Lethal mitochondrial genotypes in Podospora anserina: A model for senescence

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.

Plasmid-like DNA is part of mitochondrial DNA in Podospora anserina

As previously reported, a ccc DNA with a contour length of 0.75 µm and molecular weight of 2.4 kb (termed plasmid-like, p1DNA) is the causative agent of senescence in the fungus Podospora anserina. Its postulated location in mtDNA was proved correct by the following experiments: 1. Restriction analysis of mtDNA resulted in different molecular weights for both, juvenile (95 kb) and senescent (30 kb) mtDNA. The construction of a detailed restriction map made evident the fact that senescent mtDNA comprises only a part of its juvenile counterpart. 2. Hybridization experiments (Southern blots) between (3)H-labelled plDNA and mtDNA cleaved by restriction juvenile mtDNA are homologous to plDNA. 3. Fine mapping experiments (construction of restriction maps and heteroduplex experiments) between plDNA integrated into a bacterial vector and its postulated equivalent, derived from juvenile mtDNA and also integrated into a bacterial vector, allowed a precise determination of the site of plDNA insertion within the juvenile mtDNA. All of these data fit into a previously published model in which, during aging, plDNA is excised from mtDNA and becomes autonomous for replication and function.

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

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.

Transcription of a mitochondrial plasmid during senescence in Podospora anserina

In the ascomycete fungus Podospora anserina, cellular senescence is characterized by the excision, circularization, and amplification of specific segments of the non-senescent mitochondrial genome. During senescence, various plasmids can be found in the mitochondria, and different senescent events produce different plasmid populations. In this paper we have examined the transcriptional activity of one mitochondrial plasmid (α-sen DNA) and have contrasted this with the non-senescent mitochondrial genome of rapidly (A(+)) and slowly (s(+)) senescing races. In non-senescent and senescent mitochondria we observe two RNAs which are homologous to α-sen DNA and to the parental locus on the native genome. These are 2.4 and 2.5 kb long and have different 5' ends while overlapping throughout most of their lengths. They may represent different transcripts for α-sen DNA and the parental genome and indicate that excision of the plasmid begins 450 bp from the 5' end of the genomic coding sequence. Transcription of the α-sen DNA plasmid appears to be active in both senescent and in non-senescent mycelia.

Role of Mitochondrial DNA in the Senescence and Hypovirulence of Fungi and Potential for Plant Disease Control

The unique coenocytic anatomy of the mycelia of the filamentous fungi and the formation of anastomoses between hyphae from different mycelia enable the intracellular accumulation and infectious transmission of plasmids and mutant mitochondrial DNAs (mtDNAs) that cause senescence. For reasons that are not fully apparent, mitochondria that are rendered dysfunctional by so-called "suppressive" mtDNA mutations proliferate rapidly in growing cells and gradually displace organelles that contain wild-type mtDNA molecules and are functional. The consequence of this process is senescence and death if the suppressive mtDNA contains a lethal mutation. Suppressive mtDNA mutations and mitochondrial plasmids can elicit cytoplasmically transmissible "mitochondrial hypovirulence" syndromes in at least some of the phytopathogenic fungi. In the chestnut-blight fungus Cryphonectria parasitica, the pattern of asexual transmission of mutant mtDNAs and mitochondrial plasmids resembles the pattern of "infectious" transmission displayed by the attenuating virus that is most commonly used for the biological control of this fungus. At least some of the attenuating mitochondrial hypovirulence factors are inherited maternally in crosses, whereas the viruses are not transmitted sexually. The natural control of blight in an isolated stand of chestnut trees has resulted from the invasion of the local population of C. parasitica by a senescence-inducing mutant mtDNA. Moreover, a mitochondrial plasmid, pCRY1, attenuates at least some virulent strains of C. parasitica, suggesting that such factors could be applied to control plant diseases caused by fungi.

A causal link between respiration and senescence in Podospora anserina

Senescence, a progressive degenerative process leading to age-related increase in mortality, is found in most eukaryotes. However, the molecular events underlying aging remain largely unknown. Understanding how longevity is regulated is a fundamental problem. Here we demonstrate that the respiratory function is a key factor that contributes to shortening lifespan of the filamentous fungus Podospora anserina. In this organism, senescence is systematically associated with mitochondrial DNA instabilities. We show that inactivation of the nuclear COX5 gene encoding subunit V of the cytochrome c oxidase complex leads to the exclusive use of the alternative respiratory pathway and to a decrease in production of reactive oxygen species. This inactivation results in a striking increase of longevity associated with stabilization of the mitochondrial chromosome. Moreover, accumulation of several senescence-specific mitochondrial DNA molecules is prevented in this nuclear mutant. These findings provide direct evidence of a causal link between mitochondrial metabolism and longevity in Podospora anserina.

