Changes in Saccharomyces cerevisiae ascospore proteins during early germination

Abstract Proteins present in Saccharomyces cerevisiae ascospores and in germinating ascospores were compared using two-dimensional polyacrylamide gel electrophoresis. Yeast ascospores incorporated labeled methionine efficiently facilitating the electrophoretic analysis. Proteins synthesized in the yeast ascospores differed significantly from those proteins found 15 min after the initiation of germination in the ascospores. An immediate transition from ascospore proteins to proteins required for ascospore germination appears likely.     

Effects of temperature on germination and hyphal growth from ascospores of A-group and B-group Leptosphaeria maculans (phoma stem canker of oilseed rape)

Ascospores of both A‐group and B‐group Leptosphaeria maculans germinated at temperatures from 5–20°C on distilled water agar or detached oilseed rape leaves. After 2 h of incubation on water agar, some A‐group ascospores had germinated at 10–20°C and some B‐group ascospores had germinated at 5–20°C. The percentages of both A‐group and B‐group ascospores that had germinated after 24 h of incubation increased with increasing temperature from 5–20°C. The observed time (Vo₅₀) which elapsed from inoculation until 50% of the spores had germinated was shorter for B‐group than for A‐group ascospores. Germ tube length increased with increasing temperature from 5–20°C for both ascospore groups. Germ tubes from B‐group ascospores were longer than germ tubes from A‐group ascospores at all temperatures tested, but the mean diameter of germ tubes from A‐group ascospores (1.8 μm) was greater than that of those from B‐group ascospores (1.2μm) at 15°C and 20°C. The average number of germ tubes produced from A‐group ascospores (3.8) was greater than that from B‐group ascospores (3.1) after 24 h of incubation at 20°C, on both water agar and leaf surfaces. Germ tubes originated predominantly from interstitial cells or terminal cells of A‐group or B‐group ascospores, respectively, on both water agar and leaf surfaces. Hyphae from A‐group ascospores grew tortuously with extensive branching, whilst those from B‐group ascospores were predominantly long and straight with little branching, whether the ascospores were produced from oilseed rape debris or from crosses between single ascospore isolates, and whether ascospores were germinating on water agar or leaf surfaces.     

The release of elongated, sheathed ascospores from bottle-shaped asci in Dipodascus geniculatus

Yeasts use different mechanisms to release ascospores of different lengths from bottle-shaped asci. Round to oval-shaped ascospores are enveloped in oxylipin-coated compressible sheaths, enabling ascospores to slide past each other when they reach the narrowing ascus neck. However, more elongated ascospores do not contain sheaths, but are linked by means of oxylipin-coated interlocked hooked ridges on the surfaces of neighboring ascospores, thereby keeping them aligned while they are pushed towards the ascus tip by turgor pressure. In this study, we found elongated, oxylipin-coated sheathed ascospores in Dipodascus geniculatus that are released effectively from bottle-shaped asci without alignment. This is possible because the ascus neck and opening have a diameter that is the same as the length of the ascospore, thus allowing the ascospores to turn sideways without blocking the ascus when they are released. We found that increased concentrations of acetylsalicylic acid inhibit both ascospore release and 3-hydroxy oxylipin production in this yeast, thereby implicating this oxylipin in sexual reproduction.     

Mapping the distribution of 3-hydroxy oxylipins in the ascomycetous yeast Saturnispora saitoi

The distribution of 3-hydroxy oxylipins in Saturnispora saitoi was mapped using immunofluorescence microscopy. Fluorescence was observed on aggregating ascospores, indicating the presence of 3-hydroxy oxylipins on the surface or between ascospores. The oxylipin was identified as 3-hydroxy 9:1 using gas chromatography mass spectrometry. Furthermore, ultrastructural studies using scanning and transmission electron microscopy on ascospores revealed a clear equatorial ledge surrounding oval-shaped ascospores.     

Ascospore release from bottle-shaped asci in Dipodascus albidus

Yeasts utilize different mechanisms to release ascospores of different lengths from bottle-shaped asci. Using electron microscopy, confocal laser scanning microscopy, gas chromatography-mass spectrometry and digital live imaging, the individual release of oval ascospores from tight-fitting narrow bottle-necks, is reported in the yeast Dipodascus albidus. These ascospores are surrounded by compressible, oxylipin-coated sheaths enabling ascospores to slide past each other when forced by turgor pressure and by possible sheath contractions towards the narrowing ascus-neck. In this paper, the release mechanisms of ascospores of various lengths from bottle-shaped asci and produced by different yeasts are compared. We suggest that different release mechanisms, utilizing compressible sheaths or geared-alignment, have possibly evolved to compensate for variation in ascospore length. Alternatively, sheaths and ridges might be two evolutionary solutions to the same biomechanical problem, i.e. to release ascospores irrespective of length from bottle-shaped asci.     

