Conidia and Conidial Germination in Leveillula taurica (Lev.) Arn.

Septate conidiophores of Leveillula taurica, of the oidiopsistype, emerge from the endophytic hyphae through the stomataof the host leaf to the exterior. The conidia are formed indistinct chains and are abstricted in basipetal succession bya terminal generative cell. L. taurica possesses dimorphousconidia. The first-formed spore in the chain is pyriform butall subsequent ones are strictly cylindrical. The conidia germinate at any humidity between zero and ioo percent and readily produce appressoria when in firm contact withthe substratum. Mature conidia still attached to the conidiophorenever germinate, but readily do so when detached from the conidiophore.Conidia held in detached chains germinate just as freely assingle ones.     

Visualizing nuclear migration during conidiophore development in Aspergillus nidulans and Aspergillus oryzae: multinucleation of conidia occurs through direct migration of plural nuclei from phialides and confers greater viability and early germination in Aspergillus oryzae

Nuclear migration is indispensable for normal growth, differentiation, and development, and has been studied in several fungi including Aspergillus nidulans and Neurospora crassa. To better characterize nuclear movement and its consequences during conidiophore development, conidiation, and conidial germination, we performed confocal microscopy and time-lapse imaging on A. nidulans and Aspergillus oryzae strains expressing the histone H2B-EGFP fusion protein. Active trafficking of nuclei from a vesicle to a phialide and subsequently into a conidium provided the mechanistic basis for the formation of multinucleate conidia in A. oryzae. In particular, the first direct visual evidence on multinucleate conidium formation by the migration of nuclei from a phialide into the conidium, rather than by mitotic division in a newly formed conidium, was obtained. Interestingly, a statistical analysis on conidial germination revealed that conidia with more nuclei germinated earlier than those with fewer nuclei. Moreover, multinucleation of conidia conferred greater viability and resistance to UV-irradiation and freeze-thaw treatment.     

FINE STRUCTURE OF ANNELLOPHORES. I. SCOPULARIOPSIS BREVICAULIS AND S. KONINGII

Fine-structure observations of annelloconidium production in filamentous Hyphomycetes are reported for the first time. The difference in conidium morphology between Scopulariopsis brevicaulis and S. koningii was quite distinct. In S. brevicaulis, verrucosities appeared early in conidium ontogeny and formed an integral part of the primary wall layer of mature conidia. In S. koningii, verrucosities were absent. In S. brevicaulis, annellations did not invariably result on conidiophore necks with the production of each conidium in the basipetal sequence, but alternatively could be left on subapical regions of subsequently formed conidia. In S. koningii, annellations were more distinct, and the position of a conidium-delimiting septum was variable. If a septum were formed at a position proximal to previous septa, a portion of the annellophore neck remained attached to the base f the seceding conidium. In both species, a spherical electron-dense body, perhaps analogous to septal pore plugs in vegetative hyphae, plugged the pore between conidia and conidiophores and remained embedded in the base of seceded conidia.     

Successful induction and recognition of conidiation,conidial germination and chlamydospore formation in pure culture of Morchella

Morels, fungi from the genus Morchella, are popular edible mushrooms. However, little knowledge of their asexual reproduction and inaccessible pure mitospores hamper illumination of their life cycle. Herein, we successfully induced conidiation, conidial germination and chlamydospore formation in pure culture of Morchella sextelata. Conidiation proceeded via four morphologically distinct stages: development of the conidiophore stalk, stalk branching, phialide differentiation, and conidium production. Terminal and intercalary chlamydospores were formed on conidial hyphae. The development of conidiophores occurred earlier, with more conidia produced, in cross-mating cultures than in single-spore cultures. Mature conidia were spherical and 2.5–8 μm in diameter, with a vast majority (nearly 99%) 2.5–5 μm in diameter. Each conidium contained one to three nuclei (80.2% conidia contained one nucleus, 19.1% contained two nuclei, and 0.7% contained three nuclei). The conidial nucleus diameter was 1–2 μm. The nuclear mitosis in detached conidia that was observed may benefit their colony initiation. Additionally, morel conidia formed conidial anastomosis tubes. Conidia (mitospores) likely not only function as spermatia, but also as reproductive propagules in Morchella. Further research is imperative to elucidate the relationship between the conidia and chlamydospores, and their unique function in the morel life cycle.     

