Fungal adhesion in aquatic hyphomycetes

The attachment of propagules of aquatic fungi often takes place under turbulent conditions, i.e. spores of marine lignicolous fungi and conidia of freshwater Hyphomycetes. It has been demonstrated that attachment in Lemonniera aquatica is effected by three arms of the conidium making contact with the surface and forming appressoria. In this study the mechanisms of attachment of conidia of 10 aquatic Hyphomycetes to a variety of natural and artificial substrata were followed at the light microscope and scanning electron microscope levels.Five species produced appressoria, while in the remaining species attachment and subsequent retention to the substratum was effected solely by the production of mucilage. Examination of selected appressorium-forming species in the transmission electron microscope showed that conidium attachment involved the production of mucilage in the regions of initial contact and only then were appressoria formed. The ecological significance of appresoiria to the aquatic Hyphomycetes is discussed.     

Basidiomycetes with branched, water-borne conidia

A number of water-borne fungi with branched conidia have been shown to be basidiomycetes. These fungi resemble aquatic hyphomyectes in their habitat, conidial morphology and ontogeny. Their conidia are typically tetraradiate or elaborately branched. Ingoldiella hamata and Taeniospora gracilis, which produce clamped, tetraradiate conidia, are anamorphs connected to the teleomorphs Sistotrema hamalum and Leptosporomyces galzinii, respectively. Both teleomorphs are members of the Corticiaceae. Dendrosporomyces prolifer and D. splendens, which produce non-clamped conidia resembling the aquatic hyphomycete Dendrospora, have binucleate conidia and typical dolipore septa are present. Other water-borne fungi with basidiomycete affinities include Ingoldiella fibulata and Tricladiomyces malaysianum.     

Influence of conidial traits and leaf structure on attachment success of aquatic hyphomycetes on leaf litter

Attachment of conidia on leaves is a critical first step in the life cycle of aquatic hyphomycetes in streams. In a first series of microcosm experiments, attachment success of three common aquatic hyphomycete species differing in conidial shape (compact, filiform and tetraradiate) was determined on two leaf species, black alder and downy oak. Fungal species identity and leaf surface structure significantly affected conidial attachment after 24 h. The lower sides of oak leaves with extensive tufts trapped 2.4-8.8 more conidia than the upper sides of oak leaves and both sides of alder leaves. In a second experiment with seven fungal species, attachment success of two species with tetraradiate conidia was much greater than that of two other tetraradiate and three compact conidia, which all had similar attachment success. The species with the largest spores was also the most successful, but this pattern was not consistent across the size range of tested conidia. These results highlight the importance of leaf surface structure, possibly conidial shape and size and additional properties of aquatic hyphomycete conidia in determining attachment success on leaves and they point to the potential role of these factors in structuring fungal communities on decomposing leaves in streams.     

Gonidiogenesis in Padixonia bispora Subram. (Hyphomycetes)

(Hyphomycetes). Padixonia bispora produces two kinds of conidium arranged as acropetal tandem pairs. The pair consists of a distal enteroblastic conidium connected via a narrow neck to a proximal broad-based holoblastic conidium. The proximal blastospore is derived from a branched conidiphore axis and initially forms as a distal conidiogenous cell from which arises the distal blastospore. The wall between the two conidia is formed from the narrow neck occluded by a layered plug. Conidial maturation is concurrent with conidiogenesis. Secession of the proximal spore is by a rounding-off mechanism with circumscissile rupture of the outer layer of the continuous wall between the conidiogenous cell and the conidium and concurrent schizolysis of the duplex septum. The distal blastospore is released by mechanical transverse tearing of the plug through an undulate abscission zone. The abscission zone has two major concentric rings of thickening. The outer ring is derived from the outer layer of proximal spore cell wall.     

Experiments with Spores of Aquatic Hyphomycetes: I. Sedimentation, and Impaction on Smooth Surfaces

Techniques are described for the production of heavy concentrationsof aquatic Hyphomycete spores, for estimating the spore concentration,the sedimentation rate of spores and their trapping efficiencyon smooth cylinders. No correlation could be discovered betweenthe rates of sedimentation and spore shape. Trapping experimentsshowed that the trapping efficiency of the tetraradiate sporeswas higher than that of spores of different shape. It is suggestedthat the higher efficiency might be the result of contact ofthe tetraradiate spore at three points on a surface.     

