Loss of EZH2-like or SU(VAR)3-9-like proteins causes simultaneous perturbations in H3K27 and H3K9 tri-methylation and associated developmental defects in the fungus Podospora anserina.

BACKGROUND: Selective gene silencing is key to development. It is generally accepted that H3K27me3-enriched heterochromatin maintains transcriptional repression established during early development and regulates cell fate. Conversely, H3K9me3-enriched heterochromatin prevents differentiation but constitutes protection against transposable elements. We exploited the fungus Podospora anserina, a valuable alternative to higher eukaryote models, to question the biological relevance and functional interplay of these two distinct heterochromatin conformations. RESULTS: We established genome-wide patterns of H3K27me3 and H3K9me3 modifications, and found these marks mutually exclusive within gene-rich regions but not within repeats. We generated the corresponding histone methyltransferase null mutants and showed an interdependence of H3K9me3 and H3K27me3 marks. Indeed, removal of the PaKmt6 EZH2-like enzyme resulted not only in loss of H3K27me3 but also in significant H3K9me3 reduction. Similarly, removal of PaKmt1 SU(VAR)3-9-like enzyme caused loss of H3K9me3 and substantial decrease of H3K27me3. Removal of the H3K9me binding protein PaHP1 provided further support to the notion that each type of heterochromatin requires the presence of the other. We also established that P. anserina developmental programs require H3K27me3-mediated silencing, since loss of the PaKmt6 EZH2-like enzyme caused severe defects in most aspects of the life cycle including growth, differentiation processes and sexual reproduction, whereas loss of the PaKmt1 SU(VAR)3-9-like enzyme resulted only in marginal defects, similar to loss of PaHP1. CONCLUSIONS: Our findings support a conserved function of the PRC2 complex in fungal development. However, we uncovered an intriguing evolutionary fluidity in the repressive histone deposition machinery, which challenges canonical definitions of constitutive and facultative heterochromatin.

Mutations in mating-type genes of the heterothallic fungus Podospora anserina lead to self-fertility.

The heterothallic fungus Podospora anserina has two mating-type alleles termed mat+ and mat-. The mat+ sequence contains one gene, FPR1, while mat- contains three genes: FMR1, SMR1, and SMR2. FPR1 and FMR1 are required for fertilization, which is followed by mitotic divisions of the two parental nuclei inside the female organ. This leads to the formation of plurinucleate cells containing a mixture of parental mat+ and mat- nuclei. Further development requires a recognition between mat+ and mat- nuclei before migration of the mat+/mat- pairs into specialized hyphae in which karyogamy, meiosis, and ascospore formation take place. FPR1, FMR1, and SMR2 control this internuclear recognition step. Initial development of the dikaryotic stage is supposed to require SMR1; disruption of SMR1 results in barren perithecia. In a systematic search for suppressors restoring fertility, we isolated 15 suppressors-all of them mutations in the mating-type genes. These fmr1, smr2, and fpr1 mutants, as well as the strains disrupted for FMR1, SMR2, and FPR1, are weakly self-fertile. They are able to act as the male partner on a strain of the same mating type and give a mixture of biparental and uniparental progeny when crossed with a wild-type strain of opposite mating type. These observations lead us to propose that SMR2, FMR1, and FPR1 act as activators and repressors of fertilization and internuclear recognition functions.

pah1: a homeobox gene involved in hyphal morphology and microconidiogenesis in the filamentous ascomycete Podospora anserina.

Homeobox-containing genes are widely described among eukaryotic species other than filamentous ascomycetes. We describe here the isolation and characterization of the first homeobox gene (pah1) identified in a filamentous ascomycete. It encodes a putative protein of 610 amino acids containing a typical homeodomain with 60 amino acids. Deletion of the pah1 gene enhances the number of male gametes (microconidia), whereas overexpression of pah1 results in a decrease in microconidia. These results led us to suppose that pah1 may be a repressor of genes involved in the microconidiation process. Moreover, pah1 is involved in hyphal branching and possibly in the development of female organs.

Co-expression of the mating-type genes involved in internuclear recognition is lethal in Podospora anserina.