Senescence is coupled to induction of an oxidative phosphorylation stress response by mitochondrial DNA mutations inNeurospora

In Neurospora and other genera of filamentous fungi, the occurrence of a mutation affecting one or several genes on the chromosome of a single mitochondrion can trigger the gradual displacement of wild-type mitochondrial DNA by mutant molecules in asexually propagated cultures. As this displacement progresses, the cultures senesce gradually and die if the mitochondrial mutation is lethal, or develop respiratory deficiencies if the mutation is nonlethal. Mitochondrial mutations that elicit the displacement of wild-type mitochondrial DNAs are said to be "suppressive." In the strictly aerobic fungi, suppressiveness appears to be associated exclusively with mutations that diminish cytochrome-mediated mitochondrial redox functions and, thus, curtail oxidative phosphorylation. In Neurospora, suppressiveness is connected to a regulatory system through which cells respond to chemical or genetic insults to the mitochondrial electron-transport system by increasing the number of mitochondria approximately threefold. Mutant alleles of two nuclear genes, osr-1 and osr-2, affect this stress response and abrogate the suppressiveness of mitochondrial mutations. Therefore, we propose that mitochondrial mutations are suppressive because their phenotypic effect is limited to the organelles within which the mutant DNA is located. Consequently, mitochondria that are "homozygous" for a mutant allele are functionally crippled and are induced to proliferate more rapidly than the normal mitochondria with which they coexist in a common protoplasm. While this model provides a plausible explanation for the suppressiveness of mitochondrial mutations in the strictly aerobic fungi, it may not account for the biased transmission of mutant mitochondrial DNAs in the facultatively anaerobic yeasts. Key words: mitochondria, mitochondrial DNA, mutations, suppressiveness, oxidative phosphorylation, stress response.

A mitochondrial DNA rearrangement and three new mitochondrial plasmids from long-lived strains of Podospora anserina

The excision-junction sites of a mtDNA rearrangement of a long-lived strain of Podospora anserina, Mn19, were cloned and sequenced. Analysis of sequence and hybridization data lead to the conclusion that the Mn19 mtDNA consists of two nonoverlapping circular molecules. Three plasmids, LMt-2, LMt-3, and LMt-4, cloned from long-lived progeny of crosses between the Mn19 strain and wild type were cloned and sequenced. These plasmids share features and excision-junction sites with previously described longevity and senescence plasmids. The Mn19 mtDNA rearrangement and plasmids LMt-2, LMt-3, and LMt-4 are described. The possible significance of similarities to previously described plasmids is discussed.

An evolutionary comparison of homologous mitochondrial plasmid DNAs from three Neurospora species

We have discovered a mitochondrial DNA plasmid in N. crassa 516 (Roanoke, LA) which is homologous to those previously described from N. intermedia 435 (Fiji) and N. tetrasperma 2510 (Hanalei, HA). Subsequent analysis by DNA-DNA hybridization showed that 6 of 14 other Louisiana N. crassa isolates possessed plasmids homologous to these three plasmids, but at lower copy number. Plasmids from the three named strains were studied to examine possible plasmid diversity within each isolate, the extent of the homology between the plasmids, and the possibility that these plasmids could be inherited separately from their host mitochondria. Comparison of cloned plasmids and covalently closed circular mitochondrial DNA showed that only one plasmid line was present in each of the three intensively studied isolates. DNA-DNA hybridization and restriction endonuclease site mapping showed that the mitochondrial plasmids from the three species were very similar; most of the variation was due to presumed nucleotide substitutions. Plasmids judged identical by our analysis were found in different species. The distribution of the homologous plasmids in nature and the presence of these identical plasmids in different species, suggested that these plasmids could be transmitted between isolates independently of their host mitochondria.

Circular mitochondrial genome of Candida albicans contains a large inverted duplication

The mitochondrial DNA (mtDNA) of the dimorphic fungus Candida albicans has a molecular size of 41 kilobase pairs as judged by summation of the fragment sizes produced by digestion with restriction endonucleases EcoRI, PvuII, and a combination of both enzymes. Five of the six EcoRI fragments comprising the mitochondrial genome have been cloned into the plasmid vector, pBR322. Restriction mapping revealed a circular map as predicted by previous observations with the electron microscope. The use of nick-translated, purified mtDNA to probe digests of mtDNA from other strains of C. albicans revealed a common restriction pattern. Use of nick-translated, cloned EcoRI fragments to probe digests of mtDNA revealed a large (at least 5 kilobase pairs), inverted duplication as well as a smaller (less than 0.4 kilobase pairs) region of related sequences.

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.

