Advertisement
Research Article

HapX-Mediated Adaption to Iron Starvation Is Crucial for Virulence of Aspergillus fumigatus

  • Markus Schrettl,

    Affiliation: Division of Molecular Biology/Biocenter, Innsbruck Medical University, Innsbruck, Austria

    X
  • Nicola Beckmann,

    Affiliation: Division of Molecular Biology/Biocenter, Innsbruck Medical University, Innsbruck, Austria

    X
  • John Varga,

    Affiliation: J. Craig Venter Institute, Rockville, Maryland, United States of America, and The George Washington University School of Medicine, Department of Biochemistry and Molecular Biology, Washington, D.C., United States of America

    X
  • Thorsten Heinekamp,

    Affiliation: Department of Molecular and Applied Microbiology, Leibniz Institute for Natural Product Research and Infection Biology (HKI), and Friedrich Schiller University Jena, Jena, Germany

    X
  • Ilse D. Jacobsen,

    Affiliation: Department for Microbial Pathogenicity Mechanisms, Leibniz Institute for Natural Product Research and Infection Biology (HKI), and Friedrich Schiller University Jena, Jena, Germany

    X
  • Christoph Jöchl,

    Affiliation: Division of Molecular Biology/Biocenter, Innsbruck Medical University, Innsbruck, Austria

    X
  • Tarek A. Moussa,

    Affiliation: Division of Molecular Biology/Biocenter, Innsbruck Medical University, Innsbruck, Austria

    X
  • Shaohua Wang,

    Affiliation: Division of Molecular Biology/Biocenter, Innsbruck Medical University, Innsbruck, Austria

    X
  • Fabio Gsaller,

    Affiliation: Division of Molecular Biology/Biocenter, Innsbruck Medical University, Innsbruck, Austria

    X
  • Michael Blatzer,

    Affiliation: Division of Molecular Biology/Biocenter, Innsbruck Medical University, Innsbruck, Austria

    X
  • Ernst R. Werner,

    Affiliation: Division of Biological Chemistry/Biocenter, Medical University Innsbruck, Innsbruck, Austria

    X
  • William C. Niermann,

    Affiliation: J. Craig Venter Institute, Rockville, Maryland, United States of America, and The George Washington University School of Medicine, Department of Biochemistry and Molecular Biology, Washington, D.C., United States of America

    X
  • Axel A. Brakhage,

    Affiliation: Department of Molecular and Applied Microbiology, Leibniz Institute for Natural Product Research and Infection Biology (HKI), and Friedrich Schiller University Jena, Jena, Germany

    X
  • Hubertus Haas mail

    hubertus.haas@i-med.ac.at

    Affiliation: Division of Molecular Biology/Biocenter, Innsbruck Medical University, Innsbruck, Austria

    X
  • Published: September 30, 2010
  • DOI: 10.1371/journal.ppat.1001124

Abstract

Iron is essential for a wide range of cellular processes. Here we show that the bZIP-type regulator HapX is indispensable for the transcriptional remodeling required for adaption to iron starvation in the opportunistic fungal pathogen Aspergillus fumigatus. HapX represses iron-dependent and mitochondrial-localized activities including respiration, TCA cycle, amino acid metabolism, iron-sulfur-cluster and heme biosynthesis. In agreement with the impact on mitochondrial metabolism, HapX-deficiency decreases resistance to tetracycline and increases mitochondrial DNA content. Pathways positively affected by HapX include production of the ribotoxin AspF1 and siderophores, which are known virulence determinants. Iron starvation causes a massive remodeling of the amino acid pool and HapX is essential for the coordination of the production of siderophores and their precursor ornithine. Consistent with HapX-function being limited to iron depleted conditions and A. fumigatus facing iron starvation in the host, HapX-deficiency causes significant attenuation of virulence in a murine model of aspergillosis. Taken together, this study demonstrates that HapX-dependent adaption to conditions of iron starvation is crucial for virulence of A. fumigatus.

Author Summary

Due to its requirement for a wide range of cellular processes, iron is an essential nutrient for virtually every organism. The mammalian immune system utilizes iron-withholding mechanisms to deny access to free iron. Therefore, pathogens must overcome extreme iron limitation. Patients with suppressed immune systems due to cancer treatments, organ transplantation, or genetic disorders are at high risk of infection with the ubiquitously present fungal pathogen Aspergillus fumigatus. In this study we found that in Aspergillus fumigatus iron starvation results in drastic metabolic changes depending on the transcription factor HapX. During iron starvation, HapX functions include the repression of iron-consuming pathways to spare iron and activation of iron uptake by siderophores. Siderophores are small molecules able to “steal” iron from host molecules and have previously been shown to play a crucial role in the virulence of Aspergillus fumigatus. Genetic inactivation of HapX attenuates virulence of Aspergillus fumigatus in a murine model of aspergillosis, demonstrating that adaption to iron limitation is a crucial virulence determinant. The identification of numerous HapX-affected genes with a yet uncharacterized link to iron will aid in the further characterization of the metabolic pathways required for fungal adaption to iron starvation and virulence traits.

Introduction

Iron is an essential nutrient for virtually every organism. The ability to exist in two redox states makes this metal an essential cofactor of proteins involved in numerous major cellular processes including respiration, amino acid metabolism and DNA metabolism. However, excess iron has the ability to generate toxic reactive species that can damage cellular components [1]. Despite its general abundance, the bioavailability of iron is very limited owing to its oxidation into insoluble ferric hydroxides by atmospheric oxygen. Consequently, all organisms have developed tightly regulated homeostatic mechanisms in order to balance uptake, storage and consumption of iron. Moreover, the mammalian immune system utilizes iron-withholding mechanisms to deny invading microorganism's access to free iron [2], [3]. Consequently, the control over access to iron is one of the central battlefields deciding the fate of an infection. Furthermore, iron starvation activates not only iron uptake but also virulence determinants in many prokaryotic and eukaryotic pathogens.

Aspergillus fumigatus is a typical ubiquitous saprophytic mold. Nevertheless, it causes life-threatening invasive disease especially in immuno-compromised patients and has become the most common airborne fungal pathogen of humans [4]. A. fumigatus lacks specific uptake systems for host iron sources as heme, ferritin, or transferrin [5]. However, it employs two high-affinity iron uptake systems, siderophore-assisted iron uptake and reductive iron assimilation, both of which are induced upon iron starvation. Siderophores are low molecular mass, ferric iron-specific chelators [6]. A. fumigatus excretes the siderophores fusarinine C (FsC) and triacetylfusarinine C (TAFC) to mobilize extracellular iron. Subsequent to chelation of iron, the ferric forms of FsC and TAFC are taken up by specific transporters [7]. For release of iron, the siderophores are intracellularly hydrolyzed [8] and the iron is transferred to the metabolic machinery or stored. A. fumigatus employs also intracellular siderophores: ferricrocin (FC) for hyphal storage and distribution of iron, and hydroxyferricrocin (HFC) for conidial iron storage [9], [10].

FsC is a cyclic tripeptide consisting of three N5-cis-anhydromevalonyl-N5-hydroxyornithine residues linked by ester bonds, TAFC is the N2-acetylated FsC, FC is a cyclic hexapeptide with the structure Gly-Ser-Gly-(N5-acetyl-N5-hydroxyornithine)3 and HFC is the hydroxylated FC [6]. The siderophore biosynthetic pathway is shown in Fig. S1. The first committed step in the biosynthesis of all four siderophores is hydroxylation of ornithine (Orn). Subsequently, the pathways for biosynthesis of TAFC and FC split involving acylation of N5-hydroxyornithine, assembly of siderophore-back bones by nonribosomal peptide synthetases (NRPS), and derivatization by acetylation or hydroxylation. Five A. fumigatus genes encoding respective enzyme activities have been identified [5], [10]: sidA (N5-ornithine-monooxygenase), sidF (N5-hydroxyornithine:cis-anhydromevalonyl coenzyme A-N5-transacylase), sidC (FC NRPS), sidD (fusarinine C NRPS) and sidG (fusarinine C:acetyl coenzyme A-N2-transacetylase). Elimination of both intra- and extracellular siderophores (ΔsidA mutants) results in absolute avirulence of A. fumigatus in a mouse model of pulmonary aspergillosis [5]. Deficiency in either extracellular (ΔsidF or ΔsidD mutants) or intracellular siderophores (ΔsidC mutants) causes partial attenuation of virulence [10]. Recently, siderophores have also been implicated in virulence of Histoplasma capsulatum and various phytopathogenic ascomycetes [11], [12], [13]. Consequently, the siderophore system represents an attractive target for antifungal therapy. However, not all fungi produce siderophores; notable examples are Saccharomyces cerevisiae, Candida albicans and Cryptococcus neoformans [6].

