Morphological and cytological aspects of oidium formation in a basidiomycete,Pholiota nameko

Pholiota nameko produced abundant oidia on aerial hyphae from monokaryotic and dikaryotic test stocks, but oidia were rare on submerged hyphae. The oidia from the former stocks had a layer of hydrophobic protein between the cell wall and the inner cell membrane which was absent in the oidia from the latter. The only remarkable differences in the morphological features of the oidia from monokaryotic and dikaryotic mycelia was the slightly larger size of the latter. Observation of various test stocks on slide cultures revealed that about 80% of oidia were produced from the secondary branched hypha, and about 20% from the terminal hyphal, cell of the main hypha. In the former, the secondary hyphae were segmented to form several oidium cells; in the latter, a single or several oidia were formed at the terminal end of the main hypha. Most oidia from monokaryons and dikaryons had only one haploid nucleus, while the remainders were multinucleate. Among the stocks tested, most oidia had a DNA content with a haploid amount at the G1 phase of the cell cycle, but a few contained twice that amount corresponding to the G2 phase     

Nuclear selection in oidium formation from dikaryotic mycelia ofFlammulina velutipes

The effect of nuclear dominance in monokaryotic oidium formation from dikaryotic mycelia in a tetrapolar basidiomycete,Flammulina velutipes, was examined. A total of 46 monokaryotic stocks were used to produce 194 hybrid dikaryotic stocks by crossing. The proportion of homokaryons among the oidium isolates from dikaryotic mycelia was over 95%. The staining of nuclei of oidia with propidium iodide showed that over 90% of oidia were monokaryotic and suggested that these oidia had single haploid nuclei at the G1 stage. The monokaryotic oidium isolates from hybrid dikaryons were backrossed to parental monokaryotic stocks. Although most of the monokaryotic oidium isolates (except for those from 17 hybrid dikaryons from a total of 194 test stocks) showed nuclear types similar to only one of the parental stocks, the process seems to produce essentially the split nuclear type composition. Therefore, the monokaryotization in oidium formation from dikaryotic mycelia essentially involves the process of nuclear selection. The two separate results of hierarchies of relative dominance among two nuclei of the parental dikaryons in the monokaryotic oidium formation by grouping with incompatibility factor compositions were determined. Only a few discrepancies were found in the hierarchies between the two specific nuclear compositions of hybrid dikaryons.     

Ectomycorrhiza formation between Pseudotsuga menziesii seedling roots and monokaryotic and dikaryotic isolates of Laccaria bicolor

Seedling roots of Pseudotsuga menziesii were colonized with three monokaryotic isolates and one dikaryotic isolate of Laccaria bicolor to assess the effect of fungal genotype on ectomycorrhiza formation. Ectomycorrhizas resulting from colonization by the dikaryotic isolate had a multilayered mantle and a cortical Hartig net. One monokaryotic isolate (ss7) formed ectomycorrhizas comparable in anatomy to those induced by the dikaryotic isolate. Two other monokaryotic isolates (ss5, ss1) failed to form mantles or Hartig nets. Roots colonized by these isolates developed characteristics indicating an incompatible reaction.     

Microtubule organization and cell division in embryogenie protoplast cultures of white spruce (Picea glauca)

Summary Immunofluorescence methods were developed for examining the distribution of microtubules in freshly isolated and cultured protoplasts and regenerated somatic embryos of white spruce (Picea glauca). Freshly isolated protoplasts consisted of both uniand multinucleate types. Uninucleate protoplasts established parallel cortical microtubules during cell wall formation and cell shaping, divided within 24 h and developed into somatic embryos in culture. Dividing cells were characterized by preprophase bands (PPBs) of microtubules, atypical spindle microtubules focused at the poles and a typical phragmoplast at telophase. Multinucleate protoplasts also established parallel arrays of cortical microtubules during cell wall formation. In addition their nuclei divided synchronously within 4 days, then cell walls formed between the daughter nuclei. Individual multinucleate protoplast-derived colonies subsequently gave rise to elongate suspensor cells thereby forming embryo-like structures by 7 days.     

