Patricia J. Pukkila

The genome of Laccaria bicolor provides insights into mycorrhizal symbiosis

Mycorrhizal symbioses—the union of roots and soil fungi—are universal in terrestrial ecosystems and may have been fundamental to land colonization by plants. Boreal, temperate and montane forests all depend on ectomycorrhizae. Identification of the primary factors that regulate symbiotic development and metabolic activity will therefore open the door to understanding the role of ectomycorrhizae in plant development and physiology, allowing the full ecological significance of this symbiosis to be explored. Here we report the genome sequence of the ectomycorrhizal basidiomycete Laccaria bicolor (Fig. 1) and highlight gene sets involved in rhizosphere colonization and symbiosis. This 65-megabase genome assembly contains ∼20,000 predicted protein-encoding genes and a very large number of transposons and repeated sequences. We detected unexpected genomic features, most notably a battery of effector-type small secreted proteins (SSPs) with unknown function, several of which are only expressed in symbiotic tissues. The most highly expressed SSP accumulates in the proliferating hyphae colonizing the host root. The ectomycorrhizae-specific SSPs probably have a decisive role in the establishment of the symbiosis. The unexpected observation that the genome of L. bicolor lacks carbohydrate-active enzymes involved in degradation of plant cell walls, but maintains the ability to degrade non-plant cell wall polysaccharides, reveals the dual saprotrophic and biotrophic lifestyle of the mycorrhizal fungus that enables it to grow within both soil and living plant roots. The predicted gene inventory of the L. bicolor genome, therefore, points to previously unknown mechanisms of symbiosis operating in biotrophic mycorrhizal fungi. The availability of this genome provides an unparalleled opportunity to develop a deeper understanding of the processes by which symbionts interact with plants within their ecosystem to perform vital functions in the carbon and nitrogen cycles that are fundamental to sustainable plant productivity.

Insights into evolution of multicellular fungi from the assembled chromosomes of the mushroom Coprinopsis cinerea (Coprinus cinereus)

The mushroom Coprinopsis cinerea is a classic experimental model for multicellular development in fungi because it grows on defined media, completes its life cycle in 2 weeks, produces some 108 synchronized meiocytes, and can be manipulated at all stages in development by mutation and transformation. The 37-megabase genome of C. cinerea was sequenced and assembled into 13 chromosomes. Meiotic recombination rates vary greatly along the chromosomes, and retrotransposons are absent in large regions of the genome with low levels of meiotic recombination. Single-copy genes with identifiable orthologs in other basidiomycetes are predominant in low-recombination regions of the chromosome. In contrast, paralogous multicopy genes are found in the highly recombining regions, including a large family of protein kinases (FunK1) unique to multicellular fungi. Analyses of P450 and hydrophobin gene families confirmed that local gene duplications drive the expansions of paralogous copies and the expansions occur in independent lineages of Agaricomycotina fungi. Gene-expression patterns from microarrays were used to dissect the transcriptional program of dikaryon formation (mating). Several members of the FunK1 kinase family are differentially regulated during sexual morphogenesis, and coordinate regulation of adjacent duplications is rare. The genomes of C. cinerea and Laccaria bicolor, a symbiotic basidiomycete, share extensive regions of synteny. The largest syntenic blocks occur in regions with low meiotic recombination rates, no transposable elements, and tight gene spacing, where orthologous single-copy genes are overrepresented. The chromosome assembly of C. cinerea is an essential resource in understanding the evolution of multicellularity in the fungi.

Unusual organization and lack of recombination in the ribosomal RNA genes of Coprinus cinereus.

SummaryWe find three interesting characteristics of the genes encoding the ribosomal RNA (rRNA) in the basidiomycete Coprinus cinereus. First, there are only 60 to 90 copies of the genes, fewer than in other fungi. Second, the genes are organized in an unusual arrangement. The 5S rRNA genes are located in the repeat unit which encodes the other rRNAs and all four rRNAs are transcribed in the same direction. Third, meiotic recombination is inhibited within the ribosomal DNA.

Polymorphisms in DNA of Coprinus cinereus.

SummaryTwo types of DNA sequence polymorphisms were found among different geographic isolates of the basidiomycete fungus Coprinus einereus. These strains showed gains and losses of restriction enzyme recognition sites as well as extensive insertion/ deletion variation within DNA sequences present in a single copy per haploid genome. The same types of DNA sequence variants were also found within the tandemly repeated ribosomal RNA genes in these strains. There appears to be very little interspersed repetitive DNA in Coprinus, since all the randomly selected cloned DNA sequences studied in this survey were present only once in each haploid genome.

Silver staining of meiotic chromosomes in the fungus, Coprinus cinereus

We have taken advantage of the synchronous meiotic process in the basidiomycete Coprinus cinereus to develop a simple and rapid method to selectively stain meiotic chromosomes and nucleoli in this fungus without prior removal of the cell wall. Electron microscopic examination of these silver-stained chromosomes indicated that the lateral elements of the synaptonemal complexes were prominently stained, and terminal attachment plaques were apparent. We found that a translocation quadrivalent could be recognized easily in the light microscope using these methods. The procedures appear suitable for the characterization of chromosome rearrangements in this small genome, and should facilitate cytogenetic analysis in this fungus.

