DNA deletion of mitochondrial introns is correlated with the process of senescence in Podospora anserina.

In the filamentous fungus Podospora anserina, the unavoidable phenomenon of senescence is associated with specific mitochondrial rearrangements and particularly with the amplification of some regions of the mitochondrial chromosome. Mechanisms responsible for these rearrangements are still unknown. The implication in this phenomenon, of the first intron of the mitochondrial gene cox1 (intron alpha), a class II intron that presents significant amino acid similarity with retroviral reverse transcriptases, was postulated several years ago. We demonstrate here by polymerase chain reaction experiments: (1) that senescent and young cultures contain DNA molecules precisely deleted for intronic sequences; (2) that these deletions are found to a much greater extent in senescent than in young cultures; (3) that DNA intron deletion likely results from a reverse transcriptase-mediated mechanism as indicated by the detection of copies of the gene 1 cox1 completely devoid of its 15 introns; (4) that the intron alpha-encoded protein could intervene in this process. On the whole, these results strongly suggest that in Podospora, an increase in a mitochondrial reverse transcriptase activity probably mediated by the intron alpha-encoded protein is involved in the process of senescence.

DNA double-strand break in vivo at the 3' extremity of exons located upstream of group II introns. Senescence and circular DNA introns in Podospora mitochondria.

In the filamentous fungus Podospora anserina, the unavoidable phenomenon of senescence is associated with the amplification of the first intron of the mitochondrial cox1 that accumulates as circular DNA molecules consisting of tandem repeats. This group II intron (cox1-i1 or alpha) is able to transpose and contains an open reading frame with significant amino acid similarity with reverse transcriptases. The generation of these intronic circular DNA molecules, their amplification and their involvement in the senescence process are unresolved questions. We demonstrate here that: (1) another group II intron, the fourth intron of gene cox1, cox1-i4, is also able to give precise DNA end to end junctions; (2) this intronic sequence can be found amplified during senescence, although to a lesser extent than cox1-i1; (3) the amplification of the DNA multimeric cox1-i1 molecules likely does not proceed by autonomous replication; (4) the generation of the DNA intronic circles does not require efficient intron splicing; (5) a DNA double-strand break occurs in vivo at the 3' extremity of the cox1-e1 and cox1-e4 exons preceding the group II introns that form circular DNAs. On the whole, these results show that the ability to form DNA circular molecules is a property of some group II introns and they demonstrate the occurrence of a specific DNA cleavage at or near the integration site of these group II introns. The results strongly suggest that this cleavage is involved in the formation of the group II intronic DNA circles and could also be involved in the phenomenon of group II intron homing.

Premature death in Podospora anserina: sporadic accumulation of the deleted mitochondrial genome, translational parameters and innocuity of the mating types.

The Podospora anserina premature death syndrome was described as early growth arrest caused by a site-specific deletion of the mitochondrial genome (mtDNA) and occurring in strains displaying the genotype AS1-4 mat-. The AS1-4 mutation lies in a gene encoding a cytosolic ribosomal protein, while mat- is one of the two forms (mat- and mat+) of the mating-type locus. Here we show that, depending on culture conditions, death due to the accumulation of the deleted mtDNA molecule can occur in the AS1-4 mat+ context and can be delayed in the AS1-4 mat- background. Furthermore, we show that premature death and the classical senescence process are mutually exclusive. Several approaches permit the identification of the mat-linked gene involved in the appearance of premature death. This gene, rmp, exhibits two natural alleles, rmp- linked to mat- and rmp+ linked to mat+. The first is probably functional while the second probably carries a nonsense mutation and is sporadically expressed through natural suppression. A model is proposed that emphasizes the roles played by the AS1-4 mutation, the rmp gene, and environmental conditions in the accumulation of the deleted mitochondrial genome characteristic of this syndrome.

Mitochondrial intronic open reading frames in Podospora: mobility and consecutive exonic sequence variations.

