GliZ, a Transcriptional Regulator of Gliotoxin Biosynthesis, Contributes to Aspergillus fumigatus Virulence

Gliotoxin is a nonribosomal peptide produced by Aspergillusfumigatus. This compound has been proposed as an A. fumigatusvirulence factor due to its cytotoxic, genotoxic, and apoptoticproperties. Recent identification of the gliotoxin gene clusteridentified several genes (gli genes) likely involved in gliotoxinproduction, including gliZ, encoding a putative Zn₂Cys₆ binucleartranscription factor. Replacement of gliZ with a marker gene( ${Delta}$ gliZ) resulted in no detectable gliotoxin production and lossof gene expression of other gli cluster genes. Placement ofmultiple copies of gliZ in the genome increased gliotoxin production.Using endpoint survival data, the ${Delta}$ gliZ and a multiple-copy gliZstrain were not statistically different from the wild type ina murine pulmonary model; however, both the wild-type and themultiple-copy gliZ strain were more virulent than ${Delta}$ laeA (a mutantreduced in production of gliotoxin and other toxins). A flow-cytometricanalysis of polymorphonuclear leukocytes (PMNs) exposed to supernatantsfrom wild-type, ${Delta}$ gliZ, complemented ${Delta}$ gliZ, and ${Delta}$ laeA strains supporteda role for gliotoxin in apoptotic but not necrotic PMN celldeath. This may indicate that several secondary metabolitesare involved in A. fumigatus virulence.

INTRODUCTION

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Introduction

Aspergillus fumigatus, a saprophytic and opportunistic pathogenicfilamentous fungus, causes mycotoxicosis, allergic reactions,and a life-threatening systemic disease called "invasive aspergillosis"(IA) in immunocompromised individuals. Insufficient defensemechanisms by the innate and acquired immune systems resultin high IA mortality rates in neutropenic and immunosuppressedpatients. The incidence of IA has increased in recent decades,largely due to an increased population of immunosuppressed patientsat risk after organ transplantation or therapy for cancer. Inspite of advances in early diagnosis and new antifungal therapy,IA continues to be a leading cause of death in these patients,with mortality rates reported to be as high as 80% to 95% (11).

A. fumigatus virulence attributes contributing to IA are notlikely to be due to a single factor but rather a combinationof interactions of various molecules and biological propertiesof the fungus (22, 32, 40). Growth characteristics such as itshigh spore concentration in the air and its faster growth relativeto any other airborne fungi at 40°C are thought to contributeto its virulence (22, 39). However, identification of unique,single-molecule, virulence factors has been elusive in thissystem. One molecule hypothesized as a unique virulence factoris the secondary metabolite gliotoxin.

Gliotoxin is a well-studied nonribosomal peptide toxin (14)and has long been fingered as a putative factor contributingto IA due to its cytotoxic (15), genotoxic (26), and apoptoticproperties (21, 29, 38). A potential role for gliotoxin in IAwas recently supported by genetic studies of an A. fumigatussecondary metabolite mutant, ${Delta}$ laeA, which was shown to be crippledin gliotoxin biosynthesis (5, 6). The loss of laeA in A. fumigatusresults in reduced virulence in a murine model, increased conidialsusceptibility to macrophage phagocytosis, and decreased hyphalkilling of neutrophils (5). This latter trait was hypothesizedto be due to lack of gliotoxin production. However, along withthe decrease in gliotoxin production, the ${Delta}$ laeA strain is decreasedin the production of several other secondary metabolites implicatedas virulence factors, including fumagillin, fumagatin, and helvolicacid, among others (5; http://www.aspergillus.man.ac.uk/indexhome.htmand references therein).

Recently, a predicted gliotoxin biosynthetic gene cluster wasidentified in A. fumigatus (14). In an attempt to assess thecontributions of gliotoxin to the role of LaeA in virulence,we have created a null mutant in gliZ encoding a putative Zn₂Cys₆binuclear finger transcription factor. Here we show that gliZis required for gliotoxin biosynthesis and expression of othergenes in the gli gene cluster and that placement of two or morecopies of gliZ in the genome results in increased gliotoxinsynthesis. Although statistical examination of the results ofa murine pulmonary model did not support a difference in virulencein the wild type compared to either ${Delta}$ gliZ or multiple-copy gliZ,there was a tendency towards a decrease and increase in micedeath associated with these strains, respectively. Two concurrentstudies, where gliP encoding a nonribosomal peptide synthaserequired for gliotoxin synthesis was deleted from the A. fumigatusgenome, yielded similar results where the authors report nodifference in mouse survival (10, 20). However, in both studiesloss of gliotoxin resulted in decreased toxicity as measuredeither by mast cell degranulation (10) or macrophage/T-cellviability (20), thus leading to speculation that this metabolitecan play a role in disease development. Here, cytotoxicity assayswith polymorphonuclear leukocytes (PMNs) support a role forgliotoxin in apoptotic but not necrotic cell death. Taken together,we posit that gliotoxin is one factor that can be involved indisease development and that its effects may not be readilymeasured by the current animal model systems. We suggest thatother LaeA-regulated metabolites or attributes also contributeto A. fumigatus virulence.

