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.     

Internuclear Genetic Transfer in Vegetative Dikaryons of SCHIZOPHYLLUM COMMUNE: I. Di-Mon Mating Analysis

A series of hemi-compatible dikaryon x monokaryon (di-mon) matings was designed to determine whether there was any genetic interaction between the dikaryotic nuclei. One of the nuclei in each dikaryon was known to carry a recessive gene (mnd) that promoted the development of an abnormal growth form, mound. Dikaryons containing both mnd ⁺ and mnd nuclei produced mosaic colonies that consisted of three distinct kinds of hyphae: mound, fruiting body, and vegetative (devoid of any multihyphal structure). When dikaryotic hyphae from each of these morphological regions were used in di-mon matings, the genetic and developmental characteristics of the selected nuclear types were examined in the resulting derived dikaryons. The results showed that fruiting-body and vegetative cells contained the expected mnd and mnd⁺ nuclei. Dikaryotic mound hyphae, however, contained only mnd nuclei. In a manner as yet unresolved, but clearly dependent on the presence of the mnd allele, the mnd ⁺ allele of a wild nucleus was altered to, or acquired, the mnd allele. A number of hypotheses were considered to explain the genetic event(s) that generates [mnd + mnd*] dikaryotic cells from [mnd⁺ + mnd] cells, but none was found to be entirely satisfactory.     

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%.     

Ribosomal DNA variation,recombination and inheritance in the basidiomycete Trichaptum abietinum: implications for reticulate evolution

Two divergent nuclear ribosomal DNA (nrDNA) types, designated alpha and beta, were found distributed in 11 North European populations of the basidiomycete Trichaptum abietinum. These types differed by a 220 bp indel in the internal transcribed spacer 1 (ITS1) sequence and a number of linked substitutions and small indel motives in the internal transcribed and intergenic spacers (ITS1, ITS2, IGS1 and IGS2). The alpha and beta haplotypes co-occurred in heterozygous somatic individuals (dikaryons) and segregated in a Mendelian fashion in monokaryotic single spore progenies. This result suggests that the haplotypes are encoded in different nuclei of field-collected dikaryons and inherited as a single locus. No meiotic recombinants were observed among the sequenced monokaryons. Population genetic analyses by PCR-RFLP revealed that a low frequency of evolutionary intermediate nrDNA types also existed in natural populations, presumably as a result of meiotic recombination of alpha and beta nrDNA. The existence of divergent nrDNA types in T. abietinum could be a result of a former independent evolution followed by a hybridization event. Phylogenetic analyses of ITS sequences suggest that the sister taxon T. fusco-violaceum has been involved in the evolutionary history of T. abietinum. Sequence polymorphisms observed in the translation elongation factor 1alpha (efa) and glyceraldehyde-3-phosphate dehydrogenase (gpd) genes, did not reveal two well-defined types of these genes. The results are discussed in the light of other evolutionary mechanisms as well.     

Sorosporium consanguineum: Relation between variable nuclear condition and dissociation

Saprophytic development of Sorosporium consanguineum and its nuclear cycle were studied on laboratory media. During vegetative reproduction, the nuclei of the monokaryotic sporidia were shown to first migrate into developing bud cells where division occurs, one nucleus returning to the parent cell prior to completion of cell division. Following fusion of sporidia of opposite mating type and subsequent formation of infection hyphae, dikaryons eventually dissociated, giving rise to sporidia of both sex groups in the process. As a result of dissociation, shown to occur in several ways, "satellite" sporidial colonies characteristically formed in advance of the parent colony and fusions again occurred between sporidia of opposite mating type. Reports of variable nuclear condition of mycelia in other species of smut fungi in culture are discussed in light of these findings.     

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     

Uncontrolled growth associated with novel somatic recombination in the fungus Schizophyllum

In the bracket mushroom, Schizophyllum commune, a recessive genetic alteration, mnd, causes abnormally hyperplastic three-dimensional mounds of hyphae to rise from the surface of both haploid and dikaryotic mycelia. mnd, although not a genetic block in the fruiting body developmental pathway, is at least partially epistatic to fruiting. Within dikaryons containing both mutant and wild-type nuclei, [mnd + mnd⁺], a nonreciprocal somatic recombination event can lead to stable conversion of the mnd⁺ region of the wild-type nucleus to mnd. This transformation to the homoallelic [mnd + mnd] condition involves no genomic areas other than the mnd region and permanently prevents any further fruiting. Studies relating to the recombination mechanism have ruled out a diploid intermediate state and other concomitants of orthodox somatic recombination, as well as whole chromosome transfer. Instead, a novel form of internuclear genetic transfer is postulated whereby a nearby locus, mob⁺, controls the mobilization of the mnd chromosomal region alone from one nucleus to the other within the binucleate cells of dikaryotic mycelia.     