In agreement with iron playing an important role in the pathophysiology of A. fumigatus, increased bone marrow iron stores represent an independent risk factor for invasive aspergillosis [14]. Moreover, polymorphonuclear leukocytes inhibit growth of A. fumigatus conidia by lactoferrin-mediated iron depletion [15], and the human body produces proteins able to sequester fungal siderophores [16]. Consistently, the chelators EDTA and deferasirox enhance the efficacy of amphotericine B in animal models for invasive pulmonary aspergillosis [17], [18].

In Aspergillus nidulans, maintainance of iron homeostasis is mediated by two transcription factors, SreA and HapX, which are interconnected in a negative feed-back loop: SreA represses expression of hapX during iron sufficiency and HapX represses sreA during iron starvation [19], [20]. SreA is a DNA-binding GATA-factor whereas HapX functions by protein-protein interaction with the heterotrimeric CCAAT-binding factor. SreA represses iron uptake during iron sufficiency to avoid toxic effects and HapX represses iron-dependent pathways during iron starvation to spare iron. This regulatory circuit is largely conserved in Schizosaccharomyces pombe and orthologs to SreA and HapX are found in most fungal species; a notable exception is the fungal prototype S. cerevisiae, which employs entirely different regulators [6], [21].

We have previously demonstrated the role of SreA in repression of iron acquisition in A. fumigatus [22]. In this study we characterized the function of HapX and its interplay with SreA. We demonstrate that HapX function is crucial for the metabolic reprogramming required for adaption to iron starvation and for virulence of A. fumigatus.

Results/Discussion

HapX-deficiency decreases growth and sporulation specifically during iron starvation

In A. nidulans, HapX has been shown to repress iron-dependent pathways during iron starvation [20]. The A. fumigatus HapX ortholog displays 70% overall identity and contains all typical features common to this class of transcription factors: an N-terminal 17 amino acid motif, which is essential for interaction with the CCAAT-binding complex, a bZip domain, and three cysteine-rich regions, which are potentially involved in iron-sensing. Genome-wide transcriptional profiling revealed that the transcript level of the A. fumigatus hapX ortholog (Afu5g03920) is SreA-dependently down-regulated in a shift from iron depleted to iron-replete conditions [22]. In agreement, Northern analysis demonstrated up-regulation of the hapX transcript level under steady-state iron depleted compared to iron-replete conditions and partial derepression during iron-replete conditions in a ΔsreA mutant (Fig. 1A). This expression pattern matches that of the A. nidulans ortholog [20]. In order to analyze the function of HapX in A. fumigatus, a deletion mutant (ΔhapX) was generated as described in Methods. Consistent with undetectable expression of hapX during iron sufficiency in wt (Fig. 1A), ΔhapX displayed no significant difference to the wt with respect to conidiation and growth rate on solid or liquid media during iron sufficiency (Fig. 2). In contrast, ΔhapX showed mildly reduced radial growth on solid media (Fig. 2A) and was not able to form colonies from single conidia in the presence of the iron chelator bathophenanthroline disulfonate (BPS) (Fig. 2B). Furthermore, hapX deletion decreased conidiation to 62% of the wt during iron starvation and 4% during iron starvation in the presence of BPS (Fig. 2C). In iron-starved liquid culture, hapX deletion decreased the biomass production to 58% of the wt (Fig. 2E) and caused a reddish pigmentation of the mycelia (Fig. 2D). Reintegration of a functional hapX copy at the hapX locus in the ΔhapX strain, yielding strain ΔhapXC, cured these and all other defects (Fig 2 and data not shown), which demonstrates that the ΔhapX phenotype is a direct result of the loss of HapX activity. Notably, germination of ΔhapX was wt-like under iron-replete and depleted conditions (data not shown) demonstrating that the phenotypes of ΔhapX are caused by growth defects. Limitation of nitrogen, carbon, copper, or zinc decreased biomass production of ΔhapX and wt to similar extents (Fig. 2E), which indicates that inactivation of HapX does not result in general sensitivity to starvation but in particular to iron starvation.

thumbnail

Figure 1. HapX affects iron regulation.

(A) Mutual transcriptional control between HapX and SreA. (B) Examples for negative (cycA) and positive (aspF1) impact of HapX in iron regulation. (C) HapX is required for transcriptional activation of the siderophore system. A. fumigatus wt, ΔsreA and ΔhapX were grown in shake flask cultures under iron-replete (+Fe) and depleted (−Fe) conditions. Total RNA was isolated and subjected to Northern analysis of genes selected from the genome-wide expression profiling (Fig. S1 and S2). As a control for quality and quantity, RNAs were hybridized with the ß-tubulin encoding tubA gene.

doi:10.1371/journal.ppat.1001124.g001
thumbnail

Figure 2. During iron depleted but not iron-replete conditions, HapX-deficiency impairs growth in liquid and solid media, colony formation from single conidia, conidiation, resistance to zinc and tetracycline, and causes reddish pigmentation.

(A) Growth on solid media with and without tetracycline: conidia were point-inoculated on plates reflecting harsh iron starvation (−Fe +BPS), iron starvation (−Fe) and iron-replete conditions (+Fe). Radial growth was recorded after 48h of growth at 37°C and normalized to that of wt grown under the same condition. (B) Colony formation from single conidia: approximately 100 conidia were plated and photographs were taken after growth for 48h at 37°C. (C) Conidiation: conidia production by 1 cm2 of mycelia after growth for 120h of at 37°C was recorded and normalized to that of wt under the same condition. (D) Hyphal pigmentation: photographs of liquid cultures were taken after 24h of growth at 37°C. (E) Growth in liquid media with and without limitations or zinc excess: biomass production of 108 conidia inoculated in 100 ml media was scored after 24 h of growth at 37°C and normalized to that of wt in +Fe. For limitation of carbon (−C), nitrogen (−N), zinc (−Zn) and copper (−Cu), the growth medium contained 0.1% glucose, 2 mM glutamine, 1 mM ZnSO4 and no added copper, respectively, which decreased the biomass production of the wt to about the same extent as iron limitation. High zinc-medium (hZn) contained 0.5mM ZnSO4. The data in (A), (C), and (E) represent the means ± standard deviations from three independent experiments.

doi:10.1371/journal.ppat.1001124.g002

HapX and SreA are interconnected by a negative regulatory feedback loop

In line with the growth defect of ΔhapX under iron starvation but not iron sufficiency, expression of hapX was repressed by iron at the transcriptional level, partly dependent on SreA (Fig. 1A). In turn, HapX repressed sreA during iron starvation (Fig. 1A). A similar expression pattern was described previously for the hapX and sreA orthologs of A. nidulans and S. pombe [20], [21].

HapX is required for repression of genes during iron starvation

Genome-wide transcriptional profiling revealed that expression of hapX is repressed within ≤30 minutes in a shift from iron depleted to iron-replete conditions [22], which predicts that HapX targets also respond quickly to the availability of iron. This HapX feature allowed analysis of short-term effects of hapX deletion. In order to identify the genes that are negatively affected by HapX at the transcript level, we therefore searched by genome-wide transcriptional profiling for genes fulfilling three criteria: (i) up-regulation in a 1h-shift from iron starvation to iron sufficiency in wt (identification of genes repressed by iron starvation), (ii) decreased up-regulation in a 1h-shift from iron starvation to iron sufficiency in ΔhapX compared to wt (identification of genes showing a short-term response to HapX inactivation), and (iii) up-regulation during steady-state iron starved growth in ΔhapX compared to wt (identification of genes showing a long-term response to HapX inactivation). This strategy is supposed to select for rather direct effects of HapX inactivation.