MATERIALS AND METHODS

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Materials and Methods

Strains. All fungal strains used in this study (Table 1) were maintainedas glycerol stocks and were routinely cultured at 25°C or37°C on glucose minimal medium (GMM) (34).

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TABLE 1. A. fumigatus strains used for this study

gliZ deletion and complementation. Aspergillus fumigatus gliZ was disrupted in wild-type strainAF293.1 (a pyrG auxotroph [46]) by replacement of gliZ withthe A. parasiticus pyrG marker gene obtained from pBZ5 (35).An A. fumigatus gliZ gene disruption vector, pJW74.3, was constructedby insertion of a 1.2-kb DNA fragment upstream of the gliZ startcodon (primers GZ5F and GZ5R) and a 0.9-kb DNA fragment downstreamof the gliZ stop codon (primers GZ3F and GZ3R) on either sideof the A. parasiticus pyrG marker gene. Fungal protoplasts weretransformed by the polyethylene glycol method as previouslydescribed (5). Homologous single-gene replacement of gliZ wasconfirmed by Southern blot analysis and PCR.

pJW78.3 was constructed to complement the ${Delta}$ gliZ strain TDWC5.6.The plasmid contained a 3.2-kb wild-type gliZ gene includinga 1.2-kb promoter. The 3.2-kb gliZ gene was amplified by primersGZCOMF and GZCOMR. The PCR product was subcloned in the ZeroBlunt TOPO vector (Invitrogen Co.) to produce pJW75.1. pJW78.3was created by inserting the 3.2-kb HindIII-XbaI gliZ fragmentfrom pJW75.1 into a HindIII-XbaI site of pUCH2-8 (2), whichcontains the selectable marker hygromycin B phosphotransferase.

Extraction of fungal DNA, restriction enzyme digestion, gelelectrophoresis, Southern and Northern blotting, hybridization,and probe preparation were performed using standard methods(33). RNA blots were hybridized with a 1.2-kb PCR fragment ofgliZ amplified with primers GZINTF and GZINTR and a 0.7-kb gliIPCR product using primers GIINTF and GIINTR. Primers for PCRand probes are listed in Table 2.

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TABLE 2. Primers used in this study

Detection of gliI expression in A. fumigatus-infected lung by reverse transcriptase PCR (RT-PCR). Total RNA was extracted from lungs of 10 mice of two groups;one of them was infected intranasally by A. fumigatus as describedpreviously (5) with 10⁸ spores/ml, and the other group, notinfected by the fungus, served as a negative control. Thesemice were separate from the mice used for the virulence testas described below. At day 3, all mice were sacrificed and alllungs from each group were combined per treatment and homogenizedwith 10 ml of phosphate-buffered saline. Nonhomogenizable tissuewas removed using a pipette. The homogenate was spun down in50-ml Oakridge tubes at 5,000 rpm, and then supernatant (SN)was removed. The pellet was resuspended with 4 ml of 1% TritonX-100 and homogenized for 1 min. The homogenate was spun downin 50-ml Oakridge tubes at 5,000 rpm, and supernatant was removed.These last two steps were repeated one more time. The pelletwas washed twice with sterile distilled water, and then homogenatewas spun down at 5,000 rpm to obtain the final pellet. Thispellet was lyophilized overnight. The freeze-dried pellet wasmixed with TRIzol (Invitrogen Co.) to extract total RNA accordingto the manufacturer's instructions. The RNA pellet was dissolvedin diethyl pyrocarbonate-treated water prior to cDNA synthesisusing a SuperScript III kit (Invitrogen Co.) according to themanufacturer's directions. The following primers were used toamplify the A. fumigatus-specific gene, gliI (a biosyntheticgene of gliotoxin [14]), from the cDNA pool. gliIRTF and gliIRTRwere used to amplify the primary PCR product. Two microlitersof this PCR product was used as template for secondary PCR amplificationwith nested primers, nestedgliIF and nestedgliIR. These primersare described in Table 2.