Mating type of isolates derived from the spermogonial state ofPuccinia coronata var.coronata

Hyphal confrontation between two haploid cultures originating from single basidiospores was used to determine the mating type ofPuccinia coronata var.coronata. Pairs of 15 single-basidiospore cultures were placed approximately 1 mm apart on the medium in all possible combinations. Hyphae of the pairs of colonies came into contact with each other in all combinations approximately two weeks after confrontations. When the nuclear number of hyphal cells in a contact zone was investigated one month after confrontation, monokaryotic hyphae were observed in selfing combination. On the other hand, dikaryotic hyphae were observed in 90.5% of crossing combinations between different cultures. Two isolates are considered compatible if dikaryotic hyphae are present in the contact zone but incompatible if they are absent. The mating type of the fungus was found to be characterized by multiple-allelomorphic tetrapolar incompatibility controlled by the “A” and “B” incompatible factors. Contribution No. 116, Laboratories of Plant Pathology and Mycology, Institute of Agriculture and Forestry, University of Tsukuba     

Karyology and hyphal characters as taxonomic criteria in Ascomycetous black yeasts and related fungi

Mycelial development of seventy-three strains of black yeasts and related fungi were studied, and numbers of nuclei per hyphal cell were counted. Two main patterns were apparent in expanding hyphae, viz. (1) uninucleate expanding hyphal cells, septum formation strictly following mitosis, and (2) multinucleate, branched, aseptate hyphal tips, septa being formed in a later stage, leading to oligo- or uninucleate mature cells. Characteristic genera in the two groups areExophiala andAureobasidium, respectively. InZasmidium and in someRamichloridium species all mycelial cells are oligonucleate. The character is indicative for relationships at the family level in black yeasts.     

Monokariotic fruiting body and clamp cell formation in Mycoleptodonoides aitchisonii (Bunaharitake)

The ability to produce monokaryotic fruiting bodies and clamp cells in culture was examined in monokaryotic strain isolated from several dikaryotic parental strains of the edible mushroom, Mycoleptodonoides aitchisonii (Bunaharitake). We describe a single dikaryotic M. aitchisonii strain, TUFC50005, and 20 monokaryons derived from it, which exhibited a wide spectrum of monokaryotic fruiting types. Most strains formed primordia, or young fruiting body-like structures, but only one of the monokaryons, strain TUFC50005-4, formed a fruiting body, even though it had only one nucleus and produced only two spores after meiosis. We demonstrated that dikariotization was not required for clamp cell formation, fruiting body formation, or meiosis, in this mushroom.     

Genetic evidence for somatic haploidization in developing fruit bodies of Armillaria tabescens

Armillaria spp. have vegetative hyphae with diploid uninucleate cells, but the fruit bodies of many species contain clamped dikaryotic hyphae. Earlier observations suggest that somatic haploidization takes place in developing fruit bodies. To verify this, a uninucleate diploid cell was isolated from each of the 49 mating combinations between single-spore isolates of Armillaria tabescens and they were fruited. Twenty-four isolates produced fruit bodies with at least a partially dikaryotic subhymenium. Dikaryotic hyphae were isolated from fruit-body primordia and homokaryons were obtained by micromanipulation or by protoplasting. Approximately half of the isolates proved to represent recombinant mating types in respect to parent homokaryons, and most of them contained recombinant haploid DNA, based on random-amplified microsatellite markers. The results show that the nuclei in dikaryotic hyphae found in fruit bodies result from somatic haploidization. The mechanism of haploidization remains unclear.     

长根小奥德蘑双孢菌株与四孢菌株核相变化的比较

用双苯并咪唑（Hoechst 33258）染色法分别对长根小奥德蘑Oudemansiella radicata双孢菌株和四孢菌株的菌丝、子实体、担孢子进行染色观察,结果表明：双孢长根小奥德蘑菌丝细胞多为单核,无锁状联合;原担子中单核进行一次有丝分裂形成两个横向或纵向排列的子核,这2个子核分别进入2个担孢子中,留下无核的空担子;成熟担孢子具有一个核。四孢长根小奥德蘑菌丝细胞大多数为双核,具有锁状联合;进入原担子中的两个单倍性细胞核先发生核配,形成一个二倍性的核,再经过减数分裂形成四个染色体减半的单倍性子核,     