Among the 131 genes negatively affected by HapX (Table S1 in Supporting Information S1 and Table 1A), 34% can be directly assigned to iron-dependent pathways including respiration, TCA cycle, amino acid metabolism, iron-sulfur-cluster biosynthesis, heme biosynthesis, oxidative stress detoxification, biotin synthesis (Afu6g03670), vacuolar iron storage (CccA, Afu4g12530), and iron regulation (SreA, Afu5g11260). This gene set included the orthologs of all five previously identified A. nidulans HapX-repressed genes [20]: cycA (cytochrome C, respiration, Afu2g13110), acoA (aconitase, TCA cycle, Afu6g12930), hemA (α-amino-levulinic acid synthase; heme biosynthesis, Afu4g11400), lysF (homoaconitase, lysine biosynthesis, Afu5g08890), and sreA (repressor of iron uptake). A representative Northern analysis of cycA is displayed in Fig. 1B.

thumbnail

Table 1. Categorization of the genes affected by HapX.

doi:10.1371/journal.ppat.1001124.t001

The majority of the cellular iron-consuming pathways, e.g. heme biosynthesis, iron-sulfur cluster biosynthesis, respiration, TCA cycle, is localized in mitochondria, which might explain the co-regulation of mitochondrial components that are not directly iron-dependent, e.g. the mitochondrial processing peptidase (Afu1g14200), which is essential for import of all mitochondrial matrix proteins. Strikingly, 31% (n = 41) of the genes negatively affected by HapX encode proteins that are localized in mitochondria (Table S1 in Supporting Information S1 and Table 1A), which indicates a significant impact of HapX on mitochondrial metabolism.

23% (n = 30) of the identified genes repressed during iron starvation in a HapX-dependent manner are involved in ribosomal biogenesis and translation (Table S1 in Supporting Information S1 and Table 1A). These data might reflect the iron-dependence of the translation machinery due to the essentiality of iron-sulfur clusters for function of Rli1 (RNase L inhibitor, Afu1g10310). Because of its fundamental role in translation initiation and ribosome biogenesis, RLI1 is one of the most conserved proteins present in all organisms except eubacteria and it is essential in all organisms tested [23]. Consistent with its iron-dependence, Rli1 expression is repressed during iron starvation in a HapX-dependent manner (Table S1 in Supporting Information S1). The down-regulation of translation during iron starvation indicates a slow-down of the entire metabolism, which might serve extended cellular survival.

Among the 131 A. fumigatus genes negatively affected by HapX, 21 have orthologs in S. pombe (Table S1 in Supporting Information S1), which are negatively affected by the HapX ortholog Php4 [24]. S. cerevisiae lacks an HapX ortholog and down-regulation of iron-dependent pathways during iron starvation is mediated by the paralogous proteins Cth1 and Cth2, which promote decay of target mRNA's during iron starvation [25]. A total of 21 of HapX-repressed genes have orthologs in S. cerevisiae, which are repressed during iron starvation via Cth1/2 (Table S1 in Supporting Information S1). Taken together, all three fungal species repress 15 orthologous genes during iron starvation (Table S1 in Supporting Information S1). All 15 deduced gene products are involved in iron-dependent pathways including respiration, iron sulfur cluster biosynthesis, TCA cycle, amino acid metabolism and translation and all are localized in mitochondria with exception of Rli1 and the leucine biosynthetic enzyme Leu1 (Table S1 in Supporting Information S1). These data underscore the evolutionary conservation of iron-sparing in different fungal species.

Comparison of the genes negatively affected by HapX with the previously identified SreA regulon [22] displayed no overlap (Table S1 in Supporting Information S1). However, 38% of these genes were previously found to be up-regulated indirectly by SreA-deficiency; i.e., in a shift from iron starvation to iron sufficiency these genes were up-regulated in ΔsreA only at late time points. As iron represses expression of hapX at the transcriptional level (see above) and most likely also post-translationally, as shown for its orthologs in A. nidulans and S. pombe [20], [26], these data suggest that the up-regulation of these genes in ΔsreA cells is caused by inactivation of HapX through the iron overload in ΔsreA.

HapX is involved in induction of genes during iron starvation

To identify the genes affected positively by HapX, the inverse criteria compared to the screening for HapX-repressed genes by transcriptional profiling were applied (see above): (i) down-regulation in a shift from iron starvation to iron sufficiency in wt, (ii) decreased down-regulation in a shift from iron starvation to iron sufficiency in ΔhapX compared to wt, and (iii) down-regulation during steady-state iron starved growth in ΔhapX compared to wt.

Genes affected positively by HapX or its ortholog have been described for neither A. nidulans nor S. pombe yet. However, the transcriptional profiling identified 139 such genes in A. fumigatus, which are mainly involved in siderophore metabolism, amino acid metabolism, protein degradation and uptake, carbohydrate metabolism, and lipid metabolism (Table S2 in Supporting Information S1 and Table 1B). Strikingly, 27% of these genes were previously found to be SreA targets, i.e. repressed during iron sufficiency by SreA [22], e.g., genes involved in siderophore metabolism (Table S2 in Supporting Information S1 and Table 1B). As hapX deletion derepressed expression of sreA during iron starvation (see above), hapX deletion might repress SreA-targets indirectly via its transcriptional derepression of sreA.

However, hapX deletion affected expression of various SreA-target genes differently (Table S2 in Supporting Information S1, Fig. 1C). HapX-deficiency drastically reduced the transcript levels of the putative siderophore transporter-encoding mirB and the siderophore-biosynthetic sidG but had only minor effects on the siderophore transporter-encoding mirD and siderophore-biosynthetic sidA and sidF, which indicates SreA-independent effects. In line, 73% of the genes negatively affected by hapX deletion do not appear to be SreA targets (Table S2 in Supporting Information S1 and Table 1B). A prominent example is one of the major allergens of A. fumigatus, the ribotoxin Aspf1 (Afu5g02330) [27]. The microarray data (Table S2 in Supporting Information S1) and Northern analysis revealed that the transcriptional up-regulation of AspF1 during iron starvation is strictly dependent on HapX (Fig. 1B) and not affected by SreA as shown previously [22]. AspF1 is cytotoxic and was shown to induce apoptosis of human immature dendritic cells, which indicates that it is involved in immune evasion of A. fumigatus [28]. However, AspF1 was previously shown to be dispensable for virulence of A. fumigatus in a murine model of aspergillosis [29]. A possible explanation for this discrepancy is that the immunosuppressive regimen used in the murine model interferes with the ability of the immune system to preferentially identify the mutant strains. As AspF1-activity is neither iron-dependent nor directly involved in iron acquisition, iron starvation might serve in this case as a signal for expression of a general virulence determinant not related to iron uptake. On the other hand, AspF1 might indirectly increase iron supply of A. fumigatus during the interaction with predators and hosts via cellular iron release due its cytotoxicity.

To further investigate the link between HapX and SreA activities we aimed to generate an A. fumigatus mutant lacking both regulators. However, several approaches to generate a ΔsreAΔhapX double mutant failed indicating that deletion of sreA and hapX is synthetically lethal as shown previously in A. nidulans (Hortschansky et al., 2007), which underlines the importance of iron regulation.

Genomic organization of the genes affected by HapX

Genes involved in common pathways tend to be genomically clustered in filamentous fungi. Therefore it is interesting to note that among the genes affected by HapX, 41 are organized in gene clusters (Tables S3 and S4 in Supporting Information S1). Interestingly, the AspF1-encoding gene is neighboured by a co-regulated gene encoding a hypothetical protein (Afu5g02320) and this gene organization is conserved in various fungal species, e.g., Neosartorya fischeri, Aspergillus clavatus, Microsporum canis, and Arthroderma benhamiae (data not shown). The acetyl transferase-encoding gene Afu5g00720, one of the clustered genes, was subjected to deletion analysis. Due to its expression pattern it appeared to be a good candidate for the still unidentified acetyl transferase required for FC biosynthesis (Fig. S1). However, the deletion did not reveal any phenotype (data not shown).

