Quantitative variation of a 60S ribosomal protein during growth of the fungus Podospora anserina

During the growth phase, in the fungus Podospora anserina, a variation is observed in the composition of the ribosomal proteins. A protein of the 60S subunit which is absent in the ribosomes from 2 days old cultures becomes gradully more abundant as the culture time is prolonged.     

Genetic and biochemical analysis of cycloheximide resistance in the fungus Podospora anserina

Genetic analysis of cycloheximide-resistant mutants has shown that at least three genes control the resistance to cycloheximide in Podospora anserina and that the antibiotic resistance is recessive to sensitivity. In vitro and in vivo studies of protein synthesis indicated that for two mutants cycloheximide resistance is associated with the ribosomes. For one of these mutants, the elongation step in protein biosynthesis is insensitive to cycloheximide over a wide range of concentration. In this mutant the resistance to cycloheximide is a property of the 60S subunit.This work was supported by the Centre National de la Recherche Scientifique ERA No. 485.     

Grafting as a method for studying development in the filamentous fungus Podospora anserina

While grafting and transplant experiments have extensively been used to study development in animals and plants, they have seldom been employed to study fungal development. Here, grafting is used to study the interplay between mycelium and multicellular fruiting bodies during maturation in the model ascomycete Podospora anserina. Data indicate that grafts need a competent mycelium to continue their ripening. Vegetative incompatibility does not prevent transplanted fructifications to undergo development. Grafting onto mutant mycelia confirmed a previous model stating that the NADPH oxidase PaNox1 is required in the developing fruiting bodies, while the MAP kinase cascade PaMpk1 is required in the mycelium. Data also show that the IDC1 protein is required not only in the developing fruiting bodies but also in the mycelium, likely because of its role in anastomosis. Finally, entry inside the grafted fruiting bodies of a ribosomal protein tagged with GFP could be detected, suggesting that cellular components are imported from the underlying mycelium during maturation.     

Identification of the structural gene for the S9 ribosomal protein in the fungus Podospora anserina: a new protein involved in the control of translational accuracy

Summary AS9-1 was isolated as a mutation restoring growth in a strain carrying the ribosomal mutation su12-1. The AS9-1 mutation confers a weak antisuppressor effect and a low level of resistance to paromomycin. Two-dimensional polyacrylamide gel electrophoresis patterns of the ribosomal proteins from AS9-1 strains show an altered S9 protein which is more basic than the wild-type form. The presence of the two forms of the protein (wild-type and mutant) in heterocaryotic strains strongly suggests that AS9 is the structural gene for the ribosomal protein S9.     

Different alterations of the ribosomal protein S7 lead to opposite effects on translational fidelity in the fungus Podospora anserina

In the fungus Podospora anserina, the su12-1 mutation was previously found to decrease translational accuracy and to alter the ribosomal protein S7. The mutant protein is more basic than the wild type. Among the revertants of the two ribosomal mutations su12-1 and su12-2, 29 contained a second mutation very closely linked to su12. Biochemical analysis of these revertants by functional poly(U) tests and electrophoretical study of the ribosomes led to two conclusions. First, some revertant strains contain new mutant forms of S7. This suggests that su12 is the structural gene for the ribosomal protein S7. Second, the su12-2 revertants display antisuppressor properties in vivo and in vitro (i.e. increased translational accuracy). The electrophoretical patterns of their ribosomal proteins show new, more acidic, forms of S7. Therefore, su12 can be mutated towards either a lower or a greater translational accuracy corresponding to two opposite modifications of the global charge of the ribosomal protein S7. A more acidic form than wild type leads to increased accuracy and a more basic form to decreased accuracy.     

Spore-killing meiotic drive factors in a natural population of the fungus Podospora anserina

In fungi, meiotic drive is observed as spore killing. In the secondarily homothallic ascomycete Podospora anserina it is characterized by the abortion of two of the four spores in the ascus. We have identified seven different types of meiotic drive elements (Spore killers). Among 99 isolates from nature, six of these meiotic drive elements occurred in a local population. Spore killers comprise 23% of the natural population of P. anserina in Wageningen, The Netherlands, sampled from 1991 to 1997. One Spore-killer type was also found in a French strain dating from 1937. All other isolates found so far are sensitive to spore killing. All seven Spore killer types differ in the percentage of asci that show killing and in their mutual interactions. Interactions among Spore killer types showed either mutual resistance or dominant epistasis. Most killer elements could be assigned to linkage group III but are not tightly linked to the centromere.     

The HET-s prion protein of the filamentous fungus Podospora anserina aggregates in vitro into amyloid-like fibrils.

