Two genes specifically expressed in fruiting dikaryons of Schizophyllum commune: homologies with a gene not regulated by mating-type genes

The nucleotide (nt) sequences of the Sc3 and Sc4 genes of the filamentous fungus Schizophyllum commune, and the deduced amino acid (aa) sequences, were determined; moreover, the previously published sequence for the ScI gene [Dons et al., EMBO J. 3 (1984) 2101–2106] was corrected. All three independently isolated genes were found to have similar structures and nt sequences of their coding regions. At the aa level the homology is 43–62% (63–69% in the C-terminal parts of the proteins), the hydrophobic aa predominate and the hydrophobicity patterns are similar. All three proteins contain leader sequences and eight cysteines among about 110 aa, conserved at the same positions. Yet these genes are differentially regulated: Sc1 and Sc4 are only expressed at high levels in fruiting dikaryons, whereas Sc3 is highly expressed in both monokaryons and dikaryons, independent from fruiting.     

RNA-Mediated Gene Silencing in Monokaryons and Dikaryons of Schizophyllum commune

Disruption of genes by homologous recombination occurs at a low frequency in the basidiomycete Schizophyllum commune. For instance, the SC3 and SC15 genes were inactivated at frequencies of 1 and 5%, respectively. As an alternative to disruption, we used gene silencing through the introduction of a hairpin construct. The SC15 gene, which encodes an abundantly secreted structural protein, was silenced at a frequency of 80% in monokaryons of S. commune after introduction of a hairpin construct of the gene. Silencing also occurred in dikaryons in which one of the partners was not a silenced strain. The silencing mechanism resembles RNAi in other filamentous fungi and is a powerful tool for the functional analysis of genes expressed in monokaryons or dikaryons.     

Two genes specifically expressed in fruiting dikaryons of Schizophyllum commune: homologies with a gene not regulated by mating-type genes

The nucleotide (nt) sequences of the Sc3 and Sc4 genes of the filamentous fungus Schizophyllum commune, and the deduced amino acid (aa) sequences, were determined; moreover, the previously published sequence for the ScI gene [Dons et al., EMBO J. 3 (1984) 2101–2106] was corrected. All three independently isolated genes were found to have similar structures and nt sequences of their coding regions. At the aa level the homology is 43–62% (63–69% in the C-terminal parts of the proteins), the hydrophobic aa predominate and the hydrophobicity patterns are similar. All three proteins contain leader sequences and eight cysteines among about 110 aa, conserved at the same positions. Yet these genes are differentially regulated: Sc1 and Sc4 are only expressed at high levels in fruiting dikaryons, whereas Sc3 is highly expressed in both monokaryons and dikaryons, independent from fruiting.     

SC3 and SC4 hydrophobins have distinct roles in formation of aerial structures in dikaryons of Schizophyllum commune

Two monokaryons of Schizophyllum commune can form a fertile dikaryon when the mating-type genes differ. Monokaryons form sterile aerial hyphae, while dikaryons also form fruiting bodies that function in sexual reproduction. The SC3 hydrophobin gene is expressed both in monokaryons and in dikaryons. The SC4 hydrophobin is dikaryon specific. In the monokaryon, SC3 lowers the water surface tension, coats aerial hyphae with a hydrophobic layer and mediates attachment of hyphae to hydrophobic surfaces. The SC4 protein lines gas channels within fruiting bodies with a hydrophobic membrane. Using gene disruptions, in this study, we show that in dikaryons SC3 fulfils the same roles as in monokaryons. SC4, on the other hand, has a role within fruiting bodies. In contrast to gas channels in fruiting bodies of the wild type, those of a DeltaSC4 strain easily filled with water. Thus, SC4 prevents gas channels filling with water under wet conditions, probably serving uninterrupted gas exchange. Other dikaryon-specific hydrophobin genes, SC1 and SC6, apparently do not substitute for the SC4 gene. In addition, by expressing the SC4 gene behind the SC3 promoter in a DeltaSC3 monokaryon, it was shown that SC4 cannot fully substitute for SC3, indicating that both hydrophobins evolved to fulfil specific functions.     