The mitochondrial genome of 23 wild-type strains belonging to three different species of the filamentous fungus Podospora was examined. Among the 15 optional sequences identified are two intronic reading frames, nad1-i4-orf1 and cox1-i7-orf2. We show that the presence of these sequences was strictly correlated with tightly clustered nucleotide substitutions in the adjacent exon. This correlation applies to the presence or absence of closely related open reading frames (ORFs), found at the same genetic locations, in all the Pyrenomycete genera examined. The recent gain of these optional ORFs in the evolution of the genus Podospora probably account for such sequence differences. In the homoplasmic progeny from heteroplasmons constructed between Podospora strains differing by the presence of these optional ORFs, nad1-i4-orf1 and cox1-i7-orf2 appeared highly invasive. Sequence comparisons in the nad1-i4 intron of various strains of the Pyrenomycete family led us to propose a scenario of its evolution that includes several events of loss and gain of intronic ORFs. These results strongly reinforce the idea that group 1 intronic ORFs are mobile elements and that their transfer, and concomitant modification of the adjacent exon, could participate in the modular evolution of mitochondrial genomes.

Variable DNA splicing sites of a mitochondrial intron: relationship to the senescence process in Podospora.

The unavoidable phenomenon of senescence in Podospora was previously shown to be correlated with the presence of a senescence-specific DNA originating from amplification of some regions of the mitochondrial chromosome. The most frequently amplified region (alpha) corresponds to the first intron of the gene coding for subunit one of cytochrome oxidase. Eleven long-lived mitochondrial mutants were isolated. Here we report sequencing experiments that show that three of them are deleted for most of intron alpha and for a few base pairs belonging to the upstream adjacent exon. We also report an analysis of the residual mitochondrial DNA associated with amplification of senescence-specific DNA alpha which allows us to identify, in senescent cultures, mitochondrial chromosomes lacking sequence alpha. These results taken together suggest that excision of intron alpha from the mitochondrial DNA occurs systematically during the aging process in Podospora. They furthermore provide the first example of inaccurate intron excision at the DNA level.

Mitochondrial genes in Podospora anserina: recombination and linkage.

A fifth cytoplasmic mutation (capr 1) obtained in Podospora anserina is described. In addition to chloramphenicol resistance it confers a strong deficiency in cytochrome aa3 and impairs the germination of ascospores. Genetic analysis shows: 1) strict maternal inheritance of (capr 1) allele; 2) selection against the (capr 1) allele as well in sexual crosses as during vegetative growth; 3) complete reversion of this selection by even low concentration of CAP. On the basis of their cytoplasmic inheritance and altered cytochrome spectra the five cytoplasmic mutations are assumed to be mitochondrial. Analysis of crosses between them allows to class them in 3 loci, 2 of which being closely linked.

The in vivo use of alternate 3'-splice sites in group I introns.

Alternative splicing of group I introns has been postulated as a possible mechanism that would ensure the translation of proteins encoded into intronic open reading frames, discontinuous with the upstream exon and lacking an initiation signal. Alternate splice sites were previously depicted according to secondary structures of several group I introns. We present here strong evidence that, in the case of Podospora anserina nad 1-i4 and cox1-i7 mitochondrial introns, alternative splicing events do occur in vivo. Indeed, by PCR experiments we have detected molecules whose sequence is precisely that expected if the predicted alternate 3'-splice sites were used.

Insertion of short poly d(A) d(T) sequences at recombination junctions in mitochondrial DNA of Podospora.

We have characterized the DNA sequences at recombination points in the mitochondrial DNA of two independent mitochondrial mutants of Podospora anserina. These sequences reveal the presence of foreign DNA at each recombination border, consisting of short stretches of A and T residues. We discuss the possible origin of this DNA and suggest the involvement of a reverse transcriptase activity.

A site-specific deletion in mitochondrial DNA of Podospora is under the control of nuclear genes.

In the filamentous fungus Podospora anserina, the association of two nuclear genes inevitably leads to a "premature death" phenotype consisting of an early end of vegetative growth a few days after ascospore germination. Mycelia showing this phenotype contain a mitochondrial chromosome that always bears the same deletion. One of the break points is exactly at the 5' splice site of a particular mitochondrial intron, suggesting that the deletion event could result from molecular mechanisms also involved in intron mobility. One of the nuclear genes involved in triggering this site-specific event belongs to the mating-type minus haplotype; the other is a mutant allele of a gene encoding a cytosolic ribosomal protein.

Intron open reading frames as mobile elements and evolution of a group I intron.