Coptinus cinereus: an ideal organism for studies of genetics and developmental biology

All stages of the life cycle of the basidiomycete fungus Coprinus cinereus are readily cultured, and the organism is easy and safe to manipulate. It is representative of many other filamentous microorganisms and provides opportunity to demonstrate microbiological techniques with an amenable organism which can also be used to illustrate gene segregations, and cytological, biochemical, and morphological aspects of the morphogenesis of the highly differentiated mushroom fruit bodies.

QIP, a Protein That Converts Duplex siRNA Into Single Strands, is Required for Meiotic Silencing by Unpaired DNA

RNA interference (RNAi) depends on the production of small RNA to regulate gene expression in eukaryotes. Two RNAi systems exist to control repetitive selfish elements in Neurospora crassa. Quelling targets transgenes during vegetative growth, whereas meiotic silencing by unpaired DNA (MSUD) silences unpaired genes during meiosis. The two mechanisms require common RNAi proteins, such as RNA-directed RNA polymerases, Dicers, and Argonaute slicers. We have previously demonstrated that, while Quelling depends on the redundant dicer activity of DCL-1 and DCL-2, only DCL-1 is required for MSUD. Here, we show that QDE-2-interacting protein (QIP), an exonuclease that is important for the production of single-stranded siRNA during Quelling, is also required for MSUD. QIP is crucial for sexual development and is shown to colocalize with other MSUD proteins in the perinuclear region.

2 Meiotic Sister Chromatid Recombination

Publisher Summary This chapter focuses on meiotic recombination occurring after DNA synthesis. Meiotic recombination is usually analyzed by detecting new linkage relationships between two or more heterozygous markers. The chapter also focuses on sister chromatid exchanges, which are invisible to this type of analysis, because exchange between two identical DNA molecules does not alter linkage relationships. The chapter also discusses the genetic and cytogenetic evidence that sister chromatid meiotic recombination events occur. Various properties of sister chromatid exchange with “classical” recombination events are compared. Two types of recombination are discussed—crossovers and gene conversions. Distinctions between these types of exchange are most easily made in organisms in which all four products of meiosis can be analyzed. In tetrads derived from a diploid with linked markers A and B on one homologue and a and b on the other, a single crossover between the markers results in two spores with markers in the parental configurations ( AB and ab) and two markers with markers in the recombinant configurations ( Ab and aB ). Each marker examined individually shows 2:2 segregation within the tetrad.

Biased inheritance of optional insertions following mitochondrial genome recombination in the basidiomycete fungus Coprinus cinereuss

SummaryTwo mitochondrial genomes of Coprinus cinereus, H and J, were found to have alternative 1.23 kb insertions. Using the Neurospora crassa cytochrome oxidase-1 (co-1) gene as a probe, the “J” insertion site was shown to be located within the Coprinus co-1 gene, whereas the “H” insertion was some 2 kb distant. The insertions showed biased inheritance following mitochondrial genome recombination. Recombination between H and J genomes was detected using the mitochondrial gene mutations acu-10, which causes a cytochrome oxidase defect, and cap-1, which confers chloramphenicol resistance. Fourteen of fifteen independently derived recombinants for these two genes were shown to have both DNA insertions. In a second series of H x J crosses, intragenic recombination between different cap-1 alleles was detected. These mutations are assumed to be in the large ribosomal RNA gene some 6 kb distant from the nearest insertion site. Each of eight independently derived cap-1+ recombinants had both DNA insertions. Despite their similar size and similar behaviour following recombination the insertions do not share extensive sequence homology.

Analysis of the Basidiomycete Coprinopsis cinerea Reveals Conservation of the Core Meiotic Expression Program over Half a Billion Years of Evolution

Coprinopsis cinerea (also known as Coprinus cinereus) is a multicellular basidiomycete mushroom particularly suited to the study of meiosis due to its synchronous meiotic development and prolonged prophase. We examined the 15-hour meiotic transcriptional program of C. cinerea, encompassing time points prior to haploid nuclear fusion though tetrad formation, using a 70-mer oligonucleotide microarray. As with other organisms, a large proportion (∼20%) of genes are differentially regulated during this developmental process, with successive waves of transcription apparent in nine transcriptional clusters, including one enriched for meiotic functions. C. cinerea and the fungi Saccharomyces cerevisiae and Schizosaccharomyces pombe diverged ∼500-900 million years ago, permitting a comparison of transcriptional programs across a broad evolutionary time scale. Previous studies of S. cerevisiae and S. pombe compared genes that were induced upon entry into meiosis; inclusion of C. cinerea data indicates that meiotic genes are more conserved in their patterns of induction across species than genes not known to be meiotic. In addition, we found that meiotic genes are significantly more conserved in their transcript profiles than genes not known to be meiotic, which indicates a remarkable conservation of the meiotic process across evolutionarily distant organisms. Overall, meiotic function genes are more conserved in both induction and transcript profile than genes not known to be meiotic. However, of 50 meiotic function genes that were co-induced in all three species, 41 transcript profiles were well-correlated in at least two of the three species, but only a single gene (rad50) exhibited coordinated induction and well-correlated transcript profiles in all three species, indicating that co-induction does not necessarily predict correlated expression or vice versa. Differences may reflect differences in meiotic mechanisms or new roles for paralogs. Similarities in induction, transcript profiles, or both, should contribute to gene discovery for orthologs without currently characterized meiotic roles.