冬虫夏草子囊孢子的发育

经光学显微镜观察,冬虫夏草[Cordyceps sinensis(Berk.)Sacc.]子囊孢子的发育可分为三个阶段:(1)原子囊孢子期:孢子近球形,椭圆形,卵圆形或长圆形,4.8—10×3.6—6μm。(2)孢子伸长期:从孢子一端突出,伸长生长,出现分隔,隔细胞较长,30—37.5μm。(3)子囊孢子形成期:孢子继续伸长并不断出现分隔,隔间长6—12μm。一般仅有两个孢子成熟,其余多数原子囊孢子败育,不萌发或形成极纤细的丝状物。基于子囊孢子发育的过程,讨论了冬虫夏草及其近缘种的分类地位。     

Environmental Factors Influencing the Dispersal of Venturia inaequalis Ascospores in the Orchard Air

A 6-year study was carried out in an apple-growing region of North Italy by trapping airborne ascospores of Venturia inaequalis with a volumetric spore trap operated continuously during the ascospore season, with the aim of better defining the weather conditions that allow ascospores both to discharge and to disperse into the orchard air. A total of more than 60 ascospore trapping events occurred. Rain events were the only occurrences allowing ascospores to become airborne (a rain event is a period with measurable rainfall ≥0.2 mm/h – lasting one to several hours, uninterrupted or interrupted by a maximum of two dry hours); on the contrary, dew was always insufficient to allow ascospores to disperse into the air at a measurable rate, in the absence of rain. In some cases, rain events did not cause ascospore dispersal; this occurred when: (i) rain fell within 4–5 h after the beginning of a previous ascospore trapping; (ii) rain fell at night but the leaf litter dried rapidly; (iii) nightly rainfalls were followed by heavy dew deposition that persisted some hours after sunrise. Daytime rain events caused the instantaneous discharge and dispersal of mature ascospores so that they became airborne immediately; for night-time rainfall there was a delay, so that ascospores became airborne during the first 2 h after sunrise. This delay did not always occur, and consequently the ascospore trapping began in the dark, when: (i) the cumulative proportion of ascospores already trapped was greater than 80% of the total season's ascospores; (ii) more than one-third of the total season's ascospores was mature inside pseudothecia and ready to be discharged.     

Survival of A-group and B-group Leptosphaeria maculans (phoma stem canker) ascospores in air and mycelium on oilseed rape stem debris

Mycelium of Leptosphaeria maculans survived on oilseed rape stem base debris buried in sand for 2,4, 6, 8,10 or 12 months and produced pseudothecia after subsequent exposure on the surface of the ground under natural conditions for 2–4 months, but did not survive on upper stem debris buried for 2 months. Only A‐group L. maculans ascospores were produced on the stem base debris which had been buried; no B‐group ascospores were produced. Mycelium of L. maculans survived on both stem base and upper stem debris exposed on the sand surface for 2, 4, 6, 8, 10 or 12 months and pseudothecia with viable ascospores were observed at the time of sampling. Both A‐group L. maculans (predominant on stem bases) and B‐group L. maculans (predominant on upper stems) ascospores were produced on unburied stem base and upper stem debris. Thus B‐group L. maculans survived longer on unburied debris than on buried debris. A‐group ascospores which were exposed in dry air in darkness at 5–20°C survived longer than B‐group ascospores; 10–37% of A‐group ascospores, compared with 2–31% of B‐group ascospores, survived after 35 days.     

Carrefour Mme. Gras: a wild-isolated Neurospora crassa strain that suppresses meiotic silencing by unpaired DNA and uncovers a novel ascospore stability defect

Ordinarily, RIP-induced erg-3 mutant Neurospora crassa ascospores and their erg(+) siblings do not differ in stability during long-term storage. Consequently, the frequency of RIP-induced erg-3 mutants remains about constant regardless of the time that has elapsed between ascospore harvest and germination. We found, however, that RIP-induced erg-3 mutants were apparently selectively lost with time from among the ascospores stored from a cross with the wild-isolated Carrefour Mme. Gras strain from Haiti. The Haitian strain was also found to exert a dominant suppression of meiotic silencing by unpaired DNA. Similar loss of RIP-induced erg-3 mutant ascospores was seen among the stored ascospores from a subset of crosses heterozygous for the semi-dominant Sad-1 or Sad-2 suppressors of meiotic silencing. Our results suggest that crosses suppressed in meiotic silencing can compromise the stability during storage of ascospores that inherit RIP-induced mutations.     

