Investigation of Mitochondrial Transmission in Selected Matings between Homokaryons from Commercial and Wild-Collected Isolates of Agaricus bisporus (= Agaricus brunnescens)

Ten heterokaryons of Agaricus bisporus (= Agaricus brunnescens) were shown to carry four different mitochondrial (mt) genotypes by analysis of mt restriction fragment length polymorphisms (RFLPs). Fifteen homokaryons derived from these strains were used to investigate mt inheritance in A. bisporus. One hundred eighty-nine pairings were performed in 25 different combinations. Pairings in 15 different combinations produced heterokaryons on the basis of nuclear RFLP analyses and/or fruiting trials. The mt genotype of each new intraspecies hybrid was examined by using mt RFLPs as genetic markers. Our results suggest the following. (i) Recombination between the mt genomes was not a common event. (ii) From most individual pairings, all heterokaryons carried the same mt genotype. (iii) Heterokaryons carrying either of the two possible mt genotypes were observed in certain crosses after modification of the pairing procedure. A biparental transmission pattern was demonstrated for some crosses, but there appears to be a preference for one of the mt genotypes to predominate in any specific pairing.     

Localization of the Mating Type Gene in Agaricus bisporus

The cultivated mushroom Agaricus bisporus is secondarily homothallic. Most basidia produce two basidiospores, each of which receives two of the four postmeiotic nuclei. Usually, the two packaged nuclei carry compatible mating types. Previous studies suggested that there may be only a single mating type locus in A. bisporus. In this study, we determined whether the mating type segregated as a single Mendelian determinant in a cross marked with 64 segregating molecular markers. To score mating types, each of the 52 homokaryotic offspring from this cross was paired with each of the two progenitor homokaryons. Compatible matings were identified by the formation of genetically stable heterokaryons which were verified by assay of restriction fragment length polymorphisms (RFLPs). Data for screening mycelial interactions on petri plates as well as fruit body formation were compared with the RFLP results. Mating types of 43 of the 52 homokaryotic offspring were determined on the basis of RFLP analysis. Our results indicate (i) there is a segregating mating type gene in A. bisporus, (ii) this mating type gene is on the largest linkage group (chromosome I), (iii) mycelial interactions on petri plates were associated with heterokaryon formation under selected conditions, (iv) fruit body formation was dependent upon the mating type gene, and (v) compatible mating types may not always be sufficient for fruiting.     

Analysis of Inbreeding Depression in Agaricus Bisporus

Inbreeding depression was observed in the commercial button mushroom, Agaricus bisporus, by examining two laboratory populations. The outbred population consisted of 20 compatible pairings, 10 homokaryons with each of the homokaryons Ag1-1 and Ag89-65. The inbred population consisted of 104 backcrosses (among which 52 were expected to be sexually compatible) obtained from the pairings of two progenitor homokaryons, Ag1-1 and Ag89-65, with 52 progeny homokaryons derived from the mating between Ag1-1 and Ag89-65. The eight fitness components examined for these two populations were successful matings as identified by the analysis of restriction fragment length polymorphisms, positive mycelial interaction in these successful matings, heterokaryon growth rate, primordium formation by the successful matings, fertile fruiting body formation, time to first break, average number of fruiting bodies per square foot, and average weight per fruiting body. The outcrossed population showed a significant advantage over the inbred population in three of eight fitness components. Two pairs of traits were significantly correlated. The multiplicative fitness ratio of the inbred to the outcrossed population was 0.18. The relevance of inbreeding depression to the evolution of fungal mating systems and to mushroom breeding is discussed.     

Trikaryon formation and nuclear selection in pairings between heterokaryons and homokaryons of the root rot pathogen Heterobasidion parviporum

Pairings between heterokaryons and homokaryons of Agaricomycete fungi (he-ho pairings) can lead to either heterokaryotization of the homokaryon or displacement of the homokaryotic nucleus through migration of nuclei from the heterokaryon into the homokaryon. In species of Agaricomycetes with multinucleate cells (>2 nuclei per cell), he-ho pairings could result in the stable or transient formation of a hypha with three genetically different nuclei (trikaryons). In this study, he-ho pairings were conducted using the multinucleate Agaricomycete Heterobasidion parviporum to determine whether trikaryons can be formed in the laboratory and whether nuclear genotype affects migration and heterokaryon formation. Nuclei were tracked by genotyping the heterokaryotic mycelium using nucleus-specific microsatellite markers. The data indicated that certain nuclear combinations were favored, and that nuclei from some strains had a higher rate of migration. A high percentage of trikaryons (19 %) displaying three microsatellite alleles per locus were identified among subcultures of the he-ho pairings. Using hyphal tip and conidial isolation, we verified that nuclei of three different mating types can inhabit the same mycelium, and one of the trikaryotic strains was judged to be semi-stable over multiple sub-culturing steps, with some hyphal tips that retained three alleles and others that reduced to two alleles per locus. These results demonstrate that nuclear competition and selection are possible outcomes of heterokaryon-homokaryon interactions in H. parviporum and confirm that ratios of component nuclei in heterokaryons are not strictly 1:1. The high rate of trikaryon formation in this study suggests that fungi with multinucleate cells may have the potential for greater genetic diversity and recombination relative to dikaryotic fungi.     