In the heterothallic filamentous fungus Podospora anserina, four mating-type genes encoding transcriptional factors have been characterized: FPR1 in the mat+ sequence and FMR1, SMR1, and SMR2 in the alternative mat- sequence. Fertilization is controlled by FPR1 and FMR1. After fertilization, male and female nuclei, which have divided in the same cell, form mat+/mat- pairs during migration into the ascogenous hyphae. Previous data indicate that the formation of mat+/mat- pairs is controlled by FPR1, FMR1, and SMR2. SMR1 was postulated to be necessary for initial development of ascogenous hyphae. In this study, we investigated the transcriptional control of the mat genes by seeking mat transcripts during the vegetative and sexual phase and fusing their promoter to a reporter gene. The data indicate that FMR1 and FPR1 are expressed in both mycelia and perithecia, whereas SMR1 and SMR2 are transcribed in perithecia. Increased or induced vegetative expression of the four mat genes has no effect when the recombined gene is solely in the wild-type strain. However, the combination of resident FPR1 with deregulated SMR2 and overexpressed FMR1 in the same nucleus is lethal. This lethality is suppressed by the expression of SMR1, confirming that SMR1 operates downstream of the other mat genes.

Internuclear recognition: A possible connection between euascomycetes and homobasidiomycetes.

In the heterothallic Euascomycete Podospora anserina, fertilization is followed by mitotic divisions of parental nuclei, resulting in a plurinucleate stage. Nuclei of opposite mating type then recognize one another and form dikaryons which undergo karyogamy and meioisis. The internuclear recognition is a characteristic feature of the sexual cycle of filamentous Euascomycetes and is controlled by mating-type genes. These genes encode transcription factors which have nucleus-limited expression. It is assumed that this characteristic allows nuclei of different mating type to express a pattern of specific proteins directly involved in internuclear recognition. As the molecular nature of these proteins is unknown, the exact mechanism of internuclear recognition remains elusive. Schuurs et al. (1998) have proposed that internuclear distance affects gene expression through a pheromone/receptor system in the Homobasidiomycete Schizophyllum commune. This model can be applied to internuclear recognition in P. anserina and can account for all data resulting from genetic analyses.

A homologue of the yeast SHE4 gene is essential for the transition between the syncytial and cellular stages during sexual reproduction of the fungus Podospora anserina.

The Podospora anserina cro1 gene was identified as a gene required for sexual sporulation. Crosses homozygous for the cro1-1 mutation yield fruiting bodies which produce few asci due to the formation of giant plurinucleate cells instead of dikaryotic cells after fertilization. This defect does not impair karyogamy, but meioses of the resultant polyploid nuclei are most often abortive. Cytological studies suggest that the primary defect of the mutant is its inability to form septa between the daughter nuclei after each mitosis, a step specific for normal dikaryotic cell divisions. The cro1-1 mutant would thus be unable to leave the syncytial vegetative state while abiding by the meiotic programme. cro1-1 also shows defects in ascospore germination and growth rate. GFP-tagging of the CRO1 protein reveals that it is a cytosolic protein mainly expressed at the beginning of the dikaryotic stage and at the time of ascospore maturation. The CRO1 protein exhibits significant similarity to the SHE4 protein, which is required for asymmetric mating-type switching in budding yeast cells. Thus, a gene involved in asymmetric cell divisions in a unicellular organism plays a key role at the transition between the syncytial (vegetative) state and the cellular (sexual) state in a filamentous fungus.

Mating types and sexual development in filamentous ascomycetes.

The progress made in the molecular characterization of the mating types in several filamentous ascomycetes has allowed us to better understand their role in sexual development and has brought to light interesting biological problems. The mating types of Neurospora crassa, Podospora anserina, and Cochliobolus heterostrophus consist of unrelated and unique sequences containing one or several genes with multiple functions, related to sexuality or not, such as vegetative incompatibility in N. crassa. The presence of putative DNA binding domains in the proteins encoded by the mating-type (mat) genes suggests that they may be transcriptional factors. The mat genes play a role in cell-cell recognition at fertilization, probably by activating the genes responsible for the hormonal signal whose occurrence was previously demonstrated by physiological experiments. They also control recognition between nuclei at a later stage, when reproductive nuclei of each mating type which have divided in the common cytoplasm pair within the ascogenous hyphae. How self is distinguished from nonself at the nuclear level is not known. The finding that homothallic species, able to mate in the absence of a partner, contain both mating types in the same haploid genome has raised more issues than it has resolved. The instability of the mating type, in particular in Sclerotinia trifolorium and Botrytinia fuckeliana, is also unexplained. This diversity of mating systems, still more apparent if the yeasts and the basidiomycetes are taken into account, clearly shows that no single species can serve as a universal mating-type model.