Phenotypic characterization and secondary metabolite analysis. Colony growth radius and spore production were measured as previouslydescribed (17). Gliotoxin production was assessed by thin-layerchromatography (TLC) and by high-pressure liquid chromatography-photodiode array detection-high-resolution mass spectrometry (HPLC-HR-MS)using previously published methods (5, 8, 40). For TLC, fungiwere grown in liquid glucose minimal medium (GMM) for 3 daysat 25 or 37°C and at 280 rpm, and organic extracts weremeasured for secondary metabolites. Gliotoxin was also measuredby HPLC-diode array detection and HPLC-HR-MS from extracts ofcultures grown on Czapek yeast extract agar (CYA), malt extractagar (MEA), oatmeal agar (OAT), and yeast extract-sucrose agar(YES) media at either 25 or 37°C (13). Here, two agar plugsof the center of colonies of 11-day-old cultures (three pointinoculations) grown in the dark on each of the CYA, MEA, OAT,and YES (13) media were pooled and extracted according to Smedsgaard(36). The wild type and mutants were also grown on GMM agarin the dark for 1 week at 25°C and 37°C, and the cultureextracts were examined for gliotoxin, desmethyl-(dimethylthio)-gliotoxin,helvolic acid, fumigaclavines, pseurotins, trypacidin, mono-methylsulochrin,chloroanthraquionones, fumiquinazolines, tryptoquivalins, andfumagillin by analyzing them using HPLC-diode array detectionand HPLC-HR-MS. The monitoring wavelength was 210 nm. Gliotoxinand other metabolites were identified by their retention time,UV spectra, and positive electrospray (ESI⁺) spectra, whichshould match both the relative intensities of ions and theirrespective accurate masses (±<0.01-Da deviation).

Gliotoxin was also measured from homogenates of murine lungas previously described (5).

Animal model of Aspergillus infection. Virulence of near-isogenic strains of A. fumigatus differingonly in the presence of laeA or gliZ gene (e.g., wild-type, ${Delta}$ laeA, ${Delta}$ gliZ, and ${Delta}$ gliZ-complemented strains; Table 1) was assessedtwice in a lung infection model, as described previously (5).Briefly, 6-week-old, outbred Swiss ICR mice (Harlan SpragueDawley) weighing 24 to 27 g were immunosuppressed by intraperitonealinjection of cyclophosphamide (150 mg/kg of body weight) ondays 4 and 1 preinfection and day 3 postinfection, with a singledose of cortisone acetate (200 mg/kg) on the morning of infection.Anesthetized mice (10 mice/fungal strain in the first test and15 mice/fungal strain in the second test) were infected by nasalinstillation of 50 µl of 5 x 10⁶ conidia/ml (day 1) andmonitored three times daily for 7 days postinfection. All survivingmice were sacrificed at day 7. Homogenates of lung tissue wereexamined for gliotoxin by HPLC-HR-MS as previously described(5).

Polymorphonuclear leukocytes and fungal cytotoxicity. Whole blood of healthy adult human donors was collected afterconsent, using a protocol approved by the Fred Hutchinson CancerResearch Center Institutional Review Board. Polymorphonuclearleukocytes (PMNs) were purified by Ficoll centrifugation perthe leukocyte separation protocol (Sigma). Red blood cells werelysed in hypotonic solution, and PMNs were separated by centrifugation(800 x g, 10 min) and resuspended in RPMI 1640-HEPES. Fungalsupernatants were prepared as follows: 30 ml of GMM was inoculatedwith 10⁷ conidia/ml and incubated for 72 h at 37°C (withshaking at 220 rpm). The fungal mat was separated from the culturesupernatant by passing through sterile gauze and filtered througha 0.2-µm filter; the resultant supernatant was vacuumdried for 36 h. The dried precipitate was resuspended in 4 mlphosphate-buffered saline (concentrated SN) and frozen at –70°Cfor later use. PMNs (2 x 10⁶ cells) were exposed to 200 µlof SN (test conditions), medium (live controls), or Triton X-100(dead controls) for 60 min. Cells were centrifuged (1,200 rpm,10 min) and resuspended in 100 µl binding buffer (10 mMHEPES, 140 mM NaCl, 2.5 mM CaCl₂; pH 7.4) containing eitherAnnexin V (5 µl; BD Biochemicals, San Jose, CA), propidiumiodide (PI; 10 µl; Sigma Chemical Co., St. Louis, MO),or both Annexin V and PI. Cells were incubated for 15 min inthe dark, and 400 µl of 1x binding buffer was added. Fourseparate experiments were conducted. Propidium iodide and AnnexinV positivity were measured by a FACScan flow cytometer (BD Biosciences)with CELLQuest software (BD Biosciences).

