Mitochondrial metabolism and aging in the filamentous fungus Podospora anserina

The filamentous fungus Podospora anserina has a limited lifespan. In this organism, aging is systematically associated to mitochondrial DNA instability. We recently provided evidence that the respiratory function is a key determinant of its lifespan. Loss of function of the cytochrome pathway leads to the compensatory induction of an alternative oxidase, to a decreased production of reactive oxygen species and to a striking increase in lifespan. These changes are associated to the stabilization of the mitochondrial DNA. Here we review and discuss the links between these different parameters and their implication in the control of lifespan. Since we demonstrated the central role of mitochondrial metabolism in aging, the same relationship has been evidenced in several model systems from yeast to mice, confirming the usefulness of simple organisms as P. anserina for studying lifespan regulation.     

Identification of autophagy as a longevity-assurance mechanism in the aging model Podospora anserina

The filamentous ascomycete Podospora anserina is a well-established aging model in which a variety of different pathways, including those involved in the control of respiration, ROS generation and scavenging, DNA maintenance, proteostasis, mitochondrial dynamics, and programmed cell death have previously been demonstrated to affect aging and life span. Here we address a potential role of autophagy. We provide data demonstrating high basal autophagy levels even in strains cultivated under noninduced conditions. By monitoring an N-terminal fusion of EGFP to the fungal LC3 homolog PaATG8 over the lifetime of the fungus on medium with and without nitrogen supplementation, respectively, we identified a significant increase of GFP puncta in older and in nitrogen-starved cultures suggesting an induction of autophagy during aging. This conclusion is supported by the demonstration of an age-related and autophagy-dependent degradation of a PaSOD1-GFP reporter protein. The deletion of Paatg1, which leads to the lack of the PaATG1 serine/threonine kinase active in early stages of autophagy induction, impairs ascospore germination and development and shortens life span. Under nitrogen-depleted conditions, life span of the wild type is increased almost 4-fold. In contrast, this effect is annihilated in the Paatg1 deletion strain, suggesting that the ability to induce autophagy is beneficial for this fungus. Collectively, our data identify autophagy as a longevity-assurance mechanism in P. anserina and as another surveillance pathway in the complex network of pathways affecting aging and development. These findings provide perspectives for the elucidation of the mechanisms involved in the regulation of individual pathways and their interactions.     

Stress-dependent opposing roles for mitophagy in aging of the ascomycete Podospora anserina

Mitochondrial dysfunction is causatively linked to organismal aging and the development of degenerative diseases. Here we describe stress-dependent opposing roles of mitophagy, the selective autophagic degradation of mitochondria, in aging and life-span control. We report that the ablation of the mitochondrial superoxide dismutase which is involved in reactive oxygen species (ROS) balancing, does not affect life span of the fungal aging model Podospora anserina, although superoxide levels are strongly increased and complex I-dependent respiration is impaired. This unexpected phenotype depends on functional autophagy, particularly mitophagy, which is upregulated during aging of this mutant. It identifies mitophagy as a prosurvival response involved in the control of mitohormesis, the well-known beneficial effect of mild mitochondrial oxidative stress. In contrast, excessive superoxide stress turns mitophagy to a prodeath pathway and leads to accelerated aging. Overall our data uncover mitophagy as a dynamic pathway that specifically responds to different levels of mitochondrial oxidative stress and thereby affects organismal aging.     

Impact of ROS on ageing of two fungal model systems: Saccharomyces cerevisiae and Podospora anserina

To provide a foundation for the development of effective interventions to counteract various age-related diseases in humans, ageing processes have been extensively studied in various model organisms and systems. However, the mechanisms underlying ageing are still not unravelled in detail in any system including rather simple organisms. In this article, we review some of the molecular mechanisms that were found to affect ageing in two fungal models, the unicellular ascomycete Saccharomyces cerevisiae and the filamentous ascomycete Podospora anserina. A selection of issues like retrograde response, genomic instability, caloric restriction, mtDNA reorganisation and apoptosis is presented and discussed with special emphasis on the role reactive oxygen species (ROS) play in these diverse molecular pathways.     

