Project description:The genes defining multiple B mating types in the wood-rotting mushroom Schizophyllum commune are predicted to encode multiple pheromones and pheromone receptors. These genes are clustered in each of two recombinable and independently functioning loci, B alpha and B beta. A difference in specificity at either locus between a mated pair of individuals initiates an identical series of events in sexual morphogenesis. The B alpha 1 locus was recently found to contain genes predicted to encode three lipopeptide pheromones and a pheromone receptor with a seven-transmembrane domain. These gene products interact in hetero-specific pairs, the pheromone of one B alpha specificity with the receptor of any one of the other eight B alpha specificities, and are likely to activate a signaling cascade similar to that known for mating in Saccharomyces cerevisiae. We report here that the B beta 1 locus also contains at least three pheromone genes and one pheromone receptor gene, which function similarly to the genes in the B alpha 1 locus, but only within the series of B beta specificities. A comparison of the DNA sequences of the B alpha 1 and B beta 1 loci suggests that each arose from a common ancestral sequence, allowing us to speculate about the evolution of this unique series of regulatory genes.

Project description:The A alpha mating locus is one of four multiallelic loci that govern sexual development in the basidiomycete fungus Schizophyllum commune. We have determined the nucleotide sequence encoding three A alpha mating types, A alpha 1, A alpha 3, and A alpha 4. We have found that the locus for A alpha 3 and A alpha 4 consists of two genes: Y and Z. The locus for A alpha 1 encodes only one gene, Y. The Z polypeptides encoded by different alleles exhibit 42% identity. The Y polypeptides exhibit 49-54% identity. The finding that the deduced Z and Y polypeptides have homeodomain motifs suggests that these polypeptides may be DNA-binding regulatory proteins that control the expression of developmental genes. The deduced Z polypeptide also has acidic regions that might be functionally analogous to the acidic regions in yeast GAL4 and GCN4 that activate transcription. The Y polypeptide has a serine-rich region and a basic region that shows some identity to the lysine-rich region of H1 histones.

Project description:Transcriptome changes associated with mating interactions were performed in order to identify signaling components and targets of pheromone response. Two monokaryons (S. commune 12-43 and 4-39), a dikaryon (W22 x 12-43), both semi-compatible mating interactions (Aon: W22 x 4-39; Bon, flat: W21 x 4-39), and different S. commune pheromone receptor recipient strains (Vbar2f, Vbar2t) were analyzed for that purpose. In addition, a S. commune strain showing the thin-phenotype (W22-thin) was investigated to figure out the role of Thn1 in mating.

Project description:The B mating-type locus of the tetrapolar basidiomycete Schizophyllum commune encodes pheromones and pheromone receptors in multiple allelic specificities. This work adds substantial new evidence into the organization of the B mating-type loci of distantly related S. commune strains showing a high level of synteny in gene order and neighboring genes. Four pheromone receptor-like genes were found in the genome of S. commune with brl1, brl2 and brl3 located at the B mating-type locus, whereas brl4 is located separately. Expression analysis of brl genes in different developmental stages indicates a function in filamentous growth and mating. Based on the extensive sequence analysis and functional characterization of brl-overexpression mutants, a function of Brl1 in mating is proposed, while Brl3, Brl4 and Brl2 (to a lower extent) have a role in vegetative growth, possible determination of growth direction. The brl3 and brl4 overexpression mutants had a dikaryon-like, irregular and feathery phenotype, and they avoided the formation of same-clone colonies on solid medium, which points towards enhanced detection of self-signals. These data are supported by localization of Brl fusion proteins in tips, at septa and in not-yet-fused clamps of a dikaryon, confirming their importance for growth and development in S. commune.

Project description:Transcriptome changes associated with mating interactions were performed in order to identify signaling components and targets of pheromone response. Two monokaryons (S. commune 12-43 and 4-39), a dikaryon (W22 x 12-43), both semi-compatible mating interactions (Aon: W22 x 4-39; Bon, flat: W21 x 4-39), and different S. commune pheromone receptor recipient strains (Vbar2f, Vbar2t) were analyzed for that purpose. In addition, a S. commune strain showing the thin-phenotype (W22-thin) was investigated to figure out the role of Thn1 in mating. With microarray analysis mRNA expression in different mating interactions of the basidiomycete S. commune was analyzed. Genes which show regulation in the comparison of the two monokaryons 12-43 and 4-39 has been eliminated from other comparisons as strain specific differences. Two biological or technical replicate samples were analyzed for each condition.