A NEMATODE-DESTROYING HYPHOMYCETE FORMING PARALLEL MULTISEPTATE HYALINE CONIDIA IN CIRCULAR ARRANGEMENT

In several Petri plate cultures that had been inoculated with decaying plant detritus from central Maryland, a fungus developed which attacks nematodes by extending a rather wide infection-tube either from an adhesive hyphal protuberance, or, more often, from a subglobose adhesive cell produced terminally on its elongate-ellipsoid pluriseptate hyaline conidia. A number (sometimes three) of these conidia are borne simultaneously in peripheral positions on the broadly rounded tip of the colorless condiophore, and are directed upward, parallel to the conidiophore axis. From the segment immediately below its adhesive cell, each conidium puts forth laterally a flexible unicellular tubular appendage that grows downward approximately to the level of the spore attachment. The fungus is described as Haptocara latirostrum gen. n., sp. n. Although presumably belonging in the Moniliaceae, it shows no close kinship with the numerous interrelated clampless Hyphomycetes that have been made known as subsisting through capture of nematodes.     

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.     

Spore attachment and extracellular mucilage of aquatic hyphomycetes

Stages in conidiun attachment to surfaces of Lemmoniera aquatica and Mycocentrospora filiformis (freshwater Hyphomycetes) were studied at the light microscope and scanning and transmission electron microscope levels. Sigmoid conidia of M. filiformis attach by pre-existing conidial mucilage at the spore pole and at a point along the conidial body. Tetraradiate conidia of L. aquatica attach by the thigmotropic release of mucilage at the tips of the three "arms";. Germination in both species is followed by the production of germ tubes, germ hyphae and appressoria. The chemical composition of the mucilage involved in attachment was determined by enzymatic studies and lectin-gold cytochemical studies. The major component was found to be acidic poly-saccharide, comprising mainly ?-1, 3-glucan, N-acetyl-D-glucosamine and N-acetyl-neuraminic acid. Variation in mucilage composition exists between the two species, among different structures of the same species, and on different regions of the same structure. This indicates that mucilage producton in the two species is a dynamic process.The ability to secure rapid spore attachment, often in turbulent condition, would be a competitive advantage to these saprobic fungi in the colonization of substrata.     

Aquatic Hyphomycetes of a mountain stream in Valsesia (Piemonte)

The conidia of aquatic Hyphomycetes in a mountain stream in Italy were studied. Thirteen species previously unknown from Italy were recorded. The concentration of conidia in the waters of the stream reached a maximum from October to December, and a minimum in August.     

Conidium differentiation in Aspergillus nidulans wild-type and wet-white (wetA) mutant strains

Conidium (asexual spore) differentiation in wild-type and the wet-white (wetA) mutant of Aspergillus nidulans was compared in intact chains of successively older conidia. Carbohydrate cytochemistry helped define three stages (Stages I, II, and III) of wild-type conidium maturation on the basis of changes in the ultrastructure and composition of the conidium wall. Conidia of the wetA6 mutant strain formed normally but failed to mature during Stages II and III. Specifically, the inner wall layer of wetA6 conidia did not condense during Stage II and two wall layers that stained for carbohydrates did not form during the transition to Stage III. Concomitantly, wetA6 conidia formed large cytoplasmic vacuoles and underwent lysis. The wetA gene appears to have a conidium-specific function for the modification of the conidium wall during Stages II and III. These modifications of the conidium wall are essential for the stability of mature, dormant conidia.     

Temperature and Sporulation of Aquatic Hyphomycetes

Temperature appears to be an important factor affecting the occurrence and distribution of aquatic hyphomycetes, the dominant leaf litter-decomposing fungi in streams. We compared conidium production by eight species of aquatic hyphomycetes grown on yellow poplar leaves in stream-simulating microcosms at three temperatures (15, 20, and 25°C). The greatest conidium production occurred at 15°C for one species, 20°C for two species, and 25°C for two species. Two species produced similar numbers of conidia at 20 and 25°C, and one species produced similar numbers of conidia at all three temperatures. Linear growth rates were determined on malt extract agar. Six species had the same pattern of temperature responses for growth on malt extract agar as for sporulation on leaves, as shown by the positive correlations between the two parameters at the three temperatures. The species examined also exhibited differences in number of conidia produced from a similar amount of leaf material at a given temperature. These differences appeared to be due primarily to differences in individual conidium mass (determined by weighing conidia produced from cultures), as shown by the relationship of the type Y = k/X (r² = 0.96), where Y is the number of conidia produced, X is the individual conidium mass in milligrams, and k is a constant empirically determined to be 2.11. This finding supports the hypothesis that aquatic hyphomycetes allocate similar amounts of their resources to reproduction but vary with respect how these resources are partitioned into reproductive units (conidia).     

