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.

Introduction

Biological aging is a complex process controlled by stochastic, environmental, and genetic traits. A multitude of theories have been put forward to explain aging. Common to a number of theories- is an impact of the age-dependent accretion of damage leading to cumulative functional impairments and ultimately to cellular death. The accumulation of damaged cellular components strongly depends on the rate of reactions leading to damage and the persistence of the resulting material. The first process can be modulated by controlling the abundance of reactive oxygen species (ROS) via both their generation and by scavenging processes. Persistence of damaged compounds depends on the effectiveness of different types of surveillance systems including repair, degradation, and remodeling of damaged components (for a review see ref. 8). Autophagy is one of the pathways leading to the degradation of damaged biomolecules and organelles.

Podospora anserina is an established aging model to study basic mechanisms of organismic aging. This filamentous ascomycete is characterized by a limited, short life span which is depending on the genetic constitution and on growth conditions. Aging of individuals can be followed macroscopically, since hyphal morphology changes during senescence of this fungus. P. anserina is accessible to experimental manipulation both by classical genetics as well as by genetic engineering.- The consequences of such manipulations can be analyzed by established techniques. Over the years, various pathways including those linked to DNA instability and maintenance,- copper homeostasis,, and ROS scavenging- have been demonstrated to affect aging. More recently, different quality control pathways were investigated and found to be effective at different levels. In particular, it has been found that overexpression of PaLon encoding a mitochondrial matrix protease leads to an increased healthy life span while the deletion of the gene shortens life span. PaCLPP, another mitochondrial matrix protease, and PaIAP, the iAAA protease of the inner mitochondrial membrane of P. anserina, are involved in temperature-dependent protein quality control., Finally, the manipulation of reactions of the apoptotic cell death machinery, that brings the life of P. anserina to an end, has been found to strongly affect life span.-

In a recent computational study, published data have been used to integrate different pathways involved in the control of the quality of mitochondria. In this mathematical model, the generation of molecular damage, spread of damage, biogenesis of cellular components, mitochondrial fission and fusion, and mitophagy, as a type of selective autophagy, are modeled and simulated. The results indicate that the analyzed pathways effectively cooperate in a regulated way to keep mitochondria functional over time., While the role of mitochondrial dynamics on aging was first reported in P. anserina and the impact of the generation of damage has been previously demonstrated, the impact of autophagy on aging has not been investigated yet although autophagy has been studied in the context of vegetative incompatibility between strains of different genotypes and found to protect cells against death.-

Here, we address the impact of autophagy on aging and life span of P. anserina. We report the adaptation and use of tools developed for autophagy studies in yeast and higher eukaryotes and show that autophagy acts as a longevity-assurance mechanism.

Results

The abundance of autophagosomes increases under nitrogen starvation and during aging

In a first series of experiments, we set out to investigate whether autophagy is induced by nitrogen starvation and during aging of P. anserina. For these analyses, a Gfp-PaAtg8 strain was generated, which expresses an N-terminal fusion of the GFP protein to PaATG8, the fungal ATG8 ortholog (in mammals MAP1LC3, hereafter referred to as LC3). Labeling of ATG8/LC3 allows the visualization of the translocation of the fusion protein from the cytosol to the autophagosome to the vacuole, where the final degradation of the autophagosome takes place in fungi.

Fluorescence microscopy revealed that in juvenile strains (4 d old, grown on nitrogen-replete medium) GFP-PaATG8 was mostly diffusely distributed within the cytoplasm. During nitrogen starvation on medium lacking urea as a nitrogen source, a well-known regime to induce autophagy in other systems,- the fusion protein is localized in bright punctate structures in nearly all hyphae (Fig. 1A), indicating that autophagy is induced under these conditions also in P. anserina. Although autophagosomes are visible, the GFP signal is not seen in the vacuole after 1 d on nitrogen-replete medium, an observation consistent with earlier findings of Pinar et al. in Aspergillus nidulans. Surprisingly, and in contrast to A. nidulans, in P. anserina also under nitrogen depletion the GFP-stained vacuoles are not detectable after this short period of time. However, prolonged incubation on this medium leads to the accumulation of the GFP signal in the vacuole (Fig. 1A).

Figure 1. Comparative fluorescence microscopy analysis of juvenile vs. senescent P. anserina Gfp-PaAtg8 strains. (A) GFP-PaATG8 distributes diffusely to the cytoplasm in the juvenile (4 d old) hyphae on M2 medium while the number of punctate autophagosome-like structures is strongly increased during 1 d incubation on nitrogen-depleted medium (M2-N). Longer incubation (2 d) leads to the delivery of GFP-PaATG8 to vacuoles and further degradation. (B) In senescent cultures (20 d), GFP-PaATG8 localizes to punctate autophagosome-like structures grown on M2-N and also on M2 medium indicating that autophagy increases with age. Scale bar: 10 μm. (C) Quantification of punctate autophagosome-like structures per area for hyphae of juvenile and senescent P. anserina cultures, grown on M2 and M2-N. Error bars correspond to the standard error (n = 10). P values were determined between juvenile and senescent wild type grown on M2 medium, respectively M2-N medium and also between juvenile wild-type strains grown on M2 and M2-N medium by 2-tailed Wilcoxon rank-sum test (P < 0.01). (A–C): Nitrogen-replete: M2 medium supplemented with nitrogen (0.5 g/L urea); nitrogen-depleted: M2-medium without nitrogen.