Cyclophilin D links programmed cell death and organismal aging in Podospora anserina

Cyclophilin D (CYPD) is a mitochondrial peptidyl prolyl‐cis,trans‐isomerase involved in opening of the mitochondrial permeability transition pore (mPTP). CYPD abundance increases during aging in mammalian tissues and in the aging model organism Podospora anserina. Here, we show that treatment of the P. anserina wild‐type with low concentrations of the cyclophilin inhibitor cyclosporin A (CSA) extends lifespan. Transgenic strains overexpressing PaCypD are characterized by reduced stress tolerance, suffer from pronounced mitochondrial dysfunction and are characterized by accelerated aging and induction of cell death. Treatment with CSA leads to correction of mitochondrial function and lifespan to that of the wild‐type. In contrast, PaCypD deletion strains are not affected by CSA within the investigated concentration range and show increased resistance against inducers of oxidative stress and cell death. Our data provide a mechanistic link between programmed cell death (PCD) and organismal aging and bear implications for the potential use of CSA to intervene into biologic aging.     

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.     

Chromosomal and extrachromosomal control of senescence in the ascomycete Podospora anserina.

Summary 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:I. Mutations in at 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 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 protein quality control during biogenesis and aging

Mitochondrial dysfunction has long been associated with the aging process and the onset of numerous diseases. Regulation of the complex protein-folding environment within the organelle is essential for maintaining efficient metabolic output. Over time, dysregulation of protein homeostasis arises through stress induced by the accumulation of reactive oxygen species and mutations in the mitochondrial genome introduced during replication. To preserve organelle function during biogenesis, remodeling and stress, quality control of mitochondrial proteins must be monitored by molecular chaperones and proteases stationed in the four compartments of the organelle. Here, we review mitochondrial protein quality control with a focus on organelle biogenesis and aging.     

The phenoloxidases of the Ascomycete Podospora anserina

Summary In order to learn the internal conditions for the production of the various phenoloxidases produced by the Ascomycete Podospora anserina the wild strain has been grown under controlled conditions in a fermenter for a period of 34 days. Samples were withdrawn at regular intervals and assayed for mycelial yield and intra- and extracellular phenoloxidase production.Maximal yield was obtained at the following age of the culture: Mycelial production 9 d, tyrosinase 4 d, the high molecular weight laccase I between 9 and 19 d. The low molecular weight laccases II and III, initially present in medium concentrations, dropped to an early minimum after 4 days, followed by an increase with a maximum in the late autolytic phase.The changes in the phenoloxidase spectrum and the antiparallel production curve for the high molecular weight against the low molecular weight laccases are discussed in relation to the earlier observed genetical and physiological control of phenoloxidase synthesis and in relation to the possibility of laccase I being composed of active subunits of low molecular weight laccases.With support of the Deutsche Forschungsgemeinschaft, Bad Godesberg (Germany).     

Genetic control of an epigenetic cell degeneration syndrome in Podospora anserina

Filamentous fungi frequently present degenerative processes, whose molecular basis is very often unknown. Here, we present three mutant screens that result in the identification of 29 genes that directly or indirectly control Crippled Growth (CG), an epigenetic cell degeneration of the filamentous ascomycete Podospora anserina. Two of these genes were previously shown to encode a MAP kinase kinase kinase and an NADPH oxidase involved in a signal transduction cascade that participates in stationary phase differentiations, fruiting body development and defence against fungal competitors. The numerous genes identified can be incorporated in a model in which CG results from the sustained activation of the MAP kinase cascade. Our data also emphasize the complex regulatory network underlying three interconnected processes in P. anserina: sexual reproduction, defence against competitors, and cell degeneration.