Nuclear fusion,meiosis and the origin of dikaryotic hyphae in Armillariella mellea

The behaviour of nuclei during the growth and differentiation of basidiocarp primordia of Armillariella mellea (Vahl) Karst. is described. The primordial initials which arose from monokaryotic rhizomorphs were also monokaryotic. In older primordia, at the site of initiation of gill folds, multinucleate cells formed at the tips of monokaryotic hyphae and gave rise to the dikaryotic hyphae bearing clamp connections. These formed the gills of the older primordia. Cytological studies suggested that the nuclei in monokaryotic cells were diploid. In young basidial primordia haploidization occurred in the cells which were to become multinucleate prior to giving rise to dikaryotic hyphae of the gills. In mature basidia after nuclear fusion and meiosis had occurred, each of the four haploid daughter nucleic migrated into a basidiospore and then divided mitotically. One of the mitotic daughter nucleic migrated from each spore back into the basidium so that mature spores were uninucleate.Abbreviations M.T.O.C. microtubule organizing centre     

A new genetic element affecting somaticmnd recombination inSchizophyllum commune

Several spontaneous variants ofSchizophyllum commune, recovered both from unstable diploids and from meiotic progeny, have been found to prevent the conventional pattern of internuclear transfer of the recessive morphological markermnd. These variants, designatedmnd mob, still express the mound phenotype of unregulated hyperplasia in monokaryons and a modified mound phenotype in dikaryons homoallelic formnd. The high incidence ofmnd mob variants (ca. 2.5%) occurring among meiotic progeny of the crossmnd mob⁺ × mnd⁺ mob⁺, together with the failure to obtainmnd⁺ mob recombinants from crosses betweenmnd mob andmnd⁺ mob⁺, suggests some origin other than point mutation as the basis for generatingmnd mob variants. It is proposed thatmob⁺ is a transposable element closely linked to or withinmnd and that this element might be responsible for the internuclear transfer of themnd locus suggested to occur in the somaticmnd recombinations reported previously in [mnd + mnd⁺] dikaryons.     

Genetic evidence for nonrandom sorting of mitochondria in the basidiomycete Agrocybe aegerita.

We studied mitochondrial transmission in the homobasidiomycete Agrocybe aegerita during plasmogamy, vegetative growth, and basidiocarp differentiation. Plasmogamy between homokaryons from progeny of three wild-type strains resulted in bidirectional nuclear migration, and the dikaryotization speed was dependent on the nuclear genotype of the recipient homokaryon. Little mitochondrial migration accompanied the nuclear migration. A total of 75% of the dikaryons from the fusion lines had both parental mitochondrial haplotypes (mixed dikaryons), and 25% had only a single haplotype (homoplasmic dikaryons); with some matings, there was a strong bias in favor of one parental haplotype. We demonstrated the heteroplasmic nature of mixed dikaryons by (i) isolating and subculturing apical cells in micromanipulation experiments and (ii) identifying recombinant mitochondrial genomes. This heteroplasmy is consistent with the previously reported suggestion that there is recombination between mitochondrial alleles in A. aegerita. Conversion of heteroplasmons into homoplasmons occurred (i) during long-term storage, (ii) in mycelia regenerated from isolated apical cells, and (iii) during basidiocarp differentiation. Homokaryons that readily accepted foreign nuclei were the most efficient homokaryons in maintaining their mitochondrial haplotype during plasmogamy, long-term storage, and basidiocarp differentiation. This suggests that the mechanism responsible for the nonrandom retention or elimination of a given haplotype may be related to the nuclear genotype or the mitochondrial haplotype or both.     