Characterization of Serine Proteinase Expression in Agaricus bisporus and Coprinopsis cinerea by Using Green Fluorescent Protein and the A. bisporus SPR1 Promoter

The Agaricus bisporus serine proteinase 1 (SPR1) appears to be significant in both mycelial nutrition and senescence of the fruiting body. We report on the construction of an SPR promoter::green fluorescent protein (GFP) fusion cassette, pGreen_hph1_SPR_GFP, for the investigation of temporal and developmental expression of SPR1 in homobasidiomycetes and to determine how expression is linked to physiological and environmental stimuli. Monitoring of A. bisporus pGreen_hph1_SPR_GFP transformants on media rich in ammonia or containing different nitrogen sources demonstrated that SPR1 is produced in response to available nitrogen. In A. bisporus fruiting bodies, GFP activity was localized to the stipe of postharvest senescing sporophores. pGreen_hph1_SPR_GFP was also transformed into the model basidiomycete Coprinopsis cinerea. Endogenous C. cinerea proteinase activity was profiled during liquid culture and fruiting body development. Maximum activity was observed in the mature cap, while activity dropped during autolysis. Analysis of the C. cinerea genome revealed seven genes showing significant homology to the A. bisporus SPR1 and SPR2 genes. These genes contain the aspartic acid, histidine, and serine residues common to serine proteinases. Analysis of the promoter regions revealed at least one CreA and several AreA regulatory motifs in all sequences. Fruiting was induced in C. cinerea dikaryons, and fluorescence was determined in different developmental stages. GFP expression was observed throughout the life cycle, demonstrating that serine proteinase can be active in all stages of C. cinerea fruiting body development. Serine proteinase expression (GFP fluorescence) was most concentrated during development of young tissue, which may be indicative of high protein turnover during cell differentiation.     

Isolation and characterization of a sporeless mutant in Pleurotus eryngii

A sporeless mutant dikaryon, completely defective in sporulation, was isolated from mycelial protoplasts of Pleurotus eryngii mutagenized by UV irradiation. Newly established dikaryons between one component monokaryon from the mutant, and 12 different wild type monokaryons from 3 other wild type dikaryons, all exhibited the sporeless phenotype, whereas those between the other monokaryon and the same wild type monokaryons all produced normal fruiting bodies. These results indicated that the sporeless mutation was induced in one of two nuclei of the mutant and was dominant. In the wild type basidia, the pattern of nuclear behavior during sporulation corresponded to the pattern C nuclear behavior as defined by Duncan and Galbraith. Cytological observation revealed that in the sporeless mutant meiosis was blocked at the meta-anaphase I in most basidia and hence basidiospores and sterigmata were not produced. Although fruiting bodies of the sporeless mutant showed a somewhat leaning growth, their gross morphology and its fruiting body productivity were comparable to that of the original wild type strain. Based on these results, it was considered that the sporeless mutant could serve as a potential material in breeding of sporeless P. eryngii commercial strains.     

Meiotic-like Recombination in Vegetative Dikaryons of SCHIZOPHYLLUM COMMUNE

A total of 65 Schizophyllum commune dikaryons of three different genotypes were synthesized, maintained on agar plates, prevented from fruiting, and macerated. The macerate was plated. Germlings of homokaryotic morphology were isolated using no chemical or genetic selection, grown, and tested for recombinant genotypes. Crossover types were plentiful among the homokaryons with recombinant genotypes, indicating that meiotic-like processes in vegetative dikaryons are common and may be as important as conventional basidial meiosis in the origin of recombinant strains.     

RNA-mediated gene silencing in monokaryons and dikaryons of Schizophyllum commune

Disruption of genes by homologous recombination occurs at a low frequency in the basidiomycete Schizophyllum commune. For instance, the SC3 and SC15 genes were inactivated at frequencies of 1 and 5%, respectively. As an alternative to disruption, we used gene silencing through the introduction of a hairpin construct. The SC15 gene, which encodes an abundantly secreted structural protein, was silenced at a frequency of 80% in monokaryons of S. commune after introduction of a hairpin construct of the gene. Silencing also occurred in dikaryons in which one of the partners was not a silenced strain. The silencing mechanism resembles RNAi in other filamentous fungi and is a powerful tool for the functional analysis of genes expressed in monokaryons or dikaryons.     

Functional complementation between the two homologous genes, ops and tps, during differentiation of Myxococcus xanthus

Summary Protein S is a development-specific protein of Myxococcus xanthus encoded by the tps gene. It has been shown that there are two extensively homologous genes (ops and tps) tandemly repeated in the same direction with a 1.4 kb spacer fragment between them (Inouye et al. 1983). Seven deletion mutants were constructed by removing the ops gene, the tps gene, segments of the spacer sequence or combinations of these regions. The deleted regions were replaced with DNA fragments carrying the Tn5 gene for kanamycin resistance.The effects of deleting different regions on morphological changes and on patterns of protein synthesis during fruiting body formation were examined. The process of fruiting body formation was severely delayed when both the ops and the tps genes were deleted. However, this delay could be suppressed by either the ops gene or the tps gene, individually, although in the latter case, a slight delay was still observed. These results indicate that the ops gene is expressed during fruiting body formation and plays a role in the normal program of M. xanthus differentiation. Furthermore, the role of the ops gene can be complemented by the tps gene. The deletion of the ops and/or tps genes had no effect on glycerol-spore formation.     