HapX inactivation decreases production of TAFC and FC

A. fumigatus excretes the siderophores FsC and TAFC in roughly equal amounts (Fig S2). Inactivation of HapX did not substantially alter FsC production but reduced TAFC production to 18% of the wt (Fig. 3A). TAFC is derived from FsC by SidG-catalyzed N2-acetylation [22]. (Fig. S1). Consistent with the reduction of TAFC production, the sidG (Afu3g03650) transcript level was drastically reduced in ΔhapX as shown by Northern and microarray analyses (Fig. 1, Table S2 in Supporting Information S1). Blocking TAFC synthesis by inactivation of SidG has previously been shown to result in increased FsC production [22]. As FsC production was not increased in ΔhapX, it appears unlikely that SidG is the only siderophore biosynthetic activity affected in ΔhapX. In agreement, the microarray analyses (Table S2 in Supporting Information S1 and Table 2) revealed transcriptional down-regulation of other FsC biosynthetic enzymes such as SidF (Afu3g03400) and SidI (Afu1g17190). Moreover, supply of the siderophore precursor Orn might play a role in siderophore production (see below).

thumbnail

Figure 3. HapX-deficiency decreases production of TAFC and FC but increases cellular accumulation of PpIX.

(A) Quantification of siderophore production after growth for 24 hours at 37°C under −Fe conditions normalized to that of wt. (B) Quantification of the PpIX content after growth for 24h at 37°C under iron-replete (+Fe) and depleted (−Fe) conditions. The data represent the mean ± standard deviation of three individually performed experiments.

doi:10.1371/journal.ppat.1001124.g003
thumbnail

Table 2. Iron starvation remodels the free amino acid pool composition in A. fumigatus.

doi:10.1371/journal.ppat.1001124.t002

The transcriptional profiling (Table S2 in Supporting Information S1) also revealed down-regulation in ΔhapX of the NRPS SidC (Afu1g17200), which is essential for FC biosynthesis. Consistently, the FC content of ΔhapX was decreased to 68% of the wt.

In A. nidulans, HapX inactivation also decreased TAFC production but increased FC production [20]. Despite the general similarity of iron homeostasis-maintaining mechanisms of these two Aspergillus species, these data reveal differences.

HapX inactivation results in excessive cellular accumulation of the iron-free heme precursor protoporphyrin IX (PpIX)

In contrast to wt, ΔhapX mycelia displayed a reddish pigmentation concomitant with red autofluorescence during iron depleted but not iron-replete conditions (Fig. 2D and data not shown), which is characteristic for accumulation of PpIX, the iron free precursor of heme [20]. Accordingly, the PpIX content of ΔhapX resembled the wt during iron-replete conditions but was 17-fold increased during iron starvation (Fig. 3B). These data indicate derepression of heme biosynthesis during iron starvation in ΔhapX, consistent with the expression profile of genes encoding 5-aminolevulinate synthase (Afu5g07750), ferrochelatase (Afu5g07750) and a putative heme transporter (Afu4g11400) revealed by the microarray analysis Table S1 in Supporting Information S1 and Table 1A).

HapX is involved in remodeling of the cellular free amino acid pool in response to iron-starvation

The transcription profiling indicated changes in iron-dependent and -independent steps of the amino acid metabolism in response to HapX inactivation (Tables S1 and S2 in Supporting Information S1, Table 1). To gain further insight, we measured the relative composition of the free amino acid pool in wt, ΔhapX, ΔsreA, and ΔsidA during iron sufficiency and starvation (Table 2 and Table S5 in Supporting Information S1). In wt, iron starvation caused a dramatic remodeling of the composition of free amino acid pool: the relative amounts of nine amino acids (Arg, Asn, Gln, His, Lys, Met, Orn, Phe, and Trp) increased whereas that of three amino acids (Ala, Glu and Val) decreased >1.5-fold. ΔhapX and ΔsidA displayed differences compared to wt mainly during iron starvation, whereas ΔsreA showed differences mainly during iron sufficiency. This is in line with the expression pattern of the deleted genes: hapX and sidA are repressed while sreA is induced by iron (Fig. 1).

During iron starvation, siderophore production reaches up to 10% of the biomass and the major amino acid precursor for siderophore biosynthesis is Orn. The 6.9-fold increase of the Orn pool during iron starvation compared to iron sufficiency in wt indicates that the enormous Orn demand for siderophore biosynthesis is matched by active up-regulation of Orn biosynthesis during iron starvation and not by de-repression of Orn biosynthesis via its consumption, which could be expected to decrease the Orn pool. Consistently, blocking Orn consumption for siderophore biosynthesis by inactivation of the Orn hydroxylase SidA (ΔsidA) caused a further 2.9-fold increase of the Orn pool during iron starvation compared to wt. Orn is synthesized from glutamate or from Orn-derived Arg (Fig. 4). Consistent with the amino acid analysis, Northern analysis confirmed transcriptional up-regulation of several key enzymes of the Orn/Arg biosynthetic pathway not only in wt but also in ΔsidA, which does not consume Orn for siderophore biosynthesis (Fig. 4). Strikingly, the Orn pool was 12.5-fold decreased in ΔhapX, while Arg was 2.0-fold increased (Table 2). Consequently, the Arg:Orn ratio changed from 1.5 in wt to 49.9 in ΔhapX. Northern analysis demonstrated wt-like transcriptional up-regulation of most key enzymes of the Orn/Arg pathway in ΔhapX (Fig. 4). In perfect agreement with the microarray data (Tables S1 and S2 in Supporting Information S1), however, transcript levels of four involved enzymes were changed in ΔhapX during iron starvation (Fig. 4). Consistent with the increased Arg:Orn ratio in ΔhapX, transcriptional up-regulation of the carbamoyl-phosphate-synthetase (Afu5g06780) and transcriptional down-regulation of the mitochondrial ornithine exporter AmcA (Afu8g02760) in ΔhapX during iron starvation is expected to promote production of Arg relative to Orn; up-regulation of ornithine aminotransferase: (Afu4g09140), ornithine decarboxylase (Afu4g08010), and proline oxidase (Afu6g98760) indicates increased consumption of ornithine for purposes other than biosynthesis of siderophores. Taken together, these data indicate that HapX is required for the up-regulation of the Orn pool to fuel siderophore biosynthesis. Therefore, the largely decreased Orn pool of ΔhapX might be in part responsible for the reduced production of TAFC and FC in addition to the transcriptional down-regulation of siderophore biosynthetic enzymes (see above). Consistently, derepression of siderophore biosynthesis during iron sufficiency by deletion of sreA (ΔsreA), when HapX is inactive, decreased the Orn pool to 38% of wt (Table 2).

thumbnail

Figure 4. Iron starvation transcriptionally up-regulates biosynthesis of ornithine in a HapX-dependent manner.

(A) Schematic representation of ornithine/arginine metabolism in A. fumigatus. Ornithine biosynthesis takes place in mitochondria (mito). Ornithine and citrulline are shuttled to the cytoplasm (cyto) and serve as precursors for arginine, siderophores and polyamines. Enzymatic steps within the pathways are numbered and corresponding to the Northern analysis in (B): 1, acetylglutamate synthetase (Afu2g11490) 2, acetylglutamate kinase and glutamate-5-semialdehyde dehydrogenase (Afu6g02910); 3, acetylornithine aminotransferase (Afu2g12470); 4, arginine biosynthesis bifunctional enzyme (Afu5g08120); 5, carbamoylphosphate synthase(Afu5g06780); 6, ornithine carbamoyltransferase (Afu4g07190); 7, arginase (Afu3g11430); 8, ornithine aminotransferase (Afu4g09140); 9, ornithine decarboxylase (Afu4g08010); 10, pyrroline carboxylate dehydrogenase (Afu6g08750); 11, ornithine transporter (Afu8g02760). Red and green arrows mark enzymatic steps transcriptionally up and down-regulated, respectively, by iron starvation in the wt as shown in (B); Red and green circles mark genes, which are transcriptionally up- and down-regulated, respectively, in a ΔhapX strain as shown in (B). (B) For Northern analysis, wt, ΔsidA and ΔhapX strains were grown for 24h at 37°C in under iron-replete (+Fe) and depleted (−Fe) conditions, respectively.

doi:10.1371/journal.ppat.1001124.g004

The 4.9-fold increased lysine pool in ΔhapX compared to wt during iron starvation is consistent with transcriptional up-regulation of the lysine biosynthetic enzymes homoaconitase LysF (Afu5g08890) and homocitrate synthase (Afu4g10460) (Table S1 in Supporting Information S1). The iron-dependence of LysF might explain the 0.7-fold decrease of the lysine pool in ΔsidA (Table 2) because lack of siderophore biosynthesis in ΔsidA causes increased iron starvation, which in turn down-regulates and inactivates iron-dependent pathways.