A Mutant Affecting Meiosis in Neurospora

Many mutants affecting meiosis increase the occurrence of aneuploid meiotic products. In Neurospora, mutants of this type cause ascospore abortion which is reflected by an increase in the proportion of ascospores failing to develop black pigment. The usefulness of the criterion white-ascospore-production as a signal for the presence of a mutant affecting meiosis is demonstrated by the recovery of several such mutants. One of these is mei-1 (meiotic-1), a recessive mutant on linkage group IV. Crosses homozygous for mei-1 produce 90% white ascospores (vs. 5% in wild-type crosses). Viable ascospores, invariably black, are always disomic for one or more linkage groups; the chromatids assorted into viable ascospores do not engage in crossing over in meiosis. The distribution of viable ascospores in individual asci suggests that all meioses are defective in the first meiotic division, and that most meioses are defective in both divisions.     

Electron Micrograph Study of the Asci and Ascospores of Metschnikowia Kamienski

Internal and surface structures of asci and ascospores were studied by transmission electron microscopy (TEM) and by scanning electron microscopy (SEM) to establish the character and number of ascospores within the ascus of Metschnikowia krissii. Enzyme digestion with snail gut enzymes and SEM examination suggested the presence of a single ascospore enclosed in a thick sheath of epiplasmic materials. Two closely associated ascospores without an epiplasmic sheath were clearly distinguishable from asci of M. bicuspidata var. chathamia when similarly treated. Ultramicrotomy and TEM established conclusively that M. krissii produced a single ascospore per ascus. Neither SEM nor TEM revealed any morphological detail of the ascospores of taxonomic significance.     

An acetylsalicylic acid-sensitive aggregation phenomenon in Dipodascopsis uninucleata

Aggregation of ascospores has been discovered in the yeast Dipodascopsis uninucleata. When this yeast is cultivated to reach the sexual reproductive stage, small ascospores are individually released from the tip of a sac-like ascus which then aggregate in orderly clusters. Acetylsalicylic acid (ASA) inhibited ascospore release and subsequent ordered aggregation process. We suggest that novel ASA-sensitive oxidised fatty acids (3 R-hydroxy-oxylipins) and small hooks located on the surface of these ascospores, are involved.     

Soil ascomycetes from Spain. XIII. Two new species of Apiosordaria

Apiosordaria hispanica sp. nov. and Apiosordaria globosa sp. nov. isolated from soil samples collected in Tarragona, Catalonia, Spain, are described and illustrated. Both species are morphologically close to A. otanii. The ascospores of A. hispanica have tuberculate walls, while those of A. otanii have small warts. Apiosordaria globosa differs from those species by the globose upper cell of the ascospores, which has a small apical protrusion with sub-apical germ pore when young. In A. hispanica and A. globosa the lower cells of the ascospores are slightly warted, while in A. otanii the lower cell of the ascospores is smooth-walled.     

Oxylipin covered ascospores of Eremothecium coryli

Eremothecium coryli is known to produce intriguing spindle-shaped ascospores with long and thin whip-like appendages. Here, ultra structural studies using scanning electron microscopy, indicate that these appendages serve to coil around themselves and around ascospores causing spore aggregation. Furthermore, using immunofluorescence confocal laser scanning microscopy it was found that hydrophobic 3-hydroxy oxylipins cover the surfaces of these ascospores. Using gas chromatography–mass spectrometry, only the oxylipin 3-hydroxy 9:1 (a monounsaturated fatty acid containing a hydroxyl group on carbon 3) could be identified. Sequential digital imaging suggests that oxylipin-coated spindle-shaped ascospores are released from enclosed asci probably by protruding through an already disintegrating ascus wall.     

Immunodetection of Venturia inaequalis Ascospores with Phage Antibodies

We describe the bacterial expression of single chain variable fragment (scFv) antibodies that bind specifically to the ascospores of Venturia inaequalis (Cooke). A scFv phage display library was prepared from the expressed V‐gene repertoire of a mouse immunized with whole V. inaequalis ascospores. Affinity selection was then carried out using intact, non‐germinated ascospores. The binding of selected phage antibodies was monitored by enzyme‐linked immunosorbent assay, flow cytometry and fluorescence microscopy. Several scFv antibodies were found to bind specifically to V. inaequalis ascospores. No cross‐reactivity was detected with spores from other phytopathogenic fungi, such as Plectosphaerella cucumerina, Cladosporium spp. and Alternaria brassicicola. Moreover, the scFvs did not bind to V. inaequalis conidiospores or mycelia. This is the first report describing the immunodetection of V. inaequalis ascospores by phage‐derived scFv antibody fragments. The degree of specificity of the antibodies is sufficiently high to allow rapid detection of ascospores within environmental probes such as those from particle samplers.     