Statistical analyses. Wilcoxon rank-sum tests (44) were performed to detect differencesin PMN death and apoptosis after exposure to supernatant fromwild-type and mutant strains. In animal experiments, Fisher'sexact tests (12) were used to compare proportions survivingat day 7. All P values presented were adjusted for multiplecomparisons using the false discovery rate method (4).

RESULTS

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Results

gliZ is required for gliotoxin production. gliZ was deleted from the A. fumigatus genome by replacing itwith the A. parasiticus pyrG gene. Six gliZ null mutants ( ${Delta}$ gliZ)were obtained from 55 transformants. Southern blot and PCR analyseswere carried out to confirm single-gene replacement events inthe transformants (Fig. 1; unpublished data). Two transformants,TDWC5.6 and TDWC5.33, were selected for physiological and virulencestudies. The ${Delta}$ gliZ mutant TDWC5.6 was complemented with the gliZgene. Two complemented strains, TDWC8.3 and TDWC8.10, were confirmedby PCR and Southern blot hybridization (data not shown). Bothof these strains carried two or more copies of gliZ. Wild-type, ${Delta}$ gliZ, and ${Delta}$ gliZ-complemented strains were not statistically differentin growth rate or conidial production (data not shown).

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FIG. 1. Disruption of a transcription factor of gliotoxin biosynthesis, gliZ, in A. fumigatus. A. Schematic diagram of the gliZ open reading frame and how it was replaced with the pyrG selectable marker from pJW74.3 by homologous recombination to generate the gliZ mutant TDWC5. B. Southern blot analysis of the wild-type (WT) strain and the gliZ mutant strain. Genomic DNA was digested by EcoRI. A 3.2-kb PCR product containing gliZ was obtained with the primers GZ5F and GZ3R and was used as a gliZ probe (indicated by a bar in panel A). Expected hybridization band patterns: wild-type strain, 7-kb band; ${Delta}$ gliZ strain, 6- and 3.5-kb bands. The arrowheads at the top of the figure indicate correct knockout mutants. The $~$ 5-kb bands in the other three lanes indicate ectopic copies of knockout cassettes, and thus these strains were discarded.

A thin-layer chromatography (TLC) examination of chloroformextracts from liquid shake GMM cultures of A. fumigatus ${Delta}$ gliZand the ${Delta}$ gliZ-complemented strains grown at 25°C showed lossof or increased production of gliotoxin, respectively (Fig.2). Production of a few other unknown metabolites was also affectedby loss or gain of gliZ in this condition (Fig. 2). HPLC dataof the ${Delta}$ gliZ and ${Delta}$ gliZ-complemented strains grown on solid GMMsupported the TLC gliotoxin results and further showed thatstrains produced levels of fumigaclavine C, mono-methylsulochrin,trypacidin, and fumiquinazolins similar to those of the wildtype. However, at 37°C on solid GMM, the ${Delta}$ gliZ-complementedstrains produced helvolic acid, which was not detected in thewild type or the ${Delta}$ gliZ mutant (Table 3) .

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FIG. 2. Thin-layer chromatography profiles of metabolite production by A. fumigatus ${Delta}$ laeA (TJW54.2), wild-type (AF293), ${Delta}$ gliZ (TDWC5.6), and two complemented ${Delta}$ gliZ (TDWC8.3 and TDWC8.10, designated ${Delta}$ gliZcom8.3 and ${Delta}$ gliZcom8.10, respectively) strains. Metabolites were extracted by chloroform from 50 ml GMM liquid shaking culture grown for 3 days at 25°C and 280 rpm. Dried chloroform extracts were resuspended in 100 µl of methanol, and 10 µl was used for separation on TLC. All experiments were triplicated. Solvent condition was the following: 7:3 chloroform:acetone. Gt, gliotoxin standard. Solid black arrows indicate gliotoxin, and dotted black arrows indicate possible changes in production of other metabolites in ${Delta}$ gliZ and/or complemented gliZ mutants. Note the near-complete absence of metabolites in ${Delta}$ laeA. WT, wild type.

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TABLE 3. Metabolite production in strains grown on GMM agar for 1 week at 25 and 37°C in the dark

As the purported role of GliZ as a Zn(II)₂Cys₂ transcriptionfactor would be to activate expression of biosynthetic genesin the gli gene cluster (14, 49), we assessed the expressionof gliI in wild-type, ${Delta}$ laeA, ${Delta}$ gliZ, and ${Delta}$ gliZ-complemented strainsgrown in liquid GMM. gliI encodes a putative aminocyclopropanecarboxylate synthase, a function required for gliotoxin synthesis(14). As predicted, gliI expression was abolished in both the ${Delta}$ laeA and ${Delta}$ gliZ strains and increased in the ${Delta}$ gliZ-complementedstrains in comparison to the wild type (Fig. 3A). Early expressionof both gliI and gliZ was observed in the complemented strainunder these conditions.