In the first commited step of heme biosynthesis, 5-aminolevulinate is synthesized from glycine and succinyl-CoA by HemA. As HemA expression and the heme biosynthetic pathway is derepressed during iron starvation in ΔhapX (see above), the 7.5-fold increase in the glycine pool might indicate synchronization of heme biosynthesis and supply of its precursor glycine by HapX (Table 2). Here, HapX would formally function as a repressor, whereas it acts as an activator for biosynthesis of siderophores and their precursor ornithine. We have previously shown that iron starvation down-regulates heme biosynthesis [22]. Therefore, the possibility of a regulatory link of glycine and heme biosynthesis is underlined by the 0.7-fold decrease of the glycine pool during iron starvation compared to iron sufficiency in wt and the further 0.5-fold decrease in ΔsidA.

Recently, iron starvation was found to influence the composition of the free amino acid pool in S. cerevisiae only mildly [30] with low concordance to A. fumigatus (Table S6 in Supporting Information S1). The difference might be due to the different life styles of A. fumigatus and S. cerevisiae and of course the inability of S. cerevisiae to synthesize siderophores.

HapX inactivation increases the mitochondrial DNA (mtDNA) content and decreases resistance to tetracycline

As mentioned above, 31% of the genes de-repressed during iron starvation in ΔhapX encode mitochondrial-localized proteins and 66% (27 genes) of those are up-regulated in ΔsreA during iron sufficiency (Table 1A and Table S1 in Supporting Information S1), which indicates a major impact of iron de-regulation on mitochondrial metabolism. Live cell imaging by laser scanning confocal microscopy of the mitotracker-stained mitochondrial network revealed no differences between wt, ΔhapX, and ΔsreA neither during iron-replete nor iron-depleted conditions (data not shown). Next we analyzed the mtDNA content of wt, ΔhapX and ΔsreA by qPCR normalized against the content of nuclear DNA (Table S7 in Supporting Information S1). Concomitant with derepression of genes encoding mitochondrial proteins, HapX deficiency increased the mtDNA content during iron starvation 1.9-fold but had no effect during iron sufficiency. Vice versa, SreA-deficiency increased the mtDNA content during iron sufficiency 2.3-fold but had no effect during iron starvation. Little is known about the molecular mechanisms coordinating replication of nuclear DNA and mtDNA in Aspergilli. Inactivation of SreA and HapX, respectively, may disturb this coordination by deregulation of either the general mitochondrial metabolism (proteins and/or metabolites) and/or of a specific regulator. Notably, ΔhapX and ΔsreA display decreased growth rates under the conditions, in which they have increased mtDNA contents (see above and [22]). Formally, it is therefore also possible that toxic effects caused by deficiency in SreA and HapX slow down nuclear DNA replication, whereby the deregulation of nuclear-encoded mitochondrial proteins disturbs the coordination with mitochondrial replication. HapX-deficiency also decreased resistance to tetracycline, an inhibitor of bacterial and mitochondrial protein synthesis [31], during iron-depleted but not iron-replete conditions (Fig. 2A), which underlines that HapX-deficiency affects mitochondrial metabolism.

HapX inactivation increases zinc sensitivity

We have previously shown that there is a close connection between zinc and iron metabolism [32]. In order to avoid zinc excess and zinc toxicity, iron starvation down-regulates expression of genes encoding plasma membrane zinc transporters such as zrfB (Afu2g03860) and the respective transcription activator zafA (Afu1g10080) and concomitantly up-regulates the vacuolar zinc/cadmium transporters zrcA (Afu7g06570) and cotA (Afu2g14570). The expression profiling indicated increased expression of zrfB and zafA (Fig. S1) and decreased expression of zrcA and cotA (Fig. S2) in ΔhapX during iron starvation suggesting increased zinc uptake and decreased vacuolar zinc storage. In agreement, ΔhapX displayed increased sensitivity to zinc (Fig 2E), which indicates a role of HapX in coordination of iron and zinc homeostasis.

HapX is crucial for virulence in a murine model of invasive aspergillosis

To determine whether HapX-mediated regulation is relevant for growth of A. fumigatus in the environment of the host, we compared the virulence of the ΔhapX strain with that of the complemented ΔhapXc strain and the wt strain in two different mouse models of pulmonary invasive aspergillosis: (i) a leucopenic mouse model using immunosuppression with both cortisone acetate and cyclophosphamide [33], [34], and (ii) a non-leucopenic model with immunosuppression by cortisone acetate [35], [36]. In the leucopenic host, a cellular immune response is virtually absent and development of invasive aspergillosis is characterized by extensive invasive growth of the fungus [37]. Thus, this model allows assessing whether fungal factors are required for survival and growth on lung tissue in general. In contrast, the cortisone acetate model allows recruitment of neutrophils and monocytes, which, despite partially impaired phagocytosis, attack fungal cells and prevent rapid fungal dissemination [38]. Mice were infected with 1×105 conidia in the leucopenic mouse model and 1×106 conidia in the cortisone acetate mouse model to account for the decreased killing rate; survival was monitored over a period of 14 days, followed by histological analyses of the lungs.

As shown in the survival curves in Fig. 5A both wt and ΔhapXc caused high mortality rates in the leucopenic mouse model, which were statistically not significantly different (p = 0.29) by Kaplan-Meyer estimation and log rank tests. The ΔhapX mutant displayed attenuation in virulence, which was however statistically significant only compared to ΔhapXc (p = 0.033) but not compared to wt (p = 0.28). At necropsy, the reduced virulence of ΔhapX was reflected in the incidence of macroscopic lung alterations in comparison to both ΔhapXc and wt (Fig. 5C): eight of ten mice infected with ΔhapXc, seven of ten mice infected with wt, but only one of ten mice infected with ΔhapX displayed lung alterations. The presence of invasive mycelia could be confirmed in the majority of mice infected with ΔhapXc and wt but no mycelium could be found in any mouse infected with ΔhapX (Fig. 5C).

thumbnail

Figure 5. HapX-deficiency results in attenuation of A. fumigatus virulence.

Survival of leucopenic mice (A) and mice immunosuppressed with cortisone acetate (B) after infection with ΔhapX, the complemented strain ΔhapXC, or wt. (C) Histopathology using PAS staining (hyphae stain pink) of leucopenic mice infected with ΔhapX, ΔhapXC, or wt.

doi:10.1371/journal.ppat.1001124.g005

In the cortison acetate mouse model, no statistically significant difference in survival were detected between mice infected with either wt or ΔhapXc (p = 0.67). In contrast, ΔhapX was completely attenuated compared to both wt and ΔhapXc (p = 0.004). Consistently, the lungs of all 10 mice infected with ΔhapX were unaltered whereas the lungs of six of ten mice infected with ΔhapXc showed clear symptoms of inflammation (data not shown).