What is a bona fide mating-type gene? Internuclear complementation of mat mutants in Podospora anserina.

In the heterothallic ascomycete Podospora anserina, the mating-type locus is occupied by two mutually exclusive sequences termed mat+ and mat-. The mat+ sequence contains only one gene, FPR1, while the mat- sequence contains three genes: FMR1, SMR1 and SMR2. Previous studies have demonstrated that FPR1 and FMR1 are required for fertilization. Further analyses have led to the hypothesis that mat+ and mat- genes establish a mat+ and mat- nuclear identity, allowing recognition between nuclei of opposite mating type within the syncytial cells formed after fertilization. This hypothesis was based on the phenotypes of strains bearing mutations in ectopic mat genes. Here we present an analysis of mutations in resident mat- genes which suggests that, unlike FMR1 and SMR2, SMR1 is not involved in establishing nuclear identity. In fact, mutations in these two genes impair nuclear recognition, leading to uniparental progeny, while mutations in SMR1 block the sexual process, probably at a step after nuclear recognition. The nuclear identity hypothesis has also been tested through internuclear complementation tests. In these experiments, the mat- mutants were crossed with a mat+ strain carrying the wild-type mat- genes. Our rationale was that internuclear complementation should not be possible for nuclear identity genes: the relevant genes should show nucleus-restricted expression, and diffusion of their products to other nuclei should not occur. This test confirmed that SMR1 is not a bona fide mat gene since it can fulfill its function whatever its location, in either a mat- or a mat+ nucleus, and even when present in both nuclei. SMR2, but not FMR1, behaves like a nuclear identity gene with respect to internuclear complementation tests. A model is proposed that tentatively explains the ambiguous behaviour of the FMR1 gene and clarifies the respective functions of the three mat- proteins.

Altered mating-type identity in the fungus Podospora anserina leads to selfish nuclei, uniparental progeny, and haploid meiosis.

In wild-type crosses of the filamentous ascomycete Podospora anserina, after fertilization, only nuclei of opposite mating type can form dikaryons that undergo karyogamy and meiosis, producing biparental progeny. To determine the role played by the mating type in these steps, the four mat genes were mutagenized in vitro and introduced into a strain deleted for its mat locus. Genetic and cytological analyses of these mutant strain, crossed to each other and to wild type, showed that mating-type information is required for recognition of nuclear identity during the early steps of sexual reproduction. In crosses with strain carrying a mating-type mutation, two unusual developmental patterns were observed: monokaryotic cells, resulting in haploid meiosis, and uniparental dikaryotic cells providing, after karyogamy and meiosis, a uniparental progeny. Altered mating-type identity leads to selfish behavior of the mutant nucleus: it migrates alone or paired, ignoring its wild-type partner in all mutant x wild-type crosses. This behavior is nucleus-autonomous because, in the same cytoplasm, the wild-type nuclei form only biparental dikaryons. In P. anserina, mat genes are thus required to ensure a biparental dikaryotic state but appear dispensable for later stages, such as meiosis and sporulation.

The mat- allele of Podospora anserina contains three regulatory genes required for the development of fertilized female organs.

