent. The shape and alignment of mitochondria was altered in a manner suggesting cessation of cytoplasmic streaming. Small vacuoles coalesced to form fewer large ones. With longer exposure to low temperature the mitochondrial cristae were altered in form and the membranes of the nuclear envelope tended to separate. The amount of endoplasmic reticulum associated with nuclei was reduced. Similar changes occurred in young zygospores, and in addition the normal processes of dissolution of the fusion wall and formation of gametangial septa were disrupted and the vesicles associated with these processes largely disappeared. The significance of these ultrastructural changes is discussed in relation to the known effects of low temperature on zygospore development.     

榆耳有性结构及生活史的研究

本文通过电镜扫描、石腊切片及用苏木精染色法和DAPI荧光染色,对榆耳子实体有性结构进行观察,证实榆耳子实体菌盖结构分三层:上表层为毛层,表面着生有排列较密集顶端游离的菌丝,它们相互粘连呈菌丝束;中间层为髓部,由较疏松而相互交织在一起的薄壁菌丝组成,菌丝间充满胶质物质;下表层为子实层,表面起伏不平,呈不规则的疣状突起,上面着生担子和囊状体,担子无隔膜棍棒形,外表有不规则的网状纹饰,其顶部着生4个瓶梗状小梗,每个小梗上着生1个椭圆形或腊肠形担孢子,大小为2.5—3.0×6.0—6.5μm,担孢子表面有不规则的网状纹饰结构。在担子间的囊状体为长圆柱形或圆锥形,表面有较密的不规则的网状纹饰。 榆耳有性生殖为异宗配合。绝大多数担孢子含一个细胞核,很少数担孢子含两个细胞核。孢子萌发为一端萌发,也有少数为两端萌发。初生菌丝单核,不能形成子实体,当两种不同遗传性的交配型的初生菌丝结合后,形成具有锁状联合结构的双核菌丝,并可发育成子实体。榆耳具有典型减数分裂过程,不具有减数分裂后核分裂行为,四个子核分别进入四个担孢子内。 在初生菌丝或次生菌丝上,均可产生间生的或顶生的厚垣孢子。经过温度、光照和紫外线照射的诱发,均未发现有其它类型的无性孢子产生。因此,榆耳菌的生活史和大多数担子     

Loss of NAD(P)-reducing power and glutathione disulfide excretion at the start of induction of aerial growth in Neurospora crassa.

When exponentially growing hyphae of Neurospora crassa in aerated liquid cultures are filtered and the resulting mycelial mat is exposed to air, aerial hyphae develop and synchronous conidiation is obtained. The hyphae in direct contact with air adhere to each other within minutes and form aerial hyphae during the following 12 h; the hyphae which are not in direct contact with air do not adhere to each other and do not form aerial hyphae. Previous data indicated that oxidative stress was generated in the adhering hyphae; proteins and specific enzymes were found to be oxidatively modified and degraded. In this work, we report a dramatic fall in the reduced-to-oxidized ratio of NAD and NADP coenzymes during the first 6 min of exposure to air. This drop did not occur in a mycelial mat exposed to a N2-enriched atmosphere. Adding a carbon source to the mycelial mat did not abolish the loss of NAD(P)-reducing power. After the initial fall, the reducing levels of the coenzymes returned to the starting value in about 30 min. A peak of extracellular glutathione disulfide occurred simultaneously with the loss of NAD(P)-reducing power. The reducing power loss and the excretion of glutathione disulfide are thought to be consequences of a hyperoxidant state; the adhesion of hyphae is thought to be a response to the hyperoxidant state.     

Regulation of Streptomyces development: reach for the sky!

Streptomyces coelicolor is characterized by a complex life cycle and serves as a model system for bacterial development. After a feeding substrate mycelium has been formed, this filamentous bacterium differentiates by forming aerial hyphae that septate into spores. The bld cascade regulates initiation of aerial growth, whereas the whi genes control spore formation. Recent findings indicate the existence of another regulatory pathway that operates after aerial hyphae have started to grow into the air, which we call the sky pathway. This pathway controls the expression of the chaplin and rodlin genes. These genes encode proteins that assemble into a rodlet layer that provides surface hydrophobicity to aerial hyphae and spores.     