Nuclear selection in monokaryotization of dikaryotic mycelia ofPholiota nameko as described by leading and following nuclei

To examine monokaryotization of dikaryotic mycelia ofPholiota nameko, 18 monokaryotic stocks were used to produce a total of 130 dikaryotic stocks by reciprocal crossing. Monokaryotized mycelium was raised from dikaryotic mycelium in the peripheral zone of the growing colony. The stocks mated with a particular group of monokaryons produced wide-range monokaryotization at higher rates than the other combinations of hybridization. The growth rates of the monokaryotized mycelia exceeded from those of the corresponding parental dikaryons. The monokaryotized mycelium was isolated and back-crossed to parental monokaryotic stocks. Most of the isolates had nuclear types similar to only one of the parental stocks, while the replicates of isolates from two dikaryotic hybrids showed split nuclear type compositions. It is suggested that a relative dominance is active in the selection of one of the two nuclei of the dikaryotic cells in monokaryotization. The hierarchy of relative dominance among nuclei of 18 parental monokaryotic stocks in the monokaryotization of their reciprocal crossing products was estimated. We propose the involvement of a cascade process in dikaryotic cell division, in which the first dividing nucleus (to be found in the monokaryotized cell) may act as the leading nucleus and the other one as the following nucleus.     

CYTOLOGY OF HELMINTHOSPORIUM TURCICUM AND ITS ASCIGEROUS STAGE,TRICHOMETASPHAERIA TURCICA

Knox- Davies , P. S., and J. G. Dickson . (U. Wisconsin, Madison.) Cytology of Helmintho sporium turcicum and its ascigerous stage, Trichometasphaeria turcica . Amer. Jour. Bot. 47(5) : 328—339. Illus. 1960.–The cells of the vegetative hyphae were generally multinucleate. Interphase nuclei resembled those of higher organisms, with a matrix of thread-like chromatin material surrounding a spherical nucleolus. “Beaked” nuclei frequently associated with anastomosing hyphae were interpreted as migrating nuclei. Nuclear division in the vegetative hyphae was rapid. Various division stages were distinguished but it was difficult to make accurate chromosome counts. The nucleoli were discarded at prophase or prometaphase and were reorganized in daughter nuclei at telophase. An outstanding feature of nuclear division was that all the nuclei in a cell divided simultaneously. Conidiophores and conidia were occasionally joined by wide cytoplasmic connections. They were multinucleate throughout their development. Mechanisms therefore exist for the perpetuation of heterokaryons through the conidium. Ascus development was studied in a hybrid between a dark and an albino isolate. Crozier formation was typical and nuclear fusion occurred in the young ascus. Four nuclear divisions were completed in the ascus before there was evidence of ascospore delimitation. Further nuclear division took place in the ascospores whose cells were multinucleate. The occurrence of less than 8 ascospores in an ascus appeared to follow degeneration of nuclei rather than the incorporation of a number of division-Ill nuclei in a single ascopore. Chromosome counts and irregularities in the appearance and behavior of nuclei and chromosomes in the asci indicate that aneuploidy occurs in Trichometasphaeria turcica. It is suggested that aneuploidy is a common phenomenon in the conidial stage of the fungus H. turcicum, and possibly also in other imperfect fungi.     

Alternation of nuclear phase in the filamentous basidiomycete,Helicobasidium mompa

Variation in the number of nuclei and cellular ploidy were observed in eight strains ofHelicobasidium mompa. The basidiospores, single-spore isolates and field-isolated strains were all dikaryons. The cellular ploidy, which was assessed by analyzing the fluorescence emitted by DAPI-stained nuclei, was unstable: monokaryotic strains derived from the original dikaryotic strains by successive subcultures were mainly tetraploid, although the original dikaryon was in most cases diploid. On the other hand, a dikaryotic strain derived by treatment with benomyl was haploid. These results suggest that diploid dikaryon is a normal nuclear phase ofH. mompa in nature, and the alternation of ploidy may be due to a feature of the mating system of this fungus.     

