Evaluation of the efficiency of sexual reproduction in restoring Podospora anserina mitochondrial DNA to wild-type

A Podospora anserina mitochondrial DNA (mtDNA) rearrangement mutant, Mn19, was crossed with a deletion mutant, αΔ5. Ascospores (212) from random asci were tested for viability, growth and life-span phenotypes, and mtDNA inheritance. Some spore inviability was detected along with early growth arrest (at the time of spore germination) from which some isolates recovered. However, the majority had wild-type growth and life-span phenotypes. All isolates tested at the DNA level (102) had wild-type mtDNA hybridization patterns with probes that detected defects in the parents. About 20% also inherited low levels of mtDNA molecules with the rearrangement characteristic of the Mn19 parent. These results demonstrate that P. anserina has a remarkable ability, through sexual reproduction, to restore its mtDNA to wild-type, even when the parents are predominately mutant. Received: 3 January / 25 July 1997     

Contribution of various classes of defective mitochondrial DNA molecules to senescence in Podospora anserina

The unavoidable arrest of vegetative growth in Podospora anserina (senescence process) is always correlated with rearrangements of the mitochondrial chromosome, mainly consisting in the amplification of particular regions as tandemly repeated circular molecules (senDNAs). One sequence systematically amplified in senescent cultures corresponds precisely to the first intron (intron α) of the cox1 gene; nevertheless, other regions (called β and γ) are also frequently amplified. The experiments presented in this paper show that cellular death is in some cases associated with the sole presence of large amounts of senDNA β. In addition, we provide evidence that senDNA β and senDNA α accumulate by different mechanisms, as previously proposed. This suggests that β senDNAs have a lethal effect on the mycelium on their own and most likely have replicative properties independent of the presence of sequence α. These data do not fit well with the current opinion that gives an essential role to intron α in the senescence of P. anserina. Received: 10 May / 11 November 1996     

Genetic map of mitochondrial DNA in Podospora anserina

Summary In order to develop an eukaryotic vector with the Podospora plasmid, further characterization is required of the mitochondrial DNA into which this plasmid is integrated, a physical map (restriction sites) of the Podospora chondriome (size 95 kb) has been completed. As prerequisite for the establishment of a genetic (functional) map, 70% of the chondriome was cloned in E. coli vectors. Using mitochondrial genes from Saccharomyces cerevisiae, six structural genes were located on the Podospora chondriome by cross hybridization experiments. There is strong evidence that the plasmid is inserted into the cytochrome b gene. A comparison of the genetic map of the Podospora chondriome with those of Neurospora crassa and Aspergillus nidulans exhibits a rather good accordance with respect to the sequence of genes.     

Intramolecular cross-overs generate deleted mitochondrial DNA molecules in Podospora anserina

The unavoidable senescence process that limits the vegetative growth of Podospora anserina is always associated with an accumulation of various classes of circular, tandemly arranged, defective mitochondrial DNA molecules (senDNAs). The monomers of the senDNAs belonging to the so-called β class share a common core, but differ in both their length and termini. To understand the mechanism leading to their formation, we have determined the junction sequence of 36 senDNA β monomers present in various senescent cultures. In most cases, we observe that: (1) short direct repeats precisely bound the senDNA β termini and (2) one copy of the repeats is retained in the senDNA sequence. Moreover, PCR analysis of the mitochondrial DNA of some of the senescent cultures, has allowed us to detect another genome which is exactly lacking the sequence of the senDNA β found in the culture. These results demonstrate that an intramolecular unequal cross-over occurring between short direct repeats can generate deleted mtDNA molecules in P. anserina. In addition, the polymorphism displayed by one pair of repeats allows us to establish that this cross-over may be associated with a short conversion tract spanning a few (about 15) nucleotides. Received: 16 May / 11 November 1996     

Ethidium bromide rejuvenation of senescent cultures of Podospora anserina : Loss of senescence-specific DNA and recovery of normal mitochondrial DNA

Summary The effect of ethidium bromide (EB) which is known to be able to rejuvenate senescent mycelia in Podospora anserina, has been investigated at the level of the mitochondrial DNA (mtDNA) by restriction analysis and molecular hybridization. While senescent mycelia display a very low growth ability and gross mtDNA modifications (tandem amplification of short sequences and disorganization of the mitochondrial chromosome: deletion of large sequences), the rejuvenated mycelia display a normal life span and contain a mtDNA in all respects identical to that of wild type mycelium (neither circular molecules nor amplified fragments could be detected). These results demonstrate a strict correlation between the senescent state and the presence of amplified mtDNA and suggest that EB rejuvenation could proceed by an efficient selection of intact mitochondrial chromosomes still present in senescent cultures.     

Mitochondrial DNA amplification in senescent cultures of Podospora anserina: Variability between the retained,amplified sequences

Summary The non-nuclear DNA of a number of independent senescent cultures of Podospora anserina was extracted and studied. In all cases, a specific repetitive DNA (SEN-DNA) arranged in multimeric sets of circular molecules, was identified. Depending on the senescent culture, the SEN-DNA was found either in a band of about same density as the mitochondrial DNA from young mycelia (1.694 g/cm³) or in a band of higher density (1.699 g/cm³). Electron microscopy, restriction enzyme analysis and Southern hybridization experiments allowed us to establish that: (1) SEN-DNAs obtained from independent senescent cultures, both from the same strain and from different strains, can differ in the size of their monomer unit (from 2.5 to 6.3 kb). (2) All SEN-DNAs hybridize with mitochondrial DNA of a young culture and not with nuclear DNA. (3) These SEN-DNAs belong to two classes which hybridize with two non-overlapping regions of the mitochondrial chromosome.     