Nuclear division cycle in Neurospora crassa hyphae under different growth conditions.

Treatment with picolinic acid blocked Neurospora crassa nuclei in G1, and recovery from the treatment allowed a synchronous wave of deoxyribonucleic acid synthesis to occur. Nuclei, which appeared as compact globular bodies during the period of blockage, assumed a ring shape during the following S phase, which was also maintained in the G2 phase. The proportion of compact globular nuclei was much higher in hyphae growing at lower rates, whereas that of ring nuclei increased when the hyphae were growing at higher rates. Horseshoe nuclei (probably mitotic nuclei) and double ring nuclei were also observed in growing hyphae, but their frequencies were low and fairly independent of the rate of growth. The length of the S phase of the Neurospora nuclear division cycle was determined to be about 30 min. From the frequencies of the phase-specific nuclear shapes, the durations of the G1 phase and the combined S plus G2 phases were calculated. The results showed that variations in the growth rates of the mycelia were mainly coupled with variations in the G1 phase of the nuclear division cycle. For mycelia growing in minimal sucrose, the lengths of all of the phases of the nuclear division cycle were estimated.     

Autophagy during conidiation and conidial germination in filamentous fungi

Filamentous fungi form aerial hyphae on solid medium, and some of these differentiate into conidiophores for asexual sporulation (conidiation). In the filamentous deuteromycete, Aspergillus oryzae, aerial hyphae are formed from the foot cells and some differentiate into conidiophores, which are composed of vesicles, phialides and conidia. Recently, we isolated the yeast ATG8 gene homologue Aoatg8 from A. oryzae, and visualized autophagy by the expression of an EGFP (enhanced green fluorescent protein)-AoAtg8 fusion protein and DsRed2 protein in this fungus. Furthermore, by constructing the Aoatg8 deletion and conditional mutants, we demonstrated that autophagy functions during the process of differentiation of aerial hyphae, conidiation and conidial germination in A. oryzae. Here, we discuss the contribution of autophagy towards the differentiation and germination processes in filamentous fungi.     

Interfacial Self-Assembly of a Fungal Hydrophobin into a Hydrophobic Rodlet Layer

The Sc3p hydrophobin of the basidiomycete Schizophyllum commune is a small hydrophobic protein (100 to 101 amino acids) containing eight cysteine residues. Large amounts of the protein are excreted into the culture medium as monomers, but in the walls of aerial hyphae, the protein is present as an SDS-insoluble complex. In this study, we show that the Sc3p hydrophobin spontaneously assembles into an SDS-insoluble protein membrane on the surface of gas bubbles or when dried down on a hydrophilic surface. Electron microscopy of the assembled hydrophobin shows a surface consisting of rodlets spaced 10 nm apart, which is similar to those rodlets seen on the surface of aerial hyphae. When the purified Sc3p hydrophobin assembles on a hydrophilic surface, a surface is exposed with high hydrophobicity, similar to that of aerial hyphae. The rodlet layer, assembled in vivo and in vitro, can be disassembled by dissolution in trifluoroacetic acid and, after removal of the acid, reassembled into a rodlet layer. We propose, therefore, that the hydrophobic rodlet layer on aerial hyphae arises by interfacial self-assembly of Sc3p hydrophobin monomers, involving noncovalent interactions only. Submerged hyphae merely excrete monomers because these hyphae are not exposed to a water-air interface. The generally observed rodlet layers on fungal spores may arise in a similar way.     

Homokaryotic and heterokaryotic hyphae in Terfezia

Mycelia of Terfezia pfeilii (Ascomycetes) were obtained by two methods, i.e., from the sterile hyphae of fresh fruit bodies or by germinating ascospores. Nuclear staining revealed the existence of multinucleate cells in all mycelia. Paired nuclei were observed only in mycelia obtained from sterile hyphae proliferation, while single nuclei were found in mycelia originating from singly germinated spores. Co-cultivation of mycelia from two different ascospores apparently facilitated plasmogamy, resulting in mycelia with paired nuclei. Terfezia boudieri cultures originating from sterile hyphae also exhibit paired nuclei, indicating the possible existence of a long-term heterokaryon. The timing of plasmogamy and karyogamy in Terfezia is discussed.     