The constitution of incompatibility factor and mating characteristics of spore isolates in a bipolar mushroom, <Emphasis Type="Italic">Pholiota nameko</Emphasis>

Pholiota nameko is a wood-rotting edible mushroom that carries a bipolar A incompatibility factor gene. The linkage analysis of the multiple allelomorphic A factor gene demonstrated that sexual reproduction produced a monospore isolate carrying a new A factor gene in addition to two parental mating types of isolates. However, 10%–30% of the modified monospore isolates could not produce a dikaryon with both of the parental monokaryons by crossing. It is concluded that the bipolar A incompatibility factor gene of P. nameko is constituted of two functional subunits, Aα and Aβ, which might be successively located beside each other with an apparent genetic distance of 0.3 centi-Morgan between them on the same chromosome. Further, some monospore isolates that did not conjugate with both parental monokaryons could produce dikaryons with different monokaryotic stocks with either one of the parental mating types. This result suggests that the crossing capability of these isolates were essentially those for one of the mating types of the parental monokaryons, but that their function for mating activity was made partially by unequal crossing-over in the process of sexual recombination. Received: May 1, 2001 / Accepted: December 5, 2001     

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 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.     

Control of extracellular slime accumulation in monokaryons and resultant dikaryons of Schizophyllum commune.

Extracellular slime accumulation, as alcohol-precipitable material was measured after eight days of growth in glucose-asparagine-salts broth in twenty-two different monokaryons and six resultant dikaryons of Schizophyllum commune. The nutritional control of slime accumulation was also examined in monokaryotic mycelium. Slime occurred after growth in sucrose, glucose, fructose and xylose, with glycerol best. Low inorganic phosphates limited both slime and mycelial growth while limiting MgSO4 decreased growth and enhanced slime. In glucose-asparagine broth, various monokaryons differed widely in slime accumulation, ranging from none (e.g., strain 19) to nearly 800 mg per 100 ml filtrate (strain 1) after eight days growth, followed by a marked decline in slime (eleven days to twenty-one days). Resultant dikaryons all showed less slime accumulation, even when established from two high slime-accumulating monokaryons. In contrast, conditions which arrested dikaryotic fruit-body morphogenesis led to increased slime accumulation.     

Fungal fidelity: Nuclear divorce from a dikaryon by mating or monokaryon regeneration

Basidiomycete fungi perform fertilizations by incorporation of nuclei into a monokaryotic mycelium to establish a dikaryon. The dikaryon cannot incorporate another type of nucleus, but can still act as a nucleus donor in a dikaryon–monokaryon (di–mon) mating, known as the Buller phenomenon. Previously, it has been observed that: (1) in a particular di–mon mating, one of the nuclear types of the dikaryon generally performs better as a donor than the other, and (2) when nuclei from a dikaryon are separated to form monokaryons again (dedikaryotisation), recovery of monokaryons of the two nuclear types is usually unequal. In this study, we investigated if these two observations of asymmetry are functionally related. We tested this hypothesis by performing both di–mon matings and dedikaryotisation of dikaryons derived from five different monokaryons. When a single mechanism controls both processes, the nucleus better at fertilizing a monokaryon in a Buller pairing should also be recovered upon dedikaryotisation with a higher frequency. The results showed a hierarchical structure for recovery among nuclei in dedikaryotisation, but this hierarchy did not correspond to the fertilization success during di–mon mating. These findings thus show that the mechanism causing asymmetric regeneration of nuclei, is most likely not the same as the mechanism responsible for increased chance of fertilization in di–mon matings. We discuss the complexity of the interactions that occur during di–mon matings with regards to the mating type loci.     

Mnd1/Hop2 facilitates Dmc1-dependent interhomolog crossover formation in meiosis of budding yeast

During meiosis, each chromosome must pair with its homolog and undergo meiotic crossover recombination in order to segregate properly at the first meiotic division. Recombination in meiosis in Saccharomyces cerevisiae relies on two Escherichia coli recA homologs, Rad51 and Dmc1, as well as the more recently discovered heterodimer Mnd1/Hop2. Meiotic recombination in S. cerevisiae mnd1 and hop2 single mutants is initiated via double-strand breaks (DSBs) but does not progress beyond this stage; heteroduplex DNA, joint molecules, and crossovers are not detected. Whereas hop2 and mnd1 single mutants are profoundly recombination defective, we show that mnd1 rad51, hop2 rad51, and mnd1 rad17 double mutants are able to carry out crossover recombination. Interestingly, noncrossover recombination is absent, indicating a role for Mnd1/Hop2 in the designation of DSBs for noncrossover recombination. We demonstrate that in the rad51 mnd1 double mutant, recombination is more likely to occur between repetitive sequences on nonhomologous chromosomes. Our results support a model in which Mnd1/Hop2 is required for DNA-DNA interactions that help ensure Dmc1-mediated stable strand invasion between homologous chromosomes, thereby preserving genomic integrity.     