Scanning Electron Microscopy of Conidium Formation of Stemphylium vesicarium on Onion Leaves

Onion leaves were inoculated with conidia of Stemphylium vesicarium and the development and morphology of conidiophores and conidia on the leaf surface were examined using scanning electron microscopy. Solitary, but usually fasciculate conidiophores emerged through the epidermis. Hyphae growing on or above the leaf surface also differentiated into conidiophores. Conidiophores were straight or flexuous, simple, smooth or verrucose and cylindrical but enlarged apically at the site of conidiumproduction. Smooth, round, bud-like conidial initials were produced singly at the apex of the verrucose conidiophores. As conidia matured, they became oblong to ovoid and densely verrucose. Once the mature conidium seceded, a small pore was visible at the, apex of the conidiogenous cell. Conidiophores proliferated percurrently at the distal region, forming secondary conidiophores and conidia.     

Infection of Barley by <Emphasis Type="Italic">Ramularia</Emphasis> <Emphasis Type="Italic">collo-cygni</Emphasis>: Scanning Electron Microscopic Investigations

Ramularia collo-cygni causes leaf spots on barley (Hordeum vulgare), a disease of growing economical importance. Scanning electron microscopy was used to study the life cycle of the fungus on barley during the vegetation period and in winter. The infectious stage started with conidium germination on the surface and the penetration into the leaf via the stomatal pore where the hyphae grew within the cells that became necrotic. The conidiophores emerged through the stomatal pore. On older leaves, however, they frequently emerged apart from it and the results suggested a pushing apart of adjacent cell walls of the epidermal cells. An assessment of the amount of conidium formation of one heavily infested barley plant resulted in 4.05 × 10⁶ conidia per plant. For the first time, conidiophores, conidium production and germination of conidia were also observed in winter on barley and on maize leaves.     

Spore dispersal in Alternaria porri (Ellis) Neerg. on onions in Nebraska

In spore-trapping studies in 1965, conidia of Alternaria porri (Ellis) Neerg. were detected in the atmosphere immediately above onions affected by purple blotch disease. On calm summer days, peak conidium concentration occurred between 08.00 and 14.00 hr., few conidia being trapped between 20.00 and 06.00 hr. On windy days, there were marked increases in concentration. Concentration tended to increase with increasing wind velocity. Increased conidium concentrations were also recorded after rainfall and irrigation, and during spraying operations. Laboratory observations indicate that in A. porri, the attachment of conidium to conidiophore is weakened, if not broken, by movements in the conidial apparatus which occur in response to a decrease in vapour pressure. Possible causes of fluctuations in atmospheric content of A. porri conidia are discussed.     

Conidia of the tomato powdery mildew <Emphasis Type="Italic">Oidium neolycopersici</Emphasis> initiate germ tubes at a predetermined site

The emergence of germ tubes from the conidia of powdery mildew fungi is the first morphological event of the infection process, preceding appressoria formation, peg penetration and primary haustoria formation. Germination patterns of the conidia are specific in powdery mildew fungi and therefore considered useful for identification. In the present study, we examined conidial germination of the tomato powdery mildew Oidium neolycopersici KTP-01 in order to clarify whether germ tube emergence site in KTP-01 conidia is determined by the first contact of the conidia to leaves (as found for the conidia of barley powdery mildew), or alternatively is predetermined and is unrelated to contact stimulus. Highly germinative conidia of KTP-01 were collected from conidial pseudochains on conidiophores in colonies on tomato leaves using two methods involving an electrostatic spore attractor and a blower. In the electrostatic spore attraction method, the conidia were attracted to the electrified insulator probe of the spore collector—this being the first contact stimulus for the conidia. In addition, the blowing method was used as a model of natural infection; pseudochain conidia were transferred to detached leaves by air (1 m/s) from a blower. Thus, landing on the leaves was the first contact for the conidia. Furthermore, conidia were also blown onto an artificial membrane (Parafilm-coated glass slides forming a hydrophobic surface) or solidified agar plates in Petri dishes (hydrophilic surface). Eventually, almost all conidia on the probe and on tomato leaves or artificial hydrophobic and hydrophilic surfaces synchronously germinated within 6 h of incubation, indicating that the first contact of the conidia with any of the aforementioned substrata was an effective germination induction signal. Germ tube emergence sites were exclusively subterminal on the conidia. Moreover, the germ tubes emerged without any relation to the sites touched first on the conidia. Thus, the present study strongly indicates that conidia of O. neolycopersici produce germ tubes at a predetermined site.     