Protein changes during the asexual cycle of Neurospora crassa.

A method for synchronizing conidiation and isolating large numbers of cells at discrete stages of conidia development is described. Using two-dimensional gel electrophoresis, we analyzed the protein profiles of mycelia, aerial hyphae, and conidia and observed that the concentration of 14 polypeptides increase and 38 decrease during the asexual cycle. Twelve polypeptides were present in extracts of aerial hyphae or conidia, but not mycelia, suggesting that they may be conidiation specific. The protein profiles of mutants defective in conidiation were also analyzed. Differences were detected in the two-dimensional profiles of protein extracts from fluffy and wild-type aerial hyphae. Polyadenylated RNA isolated from wild-type mycelia and conidiating cultures was translated in vitro in a rabbit reticulocyte lysate. Differences were detected in the polypeptide products specified by the two RNA populations, suggesting that changes in steady-state levels of polyadenylated RNAs also occur during conidiation.     

猪苓分生孢子产生的电镜研究

The ultrastructure of conidia produced by the mycelia of Polyporus umbellatus was studied by use of scanning and transmission electron microscopy. The results suggested that only clamped (dikaryotic) mycelia produced aerial conidiophores with ovoid to rod-shaped conidia. There was a distinctive bulge near the top of the conidium. The contents of the conidia were dense. This type of conidium could be regarded as arthroconidia.     

The chsA gene from Aspergillus nidulans is necessary for maximal conidiation

A fragment from the open reading frame of the cloned chsA gene from Aspergillus nidulans was deleted and replaced with the argB gene. The resulting construct was used to replace the wild-type chsA gene in an argB deletion strain. The growth and morphology of the vegetative hyphae from the resulting chsA disruptant strain were indistinguishable from those of a wild-type strain but the chitin content of the hyphae from the disruptant was reduced to approximately 90% of that of wild-type. The disruptant showed reduced ability to produce the asexual spores (conidia) that are formed by differentiated aerial hyphae called conidiophores. The ability to form undifferentiated aerial hyphae was not impaired in the disruptant. The conidiophores and conidia produced by the disruptant were indistinguishable from those of wild-type. Conidium formation by the disruptant grown on a variety of media was reduced to about 30% of the wild-type. A chsE null strain did not show a defect in conidiation but a strain in which both chsA and chsE were inactivated produced about 3% of the conidia of wild-type. That finding supports the hypothesis that chsA and chsE encode a partially redundant function necessary for conidiophore development.     

Brevianamides A and B Are Formed Only After Conidiation Has Begun in Solid Cultures of Penicillium brevicompactum

In cultures of Penicillium brevicompactum grown on Czapek-Dox agar or on circles of dialysis membrane placed on Czapek-Dox agar, brevianamides A and B first appeared after conidiation had begun. The presence of these brevianamides imparted a yellow-green fluorescence to the penicilli and to the upper section of the conidiophores of actively conidiating cultures. Experiments with replacement cultures indicated that medium nutrient levels had little direct effect on brevianamide production. If P. brevicompactum was grown between two circles of dialysis membrane, no aerial hyphae were formed, and brevianamide production was not observed. Three brevianamide-minus mutants of P. brevicompactum were isolated.     

Une Technique D'obtention De Coupes Ultrafines Longitudinales Dans Les Hyphes Myceliennes Des Champignons Pour La Microscopie Électronique

The methods that consist in growing fungal mycelia on cellophane sheets, in order to get longitudinal sections for electron microscopy, show some insufficiencies. It is possible to use a derived procedure from Kühner's method of culture under a collodion film. This can be done by growing the mycelium in a drop of nutrient broth, squashed between two collodion films. The upper film prevents the mycelium from emitting aerial hyphae, and obliges it to grow only in a horizontal thin layer. The lower film does not adhere to the support and allows an easy harvesting of the specimen. Fixation and dehydratation are made on the whole culture assembly. Then, little pieces cut from this assembly are infiltrated with resin, included and sectionned. This technique was applied with good results to the root parasite fungusPyrenochaeta lycopersici.