Homokaryons are more combative than heterokaryons of Hericium coralloides

The homokaryotic stage of the basidiomycete lifecycle is generally considered to be short lived, although there is little experimental evidence relating to their longevity in the field. The vast majority of studies on basidiomycete ecology have used only heterokaryons. The few investigations comparing related homokaryons and heterokaryons have revealed no overall trend in differences of extension rate, wood decay or competitive ability. For a rare species the homokaryotic phase may be of greater importance than in common species as it is likely to last longer. Hericium coralloides, a rare wood decay basidiomycete, was used to investigate differences between homokaryons and heterokaryons in terms of extension rate and combative ability. Fifteen homokaryons from three fruit bodies and five heterokaryons (obtained by fruit body tissue isolation) were compared at 5–35 °C on malt agar for extension rate, and paired against heterokaryons of 13 wood decay species to assess combative ability. Homokaryons were paired to create ten artificial heterokaryons whose extension rate at 10 and 20 °C was compared to parental rates. There were some significant differences in extension rates between homokaryons and natural heterokaryons, between homokaryons and heterokaryons created artificially from homokaryons, and between homokaryons from different fruit bodies, but no consistent trends. Homokaryons proved more combative than heterokaryons, which was assessed quantitatively as well as qualitatively using a scoring system for outcome of each pairing. Results are discussed in relation to previous findings and in an ecological context.     

Interspecific competitive ability of homokaryotic and heterokaryotic wood decay basidiomycetes

The role of the homokaryotic life stage in the dynamics of fungal communities is relatively unknown. However, homokaryons are thought to be only a temporary stage and are therefore not generally used in ecological experiments with fungi. In this study, the relative competitive ability and growth rates of homokaryons and heterokaryons of wood decay fungi were tested to assess the potential role of homokaryons in community dynamics. A homokaryon and a heterokaryon of each of four species (Aleurodiscus lividocoeruleus, Peniophora sp. 1, Peniophora sp. 2 and Pereniporia medulla‐panis) were assessed for their competitive abilities on an agar medium. The relationship between nuclear status and competitive ability varied between species. The homokaryon of Peniophora sp. 2 was competitively superior to its heterokaryon, whereas the homokaryon of Peniophora sp. 1 was inferior to its heterokaryon. A hierarchy of competitive abilities of each isolate revealed that Pereniporia medulla‐panis homokaryon = P. medulla‐panis heterokaryon > Peniophora sp. 1 heterokaryon > Peniophora sp. 2 homokaryon > Peniophora sp. 2 heterokaryon > A. lividocoeruleus heterokaryon = A. lividocoeruleus homokaryon. This experiment indicates that homokaryons as well as heterokaryons have the potential to influence community structure through competitive effects.     

ISSR as New Markers for Identification of Homokaryotic Protoclones of Agaricus bisporus

To accelerate the breeding of Agaricus bisporus, quick and reliable methods to identify the infrequent homokaryons are necessary. A new marker, inter simple sequence repeat (ISSR) fingerprinting, is described for differentiation of homo- and hetero-karyotic protoclones. Nine slow growing protoclones, two strandy and seven appressed, were analyzed for the first time with ISSR amplifications. The patterns were highly polymorphic and very reproducible. Among 40 primers tested, 7 ISSR primers were selected for the analysis of genomic DNA and generated a total of 68 ISSR fragments. ISSR fingerprinting detected 44.12% polymorphic loci. All appressed homokaryons carried a subset of ISSR markers found in the heterokaryons, and clustered separately in dendrogram. These were not able to produce a fruiting body. A test of cross-fertility and the following fruiting trial proved that 7 of the 9 protoclones with different ISSR fingerprints were homokaryons. These results demonstrated that ISSR markers provide an efficient alternate for identification of homokaryons and suggest these markers be considered as new tools for the survey of Agaricus species.     