Isolation and characterization of a sporeless mutant in <Emphasis Type="Italic">Pleurotus eryngii</Emphasis>

 A sporeless mutant dikaryon, completely defective in sporulation, was isolated from mycelial protoplasts of Pleurotus eryngii mutagenized by UV irradiation. Newly established dikaryons between one component monokaryon from the mutant, and 12 different wild type monokaryons from 3 other wild type dikaryons, all exhibited the sporeless phenotype, whereas those between the other monokaryon and the same wild type monokaryons all produced normal fruiting bodies. These results indicated that the sporeless mutation was induced in one of two nuclei of the mutant and was dominant. In the wild type basidia, the pattern of nuclear behavior during sporulation corresponded to the pattern C nuclear behavior as defined by Duncan and Galbraith. Cytological observation revealed that in the sporeless mutant meiosis was blocked at the meta-anaphase I in most basidia and hence basidiospores and sterigmata were not produced. Although fruiting bodies of the sporeless mutant showed a somewhat leaning growth, their gross morphology and its fruiting body productivity were comparable to that of the original wild type strain. Based on these results, it was considered that the sporeless mutant could serve as a potential material in breeding of sporeless P. eryngii commercial strains. Received: September 5, 2002 / Accepted: October 16, 2002 Acknowledgments We are grateful to Mrs. Motoe Masuda for her skillful technical assistance. Contribution no. 358 from the Tottori Mycological Institute Correspondence to:Y. Obatake     

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.     

Genetical variability of glutamate dehydrogenase activity in monokaryotic and dikaryotic mycelia of the ectomycorrhizal fungus Hebeloma cylindrosporum

Summary Glutamate dehydrogenase (GDH) is the key enzyme of ammonium assimilation by ectomycorrhizal fungi. Its activity might be use as a criterion to select mycelia capable of enhancing the nitrogen nutrition of the host plants. Genetical variability of the GDH activity of the ectomycorrhizal fungus Hebeloma cylindrosporum Romagnési was studied in an attempt to determine if this enzyme activity could be improved by way of chromosomal genetics. The activity of 11 wild strains was compared with that of 70 mycelia obtained as the progeny of a laboratory fruiting strain HC1. These 70 mycelia were 20 monokaryons (5 for each mating type) and the 50 synthesized dikaryons obtained from all the compatible fusions between these monokaryons. The specific GDH activity of the 11 wild strains ranged from 1.5 to 11.6 nkat mg^-1 fungal protein. The activity of the monokaryotic progeny of the HC1 strain was, on average, three times lower (2.85 n kat mg^-1 fungal protein) than that of the parental dikaryon. In contrast, synthesized dikaryons originating from these monokaryons were very variable and had an average values similar to that of the parental dikaryon (9.1 nkat mg^-1 fungal protein). Eighteen of these synthesized dikaryons contained an activity higher than that of the original HC1 strain. The variation of the GDH activity of these dikaryons involves additive and non additive (interactive) components, each of them accounting for ca. 50% of the genetical variation. The non additive variation could not be explained by a model involving only dominance. These results are discussed with reference to the genetical improvement of mycorrhizal fungi in order to enhance nitrogen nutrition of the host plants.Abbreviations GDH glutamate dehydrogenase - IAA indole-3-acetic acid - NADP nicotimamide adenine dinucleotide phosphate     

Production of extracellular β-1,3-/β-1,6-glucan by mono- and dikaryons ofSchizophyllum commune

From the dikaryotic mycelium ofSchizophyllum commune ATCC 38548 several monokaryotic strains were obtained by isolating the two types of monokaryotic protoplasts and their reversion to hyphal growth. The dikaryoticS. commune ATCC 38548 produced about 10 g/liter of extracellular β-1,3-/β-1,6-glucan (schizophyllan) after 96 h of growth, while the monokaryons excreted much less of this polysaccharide. During growth of strains of both types of monokaryons indigo and β-1,3-glucanase activities were excreted. Two selected monokaryons were mated with other monokaryoticS. commune strains and some of the dikaryotic mycelia obtained produced about 12 g/liter of extracellular β-1,3-/β-1,6-glucan after 120 h of cultivation.     

The A mating-type genes of the mushroom Coprinus cinereus are not differentially transcribed in monokaryons and dikaryons

Summary The A mating type factor of Coprinus cinereus regulates part of a developmental sequence that leads to the conversion of the asexual monokaryon into the fertile dikaryon. The A42 factor is a complex of seven genes, at least four of which are involved in determining the specificity of mating interactions. In this report we show that the A42 genes are constitutively expressed in both monokaryons and dikaryons. This has important implications with respect to intracellular recognition of a compatible mating, which requires an interaction between proteins already present within the cells of the mating partners, and for the subsequent maintenance of dikaryotic growth.