Nuclear selection in monokaryotic oidium formation from dikaryotic mycelia in a basidiomycete,Pholiota nameko

The effect of nuclear dominance in monokaryotic oidium formation from dikaryotic mycelia inPholiota nameko was examined. Over 90% of oidium isolates from dikaryotic mycelia were monokaryotic. Although only one parental nuclear type was recovered from an average of about 80% in these isolates, the nuclear selection process in oidium formation seems essentially to produce split nuclear type composition in oidium products. The hierarchy of relative dominance among the nuclear types of the parental dikaryons in monokaryotic oidium formation was determined. The two hierarchies in nuclear selection between monokaryotic oidium formation and monokaryotic mycelium formation coincided at a level of at least 75%.     

Characterization of the nematocidal toxocyst in <Emphasis Type="Italic">Pleurotus</Emphasis> subgen. <Emphasis Type="Italic">Coremiopleurotus</Emphasis>

Toxocysts of the genus Pleurotus are blastoconidia-like ovoid structures surrounded by a liquid droplet containing a toxin that paralyzes nematodes. This study investigated toxocyst development using a strain S396 of Pleurotus cystidiosus subsp. abalonus (subgen. Coremiopleurotus). The surface of the liquid droplet was found to be an elastic envelope. When a nematode touches the toxocyst, the envelope adheres to the worm and bursts. Toxocysts are induced simultaneously with coremia formation in the absence of nematodes and developed only from aerial hyphae in which nuclear division had ceased. In the early stage of toxocyst development, liquid springs repeatedly from the tip of the sterigma-like stipe before ovoid (blastoconidium-like structure) formation. A certain substance in the liquid might polymerize to form the envelope while the ovoid simultaneously budded in the droplet. The nucleus tends to locate near the toxocyst, especially in early stage of toxocyst development. Each dikaryotic cell predominantly formed one or two toxocyst(s) while each monokaryotic cell predominantly formed one. In rare cases, a nucleus existed in the toxocyst, suggesting the possibility that the toxocyst is a vestigial blastoconidium.     

Direct studies of dikaryotization in Schizophyllum commune

The growth, duplication and fate of multikaryotic hyphae bearing true clamp connections, as derived from compatible matings of Schizophyllum commune, were studied by phase contrast microscopy. The nuclei (N) of multikaryotic apices maintained a near central position during hyphal growth. True clamp connection formation occurred with near synchronous mitosis followed by septal synthesis across the clamp neck and main hyphal axis. Nuclear progeny after mitosis in a hexakaryon included 6 N in the apex, 1 N in the clamp and 5 N in the penultimate cell; the solitary nucleus in the clamp later entered the penultimate cell. Similar events occurred for clamp connection formation and mitosis in the trikaryon, quadrikaryon or pentakaryon, whether in the apex or primary branches. Nuclear content of the multikaryotic apex (2 N through 10 N) had no apparent effect on the rate of individual hyphal growth. Reduction of the nuclear number in a trikaryon occurred by long-term entrappment of a solitary nucleus in the clamp and subsequent outgrowth of the dikaryotic penultimate cell. Occasionally, more than one nucleus became entrapped in the clamp cell. The ephemeral nature of the multikaryon was indicated by the fact that older cultures appeared to be exclusively dikaryotic hyphae at the colony periphery.     

The central role of septa in the basidiomycete Schizophyllum commune hyphal morphogenesis

The purpose of the present research was to observe in the filamentous basidiomycete Schizophyllum commune, the connection between the nuclear division and polymerization of the contractile actin ring with subsequent formation of septa in living hyphae. The filamentous actin was visualized using Lifeact-mCherry and the nuclei with EGFP tagged histone 2B (H2B). Time-lapse fluorescence microscopy confirmed that in monokaryotic and dikaryotic hyphae, the first signs of the contractile actin ring occur at the site of the nuclear division, in one to two minutes after division. At this stage, the telophase nuclei have moved tens of micrometers from the division site. The actin ring is replaced by the septum in six minutes. The apical cells treated with filamentous actin disrupting drug latrunculin A, had swollen tips but the cells were longer than in control samples due to the absence of the actin rings. The nuclear pairing and association with clamp cell development as well as the clamp cell fusion with the subapical cell was disrupted in latrunculin-treated dikaryotic hyphae, indicating that actin filaments are involved in these processes, also regulated by the A and B mating-type genes. This suggests that the actin cytoskeleton may indirectly be a target for mating-type genes.     