Next, we analyzed whether or not autophagy is upregulated during aging of P. anserina. We compared the localization of the fusion protein in young (4 d old) and senescent (20 d old) Gfp-PaAtg8 strains grown on nitrogen-replete (M2), as well as on nitrogen-depleted medium (M2-N), and quantified autophagosomes in the different cultures. In old cultures, a strong translocation of the fusion protein to punctate autophagosome-like structures was observed suggesting a strong upregulation of autophagy during aging (Fig. 1B and C). In senescent cultures, N-starvation was found to lead only to a slight increase of autophagosomes in comparison to senescent cultures grown on nitrogen-replete M2 medium (Fig. 1B and C). For visualization of the vacuoles, differential interference contrast microscopy (DIC) was used in addition to fluorescence microscopy (Fig. S1A and S1B).

The autophagy-dependent degradation of a GFP fusion protein increases during aging

The determination of punctate GFP-ATG8 signals as a measure for the intensity of autophagy has to be viewed critically. An increase in number of autophagosomes may reflect an upregulation of autophagy but as well it may result from an accumulation of autophagosomes due to an impairment of their translocation to the vacuole and the subsequent degradation. Consequently, in order to discriminate between the 2 possibilities, we used a modified experimental approach that originally was developed to monitor mitophagy in yeast., In this approach, in principle, the fate of a GFP fusion protein is followed. Upon degradation via autophagy, the processed GFP remains stable and can be detected by western blot analysis. To test whether this assay also works in P. anserina, 3 fusion proteins with different cellular localizations were analyzed: PaSOD1-GFP, PaSOD2-GFP, and PaSOD3-GFP. The corresponding strains are described in Zintel et al. PaSOD1-GFP is localized in the cytosol, PaSOD2-GFP in the perinuclear ER and PaSOD3-GFP in mitochondria. Total protein extracts were subjected to western blot analysis with a GFP antibody. As expected, the most prominent signal of processed GFP is found in PaSod1-Gfp, since this protein is highly abundant in total protein extracts. As a mitochondrial protein PaSOD3 is under-represented in total protein extracts of the PaSod3-Gfp strain. Thus, only the processed GFP is visible. Interestingly, while the PaSOD2-GFP is abundantly found in the extracts of the PaSod2-Gfp strain, no processed GFP is detectable (Fig. 2A). This suggests that the cytosolic as well as the mitochondrial PaSOD isoforms are degraded via autophagy but not the ER-located and presumably secreted PaSOD2.

Figure 2. Autophagy-induced protein degradation during aging. (A) Western blot analysis of total protein extracts from different PaSod-Gfp strains. GFP processing was monitored by immunoblotting with anti-GFP and anti-SOD1 (loading control) antibody. (B) Southern blot analysis of HindIII digested genomic DNA from PaSod1-Gfp and the Paatg1Δ PaSod1-Gfp double mutant. The Gfp-specific hybridization probe in the upper part detects a ~9.5 kb fragment containing Gfp in both strains. The PaAtg1-specific hybridization probe in the middle part detects the 6.5 kb fragment of the PaAtg1 gene only in the genomic DNA of the PaSod1-Gfp strain. The gene encoding the phleomycin resistance gene (Ble) is only present as a 6.5 kb fragment in the genomic DNA of the double mutant (lower part). (C) Monitoring autophagy by western blot analysis using the cytosolic protein PaSOD1-GFP during starvation. Wild-type (WT) and Paatg1Δ strains expressing PaSOD1-GFP were cultured in CM medium then shifted to CM-N medium for 0, 4, 6, and 24 h. GFP processing was monitored by immunoblotting with anti-GFP and anti-SOD1 (loading control) antibody. The positions of molecular mass markers are indicated on the right. (D) Monitoring autophagy by western blot using the cytosolic protein PaSOD1-GFP of juvenile and senescent cultures. Six and 20 d old wild-type (WT), and middle-aged (m.a.) Paatg1Δ strains expressing PaSod1-Gfp were cultured in CM medium for 2 d. GFP processing was monitored by immunoblotting with anti-GFP and anti-SOD1 antibody (loading control). The positions of molecular mass markers are indicated on the right. (E) The GFP protein levels of the PaSod1-Gfp strains (n = 7) were normalized to the level of SOD1, and the protein amount present in the 6 d old strain was set to 1. The 20 d old strain possesses a nearly 5-fold higher protein amount than the 6 d old PaSod1-Gfp strain. Error bars correspond to the standard error. P values were determined between juvenile (6 d old) and senescent (20 d old) PaSod1-Gfp (P < 0.001) by 2-tailed Wilcoxon rank-sum test. The arrow marks the processed GFP. (A), (C–E): CM medium = supplemented with nitrogen (NH4Cl: 3.7 g/L); CM-N medium = CM medium without nitrogen.

To verify that the occurrence of processed GFP is indeed depending on a functional autophagy machinery, a strain lacking PaATG1, the serine/threonine kinase at the start of the autophagy-induction cascade was constructed (Fig. S2A). Previously, Pinan-Lucarré et al. have reported, that in a P. anserina strain lacking PaATG1, autophagy does not occur. To follow the fate of PaSOD1-GFP in the genetic background of the Paatg1 deletion, a double mutant was constructed (Fig. 2B). Total protein extracts of this strain (Paatg1Δ PaSod1-Gfp) were isolated and analyzed by western blot analysis using GFP antibodies. As expected, in the genetic background of a Paatg1 deletion strain, no processed GFP is visible even under nitrogen-depleted conditions (Fig. 2C). Thus, the occurrence of processed GFP depends on autophagy and the amount of GFP is a measure for autophagy in P. anserina. Obviously, P. anserina is characterized by a high level of basal autophagy because even under conditions with sufficient nitrogen a pronounced band of the processed GFP is visible in the PaSod1-Gfp strain.

