No abstract available.
Colon* ; Malassezia* ; Spores

During the study of mushroom flora in Hongneung Arboretum, Ileodictyon gracile was confirmed as new to Korea and described based on morphological and microscopic characteristics in here. This species has subhypogeous, clathrate structure, and obovoid spores. The clathrate structures have 4~12 polygonal meshes.
Agaricales ; Korea* ; Spores

Page 31. The size of conidia of Alternatia brassicicola should be 20~80x8~25 microm instead of 20~120x8~30 microm.
Alternaria* ; Korea* ; Spores, Fungal

Cylindrocarpon destructans causes root rot disease in ginseng and can survive for a long time, producing chlamydospores. We optimized conditions to induce chlamydospore production from the conidia of C. destructans, isolated from Korean ginseng. This will provide the basis for testing the efficacy of control agents targeting these chlamydospores.
Korea* ; Panax* ; Spores, Fungal*

Clubroot symptoms were frequently observed on roots of shepherd's-purse (Capsella bursa-pastoris) grown in a field in Nonsan, Chungnam province, Korea in March, 2009. Many resting spores were found in the cells of the root gall tissues collected from the field. The clubroot pathogen was identified as Plasmodiophora brassicae based on its morphological and pathological characteristics. This is the first report that P. brassicae causes clubroot of shepherd's-purse in Korea.
Brassica ; Korea ; Plasmodiophorida ; Spores

In order to breed a Cordyceps bassiana isolate that stably forms fruiting body in artificial cultivation, isolates derived from subculturing and single spores were tested through mating. From C. bassiana EFCC 783, three subcultured isolates EFCC 2830, EFCC 2831 and EFCC 2832 were obtained and fourteen single conidial isolates were obtained from these three subcultured isolates. Two different morphological types were found in the fourteen single conidial isolates. One type was able to form synnemata and another type was not able to form synnemata. Since switch of morphological type was not observed despite their continuous subculturing, cross was performed between the two types and the formation of fruiting body was examined. Ascospores were obtained from a selected fruiting body formed by hybrid of the cross. Self-cross and combinational cross of the ascospore-derived isolates generated hybrids that stably produce high quality fruiting body in artificial media.
Cordyceps* ; Fruit* ; Spores

Arthonia coreana, Arthonia superpallens, and Arthonia zelkovae are new species from South Korea. All new species are in the Euarthonia tribe, based on the key characteristics of colorless hypothecium and multi-cellular spores. A. coreana has a dull brownish hypophloedal thallus without bleaching and rounded or curved big apothecia in comparison with those of Arthonia punctiformis. A. coreana consistently exhibits 4-septate ascospores, which is a distinctive characteristic that distinguishes it from other Arthonia species. A. superpallens has a white-greenish thallus, pale yellowish apothecia, and a trentepohlioid alga. However, A. superpallens has no distinct prothallus, adnate, and convex apothecia, no pycnidia, and is UV-, in contrast with related species in the Arthonia antillarum group. A. zelkovae has a white, epiphloedal thallus, brownish-black epruinose apothecia covered with a whitish bark layer, and smaller ascospores in comparison with those of A. punctiformis. A. zelkovae consists of a chlorococcoid alga, which differs from related Arthonia species such as A. punctiformis, Arthonia pinastri, and Arthonia glaucella. Although A. zelkovae is similar to Arthonia dispersa in its white-colored thallus, blackish apothecia, and the presence of a chlorococcoid photobiont, A. zelkovae differs from the latter in having larger-sized 3-septate ascospores. Arthonia cinnabarina f. marginata, A. glaucella, Arthonia ilicinella, Arthonia lapidicola, Arthonia leioplacella, Arthonia pertabescens, A. pinastri, Arthonia spadicea, and Arthonia stellaris are newly described in Korea. The diagnostic characteristics of these species are discussed and presented. An artificial key is provided to facilitate identification of Arthonia species from Northeast Asia.
Asia ; Korea* ; Spores ; Ulmaceae

Exposure to fungal spores occurs frequently in indoor as well as in outdoor. Residential area, office, factory and farm fields are the common places of fungal spore exposure. Role of fungal spores as the causes of hypersensitivity reactions, bronchial asthma, allergic rhinitis and hypersensitivity pneumonitis was underestimated due to the lack of intensive research on the allergenicity of fungal spores. As the knowledge on fungal spores is accumulating, it is necessary to reevaluate the role of fungal spores in the field of allergic diseases.
Alveolitis, Extrinsic Allergic ; Asthma ; Fungi ; Hypersensitivity ; Rhinitis ; Spores ; Spores, Fungal*

Exposure to fungal spores occurs frequently in indoor as well as in outdoor. Residential area, office, factory and farm fields are the common places of fungal spore exposure. Role of fungal spores as the causes of hypersensitivity reactions, bronchial asthma, allergic rhinitis and hypersensitivity pneumonitis was underestimated due to the lack of intensive research on the allergenicity of fungal spores. As the knowledge on fungal spores is accumulating, it is necessary to reevaluate the role of fungal spores in the field of allergic diseases.
Alveolitis, Extrinsic Allergic ; Asthma ; Fungi ; Hypersensitivity ; Rhinitis ; Spores ; Spores, Fungal*

The typical life cycle of filamentous fungi commonly involves asexual sporulation after vegetative growth in response to environmental factors. The production of asexual spores is critical in the life cycle of most filamentous fungi. Normally, conidia are produced from vegetative hyphae (termed mycelia). However, fungal species subjected to stress conditions exhibit an extremely simplified asexual life cycle, in which the conidia that germinate directly generate further conidia, without forming mycelia. This phenomenon has been termed as microcycle conidiation, and to date has been reported in more than 100 fungal species. In this review, first, we present the morphological properties of fungi during microcycle conidiation, and divide microcycle conidiation into four simple categories, even though fungal species exhibit a wide variety of morphological differences during microcycle conidiogenesis. Second, we describe the factors that influence microcycle conidiation in various fungal species, and present recent genetic studies that have identified the genes responsible for this process. Finally, we discuss the biological meaning and application of microcycle conidiation.
Fungi* ; Germination ; Hyphae ; Life Cycle Stages ; Spores ; Spores, Fungal