The expression of hapX is repressed by iron (see above), and, consistently, deleterious effects of hapX-inactivation are limited to iron-starved conditions (see above). Therefore, the attenuated virulence of ΔhapX is in agreement with A. fumigatus facing iron-limited conditions in the host and the requirement of HapX for virulence. This is also in accordance with the importance of the iron-repressed siderophore system and the dispensability of the iron-induced iron regulator SreA for pathogenicity [5], [10], [22]. Notably, supplementation with iron-free TAFC or FsC to a final concentration of 10 mM did neither cure the growth defect nor inhibit the PpIX accumulation of ΔhapX during iron starvation in liquid flask cultures (data not shown) indicating that the reduced TAFC production does not account for the full extent of the ΔhapX phenotype. Together with the fact that HapX-deficiency causes decreased production of TAFC but not FsC (see above) and the previous finding that the A. fumigatus ΔsidG mutant strain, which produces FsC but not TAFC, displays unaltered virulence in a mouse model for pulmonary aspergillosis [10], these data suggest that the reduced virulence of ΔhapX is not caused, at least not solely, by the decreased TAFC production. Therefore, the attenuated virulence of ΔhapX might be caused by the general deregulation of gene expression (i.e. the missing metabolic adaption to iron starvation), the accumulation of toxic metabolites such as PpIX, and/or the down-regulation of possible virulence determinants such as AspF1 (see above).

The ΔhapX mutant appeared to be slightly more virulent in the leucopenic mouse model compared to the cortisone-acetate model (Fig. 5A and B). As HapX-deficiency results in sensitivity to iron starvation, these data indicate that the attack of neutrophils and monocytes, which is absent in the leucopenic model, increases extracellular iron starvation or imposes iron starvation by internalization. In this respect it is interesting to note that the siderophore system was recently shown to play a crucial role in intracellular growth and survival in murine alveolar macrophages demonstrating that A. fumigatus faces iron starvation after phagocytosis [39]. In agreement, the siderophore system was shown to be essential to alter immune effector pathways and iron homeostasis of murine macrophages [40].

Apart from A. fumigatus HapX, only one fungal iron regulator has been shown to be required for virulence so far: C. neoformans Cir1, the ortholog of A. fumigatus SreA [41]. Similar to SreA-deficiency in A. fumigatus, Cir1-deficiency impairs growth during iron-replete but not depleted conditions, which does not implicate a crucial role in virulence at first sight. But in contrast to A. fumigatus SreA, which is not required for virulence [22], C. neoformans Cir1 functions also as an activator for growth at 37°C (host temperature) and capsule formation, which are both important virulence traits.

Conclusions

This study demonstrates that the metabolic reprogramming required for adaption to iron starvation depends on HapX and that this adaption is essential for virulence of A. fumigatus. The identification of numerous HapX-affected genes with yet uncharacterized link to iron or starvation will aid in the further characterization of the metabolic pathways required for adaption to iron starvation and consequently virulence traits of A. fumigatus. This study appears to be exemplary for the iron metabolism and virulence of most fungal species as HapX is widely conserved with exception of species closely related to S. cerevisiae.

Methods

Fungal strains, growth conditions

Fungal strains used were A. fumigatus wild-type ATCC46645 (American Type Culture Collection ), ΔsreA (ATCC46645, ΔsreA::hph), ΔsidA (ATCC46645, ΔsidA::hph), ΔhapX (ATCC46645, ΔhapX::hph), and ΔhapXC (ΔhapX, (p)::hapX). ΔsreA and ΔsidA were described previously [5], [22]; generation of ΔhapX and ΔhapXC is described below. Generally, A. fumigatus strains were grown at 37°C in Aspergillus minimal medium according to Pontecorvo et al. [42] containing 1% glucose as the carbon source and 20 mM glutamine as the nitrogen source. Iron-replete media contained 30 mM FeSO4. For iron depleted conditions, iron was omitted. The BPS and tetracycline concentrations used were 200 µM and 2 mg ml−1 respectively. For growth assays, 104 and 108 conidia were used for point-inoculation on plates or inoculation of 100 ml liquid media, respectivly.

Northern analysis and DNA manipulations

RNA was isolated using TRI Reagent (Sigma). For Northern analysis, 10 µg of total RNA was analyzed as described previously [43]. Hybridization probes and Primers used are listed in Table S7 in Supporting Information S1. For extraction of genomic DNA, mycelia were homogenized and DNA was isolated according to Sambrook et al. [44]. For general DNA propagations Escherichia coli DH5α strain was used as a host.

Deletion of hapX and complementation of the ΔhapX strain

For generating the ΔhapX mutant strain, the bipartite marker technique was used [45]. Briefly, A. fumigatus was co-transformed with two DNA fragments, each containing overlapping but incomplete fragments of the pyrithiamine resistance-conferring ptrA gene fused to 1.2-kb hapX 5′- and 3′-flanking sequences, respectively. The hapX 5′-flanking region (1207bp) was PCR-amplified from genomic DNA using primers ohapX-1 and ohapX-4. For amplification of the 3′flanking region (1156bp) primers ohapX-2 and ohapX-3 were employed. Subsequent to gel-purification, these fragments were digested with SacI (5′flanking region) and XhoI (3′flanking region), respectively. The ptrA selection marker was released from plasmid pSK275 by digestion with SmaI and XhoI, respectively, and ligated with the 5′- and 3′-flanking region, respectively. The transformation construct A (2558bp, fusion of the hapX 5′-flanking region and the prtA split marker) was amplified from the ligation product using primers ohapX-5 and optrA-2. For amplification of the transformation construct B (2166bp, fusion of the hapX 3′-flanking region and the supplementary prtA split marker) primers ohapX-6 and optrA-1 were employed. For transformation of A. fumigatus ATCC46645 both constructs A and B were simultaneously used. This strategy deleted the sequence −228 to 1383 bp relative to the translation start site in hapX.

For the reconstitution of the ΔhapX strain with a functional hapX copy, a 3615bp PCR fragment generated with primers ohapX-5 and ohapX-6 was subcloned into pGEM-T (Promega) according to the supplier's manual, resulting in pHapX. A 2410bp SphI fragment from pAN7-1 containing the hygromycine B resistance-conferring hph gene was inserted into the SphI site of pHapX resulting in pHapXhph. The resulting 9.0-kb plasmid pHapXhph was linearized with EcoRV and used to transform A. fumigatus ΔhapX.

Transformation of A. fumigatus was carried out as described previously [10]. For selection of transformants 0.1 µg ml−1 pyrithiamine (Sigma) or 0.2 mg ml−1 hygromycin B (Calbiochem) was used. Screening of transformants was performed by PCR and confirmed by Southern blot analysis. The hybridization probes for Southern blot analysis of ΔhapX and ΔhapXc strains were generated by PCR using the primers ohapX-5 and ohapX-4 (Table S8 in Supporting Information S1).

Analysis of siderophores, PpIX, and free amino acids

Analysis of siderophore, PpIX and free amino acids was carried out by reversed phase HPLC as described previously [20], [43], [46]. To quantify extracellular or intracellular siderophores, culture supernatants or cellular extracts were saturated with FeSO4 and siderophores were extracted with 0.2 volumes of phenol. The phenol phase was separated and subsequent to addition of 5 volumes of diethylether and 1 volume of water, the siderophore concentration of the aqueous phase was measured photometrically using a molar extinction factor of 2996/440nm (M−1cm−1).

Determination of mtDNA content

A. fumigatus total DNA was isolated with the QIAamp kit (Qiagen). MtDNA compared to nuclear DNA content was determined by quantitative real-time PCR (qPCR) with CYBR green I (ABI; ABI 2400 Applied Biosystems, USA) by PCR amplification of a fragment of the mitochondrial apocytochrome B gene (BAA34151, 73.t00020) using primers oAfcytB-1 and oAfcytB-2, and a fragment of the nuclear mirD gene (Afu3G03440) gene, using primers oAfmirD-1 and oAfmirD-2. The PCR reactions cycle used (Applied Biosystems standard conditions) was 40 cycles at 95°C 15″, 60°C 1′. PCR assays were performed in biological triplicates and technical duplicates for each DNA sample. The expression of mtDNA copy number relative to nuclear DNA was determined using the 2−ΔCT method.