Heterokaryon formation with homokaryons derived from protoplasts ofRhizoctonia solani anastomosis group eight

Homokaryons were successfully recovered by regenerating protoplasts prepared from vegetative hyphae of field isolates ofRhizoctonia solani anastomosis group (AG) 8, the causal pathogen of bare-patch disease of cereals. A mating type incompatibility system, which is similar to that reported in AG 1 and AG 4, was demonstrated in AG 8. All homokaryons obtained in AG 8 were able to form tufts with their parent isolates and other heterokaryotic field isolates of AG 8 tested. Heterokaryons were readily recovered from tufts of pairing of certain homokaryon combinations. The synthesized heterokaryons formed tufts with both of the contributing homokaryons. The majority of hyphal tip cultures isolated from tufts resembled one of the contributing homokaryons. These nonheterokaryotic hyphae in tufts are attributed to transient heterokaryon effects.     

Expression and distribution of vimentin and keratin filaments in heterokaryons of human fibroblasts and amnion epithelial cells

The expression of intermediate filaments of the keratin- and the vimentin-type was studied in heterokaryons of human fibroblasts and amnion epithelial cells by immunofluorescence microscopy. Fibroblasts and their homokaryons showed a fibrillar, vimentin-specific fluorescence throughout the cytoplasm but were negative when stained for keratin. Amnion epithelial cells and their homokaryons, on the other hand, showed a keratin-specific fibrillar staining, and only some of them contained also detectable vimentin. When suspended epithelial cells were fused with adherent fibroblasts, keratin fibrils spread within 3 h into the fibroblasts, intermixing with the vimentin fibrils. 1-3 d after fusion, both vimentin and keratin filaments were expressed as typical fibrillar cytoplasmic arrays, and the distribution of keratin in heterokaryons resembled closely that of vimentin. A typical cell-to-cell arrangement of keratin fibrils, seen in cultures of amnion epithelial cells, could also be found between heterokaryons. Treatment of the cultures with vinblastine sulphate induced coiling of the vimentin filaments in both homo- and heterokaryons, whereas the keratin organization was only slightly affected. Our results show that both vimentin and keratin filaments are incorporated into the cytoskeleton of heterokaryons formed between fibroblasts and epithelial cells, and that they behave in the same way as in their parental cells. Both epithelial and fibroblastic characteristics thus appear to the coexpressed in such heterokaryons.     

MUTATIONS AFFECTING HETEROKARYOSIS IN SCHIZOPHYLLUM COMMUNE

Mutations that affect the basic characteristics of heterokaryons of S. commune occur spontaneously and are preferentially selected in the common-A heterokaryon and in its homokaryotic mimics, strains carrying a mutated B factor or strains disomic for heteroallelic B factors. Nine independent mutations were compared: all segregate independently of A and B incompatibility factors, and at least 3 distinct loci, of which 2 are linked, are involved. None of the mutations is phenotypically expressed in the homokaryon or in the common-AB heterokaryon. All 9 mutations increase vegetative vigor of the common-A the effects of all the mutations are additive in both heteroallelic and homoallelic combinations. At least 1 type-II mutation also affects nuclear distribution in common-B heterokaryons. Type-II mutations appear to reduce common-A, common-B, and compatible heterokaryons to a single type unlike any of the normal heterokaryons. Pseudoclamping often persists for extended periods in modified homokaryons isolated from modified heterokaryons. Several cases of somatic recombination have been observed among components of modified heterokaryons.     

Role of a cell-wall glucan-degrading enzyme in mating of Schizophyllum commune

Mycelial enzyme extracts of Schizophyllum commune were prepared during vegetative growth matings leading to common-A and common-B heterokaryons and the dikaryon, and were examined for hydrolytic activity against an alkaliinsoluble cell-wall glucan (R-glucan) isolated from this mushroom. In extracts from several individual homokaryotic mycelia the R-glucanase activity was low and did not increase when the cultures exhausted glucose in the medium. In common-A matings, a 30-fold increase in specific activity of intracellular R-glucanase was found even in the presence of glucose in the broth. An increase of this magnitude was not observed in the common-B mating nor in the fully compatible cross leading to the dikaryon. Extracts of the dikaryon did show elevated R-glucanase activity after exogenous glucose disappearance and subsequent fruiting. In none of these situations was an enzyme activity detected towards an alkali-soluble cell-wall glucan (S-glucan) prepared from S. commune. Changes in R-glucanase were not parallelled by identical changes in laminarinase, pustulanase, cellobiase, and p-nitrophenyl-beta-d-glucosidase, but comparable increases in specific activities were found for hydrolysis of glycogen and maltose. After interaction of the various mycelia in mating combinations, the S-glucan/R-glucan ratio of the cell wall of the dikaryon was found to be similar to that of the homokaryons, but increased in the common-B interaction and was elevated almost threefold in the common-A heterokaryon.     