Project description: Not available

Project description:In this study, we undertook a functional characterization and transcriptome analysis that enabled a comprehensive study of the mating type loci of the mushroom Schizophyllum commune. Induced expression of both the bar2 receptor and the bap2(2) pheromone gene within 6 to 12 h after mates' contact was demonstrated by quantitative real-time PCR. Similar temporal expression patterns were confirmed for the allelic bbr1 receptor and bbp1 pheromone-encoding genes by Northern hybridization. Interestingly, the fusion of clamp connections to the subterminal cell was delayed in mating interactions in which one of the compatible partners expressed the bar2 receptor with a truncated C terminus. This developmental delay allowed the visualization of a green fluorescent protein (Gfp)-labeled truncated receptor at the cell periphery, consistent with a localization in the plasma membrane of unfused pseudoclamps. This finding does not support hypotheses envisioning a receptor localization to the nuclear membrane facilitating recognition between the two different nuclei present in each dikaryotic cell. Rather, Gfp fluorescence observed in such pseudoclamps indicated a role of receptor-pheromone interaction in clamp fusion. Transcriptome changes associated with mating interactions were analyzed in order to identify a role for pheromone-receptor interactions. We detected a total of 89 genes that were transcriptionally regulated in a mating type locus A-dependent manner, employing a cutoff of 5-fold changes in transcript abundance. Upregulation in cell cycle-related genes and downregulation of genes involved in metabolism were seen with this set of experiments. In contrast, mating type locus B-dependent transcriptome changes were observed in 208 genes, with a specific impact on genes related to cell wall and membrane metabolism, stress response, and the redox status of the cell.

Project description:The Aalpha mating-type locus of Schizophyllum commune regulates sexual development and contains the code for two proteins, Y and Z, which are thought to form a complex and function as a transcription factor. Import of these proteins into the nucleus may be an essential step in Aalpha-regulated sexual development. The Y proteins contain a bipartite basic sequence, which is an excellent candidate for a nuclear localization sequence (NLS), while Z proteins contain no such sequence. Here we describe experiments in which deletions were made in the putative NLS sequence of Y4. We show that this putative NLS is essential to the function of the Y protein and capable of mislocalizing green fluorescent protein (GFP) to the nucleus in Saccharomyces cerevisiae. Further, we describe genetic experiments that demonstrate the first Y-Y protein interactions in vivo. These results are consistent with our previously postulated hypothesis that the Y-Z complex is likely to be of a higher order than dimer.

Project description:Tha A alpha locus of the basidiomycete fungus, Schizophyllum commune, regulates sexual development via proteins Y and Z. Each A alpha mating type encodes unique Y and Z isoforms. We used two isoforms of Y (Y4 and Y5) and two isoforms of Z (Z4 and Z5) in affinity assays of protein binding. These assays identified two types of protein interactions. Each full-length Y or Z protein binds to itself and other Y or Z proteins regardless of the A alpha mating type from which they are encoded (i.e., mating-type independent binding). A second type of binding, detected with partial-length polypeptides, occurs only between N-terminal regions of Y and Z proteins encoded from different A alpha mating types (e.g., Y4Z5 or Y5Z4); we refer to this binding as mating-type dependent binding. Deletion analysis shows that the Y4 specificity domain (an N-terminal region conferring recognition uniqueness to the Y4 isoform) is essential for mating-type dependent binding. Other regions of Y and Z are involved in mating-type independent binding. These results, obtained in vitro, raise the possibility that either of several protein complexes composed of Y and/or Z proteins may occur in vivo.

Project description:When many gametes compete to fertilize a limited number of compatible gametes, sexual selection will favour traits that increase competitive success during mating. In animals and plants, sperm and pollen competition have yielded many interesting adaptations for improved mating success. In fungi, similar processes have not been shown directly yet. We test the hypothesis that sexual selection can increase competitive fitness during mating, using experimental evolution in the mushroom-forming fungus Schizophyllum commune (Basidiomycota). Mating in mushroom fungi occurs by donation of nuclei to a mycelium. These fertilizing 'male' nuclei migrate through the receiving 'female' mycelium. In our setup, an evolving population of nuclei was serially mated with a non-evolving female mycelium for 20 sexual generations. From the twelve tested evolved lines, four had increased and one had decreased fitness relative to an unevolved competitor. Even though only two of those five remained significant after correcting for multiple comparisons, for all five lines we found a correlation between the efficiency with which the female mycelium is accessed and fitness, providing additional circumstantial evidence for fitness change in those five lines. In two lines, fitness change was also accompanied by increased spore production. The one line with net reduced competitive fitness had increased spore production, but reduced fertilisation efficiency. We did not find trade-offs between male reproductive success and other fitness components. We compare these findings with examples of sperm and pollen competition and show that many similarities between these systems and nuclear competition in mushrooms exist.