Transcriptional profiling

The A. fumigatus Af293 DNA amplicon microarray containing 9,516 genes [47] was used in this study. To profile the genome-wide expression responses to the shift from iron depleted to iron-replete conditions and to identify the genes influenced by HapX, we conducted microarray analysis with the wt and ΔhapX strains grown for 16 h at 37°C in iron-depleted (−Fe) medium (0 h time point). Subsequently iron was added to a final concentration of 30 mM and growth was continued for 1 hour (sFe). Labelling reactions with RNA, and hybridization were conducted as described in the PFGRC standard operating procedures (PFGRC SOP's) found at http://pfgrc.tigr.org/protocols/protocol​s.shtml. The sample from 0 h served as reference in all hybridizations with the 1 h iron shift samples in order to identify genes exhibiting altered transcription after the shift from iron depleted to iron replete conditions in ΔhapX compared to wt. Additionally, the 16 h iron starvation cultures of ΔhapX and wt were directly compared with the wt serving as reference. (Fig. S1 and S2)

Hybridized slides were scanned using the Axon GenePix 4000B microarray scanner and the TIFF images generated were analyzed using the TM4 suite of microarray analysis tools (http://www.tm4.org). Spotfinder was used to obtain relative transcript levels. Data from Spotfinder were stored in MAD, a relational database designed to effectively capture and store microarray data. Data normalization was accomplished using a local regression technique LOWESS (LOcally WEighted Scatterplot Smoothing) for hybridizations using the TM4 MIDAS tool. The resulting data was averaged from triplicate gene spots on each array and from duplicate flip-dye arrays for each experiment, taking a total of 6 intensity data points for each gene. Differentially expressed genes at the 95% confidence level were determined using intensity-dependent Z-scores (with Z = 1.96) as implemented in MIDAS and the union of all genes identified at each time point from the wild-type were considered significant in this experiment. Microarray data are deposited in the GEO database (http://www.ncbi.nlm.nih.gov/geo/query/ac​c.cgi?token=jhqbdcwiigqyypa&acc=GSE22052).

Virulence assay

Virulence assays in two murine models for pulmonary aspergillosis were performed as described previously [33], [34]. Infections were performed with two groups of five mice for each tested strain. A control group remained uninfected (inhalation of PBS) to monitor the influence of the immunosuppressive regime. Survival data were plotted as Kaplan-Meyer curves and were analyzed statistically by a log rank test using Graph Pad Prism version 5.00 for Windows (GraphPad Software, San Diego, CA). Lungs from euthanized animals were removed, fixed in formalin and paraffin-embedded for histopathologic analyses according to standard protocols. Sections were stained with Periodic acid-Schiff (PAS) according to standard protocols and analyzed by bright field microscopy using a Zeiss AxioImager.M1 microscope equipped with a SPOT Flex Shifting Pixel Color Mosaic camera (Diagnostic Instruments, Inc., Sterling Heights, USA).

Ethics statement

Mice were cared for in accordance with the principles outlined by the European Convention for the Protection of Vertebrate Animals Used for Experimental and Other Scientific Purposes (European Treaty Series, no. 123; http://conventions.coe.int/Treaty/en/Tre​aties/Html/123.htm). All animal experiments were in compliance with the German animal protection law and were approved (permit no. 03-001/08) by the responsible Federal State authority (Thüringer Landesamt für Lebensmittelsicherheit und Verbraucherschutz) and ethics committee (beratende Komission nach § 15 Abs. 1 Tierschutzgesetz).

Supporting Information

Figure S1.

Biosynthesis of both TAFC and FC starts with N5-hydroxylation of ornithine. Subsequently, the hydroxamate group is formed by the transfer of an acyl group from acyl-coenzyme A (CoA) derivatives to N5-hydroxyornithine. Here the pathways for biosynthesis of TAFC and FC split due to the choice of the acyl group with acetyl for FC and anhydromevalonyl for TAFC. Assembly of the cyclic siderophores fusarinine C and FC is catalysed by different non-ribosomal peptide synthetases (NRPS). TAFC and hydroxyferricrocin are formed by N2-acetylation of fusarinine C and hydroxylation of FC respectively. With exception of the acetyl transferase required for FC biosynthesis all A. fumigatus genes encoding respective enzyme activities have been identified and are indicated (Haas et al., 2008; Schrettl et al., 2004; Schrettl et al., 2007).

doi:10.1371/journal.ppat.1001124.s001

(0.55 MB TIF)

Figure S2.

A. fumigatus wt was grown for 24 h at 37°C in liquid flask cultures and 10 ml of culture supernatant was analyzed by reversed phase HPLC.

doi:10.1371/journal.ppat.1001124.s002

(0.10 MB TIF)

Supporting Information S1.

Tables S1 to S8.

doi:10.1371/journal.ppat.1001124.s003

(6.06 MB DOC)

Author Contributions

Conceived and designed the experiments: MS NB JV TH IDJ CJ TAM SW FG MB ERW WCN AAB HH. Performed the experiments: MS NB JV TH IDJ CJ TAM SW FG MB ERW. Analyzed the data: MS NB JV TH IDJ CJ TAM SW FG MB ERW WCN AAB HH. Contributed reagents/materials/analysis tools: ERW WCN AAB HH. Wrote the paper: HH.