Collection of highly germinative pseudochain conidia of Oidium neolycopersici from conidiophores by electrostatic attraction

A population of simultaneously germinating conidia is an ideal inoculum of the powdery mildew pathogen, Oidium neolycopersici. In conditions of no or low wind velocity, O. neolycopersici successively stacks mature conidia on conidiophores in a chain formation (pseudochain), without releasing the precedent mature conidia. These pseudochain conidia represent a perfect inoculum, in which all conidia used for inoculation germinate simultaneously. However, we found that conidia must be collected before they fall to the leaf surface, because the germination rate was lower among conidia deposited on the leaf surface. We used an electrostatic spore collector to collect the pseudochain conidia, and their high germination rate was not affected by this treatment. The spore collector consisted of an electrified insulator probe, which created an electrostatic field around its pointed tip, and attracted conidia within its electric field. The attractive force created by the probe tip was directly proportional to voltage, and was inversely proportional to the distance between the tip and a target colony on a leaf. Pseudochain conidia were successfully collected by bringing the electrified probe tip close to target colonies on leaves. In this way, conidia were collected from colonies at 3-d intervals. This effectively collected all conidia from conidiophores before they dropped to the leaf surface. A high germination rate was observed among conidia attracted to the probe tip (95.5 ± 0.6 %). Conidia were easily suspended in water with added surfactant, and retained their germination ability. These conidia were infective and produced conidia in pseudochains on conidiophores after inoculation. The electrostatic spore collection method can be used to collect conidia as they form on conidiophores, thus obtaining an inoculum population in which all of the conidia germinate simultaneously.     

Three newAspergillus species isolated from clinical sources as a causal agent of human aspergillosis

Three new species ofAspergillus isolated from clinical sources in China are described and illustrated:A. beijingensis, A. qizutongii andA. wangduanlii. The first species is characterized by spreading colonies, yellow to grayish green conidial heads, smooth-walled conidiophores with a clavate vesicle, uniseriate aspergilla and nearly globose, micro-verrucose conidia. The second is characterized by spreading colonies, olive-yellow conidial heads, conspicuously roughened conidiophores with a flask-shaped vesicle, uniseriate but often secondarily proliferating aspergilla and globose, smooth conidia. The third is characterized by rapidly growing colonies, dull green conidial heads, smooth to irregularly roughened conidiophores which are often surrounded by coiled hyphae in the basal part and are terminally swollen into a globose or irregular shaped vesicle, uniseriate aspergilla and globose, micro-verrucose conidia.     

Scanning electron microscopy of the conidia produced by the mycelial form of Paracoccidioides brasiliensis

The conidia produced by the mycelial form of Paracoccidioides brasiliensis were examined by scanning electron microscopy for the first time. Several different conidial types were characterized. These included intercalary arthroconidia, several types of septate conidia that are formed from other conidia, pedunculate conidia, and terminal hyphal conidia. In addition, the ultrastructure of the supporting pedestal of the pedunculate conidium was found to be separated from the mother conidium by a septum in some instances, and at other times it was not.     

Phylogenetic relationships of Chalara and allied species inferred from ribosomal DNA sequences

The phylogenetic relationships of Chalara and allied taxa are studied based on ribosomal DAN sequences. Partial 28S rDNA and 18S rDNA regions from 26 strains were sequenced in this study. These and related sequences from GenBank were analyzed using parsimony and Bayesian analyses. Most of the Chalara species clustered in a strongly supported monophyletic lineage representing Helotiales. However, a few Chalara species appeared closely related to Xylariales. The phylogenetic significance of morphological characters observed in Chalara species are evaluated based on our sequence analyses. Conidial septation, conidial width and conidiophore pigmentation are thought to be indicative in understanding their evolutionary relationships. Sterile setae, which traditionally have been used to delimitate Chaetochalara from Chalara, are phylogenetically insignificant.     

Evolutionary relationships among aquatic anamorphs and teleomorphs: Lemonniera, Margaritispora, and Goniopila

The hypothesis that similar conidial morphologies in aquatic hyphomycetes are a result of convergent evolution was tested using molecular sequence data. Cladistic analyses were performed on partial sequences of 28S rDNA of seven species of Lemonniera, one species of Margaritispora and one species of Goniopila. Lemonniera has tetraradiate conidia with long arms, whereas Margaritispora and Goniopila have typically globose (isodiametric) conidia, with short conical protuberances in a stellate or quadrangular arrangement. Lemonniera and Margaritispora have phialidic conidiogenesis and both produce dark, minute sclerotia in culture whereas Goniopila has holoblastic conidiogenesis and does not produce sclerotia in culture. Goniopila produces a microconidial phialidic synanamorph in culture. All three genera have schizolytic conidial secession. Molecular analyses demonstrate that Lemonniera species are placed in two distinct clades: one within Leotiomycetes; the other within Pleosporales, Dothideomycetes. Margaritispora is placed with Lemonniera species within Leotiomycetes. Goniopila and Lemonniera pseudofloscula are placed within Dothideomycetes. No morphological character was entirely congruent with the molecular derived phylogeny. This suggests that for the group of species studied, conidial shape is not a reliable indicator of phylogeny but more likely the result of convergent evolution in response to the aquatic environment.     