Mitochondrial Haplotype Influences Mycelial Growth of Agaricus bisporus Heterokaryons

We evaluated the influence of mitochondrial haplotype on growth of the common button mushroom Agaricus bisporus. Ten pairs of heterokaryon strains, each pair having the same nuclear genome but different mitochondrial genomes, were produced by controlled crosses among a group of homokaryons of both wild and commercial origins. Seven genetically distinct mitochondrial DNA (mtDNA) haplotypes were evaluated in different nuclear backgrounds. The growth of heterokaryon pairs differing only in their mtDNA haplotypes was compared by measuring mycelial radial growth rate on solid complete yeast medium (CYM) and compost extract medium and by measuring mycelial dry weight accumulation in liquid CYM. All A. bisporus strains were incubated at temperatures similar to those utilized in commercial production facilities (18, 22, and 26(deg)C). Statistically significant differences were detected in 8 of the 10 heterokaryon pairs evaluated for one or two of the three growth parameters measured. Some heterokaryon pairs showed differences in a single growth parameter at all three temperatures of incubation, suggesting a temperature-independent difference. Others showed differences at only a single temperature, suggesting a temperature-dependent difference. The influence of some mtDNA haplotypes on growth was dependent on the nuclear genetic background. Our results show that mtDNA haplotype can influence growth of A. bisporus heterokaryons in some nuclear backgrounds. These observations demonstrate the importance of including a number of mitochondrial genotypes and evaluating different nuclear-mitochondrial combinations of A. bisporus in strain improvement programs.     

Fibronectin expression is determined by the genotype of the transformed parental cells in heterokaryons between normal and transformed fibroblasts

The expression of fibronectin, a cell surface-associated transformation-sensitive glycoprotein, was studied in hetero- and homokaryons of normal and SV40-transformed human fibroblasts. In immunofluorescence, fibroblast homokaryons had an intense surface-associated and intracelluar fibronectin fluorescence similar to that of normal fibroblasts. Transformed cells and their homokaryons had a minimal surface-associated and a weak intracellular fibronectin fluorescence. In heterokaryons formed between transformed and normal fibroblasts, the expression of fibronectin fell within 24 h to the level of the transformed cell homokaryons. The change was detectable already at 3 h after fusion and was gene-dose dependent. These results show that the transformed genotype determines fibronectin expression in the heterokaryons.     

Mating System and Basidiospore Formation in the Lignin-Degrading Basidiomycete Phanerochaete chrysosporium

Prototrophic strains recovered from crosses between auxotrophic strains of the lignin-degrading basidiomycete Phanerochaete chrysosporium were induced to fruit. The progeny of most of these self-crosses were prototrophic, indicating that the nuclei of the original prototroph were wild-type recombinants rather than complementary heterokaryons and that the binucleate basidiospores of this organism are homokaryotic. Various wild-type strains were shown to have multinucleate cells lacking clamp connections and to possess a variable number of sterigmata per basidium. Colonies arising from single conidia of various wild-type strains were all capable of producing fruit bodies and basidiospores. In addition, single basidiospores from three wild-type strains all produced fruit bodies and basidiospores. Nonfruiting as well as fruiting isolates were obtained from single basidiospores of five other wild-type strains. Basidiospores from these fruiting isolates always yielded colonies that fruited, again indicating that the spores are homokaryotic. Nonfruiting isolates from the same strain did not produce basidiospores when allowed to form a heterokaryon, implying that these isolates do not represent mating types. All this evidence indicates that P. chrysosporium has a primary homothallic mating system. In addition to fruiting and nonfruiting phenotypes, basidiospores from strain OGC101, a derivative of ME-446, gave rise to colonies which did not grow on cellulose (Cel⁻). The fruiting, nonfruiting, and Cel⁻ phenotypes differed from each other and from the parental wild-type strain in a variety of characteristics, including growth, conidiation, and evolution of ¹⁴CO₂ from ¹⁴C-side chain-labeled lignin, indicating that strain OCG101 is a heterokaryon.     

Globin synthesis in fibroblasts fused with erythroblasts. II. Human fibroblasts.

Fusion of human (diploid) fibroblast monolayers with erythroblasts from 3-day chick embryos resulted in cultures containing on the average 14% heterokaryons and 8% fibroblast homokaryons. When these heterokaryon-containing cultures were labeled with radioactive amino acids during the first 24 h after fusion, the proportion of labeled proteins found in the globin region of analytical polyacrylamide gels showed a 40-fold increase compared with fibroblast homokaryons (0.08% vs. 4% of protein synthesized). Incorporation of radioactivity into globin decreased sharply during the second 24 h. Purified 35S-methionine-labeled globin from heterokaryon cultures gave rise to a tryptic fingerprint containing peptides characteristic of chick embryonic globins as late as 4 days after fusion. While fibroblasts in the fusion culture continue to go through the cell cycle normally, heterokaryons stop cycling almost completely soon after fusion.     