Next, we tested the effect of nitrogen starvation on the amount of processed GFP. Short-time nitrogen starvation (4 to 6 h) results in a decline in the amount of processed GFP, while prolonged nitrogen starvation (24 h) leads to a substantial increase (Fig. 2C). It is possible that this effect results from the activity of other factors, like an increased proteasome activity or simply because this short period of time is not sufficient to induce a nitrogen starvation response. During aging, a pronounced and significant increase in the amount of processed GFP can be detected in strains of old age (i.e., 20 d), strongly supporting the microscopic observations with the Gfp-PaAtg8 strain that aging in P. anserina is accompanied by enhanced autophagy (Fig. 2D and E).

Autophagy is involved in development and functions as a longevity-assurance mechanism

In an earlier publication the Paatg1Δ mutant was studied in detail with respect to its role in the vegetative incompatibility reaction between fungal strains of unlike genotype. In this study several developmental defects of the mutant were observed compared with the wild type including a slightly reduced growth rate, a lower density of aerial hyphae on rich media, a decreased pigmentation of the mycelium and the inability to form protoperithecia (the female reproductive organ) leading to female sterility. These different phenotypic characteristics were fully restored by complementation with a wild-type copy of the Paatg1 gene. In our study, we constructed an independent Paatg1 deletion strain based on a protocol described in Hamann et al. (Fig. S2A) and observed similar phenotypic characteristics of the mutant as described earlier (Fig. S2B and S2C). In addition, we tested the germination capability of monokaryotic spores isolated from a cross between 2 wild-type strains, and a cross between the wild type and the deletion mutant (Fig. 3A). The spores of the latter cross showed a significant decrease in germination rate. To test whether both, the wild-type spores as well as the spores carrying the deletion are affected, the resistance of the germinated spores was determined. From 236 germinated ascospores of a cross of the wild-type strain and Paatg1Δ, theoretically 50% (= 118) should possess the allele with the deletion, detectable as phleomycin resistance. However, only 33 (= 14% of all spores) formed phleomycin-resistant mycelia and are therefore carrying the Paatg1 deletion (Fig. 3B). This is a smaller number than the expected 50% phleomycin-resistant offspring, indicating impairment in germination of the Paatg1Δ spores. As described before, the deletion strain is virtually female sterile, however, male fertility is not impaired, since spermatization of wild-type mycelium with Paatg1Δ spermatia (the male gametes) does not significantly reduce the amount of fruiting bodies (Fig. S2D).

Figure 3. Characterization of the Paatg1∆ strain. (A) The germination rate of ascospores from perithecia of fertilized Paatg1Δ (n = 10) and WT cultures (n = 10). P values (P < 0.001) were determined in comparison with the wild-type sample by 2-tailed Wilcoxon rank-sum test. (B) Determination of the genotype (Ble resistance) of ascospores of a Paatg1Δ × WT cross (n = 10). Colonies grown from germinated ascospores were transferred to phleomycin containing BMM medium. Grey/bright = spores germinated (Ble); red/dark = Ble spores germinated with Paatg1 deletion background. (C) Ascospore phenotype of spores from WT × WT and WT × Paatg1Δ crosses. Scale bar: 20 µm. (D) Growth rates of the WT (n = 27) and the Paatg1 deletion strain (n = 27; P < 0.001). P values were determined in comparison with the wild-type sample by 2-tailed Wilcoxon rank-sum test. (E) Life span of monokaryotic wild-type (n = 27; median life span = ~25 d) and Paatg1Δ (n = 27; median life span = ~21 d; P < 0.001) isolates on M2 medium at 27 °C. P values were determined in comparison with the wild-type sample by 2-tailed Wilcoxon rank-sum test. (F) Western blot analysis of total protein extracts from the Paatg1 deletion mutant and WT strains grown on CM or CM-N media, respectively. Incubation with anti-PaPRE3 (corresponding to the β1 subunit of the 20S proteasome) and anti-PaGLO1 antibody (glyoxalase 1) showed different protein amounts in the WT and Paatg1Δ strain and in response to nitrogen starvation compared with anti-SOD1 (loading control). (G) Life span of monokaryotic wild-type (n = 11; median life span = ~80 d) and Paatg1Δ (n = 20; median life span = ~25 d; P < 0.001) isolates at 27 °C on M2-N medium. P values were determined in comparison with the wild-type sample by 2-tailed Wilcoxon rank-sum test. (H) Growth rates of the WT (n = 11) and the Paatg1 deletion strain (n = 20; P < 0.01) on M2-N medium at 27 °C. P values were determined in comparison with the wild-type sample by 2-tailed Wilcoxon rank-sum test. M2 medium: supplemented with nitrogen (0.5 g/L urea); N: M2-medium without nitrogen.

The ascospores themselves display clear morphological aberrancies. Since spores are only formed in crosses between the wild type and Paatg1Δ, in each ascus the wild-type as well as the mutant allele is equally present. If no crossing-over occurs during meiosis between the centromer and the Paatg1 locus (prereduction), 2 of the 4 dikaryotic ascospores contain exclusively the wild-type allele, while the other 2 contain the Paatg1Δ allele. These latter 2 spores are bigger, darker and possess a clearly visible appendix (Fig. 3C). Normally, the appendix becomes hyaline during ripening of the spores and this process is delayed in the mutant, which implies that autophagy is involved in this process.