Insertion of a foreign nucleotide sequence into mitochondrial DNA causes senescence in Neurospora intermedia

The kalilo variants of Neurospora contain a cytoplasmic genetic factor that causes senescence. This factor is a 9.0 kb transposable element (kalDNA) that lacks nucleotide sequence homology with mtDNA and is inserted into the mitochondrial chromosome, often at sites located within the open reading frame in the intron-DNA of the mitochondrial 25S-rRNA gene. Genomes containing the "foreign" DNA insert accumulate during growth, and death occurs as the cells become deficient in functional large and small subunits of mitochondrial ribosomes. The kalDNA transposon may be an "activator" element that causes breaks in mtDNA. Nonsenescing [+] strains of Neurospora do not contain kalDNA.

Introns, protein syntheses and aging

In the fungus Podospora, a correlation has recently been established between the presence of circular DNA molecules arising from the mitochondrial genome (SEN-DNAs) and the senescence syndrome. Here, I propose a hypothesis which accounts for the initial event which leads to the first SEN-DNA. A molecule in the most frequent situation where the SEN-DNA is an intron which might code for a maturase. This hypothesis is based upon several observations made either in Podospora or in the yeast S. cerevisiae. It assumes that mitochondrially synthesized maturases are unspecific nucleases able to work at the level of RNA and DNA molecules. Their specificity for RNA splicing instead of DNA is given by cytoplasmic proteins. Therefore, if the balance between cytoplasmic and mitochondrial protein syntheses is disturbed in favour of the mitochondrial compartment, the maturase would be accumulated and allowed to splice introns from DNA instead of RNA molecules. This hypothesis can account for aging of higher eucaryotic cells by postulating analogous processes in their nuclear compartment.

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.

Are mitochondrial structural genes selectively amplified during senescence in Podospora anserina?

Genetic and transcriptional maps have been constructed for the mitochondrial genome of the Ascomycete Podospora anserina. These data have been plotted on the restriction maps for Sal I, Xho I, Bam HI, Eco RI, BgI II and Hae III. We have characterized and cloned a new and unique senescent mitochondrial DNA (beta-event senDNA) and have organized all of the recognized senDNAs on the genomic maps. We make the observation that all of the known and characterized senDNAs are derived from specific genes or gene regions of the young mitochondrial genome. We have unambiguously assigned the alpha-event senDNA (the 2.6 kb monomer) to the oxi3 gene locus and the beta-event senDNA to the oxi2 gene locus.

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.

Amplification of a mitochondrial DNA sequence in the cytoplasmically inherited 'ragged' mutant of Aspergillus amstelodami

A comparison has been made between mtDNA of the cytoplasmically inherited 'ragged' mutant of Aspergillus amstelodami and that of the wild-type strain. Ragged mitochondria contain both the wild-type mitochondrial genome and several large DNA molecules which are not cleaved by the restriction endonucleases BamHI, HaeIII, HhaI, HindII, HindIII, PstI and MboI, but are converted by either EcoRI or HpaII into a single 820-840 base-pair fragment. Restriction analysis and molecular hybridization data indicate that this fragment contains sequences of wild-type mtDNA located within a 1200-base-pair segment of the 40,500-base-pair genome, for which a basic restriction map has been deduced. It is concluded that in the ragged mutant a small segment of wild-type mtDNA has been amplified as tandem repeats, which is reminiscent of the Rho- petite phenotype of yeast. The results are discussed in relation to the phenomenon of senescence in Podospora anserina.

Chromosomal and extrachromosomal control of senescence in the ascomycete Podospora anserina

In Podospora anserina senescence leading to cellular death occurs regularly after prolonged vegetative propagation. However, the life span of this ascomycete may be extended by various means: 1. Mutations in a least 8 morphogenetic genes belonging to 4 linkage groups postpone drastically or even prevent in certain pairwise combinations (e.g. i viv) the onset of senescence. 2. Inhibitors of mt DNA and of mitochondrial protein synthesis show a life prolonging effect when added in low concentrations to the growth medium. 3. A similar effect was found when mycelia were fed exclusively on non repressive carbon sources. Whereas the anti-aging effect of specific mutated genes is rather permanent, the life prolonging action of the inhibitors and carbon sources is restricted and temporary. These substances have no long lasting effect, since after their removal from the medium aging proceeds. Physiological experiments have further shown the existence of three phases in the life span of Podospora anserina. During the juvenile phase aging is prevented by all of these compounds; during the presenescent phase aging is prevented by inhibitors of mt DNA only, and during the senescent phase aging is irreversible. Senescence may be induced in juvenile protoplasts by DNA extracted from senescent mycelia. This, together with the well known fact that senescence is extrachromosomically inherited, points to extrachromosomal DNA as the causative agent of senescence. This kind of DNA may be connected with or perhaps located in the mitochondria. Collectively, the data are consistent in showing that the syndrome of senescence in Podospora anserina is controlled by a chromosomal-extrachromosomal interaction. In this system, extrachromosomal DNA, perhaps a mt DNA, is identical with the infectious principle initiating the decay of the cell, and nuclear genes supervise its expression.

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 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.