The HET-s protein of Podospora anserina is a fungal prion. This protein behaves as an infectious cytoplasmic element that is transmitted horizontally from one strain to another. Under the prion form, the HET-s protein forms aggregates in vivo. The specificity of this prion model compared with the yeast prions resides in the fact that under the prion form HET-s causes a growth inhibition and cell death reaction when co-expressed with the HET-S protein from which it differs by 13 residues. Herein we describe the purification and initial characterization of recombinant HET-s protein expressed in Escherichia coli. The HET-s protein self-associates over time into high molecular weight aggregates. These aggregates greatly accelerate precipitation of the soluble form. HET-s aggregates appear as amyloid-like fibrils using electron microscopy. They bind Congo Red and show birefringence under polarized light. In the aggregated form, a HET-s fragment of approximately 7 kDa is resistant to proteinase K digestion. CD and FTIR analyses indicate that upon transition to the aggregated state, the HET-s protein undergoes a structural rearrangement characterized by an increase in antiparallel beta-sheet structure content. These results suggest that the [Het-s] prion element propagates in vivo as an infectious amyloid.     

Search for ribosomal mutants in Podospora anserina: Genetic analysis of mutants resistant to paromomycin

It has recently been shown that paromomycin, an antibiotic of the aminoglycoside family, is also active on eukaryotic cytoplasmic ribosomes. In the fungus Podospora anserina, genetic analysis of ten mutants resistant to high doses of paromomycin shows that this resistance is caused by mutations in two different nuclear genes. These mutants display pleiotropic phenotypes (cold sensitivity, mycelium and spore appearance and coloration, cross-resistance to other antibiotics). Double mutants are either lethal or very altered and unstable. Moreover, the cytochrome spectra of these mutants seem to indicate that cytoplasmic protein synthesis is affected. The mutants also display a slight suppressor effect. We can therefore assume that these mutations affect cytoplasmic ribosomes.This work was supported by a C.N.R.S. Grant (ATP Microbiologie No. 3052) and by a NATO Grant.     

Evidence for a life span-prolonging effect of a linear plasmid in a longevity mutant of Podospora anserina

The linear mitochondrial plasmid pAL2-1 of the long-lived mutant AL2 of Podospora anserina was demonstrated to be able to integrate into the high molecular weight mitochondrial DNA (mtDNA). Hybridization analysis and densitometric evaluation of the mitochondrial genome isolated from cultures of different ages revealed that the mtDNA is highly stable during the whole life span of the mutant. In addition, and in sharp contrast to the situation in certain senescence-prone Neurospora strains, the mutated P. anserina mtDNA molecules containing integrated plasmid copies are not suppressive to wild-type genomes. As demonstrated by hybridization and polymerase chain reaction (PCR) analysis, the proportion of mtDNA molecules affected by the integration of pAL2-1 fluctuates between 10% and 50%. Comparative sequence analysis of free and integrated plasmid copies revealed four differences within the terminal inverted repeats (TIRs). These point mutations are not caused by the integration event since they occur subsequent to integration and at various ages. Interestingly, both repeats contain identical sequences indicating that the mechanism involved in the maintenance of perfect TIRs is active on both free and integrated plasmid copies. Finally, in reciprocal crosses between AL2 and the wild-type strain A, some abnormal progeny were obtained. One group of strains did not contain detectable amounts of plasmid pAL2-1, although the mtDNA was clearly of the type found in the long-lived mutant AL2. These strains exhibited a short-lived phenotype. In contrast, one strain was selected that was found to contain wild-type A-specific mitochondrial genomes and traces of pAL2-1. This strain was characterized by an increased life span. Altogether these data suggest that the linear plasmid pAL2-1 is involved in the expression of longevity in mutant AL2.     

Homologous and heterologous expression of a ribosomal protein gene in Podospora anserina requires an intron

Although the role of introns in eucaryotic nuclear genes has been much debated, it remains underinvestigated in fungi. The AS1 gene of Podospora anserina contains three introns and encodes a ribosomal protein (S12) belonging to the well-conserved bacterial S19 family. We attempted to complement the highly pleiotropic mutation AS1-4 with a cDNA encoding the homologous human (S15) protein (rig gene) under the control of the AS1 promoter. In a control experiment, the AS1 ⁺ cDNA was unable to complement fully the AS1-4 mutation. It was assumed that the AS1 cDNA was not well expressed and that the AS1 gene needed intron(s) to be efficiently expressed. Addition of the first intron of the AS1 gene to the AS1 and rig cDNAs did indeed allow complementation of all the phenotypic defects of the AS1-4 mutation. These data lead to two main conclusions. First, the human S15 ribosomal protein is functional in Podospora. Second, full expression of the Podospora AS1 gene requires at least one intron.     