In accordance with the findings of Pinan-Lucarré et al., we also observed a slight but significant reduction of the growth rate of the Paatg1Δ strain (Fig. 3D). Next, we analyzed the growth rate of the Paatg1Δ strain compared with wild type during heat stress (37 °C) and exogenous oxidative stress conditions applied by paraquat treatment, a widely used redox cycler to stimulate superoxide production. Heat stress applied to either 3 or 17 d old Paatg1Δ isolates results in the same growth retardation as with wild-type isolates of the same age (Fig. S3A and S3B). In contrast, after paraquat treatment, 3 d as well as 17 d old Paatg1Δ isolates displayed a significantly increased sensitivity against higher paraquat concentrations (from 200 µM on in 3 d old cultures and from 250 µM on in 17 d old cultures) compared with the corresponding wild-type isolates (Fig. S3C and S3D). This increased sensitivity against oxidative stress is not unexpected, since autophagy is important for the clearance of damaged proteins.

The increase of autophagosomes in old P. anserina cultures suggests a role of autophagy in aging. In order to investigate this possibility further, we analyzed the impact of a Paatg1 deletion on life span. We found that the genetic disruption of the autophagy pathway leads to a significant decrease in life span even under noninduced conditions, which is an indication for the important role of selective autophagy in P. anserina (Fig. 3E). Moreover, the absence of autophagy and nitrogen limitation results in a slight upregulation of PaPRE3 (proteasome core particle subunit β1) (Fig. 3F), suggesting that the proteasome-dependent protein degradation acts as an alternative, compensatory mechanism in the mutant.

Recently, a link between autophagy and the glyoxalase system was reported. This pathway is involved in the detoxification of methylglyoxal, a byproduct of glycolysis which modifies proteins, lipids, and DNA. Therefore, in order to test whether failure to undergo autophagy leads to impairments in the degradation of damaged proteins, the glyoxalase I (PaGLO1) abundance was determined. Indeed, at the protein level, we found a slight upregulation in the abundance of PaGLO1 in the deletion mutant (Fig. 3F).

Since nitrogen starvation is known to induce autophagy, we next tested the impact of nitrogen starvation on the life span of the P. anserina wild-type and the Paatg1∆ strains. We found that both strains are characterized by an increased life span under nitrogen-depleted conditions. Remarkedly, this increase is much more pronounced in the wild-type background. The median life span in the Paatg1∆ strain was 21 d on M2 (Fig. 3E) and 25 d on M2-N (Fig. 3G) compared with a median life span of WT 25 d (Fig. 3E) on M2, and 95 d on M2-N (Fig. 3G). The growth rate of the deletion mutant under nitrogen depletion is slightly decreased compared with the wild type (Fig. 3H). The life span of WT is nearly 4-fold increased under nitrogen starvation, suggesting that the induction of autophagy indeed is highly beneficial for P. anserina and providing additional data supporting a longevity assurance function of autophagy.

Finally we investigated the effect of rapamycin on life span of P. anserina. This immunosuppressant drug is known to selectively inhibit the serine/threonine kinase target of rapamycin (TOR) and thereby stimulating autophagy in a variety of organisms comparable to starvation.- First, we tested the effect of the drug on the growth rate of the fungus (Fig. S4A). Addition of rapamycin to the growth medium resulted in a dose-dependent reduction in growth rate indicating that the drug is taken up by the hyphae from the medium. Next, we determined the median life span on media containing different amounts of rapamycin. A clear life span increasing effect was observed in medium containing 10 and 20 ng/ml rapamycin (Fig. S4B). Surprisingly, lack of PaATG1 does not prevent life-span extension by rapamycin demonstrating that this effect is not autophagy-dependent (Fig. S4C).

Discussion

Autophagy is a cellular degradation and recycling process that is highly conserved in eukaryotes. It is strictly regulated and affects various processes and pathways including the adaptation to starvation, turnover of damaged organelles, immunity and modulation of host defense, cell growth, aging, and development.- Depending on the cellular conditions, excessive autophagy may lead to a special kind of programmed cell death, referred to as the “autophagic cell death.”, However, this term describes cell death accompanied by autophagy, not necessarily the execution of cell death by autophagy. Overall experimental data rather support the prosurvival role of autophagy, since it has only very rarely been shown that downregulation of autophagy genes reduces cell death, while a huge number of studies describe an acceleration of cell death upon genetic suppression of autophagy.

In filamentous fungi it has been shown that the deletion of basic autophagy related genes like Atg1, Atg4, or Atg8 affect morphogenesis and development leading to a decrease in the formation of aerial hyphae, impaired conidiation, delayed spore germination, and defects in the formation of sexual organs and fruiting bodies.,,- Moreover, SmATG7 involved in the ATG8 and ATG12 conjugation pathway as well as the autophagic kinases SmVPS34 and SmVPS15 are required for viability in Sordaria macrospora., The results of our current study with P. anserina, which identified impairments in female fertility, spore differentiation, and germination in an atg1 deletion strain are consistent with these earlier findings and provide additional evidence for an essential role of autophagy in fungal development.