Resource utilization of wood decomposers: mycelium nuclear phases and host tree species affect wood decomposition by Dacrymycetes

Throughout evolution, wood-decaying fungi have adapted to different woody plants, resulting in wide species diversity. Dacrymycetes, which are brown-rot fungi and include host-recurrent species, are useful for studying fungal adaptation to host trees. When estimating the decay abilities of basidiomycetes, the nuclear phases of the mycelium should be considered, since dikaryons are thought to be more efficient wood-decayers than monokaryons; however, the difference in their physiological performances remains largely untested. In this study, we verified the decay capabilities of dikaryotic and monokaryotic mycelia and tested the hypothesis that the host tree-recurrence of wood-decaying fungi results from their resource utilization in each host wood. The mass loss caused by eight dacrymycetous species from wood of four tree species was investigated in pure cultures. The decomposition ability of dikaryons was greater than that of monokaryons in these experiments. Dikaryotization is expected to raise certain physiological parameters, such as the quantity and variety of wood-decomposing enzymes, thus enhancing the decomposition rate of wood decomposers. The high decomposition ability of dikaryons suggests their superiority over monokaryons to survive under natural conditions. All dacrymycetous strains caused high mass loss from Pinus wood, the main host tree of Dacrymycetes. However, most of the individual tested strains did not cause the greatest mass loss from the wood of their original host group. This result suggested that host-recurrence can be partly explained by resource utilization, but it is likely that other micro-organisms and abiotic factors also affect host-recurrence in the field environment.     

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     

Relationship between monokaryotic growth rate and mating type in the edible basidiomycete Pleurotus ostreatus

The edible fungus Pleurotus ostreatus (oyster mushroom) is an industrially produced heterothallic homobasidiomycete whose mating is controlled by a bifactorial tetrapolar genetic system. Two mating loci (matA and matB) control different steps of hyphal fusion, nuclear migration, and nuclear sorting during the onset and progress of the dikaryotic growth. Previous studies have shown that the segregation of the alleles present at the matB locus differs from that expected for a single locus because (i) new nonparental B alleles appeared in the progeny and (ii) there was a distortion in the segregation of the genomic regions close to this mating locus. In this study, we pursued these observations by using a genetic approach based on the identification of molecular markers linked to the matB locus that allowed us to dissect it into two genetically linked subunits (matBalpha and matBbeta) and to correlate the presence of specific matBalpha and matA alleles with differences in monokaryotic growth rate. The availability of these molecular markers and the mating type dependence of growth rate in monokaryons can be helpful for marker-assisted selection of fast-growing monokaryons to be used in the construction of dikaryons able to colonize the substrate faster than the competitors responsible for reductions in the industrial yield of this fungus.     

Dikaryons of the basidiomycete fungus Schizophyllum commune: evolution in long-term culture

The impact of ploidy on adaptation is a central issue in evolutionary biology. While many eukaryotic organisms exist as diploids, with two sets of gametic genomes residing in the same nucleus, most basidiomycete fungi exist as dikaryons in which the two genomes exist in separate nuclei that are physically paired and that divide in a coordinated manner during hyphal extension. To determine if haploid monokaryotic and dikaryotic mycelia adapt to novel environments under natural selection, we serially transferred replicate populations of each ploidy state on minimal medium for 18 months (approximately 13,000 generations). Dikaryotic mycelia responded to selection with increases in growth rate, while haploid monokaryotic mycelia did not. To determine if the haploid components of the dikaryon adapt reciprocally to one another's presence over time, we recovered the intact haploid components of dikaryotic mycelia at different time points (without meiosis) and mated them with nuclei of different evolutionary histories. We found evidence for coadaptation between nuclei in one dikaryotic line, in which a dominant deleterious mutation in one nucleus was followed by a compensatory mutation in the other nucleus; the mutant nuclei that evolved together had the best overall fitness. In other lines, nuclei had equal or higher fitness when paired with nuclei of other histories, indicating a heterozygote advantage. To determine if genetic exchange occurs between the two nuclei of a dikaryon, we developed a 24-locus genotyping system based on single nucleotide polymorphisms to monitor somatic exchange. We observed genetic exchange and recombination between the nuclei of several different dikaryons, resulting in genotypic variation in these mitotic cell lineages.