In the filamentous fungus Podospora anserina, mating type is specified by a single locus with two alternate alleles, termed mat- and mat+. A previous study has shown that the mat+ sequence consists of 3.7 kb and contains a single gene relevant to the sexual cycle. This gene, called FPR1, encodes a protein with a HMG DNA-binding domain and is required for fertilization and for the development of the fertilized fruiting body. The mat- sequence, which is 4.7 kb in length, displays a more complex structure. We present here the characterization of two genes, called SMR1 and SMR2, which are present in the mat- allele along with the FMR1 gene. FMR1, whose role in the sexual cycle has been already partially described, encodes a protein with an alpha 1-domain and was shown to control fertilization. We demonstrate that these three genes are required for the developmental events that occur in the female organ after fertilization. The additional role of FMR1 requires a region of unknown function that is distinct from the alpha 1-domain. SMR1 encodes a protein with a putative acidic/hydrophobic alpha-helix, which has been proposed to be a feature common to transcriptional activators. The protein sequence deduced from SMR2 contains an HMG motif suggesting that it is a transcription factor.

The mating types of Podospora anserina: functional analysis and sequence of the fertilization domains.

The two idiomorphic alleles called mat+ and mat-, which control the mating types in Podospora anserina, have been cloned. Mat+ and mat- encompass 3.8 kb and 4.7 kb respectively, of unrelated DNA sequences flanked by common sequences. Subcloning allowed the identification and localization in each locus of the gene that controls fertilization, probably by determining the mating type. The mat+ gene, called FPR1, encodes a protein with a potential DNA-binding HMG domain. The presence of this motif suggests that the FPR1 polypeptide may act as a transcriptional factor. The mat- gene called FMR1 encodes a protein containing a motif that is also found in proteins controlling mating functions in Saccharomyces cerevisiae and Neurospora crassa. The role of this motif has not yet been established. Unlike the mat+ locus, where the FPR1 gene seems to represent the major information, the mat- locus contains information necessary for the post-fertilization steps of the sexual cycle besides the FMR1 gene.

Cloning the mating types of the heterothallic fungus Podospora anserina: developmental features of haploid transformants carrying both mating types.

DNAs that encode the mating-type functions (mat+ and mat-) of the filamentous fungus Podospora anserina were cloned with the use of the mating-type A probe from Neurospora crassa. Cloning the full mat information was ascertained through gene replacement experiments. Molecular and functional analyses of haploid transformants carrying both mating types lead to several striking conclusions. Mat+ mat- strains are dual maters. However, the resident mat information is dominant to the mat information added by transformation with respect to fruiting body development and ascus production. Moreover, when dual mating mat+ mat- strains are crossed to mat+ or mat- testers, there is strong selection, after fertilization, that leads to the loss from the mat+ mat- nucleus of the mat information that matches that of the tester. Finally, the mat locus contains at least two domains, one sufficient for fertilization, the other necessary for sporulation.

The argininosuccinate lyase gene of Chlamydomonas reinhardtii: an important tool for nuclear transformation and for correlating the genetic and molecular maps of the ARG7 locus.

The argininosuccinate lyase (ASL) gene of Chlamydomonas reinhardtii has been cloned using four oligonucleotide probes corresponding to highly conserved regions of the ASL polypeptide sequence. The identity of the gene was confirmed by partial sequencing. It is unique, contains several introns and spans a region less than 7.8 kb that includes highly repetitive sequences. Using a particle gun, a reliable nuclear transformation system has been established by complementing three mutants deficient in ASL activity with the wild-type ASL gene. Analysis of the transformants reveals variable patterns of integration of the transforming DNA into the nuclear genome. Previous work has mapped the mutations in the mutants arg2 and arg7 to either end of the ARG7 locus 1.0 to 1.6 recombination map units apart. Our transformation results show that these two mutations are located within a region of 7.8 kb. This allows for the first correlation of the recombination map and the molecular map at the ARG7 locus and indicates a high recombination frequency in this region of the nuclear genome.

Cloning of opal suppressor tRNA genes of a filamentous fungus reveals two tRNASerUGA genes with unexpected structural differences.

The informational suppressors su4-1 and su8-1 of Podospora anserina were isolated by transformation of Schizosaccharomyces pombe UGA mutants. The DNA sequence revealed that they were opal (UGA) suppressor tRNAs. Wild-type alleles were also isolated by hybridization. The DNA sequence showed that they both encode species of tRNASerUGA. The gene SU8 has an 18-bp intervening sequence and its primary sequence is very different from that of SU4.