With its activity to degrade damaged molecules and impaired organelles, autophagy is a component of a network of pathways involved in quality control., In the past, we have demonstrated a number of different pathways to be part of such a network to affect aging and life span control in P. anserina (reviewed in refs. 8, 69, and 70). Until now, we had no experimental evidence for such an impact of autophagy. The microscopic identification of increased autophagosome numbers in senescent cultures and the biochemical demonstration of an increased degradation of GFP-labeled SOD1 during aging, reported in the current study, provides the first evidence. Here, we report for the first time, an impact of impaired autophagy on aging and life span of the fungal aging model P. anserina. This role is supported by the observation that the life span of the Paatg1 deletion strain is not increased under nitrogen starvation to the same extent as in the wild type. Similarly, it is reported that the inactivation of different autophagy relevant genes like unc-51, bec-1, or Igg-1 (Atg1, Beclin1, Lc3 in mammals) lead to a reduced life span in C. elegans.,-

The effects on aging, observed after perturbation of the autophagy machinery, can partially be explained by impairments in the degradation of damaged cellular components. However, a known “crosstalk” with the ubiquitin-proteasome system complicates the situation. While macroautophagy and the ubiquitin-proteasome system were formerly regarded as 2 separate cellular pathways with distinct functions, it is now clear that a number of proteins can be degraded by both autophagy and the proteasome.- Recent work suggests that the 2 systems “communicate” with each other under certain circumstances.- Different studies with yeast, Drosophila, and mammalian cells report that proteasome inhibition leads to the upregulation of autophagy.- Moreover, the observed increase in glyoxalase 1 (lactoylglutathione lyase, PaGLO1) is indicative for increased molecular stress due to a lack of autophagy, identifying a link of this cellular protection pathway to autophagy. In P. anserina, the glyoxalase system is relevant for aging. In mammals, Glo1 is transcriptionally controlled by NRF2 (also known as NFE2L2) and represents a stress-responsive system that protects proteins and DNA from damage.

Another relevant link is the interaction of autophagy to the activity of TOR, a central regulator of multiple cellular responses (reviewed in ref. 93). TOR inhibits autophagy via phosphorylation of ATG13 and is itself inactivated by low amino acid levels. In yeast it has been previously described that autophagy deficiency leads to the reduction of the total free amino acid pool and subsequent impaired protein synthesis under nutrient starvation conditions. Thus, autophagy deficiency can lead to TOR inactivation and thereby results in numerous pleiotropic effects. In previous studies, a life-span-prolonging effect originating from TOR inactivation via rapamycin is reported in different organisms.- However, only in a few cases, this increase is unequivocally correlated with Atg genes., Surprisingly, in P. anserina the life-span-prolonging effect of rapamycin treatment of the wild type turns out to be autophagy-independent and the result of other rapamycin or TOR-influenced pathways or cellular functions, such as cell growth and proliferation, ribosome biogenesis, transcription, mRNA translation, cytoskeletal reorganization, and others.

In our current study, we observed an induction of autophagy to occur during aging of P. anserina that is supported by a recent longitudinal genome-wide transcriptome analysis in which transcripts of autophagy-related genes have been found to increase in abundance during aging. This was a rather unexpected finding. In other systems like rats, mice, and human fibroblasts, a decrease in autophagy is reported.,- In contrast, in aged primary fibroblasts and in aged mouse brain, macroautophagy is increased. The reasons for these seemingly contradictory findings are not clearly understood but may reflect species-, tissue- and cell type-specific differences in the age-related regulation of autophagy. However, it appears to be the consensus that upregulation or maintenance of autophagy until advanced age is beneficial for cells and whole organisms by improving quality control and mitigating accumulation of altered cellular components within the aging cell.- Keeping a high activity of autophagy and of other quality control pathways at very old age may, however, be impaired after passing a critical threshold of cellular damage. This scenario is supported by the observation that—unlike in mammalian systems—nitrogen limitation is not able to increase formation of autophagosomes at old age (Fig. 1B), suggesting that the capacity of the autophagy machinery is at its limit in old P. anserina cultures. Consequently, the system finally dies.

In conclusion, with the development of appropriate tools and the demonstration of a clear impact of autophagy as a longevity-assurance mechanism, as well as the earlier demonstration of other quality control pathways to be effective in aging and life-span control in P. anserina, we are now in the position to specifically address important issues with the aim to integrate autophagy into the network of quality control pathways in this organism. One question we are currently addressing is the potential contribution of mitophagy as part of the longevity-assurance mechanisms active in P. anserina. An impact of this type of selective autophagy is likely since this aging model is characterized by a strong mitochondrial etiology of aging., Another point of special interest is to elucidate the regulation of autophagy as a potential compensatory mechanism in situations when other pathways fail. Such mechanisms may explain unexpected and counterintuitive experimental data as they are found in the literature and may unravel yet unknown regulatory circuits in which autophagy and other pathways play a key role.