The Aspergillus nidulans bncA1 mutation causes defects in the cell division cycle, nuclear movement and developmental morphogenesis

Wild-type Aspergillus nidulans conidia are uninucleate. The mutation bncA1 (binucleated conidia) was first described as a single mutation located on chromosome IV that caused formation of approximately 25% binucleate and 1% trinucleate conidia. In this study, we show that bncA1 conidia exit G1 arrest earlier than the wild type. Germlings have hyphal elements with abnormal morphology, elevated numbers of randomly distributed nuclei and an irregular septation pattern. Older hyphal elements undergo mitotic catastrophe, suggesting the nuclear division cycle of internal (nonterminal) elements is not arrested. The bncA1 mutation also causes aberrant morphogenesis of the asexual reproductive structure, the conidiophore. Metulae and phialides are elongated and have incorrect numbers of nuclei. Phialides also have internal septation that appears to delineate hyphal-like elements. Heterokaryon analysis using strains with contrasting auxotrophic markers showed that the bncA1 mutation resulted in a higher frequency of diploid and multinucleated prototrophic conidia than control heterokaryons. These results suggest that in bncA1 strains multiple nuclei can move from the conidiophore vesicle to the metulae and/or from the phialide to the conidium. The bncA1 mutant also showed hypersensitivity to the anti-microtubule drugs thiabendazole and nocodazole, which is consistent with the defects in cell cycle regulation and nuclear movement. We propose that bncA has an important role in correctly regulating both the cell division cycle and nuclear movement.     

Ecotypes of the fungus Bipolaris oryzae with various responses of the mycochrome system

Two types of fungi based on the light required for induction of conidiophore formation are known as 'photo-induced' and 'non-photo-induced' sporulators. Conidial development in a 'photo-induced' strain of Bipolaris oryzae (formerly, Helminthosporium oryzae ) is controlled by antagonistic action of blue and near-UV radiation mediated through the 'mycochrome' system at two developmental stages: conidiophore induction and conidiophore maturation. Otherwise, conidial development in a 'non-photo-induced' strain of B. oryzae , unlike that in the 'photo-induced' strain, is controlled by antagonistic action of blue and near-UV radiation at the conidiophore maturation stage alone. In this study, we collected fungi, B. oryzae , from brown lesion spots on rice leaves cultivated in paddy fields, and investigated the possible existence of a new ecotype different from known 'photo-induced' and 'non-photo-induced' sporulators. We also investigated the sensitivity of conidial development of each isolate to blue and near-UV radiation.
The isolates were identified as B. oryzae by morphology of hyphae and conidia and the symptomatic brown lesion spots on rice leaves caused by each isolate. There was no distinction between 'photo-induced' and 'non-photo-induced' strains on rDNA base. Moreover, the existence of a new type of 'non-photo-induced' sporulator different from the one presently known was confirmed. In this newly identified sporulator, conidial development was not affected by light irradiation. Among 153 isolates, one isolate belonged to a previously known 'non-photo-induced' sporulator, five isolates belonged to a new 'non-photo-induced' sporulator ecotype, and over 95% of the isolates were "photo-induced" sporulators. Among 'photo-induced' strains, there were several subtypes having different sensitivities to near-UV radiation required for inducing conidiophore formation.     