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.     

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.     

FRESHWATER HYPHOMYCETES OF THE NORTHERN APPALACHIAN HIGHLAND INCLUDING NEW ENGLAND,AND THREE COASTAL PLAIN STATES

Twenty-seven species of freshwater Hyphomycetes from two five-state areas in the northern Appalachian Highland, New England, and three Coastal Plain states were collected, isolated, and identified. The spores of three fungi which are probably aquatic Moniliales were also studied. Sigmoidea, a new Hyphomycete genus, includes submerged aquatic fungi which produce phialides laterally along the mycelium and sigmoid, multicellular phialospores. Varicosporium giganteum sp. n. produces terminal, hyaline, branched, and multiseptate aleuriospores. The main spore axis has one to four lateral branches which arise successively on one side of this axis. Tricladium marylandicum sp. n. is similar to T. splendens in that the lateral branches are constricted where each branch joins the main spore axis. It differs from this species in that the spore has a blunt apical cell on the main axis and on each of the lateral axes. Three possible methods of dispersal are presented to explain the cosmopolitan distribution of freshwater Hyphomycetes.     

Initial colonization, nutrient supply, and fungal activity on leaves decaying in streams

Aquatic hyphomycetes dominate leaf decomposition in streams, and their biomass is an important component in the diet of leaf-eating invertebrates. After 2 weeks of exposure in a first-order stream, maple leaf disks had low levels of fungal biomass and species diversity. Spore production by aquatic hyphomycetes also was low. Subsets of these disks were left in the stream for another 3 weeks or incubated in defined mineral solutions with one of three levels of nitrate and phosphate. Stream disks lost mass, increased ergosterol levels and spore production, and were colonized by additional fungal species. External N and P significantly stimulated mass loss, ergosterol accumulation, and spore production of laboratory disks. On disks incubated without added N and P, ergosterol levels declined while conidium production continued, suggesting conversion of existing hyphal biomass to propagules. In all other treatments, approximately equal amounts of newly synthesized biomass were invested in hyphae and conidia. Net yield (fungal biomass per leaf mass lost) varied between 1% (in the laboratory, without added N or P) and 31% (decay in stream). In most treatments, the three aquatic hyphomycete species that dominated spore production during the first 2 weeks in the stream also produced the largest numbers of conidia in the following 3 weeks. Principal-component analysis suggested two divergent trends from the initial fungal community established after 2 weeks in the stream. One culminated in the community of the second phase of stream exposure, and the other culminated in the laboratory treatment with the highest levels of N and P. The results suggest that fungal production in streams, and, by extension, production of invertebrates and higher tropic levels, is stimulated by inorganic N and P.     

Initial Colonization, Nutrient Supply, and Fungal Activity on Leaves Decaying in Streams

Aquatic hyphomycetes dominate leaf decomposition in streams, and their biomass is an important component in the diet of leaf-eating invertebrates. After 2 weeks of exposure in a first-order stream, maple leaf disks had low levels of fungal biomass and species diversity. Spore production by aquatic hyphomycetes also was low. Subsets of these disks were left in the stream for another 3 weeks or incubated in defined mineral solutions with one of three levels of nitrate and phosphate. Stream disks lost mass, increased ergosterol levels and spore production, and were colonized by additional fungal species. External N and P significantly stimulated mass loss, ergosterol accumulation, and spore production of laboratory disks. On disks incubated without added N and P, ergosterol levels declined while conidium production continued, suggesting conversion of existing hyphal biomass to propagules. In all other treatments, approximately equal amounts of newly synthesized biomass were invested in hyphae and conidia. Net yield (fungal biomass per leaf mass lost) varied between 1% (in the laboratory, without added N or P) and 31% (decay in stream). In most treatments, the three aquatic hyphomycete species that dominated spore production during the first 2 weeks in the stream also produced the largest numbers of conidia in the following 3 weeks. Principal-component analysis suggested two divergent trends from the initial fungal community established after 2 weeks in the stream. One culminated in the community of the second phase of stream exposure, and the other culminated in the laboratory treatment with the highest levels of N and P. The results suggest that fungal production in streams, and, by extension, production of invertebrates and higher tropic levels, is stimulated by inorganic N and P.     