Materials and Methods

Cloning procedures and generation of Podospora anserina mutants

The generation of the Gfp-PaAtg8 strain was performed by a 4-fragment ligation using a Gfp-containing plasmid (pSM4). The plasmid pSM4 is based on pSM2 which contains an eGfp gene without promoter region. Restriction of the pSM4-plasmid with NcoI (Thermo Scientific, ER0571) and NotI (Thermo Scientific, ER0591) leads to the removal of the eGfp. The PaAtg8 own promoter region (1052 bps) was amplified by PCR from a cosmid carrying the PaAtg8 genomic region using oligonucleotides Atg8-1 (5′-GGAAGCTTTT CGGTACTTGG GATCAG-3′, Biomers, Ulm, Germany) with restriction site for HindIII (Thermo Scientific, ER0501) and Atg8-2 (5′-TTGCCGGCGG GTTGGTTGTT GCT-3′, Biomers) with restriction site for EheI (Thermo Scientific, ER0441). Restriction sites were underlined. Together with the Gfp gene, the PaAtg8 promoter region was then ligated with the pKO6 plasmid. This plasmid contains the phleomycin resistance cassette of pKO4, restricted with EcoRI and Eco72I (Thermo Scientific, ER0361) ligated into EcoRI/EcoRV (Thermo Scientific, ER0271/ER0301) digested pBSSK (Agilent Technologies, 212205). Important for the creation of the Gfp-PaAtg8 plasmid is the unusual N-terminal fusion of the Gfp gene to the PaAtg8 gene, preventing proteolytical removal of Gfp by processing through the protease ATG4 during autophagy induction. Therefore Gfp had to be ligated in front of the PaAtg8 gene but behind the PaAtg8 own promoter. The open reading frame of PaAtg8 with the PaAtg8 terminator region was amplified by PCR from the cosmid using oligonucleotides Atg8-4 (5′-GGCTCGAGAA GCAATGAGGA ACAAGAGG-3′, Biomers) with restriction site for XhoI (Thermo Scientific, ER0691) (underlined) and phosphorylated Atg8-5 (5′-GGGATGAGAT CCAAGTTTA-3′, Biomers). These 2 fragments were cloned in the vector backbone of plasmid pKO6 (SalI [Thermo Scientific, ER0641], HindIII), which carries an ampicillin-resistance gene for selection in Escherichia coli and a phleomycin resistance gene for selection in P. anserina. Ligation of these fragments resulted in a plasmid called pAtg8eGfp2 which was finally used to transform P. anserina wild-type spheroplasts according to Osiewacz et al. and Stumpferl et al. Transformants were selected on phleomycin resistance (Ble) and used for fluorescence microscopy to analyze the localization of the GFP-PaATG8 fusion protein in hyphae.

The PaSod1-Gfp, PaSod2-Gfp, and PaSod3-Gfp strains used in this study for different western blot analysis are previously described by Zintel et al.

The generation of a Paatg1 deletion strain was performed as described previously based on a method originally described by Chaveroche et al. Small flanking regions of the PaAtg1 gene were amplified using the 5′-flank oligonucleotides Paatg1-KO1-1 (5′-CCGGTACCCC ACTTTCCTACA CCACCC-3′, Biomers) and Paatg1-KO1-2 (5′-CCCTGCAGGG CTACCTGCTG ATGTTGG-3′, Biomers), introducing KpnI (Thermo Scientific, ER0521) and PstI (Thermo Scientific, ER0611) restriction sites (underlined), and the 3′-flank oligonucleotides Paatg1-KO1-3 (5′-GGACTAGTCA AAGCTGACGA TTAACG-3′, Biomers) and Paatg1-KO1-4 (5′-GGGCGGCCGCA AAAAGAAAAA CGCGC-3′, Biomers), introducing NotI and BcuI (Thermo Scientific, ER1251) restriction sites (underlined). The 5′ fragment was digested with KpnI and PstI and the 3′ fragment was digested with BcuI and NotI. Meanwhile, deletion plasmid pKO4, was digested with all 4 restriction enzymes (KpnI, PstI, BcuI, and NotI) and a 4-fragment ligation was performed, resulting in the plasmid patg1KO1, containing both fragments flanking a phleomycin and blasticidin resistance cassette for fungal and bacterial selection. The resistance cassette with the flanking regions was excised by restriction with NotI and KpnI and transformed into the E. coli KS272 strain, containing the plasmid pKOBEG, and a cosmid bearing the PaAtg1 gene. The homologous recombination between the flanks of the resistance cassette and the cosmid causes the generation of a Paatg1Δ cosmid, containing the phleomycin-blasticidin cassette with large flanking genomic regions. Subsequently, the Paatg1Δ cosmid was transformed into the P. anserina wild-type spheroplasts. Selection of received transformants, were realized by growth on phleomycin (Genaxxon, M3429) containing medium. Successful deletion of PaAtg1 was indicated by phleomycin resistance accompanied by hygromycin (Calbiochem, 400051) sensitivity. The correct replacement of the PaAtg1 gene was verified by Southern blot analysis using a PaAtg1-specific probe and a phleomycin-specific probe (Fig. S2A). Positive strains, lacking the PaAtg1 gene and possessing the phleomycin gene instead, were finally termed Paatg1Δ.

Transformation of P. anserina spheroplasts

Production, regeneration, and the integrative transformation of P. anserina spheroplasts were performed as previously described.,

P. anserina strains and cultivation

In the present study the P. anserina wild-type strain “s”, the newly generated Paatg1-deletion (Paatg1Δ) and the Gfp-PaAtg8 strain were used as well as the Gfp strains PaSod1-Gfp, PaSod2-Gfp, and PaSod3-Gfp and the newly generated PaSod1-Gfp Paatg1Δ double mutant. All strains were constructed in the genetic background of the wild-type strain “s”. Strains were grown on standard cornmeal agar (BMM) at 27 °C under constant light conditions. For spore germination, the BMM medium was added with 60 mM ammonium acetate and the spores incubated at 27 °C in the dark for 2 d. All used strains originated from monokaryotic ascospores isolated from irregular asci.