References

  1. 1. Halliwell B, Gutteridge JM (1984) Oxygen toxicity, oxygen radicals, transition metals and disease. Biochem J 219: 1–14.
  2. 2. Weinberg ED (1999) The role of iron in protozoan and fungal infectious diseases. J Eukaryot Microbiol 46: 231–238.
  3. 3. Weiss G (2002) Iron and immunity: a double-edged sword. Eur J Clin Invest 32: Suppl 170–78.
  4. 4. Tekaia F, Latge JP (2005) Aspergillus fumigatus: saprophyte or pathogen? Curr Opin Microbiol 8: 385–392.
  5. 5. Schrettl M, Bignell E, Kragl C, Joechl C, Rogers T, et al. (2004) Siderophore biosynthesis but not reductive iron assimilation is essential for Aspergillus fumigatus virulence. J Exp Med 200: 1213–1219.
  6. 6. Haas H, Eisendle M, Turgeon BG (2008) Siderophores in fungal physiology and virulence. Annu Rev Phytopathol 46: 149–187.
  7. 7. Haas H, Schoeser M, Lesuisse E, Ernst JF, Parson W, et al. (2003) Characterization of the Aspergillus nidulans transporters for the siderophores enterobactin and triacetylfusarinine C. Biochem J 371: 505–513.
  8. 8. Kragl C, Schrettl M, Abt B, Sarg B, Lindner HH, et al. (2007) EstB-mediated hydrolysis of the siderophore triacetylfusarinine C optimizes iron uptake of Aspergillus fumigatus. Eukaryot Cell 6: 1278–1285.
  9. 9. Wallner A, Blatzer M, Schrettl M, Sarg B, Lindner H, et al. (2009) Ferricrocin, a siderophore involved in intra- and transcellular iron distribution in Aspergillus fumigatus. Appl Environ Microbiol 75: 4194–4196.
  10. 10. Schrettl M, Bignell E, Kragl C, Sabiha Y, Loss O, et al. (2007) Distinct Roles for Intra- and Extracellular Siderophores during Aspergillus fumigatus Infection. PLoS Pathog 3: e128.
  11. 11. Hwang LH, Mayfield JA, Rine J, Sil A (2008) Histoplasma requires SID1, a member of an iron-regulated siderophore gene cluster, for host colonization. PLoS Pathog 4: e1000044.
  12. 12. Greenshields D, Guosheng L, Feng J, Selvaraj G, Wei Y (2007) The siderophore biosynthetic gene SID1, but not the ferroxidase gene FET3, is required for full Fusarium graminearum virulence. Mol Plant Path 8: 411–421.
  13. 13. Oide S, Moeder W, Haas H, Krasnoff S, Gibson D, et al. (2006) NPS6, encoding a non-ribosomal peptide synthetase involved in siderophore-mediated iron metabolism, is a conserved virulence determinant of plant pathogenic ascomycetes. Plant Cell 18: 2836–2853.
  14. 14. Kontoyiannis DP, Chamilos G, Lewis RE, Giralt S, Cortes J, et al. (2007) Increased bone marrow iron stores is an independent risk factor for invasive aspergillosis in patients with high-risk hematologic malignancies and recipients of allogeneic hematopoietic stem cell transplantation. Cancer.
  15. 15. Zarember KA, Sugui JA, Chang YC, Kwon-Chung KJ, Gallin JI (2007) Human polymorphonuclear leukocytes inhibit Aspergillus fumigatus conidial growth by lactoferrin-mediated iron depletion. J Immunol 178: 6367–6373.
  16. 16. Fluckinger M, Haas H, Merschak P, Glasgow BJ, Redl B (2004) Human tear lipocalin exhibits antimicrobial activity by scavenging microbial siderophores. Antimicrob Agents Chemother 48: 3367–3372.
  17. 17. Hachem R, Bahna P, Hanna H, Stephens LC, Raad I (2006) EDTA as an adjunct antifungal agent for invasive pulmonary aspergillosis in a rodent model. Antimicrob Agents Chemother 50: 1823–1827.
  18. 18. Ibrahim AS, Gebremariam T, French SW, Edwards JE Jr, Spellberg B (2010) The iron chelator deferasirox enhances liposomal amphotericin B efficacy in treating murine invasive pulmonary aspergillosis. J Antimicrob Chemother 65: 289–292.
  19. 19. Haas H, Zadra I, Stoffler G, Angermayr K (1999) The Aspergillus nidulans GATA factor SREA is involved in regulation of siderophore biosynthesis and control of iron uptake. J Biol Chem 274: 4613–4619.
  20. 20. Hortschansky P, Eisendle M, Al-Abdallah Q, Schmidt AD, Bergmann S, et al. (2007) Interaction of HapX with the CCAAT-binding complex-a novel mechanism of gene regulation by iron. Embo J 26: 3157–3168.
  21. 21. Mercier A, Pelletier B, Labbe S (2006) A transcription factor cascade involving Fep1 and the CCAAT-binding factor Php4 regulates gene expression in response to iron deficiency in the fission yeast Schizosaccharomyces pombe. Eukaryot Cell 5: 1866–1881.
  22. 22. Schrettl M, Kim HS, Eisendle M, Kragl C, Nierman WC, et al. (2008) SreA-mediated iron regulation in Aspergillus fumigatus. Mol Microbiol 70: 27–43.
  23. 23. Kispal G, Sipos K, Lange H, Fekete Z, Bedekovics T, et al. (2005) Biogenesis of cytosolic ribosomes requires the essential iron-sulphur protein Rli1p and mitochondria. EMBO J 24: 589–598.
  24. 24. Mercier A, Watt S, Bahler J, Labbe S (2008) Key function for the CCAAT-binding factor Php4 to regulate gene expression in response to iron deficiency in fission yeast. Eukaryot Cell 7: 493–508.
  25. 25. Puig S, Vergara SV, Thiele DJ (2008) Cooperation of two mRNA-binding proteins drives metabolic adaptation to iron deficiency. Cell Metab 7: 555–564.
  26. 26. Mercier A, Labbe S (2009) Both Php4 function and subcellular localization are regulated by iron via a multistep mechanism involving the glutaredoxin Grx4 and the exportin Crm1. J Biol Chem 284: 20249–20262.
  27. 27. Lacadena J, Alvarez-Garcia E, Carreras-Sangra N, Herrero-Galan E, Alegre-Cebollada J, et al. (2007) Fungal ribotoxins: molecular dissection of a family of natural killers. FEMS Microbiol Rev 31: 212–237.
  28. 28. Ok M, Latge JP, Baeuerlein C, Ebel F, Mezger M, et al. (2009) Immune responses of human immature dendritic cells can be modulated by the recombinant Aspergillus fumigatus antigen Aspf1. Clin Vaccine Immunol 16: 1485–1492.
  29. 29. Paris S, Monod M, Diaquin M, Lamy B, Arruda LK, et al. (1993) A transformant of Aspergillus fumigatus deficient in the antigenic cytotoxin ASPFI. FEMS Microbiol Lett 111: 31–36.
  30. 30. Shakoury-Elizeh M, Protchenko O, Berger A, Cox J, Gable K, et al. (2010) Metabolic response to iron deficiency in Saccharomyces cerevisiae. J Biol Chem 285: 14823–14833.
  31. 31. Chopra I, Roberts M (2001) Tetracycline antibiotics: mode of action, applications, molecular biology, and epidemiology of bacterial resistance. Microbiol Mol Biol Rev 65: 232–260 ; second page, table of contents.
  32. 32. Yasmin S, Abt B, Schrettl M, Moussa TA, Werner ER, et al. (2009) The interplay between iron and zinc metabolism in Aspergillus fumigatus. Fungal Genet Biol 46: 707–713.
  33. 33. Kupfahl C, Heinekamp T, Geginat G, Ruppert T, Hartl A, et al. (2006) Deletion of the gliP gene of Aspergillus fumigatus results in loss of gliotoxin production but has no effect on virulence of the fungus in a low-dose mouse infection model. Mol Microbiol 62: 292–302.
  34. 34. Liebmann B, Muhleisen TW, Muller M, Hecht M, Weidner G, et al. (2004) Deletion of the Aspergillus fumigatus lysine biosynthesis gene lysF encoding homoaconitase leads to attenuated virulence in a low-dose mouse infection model of invasive aspergillosis. Arch Microbiol 181: 378–383.
  35. 35. Philippe B, Ibrahim-Granet O, Prevost MC, Gougerot-Pocidalo MA, Sanchez Perez M, et al. (2003) Killing of Aspergillus fumigatus by alveolar macrophages is mediated by reactive oxidant intermediates. Infect Immun 71: 3034–3042.
  36. 36. Schobel F, Jacobsen ID, Brock M (2010) Evaluation of lysine biosynthesis as antifungal drug target: Biochemical characterization of Aspergillus fumigatus homocitrate synthase and virulence studies. Eukaryot Cell.
  37. 37. Stergiopoulou T, Meletiadis J, Roilides E, Kleiner DE, Schaufele R, et al. (2007) Host-dependent patterns of tissue injury in invasive pulmonary aspergillosis. Am J Clin Pathol 127: 349–355.
  38. 38. Balloy V, Huerre M, Latge JP, Chignard M (2005) Differences in patterns of infection and inflammation for corticosteroid treatment and chemotherapy in experimental invasive pulmonary aspergillosis. Infect Immun 73: 494–503.
  39. 39. Schrettl M, Ibrahim-Granet O, Droin S, Huerre M, Latge JP, et al. (2010) The crucial role of the Aspergillus fumigatus siderophore system in interaction with alveolar macrophages. Microbes Infect.
  40. 40. Seifert M, Nairz M, Schroll A, Schrettl M, Haas H, et al. (2008) Effects of the Aspergillus fumigatus siderophore systems on the regulation of macrophage immune effector pathways and iron homeostasis. Immunobiology 213: 767–778.
  41. 41. Jung WH, Sham A, White R, Kronstad JW (2006) Iron regulation of the major virulence factors in the AIDS-associated pathogen Cryptococcus neoformans. PLoS Biol 4: e410.
  42. 42. Pontecorvo G, Roper JA, Hemmons LM, MacDonald KD, Bufton AWJ (1953) The genetics of Aspergillus nidulans. Adv Genet 5: 141–238.
  43. 43. Oberegger H, Schoeser M, Zadra I, Abt B, Haas H (2001) SREA is involved in regulation of siderophore biosynthesis, utilization and uptake in Aspergillus nidulans. Mol Microbiol 41: 1077–1089.
  44. 44. Sambrook J, Fritsch EF, Maniatis T (1989) Molecular Cloning: A Laboratory Manual. New York: Cold Spring Harbor Laboratory Press.
  45. 45. Nielsen ML, Albertsen L, Lettier G, Nielsen JB, Mortensen UH (2006) Efficient PCR-based gene targeting with a recyclable marker for Aspergillus nidulans. Fungal Genet Biol 43: 54–64.
  46. 46. Berger H, Basheer A, Bock S, Reyes-Dominguez Y, Dalik T, et al. (2008) Dissecting individual steps of nitrogen transcription factor cooperation in the Aspergillus nidulans nitrate cluster. Mol Microbiol 69: 1385–1398.
  47. 47. Nierman WC, Pain A, Anderson MJ, Wortman JR, Kim HS, et al. (2005) Genomic sequence of the pathogenic and allergenic filamentous fungus Aspergillus fumigatus. Nature 438: 1151–1156.