Group I introns are proposed to have become mobile following the acquisition of open reading frames (ORFs) that encode highly specific DNA endonucleases. This proposal implies that intron ORFs could behave as autonomously mobile entities. This was supported by abundant circumstantial evidence but no experiment of ORF transfer from an ORF-containing intron to its ORF-less counterpart has been described. In this paper we present such experiments, which demonstrate the efficient mobility of the mitochondrial nad1-i4-orf1 between two Podospora strains. The homing of this mobile ORF was accompanied by a bidirectional co-conversion that did not systematically involve the whole intron sequence. Orf1 acquisition would be the most recent step in the evolution of the nad1-i4 intron, which has resulted in many strains of Podospora having an intron with two ORFs (biorfic) and four splicing pathways. We show that two of the splicing events that operate in this biorfic intron, as evidenced by PCR experiments, are generated by a 5'-alternative splice site, which is most probably a remnant of the monoorfic ancestral form of the intron. We propose a sequential evolution model that is consistent with the four organizations of the corresponding nad1 locus that we found among various species of the Pyrenomycete family; these organizations consist of no intron, an intron alone, a monoorfic intron, and a biorfic intron.

A 1100-bp sequence of mitochondrial DNA is involved in senescence process in Podospora: study of senescent and mutant cultures.

In Podospora, senescence is assumed to be caused by the amplification of short sequences of the mitochondrial genome (sen-DNAs). We have characterized a 1100-bp-long mitochondrial DNA sequence which could be directly involved in the phenomenon. Indeed, by hybridization experiments, we show that this sequence is both present in all the sen-DNA molecules which originate from the beta region of the mitochondrial chromosome and rearranged in the mitochondrial genome of two mitochondrial mutants selected as resistant to senescence.

Transposition of a group II intron.

Among mobile genetic elements, self-splicing introns are of particular interest. They belong to either group I or group II depending on their three-dimensional structure. Homing, the systematic intron invasion of an intronless gene when it encounters its homologous intron-bearing allele, is the only means for intron mobility so far demonstrated. It depends on the activity of the intron-encoded protein and is very specific for the acceptor site. Intron transposition, the transfer of an intron to a novel site, predicted on the basis of phylogenetic studies and in vitro reverse-splicing experiments, has been proposed to be responsible for evolutionary intron spreading. Here we present results from polymerase chain reaction experiments consistent with transposition of a group II intron. This event is proposed to account for the site-specific deletion in the mitochondrial chromosome of the fungus Podospora anserina that is associated with the premature death syndrome and might also be involved in the senescence process affecting this species.

Detection of a protein encoded by a class II mitochondrial intron of Podospora anserina.

In the filamentous fungus Podospora anserina, the amplification as circular DNA molecules of the first intron (intron alpha) of the CO1 mitochondrial gene, encoding the cytochrome oxidase subunit 1, is known to be strongly associated with aging of strains. In this study we have attempted to detect the protein potentially encoded by the open reading frame (ORF) contained in this intron. This was done by the Western blot technique using specific antisera raised against three polypeptides encoded by three non-overlapping fragments of this ORF adapted to the universal code and overexpressed in Escherichia coli. We examined about thirty independent subclones of Podospora derived from two different geographic races (A, s), using wild-type and mutant strains, young and senescent cultures. A 100 kDa polypeptide, encoded by the class II intron alpha, was detected in five senescent subclones which all showed strong amplification of the intronic alpha sequence (Sen DNA alpha).

[Electron microscopy of mitochondrial DNA in Podospora anserina and the presence of a multimeric range of circular DNA molecules from senescent cultures]. / Etude au microscope électronique du DNA mitochondrial de Podospora anserina et présence d'une série multimérique de molécules circulaires de DNA dans des cultures sénescentes.

Mitochondrial DNA from young cultures of race s of Podospora anserina was isolated. Its density in Cesium chloride density equilibrium gradients was 1.694 g/cc. Examination by the electron microscope revealed that ca 1% of this DNA consisted of circles, 31 micrometer in contour length; the remaining DNA was composed of linear molecules ranging in length from 2 to 33 micrometer. In DNA of similar density obtained from senescent cultures of the same race s, about 11% of the molecules consisted of a multimeric set of circles ranging in size from 0.9 to 15 micrometer, with most being in the 1.8 and 2.7 micrometer classes. The similarity of these DNA molecules with the mitochondrial DNA from rho(-) yeast mutants is discussed.

Senescence in Podospora anserina: amplification of a mitochondrial DNA sequence.