Fertility and germination analysis

Female fertility was assessed as previously described. In principle, freshly isolated monokaryotic wild-type or Paatg1Δ isolates of both mating types were allowed to overgrow the surface of M2 agar (M2 medium: 0.25 g/L KH2PO4, 0.3 g/L K2HPO4, 0.25 g/L MgSO4 × 7 H2O, 0.5 g/L urea and 10 g/L yellow dextrin. Addition of 2.5 mg/L biotin, 50 mg/L thiamine, 5 mg/L citric acid × 1 H2O, 5 mg/L ZnSO4 × 7 H2O, 1 mg/L Fe(NH4)2 (SO4)2 × 6 H2O, 2.5 mg/L CuSO4 × 5 H2O, 25 mg/L MnSO4 × 1 H2O, 50 mg/L Na2MoO4 × 2 H2O and 50 mg/L H3BO3 after sterilization of the basal medium) plates at 27 °C under constant light. Spermatia (corresponding to male gametes) of these strains with the opposite mating type were harvested by flooding the plates with 5 ml of sterile water. The suspension was diluted 1:1 with sterile H2O and drops of 100 μl were pipetted onto mycelium of each wild type and Paatg1Δ. After 5 min, the drops were removed carefully and the strains were incubated for 4 d at 27 °C under constant light. The number of perithecia was counted and the resulting values were divided by the area of the drop. The number of perithecia developing on plates overgrown with the wild-type “s” were set to 100% fertility.

To determine the germination rate of spores from wild-type (s− × s+) crosses and wild-type × Paatg1Δ crosses (female sterility of the Paatg1Δ strain allowed only fertilization of Paatg1Δ− × s+, respectively Paatg1Δ+ × s−) monokaryotic spores were isolated from irregular asci. After 2 d incubation on germination medium (BMM medium added with 60 mM ammonium acetate) at 27 °C in the dark, the number of germinated spores was counted.

Southern blot analysis

Isolation of total DNA of P. anserina was realized by the protocol developed by Lecellier and Silar for rapid extraction of nucleic acids from filamentous fungi. DNA digestion, gel electrophoresis, and Southern blotting were performed according to standard protocols. For Southern blot hybridization and detection, digoxigenin-labeled hybridization probes (DIG DNA Labeling and Detection Kit, Roche Applied Science, 11175033910) were used according to the manufacturer’s protocol. The PaAtg1-specific hybridization probe was amplified by PCR using the oligonucleotides Atg1-3 (5′-TCAGCCATCT ACTTCAGC-3′, Biomers) and Atg1-4 (5′-TGCTTGTACT TGACCTCG-3′, Biomers). The PaAtg8-specific hybridization probe was amplified by PCR using the oligonucleotides Atg8-for (5′-CCCGCCAAAA TGAGATCC-3′, Biomers) and Atg8-rev (5′-CCAAAGGTGT TCTCGCCC-3′, Biomers) and the respective cosmids as template. As a hybridization probe specific for the phleomycin resistance gene (Ble), the 1293 bp BamHI-fragment (ER0051, Thermo Scientific) of the plasmid pKO4 was used. The 737 bp BcuI-/NcoI-fragment of the plasmid pSM4 was used as a hybridization probe specific for the Gfp gene.

Growth rate and life-span determination

Life span and growth rate of monokaryotic isolates on M2 medium were determined as described. The life span of P. anserina is defined as the time period (d) of linear hyphal growth whereas the growth rate is defined as the measured growth (cm) per time period (d). To determine the life span and growth rate under nitrogen starvation, the monokaryotic isolates were placed on race tubes containing M2 medium lacking the nitrogen source urea (M2-N). The determination of growth rates under stress conditions was performed on M2 medium added with different concentrations (0, 10, 50, 100, 200 and 250 µM) of paraquat (Sigma-Aldrich, 856177) at 27 °C, by incubation of the strains under heat stress conditions (37 °C) at constant light or on M2 medium to which different concentrations (0, 2.5, 5, 10, and 20 ng/mL) of rapamycin (Sigma-Aldrich, R8781) is added.

Light sheet-based fluorescence microscopy (LSFM)

In order to image P. anserina with the LSFM, pieces of P. anserina cultures (Gfp-PaAtg8: 4 respectively 20 d old) were grown on a coverslip, immersed in M2 or M2-N medium, and incubated in a “wet chamber” for 1 d at 27 °C and under constant light. The “wet chamber” consists of a petri dish filled with sterile wet tissue paper. Imaging was performed with a light sheet based fluorescence microscope, in its implementation monolithic digitally scanned light sheet-based fluorescence microscope (mDSLM) developed in Ernst Stelzer’s laboratory (Frankfurt, Germany). It is an improved and compact version of the DSLM described in Keller et al. The specimen was prepared as following. First, a 5 mm × 5 mm glass coverslip was glued with nail polish onto the custom mDSLM specimen holder (Fig. S5). Shortly before imaging, a 5 mm × 5 mm square portion of mycelium was cut with a scalpel out of the agarose slab. The square portion was then deposited onto the glass coverslip. In order to ensure a stable adhesion between glass and specimen, a small quantity of liquid low-melting agarose was deposited on the glass coverslip. Finally, the mounted specimen was vertically inserted in the mDSLM chamber containing the M2 or M2-N medium. The fluorescence in the specimen was excited by a light sheet generated by scanning a thin (FWHM—full width at half maximum—of the beam waist: 2 μm) laser light beam. The light sheet illuminates the specimen from the side. In order to resolve individual autophagosomes in the hyphae, we employed a pair of CZ Plan-Neofluar 5×/0.16 objective lens (Carl Zeiss Microscopy, Jena, Germany) for the illumination (thickness of light sheet ~2 μm) and a CZ Plan-Apochromat 63× /1.0 W objective lens (Carl Zeiss Microscopy) for the detection. Green fluorescent protein (GFP) was excited at 488 nm by a diode laser and detected between 500 and 550 nm. Images were acquired by a CCD camera (pixel pitch 6.45 μm, Neo, Andor, Ireland). The specimen mounted on the mDSLM holder was placed vertically in the medium-filled chamber close to the common focal point of the 2 excitation and detection objective lenses. Image stacks consisting on average of 100 16-bit-TIFF (tagged image file format) individual images (slices) were recorded. Each slice in a stack represents a plane of the 3-dimensional specimen volume. The spacing between the slices was 0.4 µm. The image stacks were first deconvolved by employing the parallel iterative deconvolution plugin of the freeware image software Fiji (http://fiji.sc/Fiji), by choosing the WPL algorithm and performing 5 iterations. The absence of deconvolution artifacts was verified by visual inspection of the de-blurred stacks. The point-spread function (PSF) was calculated with the Fiji plugin diffraction PSF 3D by inserting the experimental imaging parameters. The deconvolved stacks were segmented by employing the manual threshold function of Fiji. The resulting segmented stacks were processed with the open 3D morphological plugin. Next, a z-projection of the stacks was generated by choosing the sum slices option. Finally, the total number of autophagosomes in the stack was determined from the z-projected stack with the analyze particles function. The area of each individual hypha was determined manually with the segmented line selection tool. Finally, the density of autophagosome was calculated for each image stack.