Occurence of microtubules and microfilaments,and origin of septa in dikaryotic hyphae ofSchizophyllum commune

Summary In an electron microscopic study on the dikaryotic hyphae ofSchizophyllum commune, microtubules were observed during the nuclear division, and close to the non-dividing nuclei of apical cells and older cells. Microtubules of the spindle were connected with semicircular bodies at nuclear poles. Microfilaments were detected in the distal part of the apical cells. Vesicles similar to those in the tips of the hyphae occured also at the sites of septa formation. The occurrence of microtubules and the structure of semicircular bodies are compared with those in other basidiomycetes. It is suggested that vesicles are involved in the primary growth of the septal cross wall.     

CYTOLOGICAL STUDIES IN LACCARIA (AGARICALES). I. MEIOSIS AND POSTMEIOTIC MITOSIS

In the genus Laccaria, basidial formation, dikaryotic basidia, karyogamy, and meiosis were generally similar to structures and phenomena reported for other Agaricales. The haploid nuclei of dikaryotic basidia resided side by side in the basidium prior to karyogamy. Following karyogamy a single nucleolus was observed in L. montana (four-spored species); several nucleoli remained in the nucleus of L. tortilis (two-spored species). The haploid number of chromosomes for L. montana appeared to be n = 9. Postmeiotic mitosis typically occurred in the basidiospores resulting in binucleate basidiospores for four-spored species and quadrinucleate basidiospores for two-spored species. Postmeiotic mitosis sometimes occurred in the sterigmata and basidia proper. In instances where postmeiotic mitosis occurred in basidia, mature basidiospores were not formed and the basidia were collapsed, and contained up to eight nuclei.     

Meiotic division and fusion of nuclei in multinucleate cells from the induced fusion of meiotic protoplasts of liliaceous plants

Multinucleate protoplasts were produced from meiotic cells at the zygotene and pachytene stages in a lily andTrillium, and their meiotic divisions were followed during subsequent culture. In each multinucleate, a complete synchrony of nuclear division was maintained throughout the meiotic process, and chromosome behavior appeared normal up to the metaphase stage. In most dinucleates, chromosome segregation movement was organized in a common spindle, and the daughter nuclei at the telophase appeared to envelope each other in the newly formed nuclear membrane. The cell was divided into two daughter cells by a common cell plate. Trinucleates were similarly converted to two cells with a hexaploid number of chromosomes. Some of the di- and trinucleates subsequently completed the second meiotic division with the formation of typical tetrad configurations. In giant cells with more than several nuclei, chromosomes separated at random but reaggregated into one giant resting nucleus, with no later cytokinesis. The rate of meiotic development in multinucleates was relatively slower in cells which contained greater numbers of nuclei.     

NUCLEAR DIVISION IN THE DEVELOPING PYCNOSPORES OF MACROPHOMINA PHASEOLI

Nuclear behavior was studied in Giemsa-stained pycnidial material of Macrophomina phaseoli. The young pycnospore was at first uninucleate but repeated nuclear division occurred as it enlarged, and the mature spore was always multinucleate. The developing spore, therefore, provided a favorable site for observing mitosis. Noteworthy features were: (1) a metaphase characterized by a loss in stainability of the nucleolus and by the appearance of centrioles, spindle fibers and countable chromosomes; (2) a short early anaphase; (3) a long late anaphase with a broad band of interzonal fibers separating the daughter nuclei; (4) the occurrence of irregularities such as aneuploidy, chromosome bridge formation and chromosome lagging. The basic chromosome number was six. Following a study of Giemsa-stained cellophane cultures of the fungus it was concluded that the method of nuclear division in the vegetative hyphae is similar to that observed in the developing spores. Some comparisons are made with observations on nuclear division in the vegetative hyphae of other fungi.