Senescence in Podospora anserina has long been shown to be under cytoplasmic control. Comparison of DNAs isolated from young and senescent cultures made it possible to detect the presence, in senescent cultures only, of a specific DNA (SEN-DNA). This DNA consists of repeated sequences arranged in a multimeric set of circular molecules. In this study we have examined one particular SEN-DNA whose monomer unit is 6300 bp long. Using the Southern hybridization technique, we have demonstrated that this SEN-DNA results from the amplication of a sequence of the mitochondrial chromosome. This amplification, which resembles the process leading to rho- ("petite") mutations in yeast, is discussed in relation to the determinism of senescence.

Mitochondrial DNA from Podospora anserina. II. Properties of mutant DNA and multimeric circular DNA from senescent cultures.

Mitochondrial (Mt) DNA from mitochondrial mutants of race s Podospora anserina and from senescent cultures of races s and A was examined. In mutants, we observed that fewer full length circles (31 mu) were present; instead, smaller circles characteristic for each mutant studied were found. Eco R1 digestion of these mutant MtDNAs indicated that in certain mutants, although specific fragments were absent, the total molecular weight of the fragments was not much different than wild-type. The properties of senescent MtDNA was strikingly different from either wild-type or mutant Mt DNA. First, a multimeric set of circular DNA was observed for both race s and A, with a monomeric repeat size of 0.89 mu. These circles ranged in size from 0.89 mu to greater than 20 mu; only one molecule out of some 200 molecules was thought to be of full length (31 mu). Density gradient analysis showed that there were two density species: a majority were at the same density as wild-type (1.694 g/cm3) and a second at 1.699 g/cm3. Most of the circular molecules from MtDNA isolated by either total DNA extraction or by extraction of DNA from isolated mitochondria were contained in the heavy DNA fraction. Eco R1 enzymatic digestion indicated that the light DNA had several fragments (amounting to about 23 x 10(6) daltons) missing, compared with young, wild-type MtDNA. Heavy senescent MtDNA was not cleaved by Eco R1. Analysis with Hae III restriction endonuclease showed also that light senescent MtDNA was missing certain fragments. Heavy MtDNA of average size 20 x 10(6) daltons, yielded only one fragment, 2,500 bp long, by digestion with Hae III restriction endonuclease. Digestion of heavy DNA with Alu I enzyme yielded 10 fragments totalling 2,570 bp. By three criteria, electron-microscopy, Eco R1 and Hae digestion, we conclude that the heavy MtDNA isolated from senescent cultures of Podospora anserina consisted of a monomeric tandemly repeating subunit of about 2,600 bp length. These results on the properties of senescent MtDNA are discussed with regard to the published properties of the rho- mutation in the yeast, S. cerevisiae.

Mitochondrial DNA from Podospora anserina. I. Isolation and characterization.

Mitochondrial (Mt) DNA from Podospora anserina was isolated and characterized with respect to density in CsCl, contour length and endonuclease restriction enzymes. The density of Mt DNA for four races examined was 1.694 g/cm3, compared with 1.712 g/cm3 for nuclear DNA. Extraction in the presence of a nuclease inhibitor, aurintricarboxylic acid and isolation in DAPI CsCl gradients allowed us to isolate high molecular weight DNA. Mt DNA isolated by total DNA extraction contained ca. 1% of circular molecules, 31 micron in contour length; Mt DNA isolated from purified mitochondria contained 2--4% of these 31 micron circles. Analysis with Eco RI restriction endonuclease revealed that each of the four races examined, s, A, T and E had a characteristic fragment pattern. Races s and A Mt DNA differed by only one fragment after Eco RI enzymatic digestion; similarly, these two DNA differed by only one or two fragments after Hae III digestion.

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

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/cm(3)) or in a band of higher density (1.699 g/cm(3)). 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.

A 20 X 10(3)-base mosaic gene identified on the mitochondrial chromosome of Podospora anserina.

By DNA sequencing and hybridization experiments we have localized the genes cob and col on the mitochondrial chromosome of Podospora anserina. The positions we have determined for these two genes are different from those previously attributed to them. The presence in the gene col of at least two introns, belonging respectively to class I and II, has been demonstrated. This gene, with a size of about 20 X 10(3) bases, appears to be the longest known mitochondrial mosaic gene.