Genome analysis of filamentous fungi: identification and characterization of an unusual GT-rich minisatellite in the ascomycete Podospora anserina

A genomic DNA fragment, PaGT7-5, of Podospora anserina was cloned that contains three different repetitive sequence motifs including a minisatellite with an unusual structure. This element, PaMin1, consists of ten copies of a 16 bp repeat unit with five GT dinucleotide repeats. Adjacent to PaMin1, a short poly(GT) stretch and four repeats of a 12 bp sequence were identified. Six alleles which differ in the number of the minisatellite unit were demonstrated in 18 different P. anserina strains. The flanking sequences of PaMin1 did not display any sequence alterations. A PCR analysis of total DNA from cultures of different age revealed no sequence changes, indicating that this repetitive DNA remains stable during aging. Southern-blot hybridization experiments of DNA from different strains detected only minor fragment length polymorphisms in the immediate vicinity of PaMin1. In contrast, major polymorphisms were observed at a greater distance from the locus indicating that this locus can be used as an informative probe to discriminate between different P. anserina strains. Received: 12 March / 24 May 1998     

Three mitochondrial unassigned open reading frames of Podospora anserina represent remnants of a viral-type RNA polymerase gene

The mitochondrial DNA of Podospora anserina is complex, consisting of a characteristic set of genes with a large number of introns and a substantial amount of sequence of unknown function and origin. In addition, as indicated by various types of reorganization, this genome is highly flexible. Here we report the identification of three unassigned mitochondrial open reading frames (ORF P', ORF Q', ORF 11) as remnants of a rearranged viral-type RNA polymerase gene. These ORFs are not transcribed and may be derived from the integration of a linear plasmid of the type recently identified in a mutant of P. anserina.     

The mitochondrial plasmid of Podospora anserina: A mobile intron of a mitochondrial gene

Summary In the ascomycete Podospora anserina strain ageing (senescence) is caused by a mitochondrial plasmid. In juvenile mycelia it is an integral part of the mtDNA and becomes liberated during ageing. The nucleotide sequence of this plasmid and of its flanking regions was determined. It consists of 2,539 by and contains an un identified reading frame (URF) originating in the adjacent mtDNA upstream of excision point 1. Within the URF a putative 48 by autonomously replicating sequence (ars) was identified. At both excision sites of the plasmid there are two short nonidentical interrupted palindromes and a few base pairs apart from these palindromes, both upstream and downstream, two short inverted repeats are localised. The experimental data make it evident that the mt plasmid is an intron of the cytochrome c oxidase gene (subunit I) which may be excised at the DNA level and thus become the mobile infective agent causing senescence. The concept of this mobile intron and current hypotheses concerning the relationship between introns and transposons are stressed.     

Induction of longevity by cytoplasmic transfer of a linear plasmid inPodospora anserina

InPodospora anserina the longevity inducing linear plasmid pAL2-1 was transferred from the extrachromosomal long-lived mutant AL2 to the shor-tlived wild-type strain A. The resulting strain, AL2-IV, exhibited the long-lived phenotype. In the short-lived progeny of crosses between this strain and wild-type strain A, the plasmid was absent. In contrast, all long-lived progeny contained both the autonomous plasmid as well as copies of it integrated in the mitochondrial DNA (mtDNA). Molecular analysis revealed that the integrated plasmid copies most likely resulted from ade novo integration of the autonomous element and the generation of AT-linker sequences at the integration site. We conclude that once the plasmid is present in mitochondria of a particular genetic background, it is able to integrate into the mtDNA and to induce longevity.     

The linear mitochondrial plasmid pAL2-1 of a long-lived Podospora anserina mutant is an invertron encoding a DNA and RNA polymerase

The molecular characterization of an additional DNA species (pAL2-1) which was identified previously in a long-lived extrachromosomal mutant (AL2) of Podospora anserina revealed that this element is a mitochondrial linear plasmid. pAL2-1 is absent from the corresponding wild-type strain, has a size of 8395 bp and contains perfect long terminal inverted repeats (TIRs) of 975 bp. Exonuclease digestion experiments indicated that proteins are covalently bound at the 5 termini of the plasmid. Two long, non-overlapping open reading frames, ORF1 (3,594 bp) and ORF2 (2847 bp), have been identified, which are located on opposite strands and potentially encode a DNA and an RNA polymerase, respectively. The ORF1-encoded polypeptide contains three conserved regions which may be responsible for a 3–5 exonuclease activity and the typical consensus sequences for DNA polymerases of the D type. In addition, an amino-acid sequence motif (YSRLRT), recently shown to be conserved in terminal proteins from various bacteriophages, has been identified in the amino-terminal part of the putative protein. According to these properties, this first linear plasmid identified in P. anserina shares all characteristics with invertrons, a group of linear mobile genetic elements.     

Sequence of the nuclear ATP synthase subunit 9 gene of Podospora anserina: lack of similarity to the mitochondrial genome

Summary The nuclear gene coding for the mitochondrial subunit 9 of the F₀F₁-ATP synthase complex was isolated from a genomic library of Podospora anserina. Nucleotide sequencing revealed an open reading frame capable to code for 144 amino acids including an amino-terminal pre-sequence of 63 amino acid residues for mitochondrial import of the pre-proteolipid. The P. anserina proteolipid shows extensive sequence identity with the corresponding gene products of the related filamentous fungi Neurospora crassa, Aspergillus nidulans and Aspergillus niger. In contrast to the situation in Saccharomyces cerevisiae, N. crassa and A. nidulans, no sequence similarity of the ATP synthase subunit 9 gene to the mitochondrial genome of P. anserina could be detected. Thus, in P. anserina this gene appears to be exclusively encoded by the nuclear genome.