橡胶树暹罗炭疽菌Zn2Cys6型转录因子CsGcc1的生物学功能

【背景】暹罗炭疽菌（Colletotrichum siamense）是一种重要的病原真菌,可以引起炭疽病,给全球橡胶产业带来巨大的经济损失。Zn₂Cys₆型转录因子是真菌特有的锌指类转录因子,通常参与调控真菌的生长发育过程。【目的】在暹罗炭疽菌中鉴定了一个与稻瘟病菌Gcc1同源的Zn₂Cys₆型转录因子CsGcc1,并研究其功能。【方法】根据同源重组原理构建CsGCC1的基因敲除突变体,并通过营养生长、H₂O₂敏感性、分生孢子产生及萌发、玻璃纸试验和致病性分析,明确CsGcc1的功能。【结果】CsGcc1编码一个含有646个氨基酸的蛋白,而且含有一个GAL4结构域。CsGCC1基因在培养36 h的菌丝及分生孢子中具有较高的表达量。CsGCC1基因敲除突变株营养生长速率降低且对H₂O₂更加敏感。相较于野生型菌株,突变株的分生孢子产量、萌发率及附着胞形成率均降低。此外,CsGCC1的敲除可以明显降低分生孢子的穿透能力,突变株对橡胶叶片的致病力减弱。【结论】Zn₂Cys₆型转录因子CsGcc1参与调控暹罗炭疽菌的营养生长、氧化应激、分生孢子发育及致病性等过程。     

Polyancora globosa gen. sp. nov., an aeroaquatic fungus from Malaysian peat swamp forests

During an investigation of submerged leaves and twigs sampled from tropical peat swamp forests located in Peninsular Malaysia, an anamorphic fungus not attributable to a described genus was detected and isolated in pure culture. Conidial ontogeny was thoroughly studied and illustrated using both light and SEM, which revealed a unique conidial morphology. Analysis of partial nuLSU rDNA and ITS data revealed a phylogenetic position within the Xylariales (Ascomycota), but family affiliation remained unclear.     

Evaluation of the potential role of water in spread of conidia of the Neotyphodium endophyte of Poa ampla

Neotyphodium endophytes are asexual, filamentous fungi, mutualistically associated with diverse cool season grasses. Infected seeds and vegetative organs of infected host plants are the only known modes of propagation of the asexual endophytes. In the last decade certain Epichloë and Neotyphodium-infected grass species have been shown to have epiphyllous structures of the endophytes, hyphae, conidiophores, and conidia, growing on leaf blades. The production of epiphyllous conidia suggests the possibility that some of these endophytes may have the ability for plant-to-plant spread. The objective of this study was to determine the possible mechanisms involved in liberation and dispersal of asexual spores of Neotyphodium growing in vitro and epiphyllously on leaves of Poa ampla. Our results indicate that water dispersal is the most likely means of dissemination of conidia of the Neotyphodium sp. Wind generated by dry compressed air does not dislodge the conidia from slide cultures or from P. ampla leaves.     

Infection Process of Botrytis cinerea on Eucalypt Leaves

This study aimed to elucidate the infection process of Botrytis cinerea on eucalypt leaves. Tests were conducted to evaluate the influence of leaf side (adaxial or abaxial), leaf age and luminosity on conidial germination, appressorium formation and grey mould (GM) severity. The adaxial and abaxial surfaces of detached eucalypt leaves were inoculated with a conidial suspension of B. cinerea and kept under constant light or dark. Subsequently, the adaxial surface of young and old leaves was inoculated and kept in the dark. To evaluate the percentage of conidia germination and appressorium formation, leaf samples were collected 6 hours after inoculation (hai), clarified (alcohol and chloral hydrate) and evaluated under a light microscope. The severity of GM was assessed 10 days after inoculation. For scanning electron microscopy analysis, samples were collected from 2 to 168 hai. A higher percentage of conidia germination (92%) and GM severity (21%) occurred on the adaxial surfaces of leaves kept in the dark. There was no statistical difference between the surfaces of young and old leaves for conidia germination. No appressorium was formed by B. cinerea. The GM severity on young leaves (17.3%) was 34 times higher than on old leaves (0.5%). The micrographs showed germinating conidia emitting 1–4 germ tubes in samples at 4 hai. The fungus penetration occurred through intact leaf surfaces, and both extra‐ and intracellular colonization of the mesophyll cells by the hyphae of the pathogen were observed at 120 hai. Sporulation occurred on the adaxial and abaxial surfaces (macronematous conidiophores) and below the epidermis (micronematous conidiophores).     

Growth and sporulation of the fungus Claviceps purpurea in batch fermentation

Summary The sporulation of the fungus Claviceps purpurea is connected with the change in its respiration rate which is effected by deficiency of dissolved oxygen tension. It stops the vegetative growth of the fungus and induces the formation of conidiophores with conidia production until glucose is exhausted. With exhaustion of glucose the conidiophores continue to produce conidia by transforming vegetative cell material into conidia. Therefore final conidial concentration in batch fermentation depends on these two processes which can be regulated by oxygen input.