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.

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.

Deletion of the mating-type sequences in Podospora anserina abolishes mating without affecting vegetative functions and sexual differentiation.

The mating-type locus of Podospora anserina controls fusion of sexual cells as well as subsequent stages of development of the fruiting bodies. The two alleles at the locus are defined by specific DNA regions comprising 3.8 kb for mat+ and 4.7 kb for mat-, which have identical flanking sequences. Here we present the characterization of several mutants that have lost mat(+)-specific sequences. One mutant was obtained fortuitously and the other two were constructed by gene replacement. The mutants are deficient in mating with strains of either mat genotype but are still able to differentiate sexual reproductive structures. The loss of the mating type does not lead to any discernible phenotype during vegetative growth: in particular it does not change the life span of the strain. The mutants can recover mating ability if they are transformed with DNA containing the complete mat+ or mat- information. The transformants behave in crosses as do the reference mat+ or mat- strains, thus indicating that the transgenic mat+ and mat- are fully functional even when they have integrated at ectopic sites.

Heterologous expression of mating-type genes in filamentous fungi.

Podospora anserina and Neurospora crassa, two filamentous heterothallic ascomycetes, have a single mating-type locus with two alternate forms called mat+ and mat- and A and a, respectively. Mating type controls entry into the sexual cycle, events subsequent to fertilization, and, in N. crassa, prevents the formation of mixed mating-type heterokaryons. The mating types of these two organisms display similarity in their DNA structure and in the encoded polypeptides involved in fertilization. Here we show that this molecular similarity reflects a functional homology with respect to mating identity. Transformation experiments show that the N. crassa mating-type genes can provide the fertilization functions in P. anserina strains devoid of mating specificity as well as in mat+ and mat- strains. Reciprocally, the introduction of P. anserina mating-type genes confers mating activity in N. crassa. Functional identity between the mating types is not observed for vegetative incompatibility or for post-fertilization events such as meiosis and ascosporogenesis.

Transformation by integration in Podospora anserina. III. Replacement of a chromosome segment by a two-step process.

We have developed in Podospora anserina a two-step procedure for DNA sequence replacement through transformation which might be applicable to other filamentous fungi. Targeting of transforming DNAs to their homologous locus is achieved provided a cosmid vector is used. Southern blot analysis of genomic DNAs from a set of transformants is presented. The data confirm that cosmids integrate into the chromosome through mostly homologous recombination which leads to a duplicated sequence separated by the vector. This event was found to be unstable in crosses. We show that this instability is due to the frequent excision of the vector together with the selective marker and one copy of the duplication, either the resident or foreign sequence. The two sequences can be distinguished because they exhibit restriction fragment length polymorphism. Therefore, Podospora anserina treats duplications occurring through transformation in a way differing from that exhibited by Neurospora crassa and Ascobolus immersus.

Genotoxic activities of 2-nitronaphthofurans and related molecules.

The genotoxic activities of 63, 2-nitronaphthofurans and related molecules were examined using two bacterial short-term tests, the Salmonella mammalian microsome assay test or Mutatest, a mutagenesis assay, and/or the SOS Chromotest, an assay for induction of an SOS function in Escherichia coli. Seven compounds were also investigated in the Chinese hamster ovary cells/hypoxanthine-guanine phosphoribosyl transferase (CHO/HGPRT) test, a mammalian gene mutation assay. Our main conclusions are the following: (a) Simple empirical rules relating structure to mutagenic activity in the Mutatest can be derived for some of the compounds. In particular, they account for the extremely high Mutagenic Potency of 7-methoxy-1-methyl-2-nitronaphtho[2,1-b]furan (R7372), approximately 2 X 10(6) mutants/nmol on strain TA100. (b) There is a good quantitative correlation between the Mutagenic Potency in the Salmonella/mammalian microsomes assay and the SOS-inducing potency in the SOS Chromotest. This, and previous evidence, suggests strongly that the 2-nitronaphthofurans derivatives are essentially recA and thus probably umuDC-dependent mutagens. (c) Four out of seven compounds tested in the CHO/HGPRT assay gave responses correlated with the bacterial responses. One of them, 7-methoxy-2-nitronaphtho[2,1-b]furan (R7000), is among, or is, the strongest mutagen described for mammalian cells. We briefly discuss the practical and theoretical implications of these results.

A system for the detection of chromosomal rearrangements using Sordaria macrospora.

A system is described for the detection and diagnosis of induced chromosomal rearrangement using Sordaria macrospora. The system uses the property of the rearrangement to produce defective white ascospores as meiotic progeny from heterozygous crosses. Two reconstruction experiments have shown that this system is able to give reliable quantitative measures of rearrangement frequencies. Evidence for a photoreactivation process was obtained, suggesting that pyrimidine dimers may well be an important lesion in UV-induced chromosomal rearrangement. No evidence of induction of chromosomal rearrangement was obtained in experiments with the powerful chemical mutagen N-methyl-N'-nitro-N-nitrosoguanidine.

Conversion in gene b1 of Ascobolus: Polarity of 6:2 and inverted polarity of aberrant 4:4 segregations.

Thirteen mutations located in gene b1 of Ascobolus immersus were studied for their non-mendelian segregation patterns. All these motations yield post-meiotic segregations. The non-mendelian segregation frequencies are the highest for the left end mutations. From left to right, the frequency of aberrant 4:4 asci increases. The hybrid DNA formation and distribution pattern as deduced from this result is consistent with that previously found in gene b2, providing further support to the Aviemore model. The frequency of 6:2 asci decreases from left to right. This constitutes an entirely new observation, the meaning of which is discussed.