Microcycle conidiation — A review

Microcycle conidiation is defined as the germination of spores by the direct formation of conidia without the intervention of mycelial growth, as occurs in most normal life cycles. It is a method of asexual spore formation in which the normal life cycle of the fungus is bypassed. Spores formed through sexual reproduction and species with unicellular thalli are not included in microcycle conidiation. The term secondary conidium or secondary spore is usually, but not always, synonymous with microcycle conidiation. In the laboratory various factors, but especially temperature, can induce the microcycle condition in such fungi asAspergillus niger, Penicillium andNeurospora crassa, providing a useful tool for research. Microcycle conidiation has also been reported in a broad range of species in nature, and comprises a normal part of the life cycle in several groups, including the Entomophthorales, Taphrinales, Clavicipitales, Uredinales, Ustilaginales, Tremellales and Exobasidiales. The presence of a microcycle in such fungi undoubtedly provides a survival mechanisn for spores that encounter unfavorable conditions.     

Visualization of nuclei in Aspergillus oryzae with EGFP and analysis of the number of nuclei in each conidium by FACS

Aspergillus oryzae has been reported to form conidia with multinuclei. In order to analyze nuclei in living cells, we developed an expression system of the A. nidutans histone H2B protein tagged by EGFP (H2B::EGFP). In both A. oryzae niaD300 and A. nidulans FGSC89 transformants expressing H2B::EGFP, fluorescence was detected in nuclear regions of hyphae and conidia. While a conidium contained only one fluorescent spot in the A. nidulans transformant, approximately 66% of conidia had two, 24% had one, and 10% had three or more in the A. oryzae transformant. The conidia expressing H2B::EGFP were put through FACS (fluorescence-activated cell sorting) analysis and two sharp peaks, corresponding to one and two nuclei in each conidium, were noted in the A. oryzae transformant. In addition, the A. oryzae uninucleate conidia that were successfully isolated by FACS reproduced conidia with almost the same number distribution of nuclei as that of the original. Conidia of five A. oryzae strains used in sake brewing were scored for the number of nuclei, showing that a varied number of nuclei existed in each conidium and some strains had a small number of uninucleate conidia.     

The role of initial spore adhesion in pellet and biofilm formation in Aspergillus niger

Fungi grow on a great variety of organic and inorganic materials. Colony establishment and growth on solid surfaces require adhesion of spores and hyphae to the substrate, while cell-to-cell interactions among spores and/or hyphae are a prerequisite for the development of three-dimensional mycelial structures such as pellets or biofilms. Surface adherence has been described as a two-step process, comprised of the initial attachment of ungerminated conidia followed by further adhesion of the forming germ tubes and growing hyphae. In the present study, we analyzed the contribution of adhesion of ungerminated spores to pellet and biofilm formation in Aspergillus niger. Mutants deficient in melanin biosynthesis were constructed by the deletion of the alb1 gene, encoding a polyketide synthase essential for pigment biosynthesis. Δalb1 conidia have an altered surface structure and changed physicochemical surface properties. Spore aggregation in liquid culture as well as spore surface attachment differ between the wild type and the mutant in a pH-dependent manner. In liquid culture further pellet formation is unaffected by altered spore-spore interactions, indicating that germ tube and hyphal adherence can compensate for deficiencies in the initial step of spore attachment. In contrast, under conditions promoting adhesion of Δalb1 conidia to polymer surfaces the mutant forms more stable biofilms than the wild type, suggesting that initial spore adhesion supports sessile growth.     

短柄链蠕孢分生孢子发育的研究

短柄链蠕孢(Dendryphion nanum)为暗色丝孢菌,其分生孢子棒状,5～20个隔膜,暗褐色,串生。试验通过玻片培养观察研究了该菌分生孢子的产生方式及发育类型。结果表明:该菌的分生孢子是由产孢细胞的顶端向外突起并生长膨大而形成,因而属于全壁芽生式产孢方式。