Heterosis among lines of mice selected for body weight

Summary After treatment of one strain of A. bitorquis and 12 strains of A. bisporus in modified monokaryotization solution, three types of mycelia were received: one is the original di- or heterokaryon, the other two were proven to be neohaplonts in A. bitorquis and two strains of A. bisporus. In neohaplonts of good fruiting strains, homokaryotic fruiting was observed.     

Genetics and QTL mapping of somatic incompatibility and intraspecific interactions in the basidiomycete Heterobasidion annosum s.l

Somatic incompatibility (SI) is a system by which filamentous fungi can distinguish self from non-self by delimiting the own mycelia from that of other individuals of the same species. In this study, we show that SI in the basidiomycete Heterobasidion annosum sensu lato is controlled by four loci by observing the frequency of somatically compatible pairings in two experiments where isolates were paired in all possible combination. The first experiment utilized 63 heterokaryons each with one unique nucleus chosen from an array of sibling homokaryons paired with one unrelated nucleus of homokaryotic isolate TC-39-7. The second experiment used 39 heterokaryons each with one unique nucleus from the array of sibling homokaryons backcrossed with one of the parental strains (TC-122-12). We observed that SI allelic differences in a pairing alone are not enough to determine the degree of somatic incompatibility. In the first experiment, we also observed other interactions such as hyphal walls in interaction zones, increased exudation of dark-coloured metabolites and increased production of aerial hyphae. QTLs for the respective traits were positioned to a genetic linkage map of the H. annosum genome. Map-based cloning of the corresponding loci will shed much new light on intraspecific interactions in basidiomycetes.     

An expanded genetic linkage map of an intervarietal Agaricus bisporus var. bisporus × A. bisporus var. burnettii hybrid based on AFLP,SSR and CAPS markers sheds light on the recombination behaviour of the species

A genetic linkage map for the edible basidiomycete Agaricus bisporus was constructed from 118 haploid homokaryons derived from an intervarietal A. bisporus var. bisporus × A. bisporus var. burnettii hybrid. Two hundred and thirty-one AFLP, 21 SSR, 68 CAPS markers together with the MAT, BSN, PPC1 loci and one allozyme locus (ADH) were evenly spread over 13 linkage groups corresponding to the chromosomes of A. bisporus. The map covers 1156 cM, with an average marker spacing of 3.9 cM and encompasses nearly the whole genome. The average number of crossovers per chromosome per individual is 0.86. Normal recombination over the entire genome occurs in the heterothallic variety, burnettii, contrary to the homothallic variety, bisporus, which showed adaptive genome-wide suppressed recombination. This first comprehensive genetic linkage map for A. bisporus provides foundations for quantitative trait analyses and breeding programme monitoring, as well as genome organisation studies.     

Fusion and hybridization of marsupial and eutherian cells. Heterokaryon formation

Marsupial x eutherian cell hybrids would be very useful for studies of mammalian genetics and cell biology. A critical step in the formation of such hybrids is the fusion of cells to form heterokaryons. We have examined many different combinations of marsupial and eutherian cells for their ability to fuse, and we have found that all combinations yielded heterokaryons, but with different frequencies, depending on the cell types used. Ranked in order of decreasing ability to fuse with eutherian cells, the marsupial cell types were; established lines, primary diploid fibroblasts and lymphocytes. In all fusion experiments there was a marked preference for the formation of homokaryons compared with heterokaryons. It was possible to control the numbers and types of heterokaryons formed by varying the input ratio of parental cells.     

DNA polymorphisms in commercial and wild strains of the cultivated mushroom,Agaricus bisporus

Summary DNA from the cultivated mushroom, Agaricus bisporus, was cloned into the bacteriophage lambda vector EMBL3 creating a partial genomic library. Ten random clones from the library were used to probe for restriction fragment length polymorphisms (RFLPs). Six of the ten probes detected polymorphisms and were used to demonstrate variation in wild and cultivated strains of the mushroom. These results suggest that RFLPs could form a basis for genetic finger-printing and subsequent strain protection in A. bisporus. In single spore progeny, RFLPs were used to demonstrate normal meiotic segregation and to differentiate between homokaryons and heterokaryons. RFLPs therefore have great potential in the development of the genetics and breeding of this commercially important species.