HET-E and HET-D belong to a new subfamily of WD40 proteins involved in vegetative incompatibility specificity in the fungus Podospora anserina

Vegetative incompatibility, which is very common in filamentous fungi, prevents a viable heterokaryotic cell from being formed by the fusion of filaments from two different wild-type strains. Such incompatibility is always the consequence of at least one genetic difference in specific genes (het genes). In Podospora anserina, alleles of the het-e and het-d loci control heterokaryon viability through genetic interactions with alleles of the unlinked het-c locus. The het-d2(Y) gene was isolated and shown to have strong similarity with the previously described het-e1(A) gene. Like the HET-E protein, the HET-D putative protein displayed a GTP-binding domain and seemed to require a minimal number of 11 WD40 repeats to be active in incompatibility. Apart from incompatibility specificity, no other function could be identified by disrupting the het-d gene. Sequence comparison of different het-e alleles suggested that het-e specificity is determined by the sequence of the WD40 repeat domain. In particular, the amino acids present on the upper face of the predicted beta-propeller structure defined by this domain may confer the incompatible interaction specificity.     

Ribosomal assembly deficiency in an Escherichia coli thermosensitive mutant having an altered L24 ribosomal protein.

Localized P1 mutagenesis was used to screen for conditionally lethal mutations in ribosomal protein genes. One such mutation, 2859mis, has been mapped inside the ribosomal protein gene cluster at 72 minutes on the Escherichia coli chromosome and cotransduces at 98% with rpsE (S5). The 2869mis mutation leads to thermosensitivity and impaired assembly in vivo of 50 S ribosomal particles at 42 °C. The strain carrying the mutation has an altered L24 ribosomal protein which at 42 °C shows weaker affinity for 23 S RNA than the wild-type protein. The mutational alteration involves a replacement of glycine by aspartic acid in protein L24 from the mutant. We conclude therefore that the 2859mis mutation affects the structural gene for protein L24 (rplX).     

Altering a gene involved in nuclear distribution increases the repeat-induced point mutation process in the fungus Podospora anserina

Repeat-induced point mutation (RIP) is a homology-dependent gene-silencing mechanism that introduces C:G-to-T:A transitions in duplicated DNA segments. Cis-duplicated sequences can also be affected by another mechanism called premeiotic recombination (PR). Both are active over the sexual cycle of some filamentous fungi, e.g., Neurospora crassa and Podospora anserina. During the sexual cycle, several developmental steps require precise nuclear movement and positioning, but connections between RIP, PR, and nuclear distributions have not yet been established. Previous work has led to the isolation of ami1, the P. anserina ortholog of the Aspergillus nidulans apsA gene, which is required for nuclear positioning. We show here that ami1 is involved in nuclear distribution during the sexual cycle and that alteration of ami1 delays the fruiting-body development. We also demonstrate that ami1 alteration affects loss of transgene functions during the sexual cycle. Genetically linked multiple copies of transgenes are affected by RIP and PR much more frequently in an ami1 mutant cross than in a wild-type cross. Our results suggest that the developmental slowdown of the ami1 mutant during the period of RIP and PR increases time exposure to the duplication detection system and thus increases the frequency of RIP and PR.     

Two allelic genes responsible for vegetative incompatibility in the fungus Podospora anserina are not essential for cell viability

Summary Vegetative incompatibility is a lethal reaction that destroys the heterokaryotic cells formed by the fusion of hyphae of non-isogenic strains in many fungi. That incompatibility is genetically determined is well known but the function of the genes triggering this rapid cell death is not. The two allelic incompatibility genes, s and S, of the fungus Podospora anserina were characterized. Both encode 30 kDa polypeptides, which differ by 14 amino acids between the two genes. These two proteins are responsible for the incompatibility reaction that results when cells containing s and S genes fuse. Inactivation of the s or S gene by disruption suppresses incompatibility but does not affect the growth or the sexual cycle of the mutant strains. This suggests that these incompatibility genes have no essential function in the life cycle of the fungus.     

Cloning gene ura5 for the orotidylic acid pyrophosphorylase of the filamentous fungus Podospora anserina: transformation of protoplasts

From a genomic library of the filamentous fungus Podospora anserina, we have cloned a 4.9-kb fragment which complements an Escherichia coli mutant strain deficient for orotidylic acid pyrophosphorylase (pyrE gene). The recombinant plasmid pPAura5 also transforms to prototrophy a mutant strain of P. anserina carrying a mutation in the ura5 gene and lacking OMPppase activity.     

The ura5 gene of the filamentous fungus Podospora anserina: nucleotide sequence and expression in transformed strains

We have sequenced the ura5 gene of the filamentous fungus Podospora anserina. The deduced sequence for the orotidylic acid pyrophosphorylase (OMPppase) has been compared with the Escherichia coli enzyme which is the only known sequence for this enzyme. This comparison shows extensive blocks of homology. The expression of the ura5 gene has been studied in a ura5 mutant which has been transformed by a recombinant plasmid carrying the ura5 gene. We observed that strains carrying integrated multicopies of the transforming vector exhibit higher specific activity for OMPppase than wild type (wt). By recombination we have constructed a strain in which the level of this enzyme is 32 times higher than in the wt strain.