Wide-field fluorescence and differential interference contrast (DIC) imaging

A Carl Zeiss Axio Imager.Z2 upright microscope equipped with a CZ AxioCamMR3 (image size 1388 × 1040, pixel pitch 6.45 µm, 12 bits) (Carl Zeiss Microscopy) and the ZEN 2012 (blue edition) acquisition software was employed for imaging. A CZ oil immersion Plan-Apochromat 63× 1.4 N.A. DIC objective lens objective lens (Carl Zeiss Microscopy) was used for both wide-field fluorescence and DIC imaging. After properly setting the Köhler illumination, the matching DIC-Prisma II HC 63× (Carl Zeiss Microscopy, 426924-9030-000) as well as the DIC-analyzer were inserted. Both the DIC shift and azimuth were adjusted in order to achieve maximum contrast. The GFP fluorescence was excited with a Colibri.2 LED light source, equipped with a 474/28 band-pass excitation filter (Carl Zeiss Microscopy). The filter set HE BFP/GFP/HcRed (Carl Zeiss Microscopy, 489062-9901-000) was employed.

Western blot analysis

For extraction of total protein extracts, mycelia from different P. anserina strains was allowed to overgrow a cellophane foil covered M2 surface for 2 d at 27 °C and constant light. Afterwards, the grown mycelia was transferred into CM-liquid medium (CM medium: 1 g/L KH2PO4, 0.5 g/L KCL, 0.5 g/L MgSO4 × 7 H2O, 10 g/L glucose-monohydrate, 3.7 g/L NH4Cl, 2 g/L trypton, 2 g/L yeast-extract, 0.001 g/L ZnSO4, 0.001 g/L FeCl2, 0.001 g/L MnCl) (nitrogen re- or depleted) for 2 further d at 27 °C under constant light and shaking conditions. Harvested mycelia were pulverized in liquid nitrogen and the protein was isolated from the powder as described. 100–300 μg total protein extracts of P. anserina strains, were fractionated by 2-phase SDS-PAGE (12% separating gels) according to the standard protocol. After electrophoresis, proteins were transferred to PVDF membranes (Millipore, IPFL00010). Blocking, antibody incubation, and washing steps were performed according to the Odyssey western blot analysis handbook (LIC-OR Biosciences, Bad Homburg, Germany). The following primary antibodies were used: Anti-GFP (mouse, 1:10000 dilution, Sigma-Aldrich, G6795), anti-PaGLO1 (1: 2000 dilution, NEP, Frankfurt, Germany) raised against a specific peptide ([AC]-CVQNERFADKANF-[OH]) of PaGLO1 (glyoxalase1) previously described in Scheckhuber et al., anti-SOD1 (1:2000 dilution) from Biomol Stressgen (Hamburg, Germany) (SOD100) and Anti-PaPRE3 (1:2500 dilution) raised against a specific synthetic peptide ([H]-LYLPDTDYKVRHEN-[OH]; Sigma) of PaPRE3 (corresponding to the β1 subunit of the 26S proteasome). In all analyses, secondary antibodies conjugated with IRDye 680 (1:15000 dilution, goat anti-mouse 680RD: 926-68070; goat anti-rabbit 680LT: LIC-OR Biosciences, 926-68021) or IRDye CW 800 (1:15000 dilution, goat anti-mouse 800: 926-32210; goat anti-rabbit 800: LIC-OR Biosciences, 926-3221) were used. The Odyssey infrared scanner (LIC-OR Biosciences) was used for detection and quantification using the manufacturer’s software.

Statistical analysis

For statistical analyses of life span, growth rate, and female fertility as well as germination rate 2-tailed Mann-Whitney-Wilcoxon U test was used. The respective samples were compared with the appropriate wild-type sample. For all analyses the minimum level of statistical significance was set at P < 0.05 (not significant different means P > 0.05; significant different (*) means P < 0.05; high significant different (**) means P < 0.01; very high significant different (***) means P < 0.001).