Airborne ascospores in Mérida (SW Spain) and the effect of rain and other meteorological parameters on their concentration

Airborne ascospores have been reported to be allergenic or plant pathogens, and their presence has traditionally been associated with rainfall events. The aim of the present study was to analyze the presence of airborne ascospores in relation to weather parameters in a town in SW Spain. A seven-day recording spore trap (Burkard) was used to sample the air over 2 years at 15 m above ground level on the terrace roof of the hospital in Mérida (SW Spain). Fungal spores were identified and counted by means of two longitudinal scans over the slides under ×1000 microscopy. A correlation analysis was made of the daily meteorological data and the airborne ascospore concentrations, and t-tests were used to compare data between the 2 years. Nineteen ascospore types were defined, including one-cell ascospores (Chaetomium, Diatrype, Helvella, Xylaria), tow-cell ascospores (Diaporthe, Mycosphaerella, Nectria, Venturia), transversally septate ascospores (Melanomma, Leptosphaeria, Paraphaeosphaeria, Sporormiella, Massaria), transversally and longitudinally septate ascospores (Pleospora), and ascospores within asci (Sordaria). Leptosphaeria consisted of a group of four types described according to the number of cells, hyaline grade, wall thickness, and ornamentation, and other ascospores comprised one last additional type. The average airborne ascospore concentration was 153 ascospores/m3. One-third each of this total were from the Leptosphaeria group, with an average 54 ascospores/m3, and the two-cell ascospores or Venturia-like group (Diaporthe, Mycosphaerella, Nectria, Venturia) with 51 ascospores/m3 on average. In third position was Pleospora with 27 ascospores/m3 on average. The month with highest concentration was September, with 238 ascospores/m3, and the lowest March, with 56 ascospores/m3. By seasons, autumn had the highest concentrations, followed by winter, spring, and summer. The maximum daily concentration reached was 3,371 ascospores/m3. Daily rainfall was significantly correlated with the ascospore types Diatrype, Mycosphaerella, Nectria, two subtypes of Leptosphaeria, and Pleospora. Relative humidity was positively correlated with those ascospore types and also with Diaporthe and Paraphaeosphaeria, and negatively with Chaetomium and Melanomma. The concentration was higher on rainy days than on days without rain for Pleospora, Leptosphaeria (3 subtypes), Diatrype, Diaporthe, Nectria, Mycosphaerella, and Paraphaeosphaeria. The daily temperatures were in general correlated with the same types as the relative humidity, but with the opposite sign. For the monthly data, there were no statistically significant differences between the 2 years studied.     

Ultrastructural aspects of ascosporulation in Arthroderma quadrifidum (=Trichophyton terrestre).

The ultrastructural features of developing and mature ascospores were delineated after mating Arthroderma quadrifidum on pablum cereal agar. Incipient ascospores each contained a granulated nucleus bounded by a nuclear envelope while presumptive ascospore cytoplasm was bounded by a double membrane and resided in glycogen-rich epiplasm of the ascus. Mature ascospores contained nuclei and mitochondria while the ascus epiplasm still retained abundant inclusions. The ascospore wall demonstrated the presence of heterogeneous material between the plasmalemma and the outer spore membrane which appeared smooth.     

Preparation of Free Heat-Resistant Ascospores from Byssochlamys Asci

When Byssochlamys is grown for production of ascospores, some of the asci break up into their constituent ascospores, whereas others do not. For heat resistance studies, it is desirable to prepare a uniform suspension of free ascospores. This was accomplished with the aid of a pressure cell, from which a suspension of asci under high pressure was released to atmospheric pressure through a small orifice. Spores so treated had about the same heat resistance as untreated spores.     

Two new lignicolous species of Nitschkia from Argentina

Two species of Nitschkia are described from bark and wood of a legume shrub, native to the semiarid regions of Argentina. Nitschkia campylospora is characterized by asci with a variable number of ascospores, mainly 16, and curved ascospores; hairy ascomata and large ascospores are two distinct features of Nitschkia pilosa. The new species are compared with most similar species. A key to Nitschkia species is provided with the inclusion of comments on those from Argentina and neighboring countries.