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FIG. 3. gliI gene expression in liquid shaking cultures and in infected mice. A. gliZ and gliI expression in A. fumigatus (AF293) wild-type, ${Delta}$ laeA (TJW54.2), ${Delta}$ gliZ (TDWC5.6), and ${Delta}$ gliZ-complemented (TDWC8.3) strains. Two lanes of TDWC8.3 are shown (designated ${Delta}$ gliZcom). All strains were grown in 50 ml GMM liquid shaking culture grown at 25°C and 280 rpm. Total RNA was extracted from mycelia grown for 36 h and 72 h and probed with gliZ and gliI. B. Amplification of gliI from wild-type A. fumigatus-infected mouse lung by reverse transcriptase PCR (RT-PCR) using the secondary PCR nested primers (see Materials and Methods). Lane 1, 1-kb size marker; lane 2, PCR from genomic DNA; lane 3, PCR from RT-PCR product from noninfected lungs; lane 4, PCR from RT-PCR product from infected lungs. The size difference between lanes 2 and 4 is due to an intron (63 bp) in the gliI gene which is only present in the genomic DNA lane. WT, wild type.

Infection with GliZ mutants is correlated with gliotoxin concentrations in murine lung. Relative virulence of wild type, ${Delta}$ laeA, ${Delta}$ gliZ, and ${Delta}$ gliZ-complementedstrains of A. fumigatus was evaluated in murine pulmonary infectionmodels by comparing the proportion surviving at day 7 afterinfection. As shown in Fig. 4, whereas a significant differencewas observed between all four groups (P = 0.002), pairwise comparisonsindicated a significant difference between groups of animalsinfected with the wild-type and ${Delta}$ laeA strains (P = 0.05). However,animals infected with ${Delta}$ gliZ and complemented ${Delta}$ gliZ did not demonstratesignificant differences in survival compared to that of thewild type (P = 0.45 for both). Animals infected with the ${Delta}$ gliZ-complementedand ${Delta}$ laeA strains also demonstrated differences in survival (P= 0.0004).

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FIG. 4. Virulence in a murine lung infection model. Fifteen outbred Swiss ICR mice immunosuppressed by intraperitoneal injection of cyclophosphamide (150 mg/kg) and cortisone acetate (200 mg/kg) were inoculated intranasally with A. fumigatus wild-type (AF293), ${Delta}$ laeA (TJW54.2), ${Delta}$ gliZ (TDWC5.6), and ${Delta}$ gliZ-complemented (TDWC8.3; designated ${Delta}$ gliZcom8.3) strains (50 µl of 5 x 10⁶ conidia/ml). Results presented are from one experiment that is representative of the two performed. Using Fisher's exact test at day 7, the overall P value was 0.002. Pairwise comparisons only indicated a significant difference between wild-type and ${Delta}$ laeA strains (P = 0.05) and the ${Delta}$ gliZ-complemented and ${Delta}$ laeA strains (P = 0.0004). WT, wild type.

Lungs of five mice of each group were homogenized and extractedto assess metabolite content. Results of liquid chromatographyhigh-resolution mass spectrometry showed that gliotoxin waspresent in lungs infected by wild-type and ${Delta}$ gliZ-complementedstrains but not in ${Delta}$ gliZ or noninfected lungs (Fig. 5). The ${Delta}$ laeA-infectedlungs showed significant amounts of gliotoxin in this test,in contrast to prior tests (5), and the ${Delta}$ gliZ-complemented strainsshowed the most gliotoxin (Fig. 5). RT-PCR analysis of noninfectedlung and lung from mice infected with wild-type A. fumigatusshowed gliI expression only in the infected lung (Fig. 3B).As previously reported (5), no trace of other known secondarymetabolites normally produced during in vitro culture of A.fumigatus (e.g., helvolic acids, fumigaclavines A to C, tryptoquivalinesA to H, fumiquinazolines A to E, pseurotins A to F2, fumagillin,fumitremorgins A to C, verruculogen, or TR-2) could be detectedin the lung tissue infected with any strain, even though thesemetabolites ionize significantly better than gliotoxin and thushave lower detections limits (25).

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FIG. 5. HPLC-electrospray-positive (ESI⁺)-MS-extracted ion chromatograms (m/z, 263.01 ± 0.04) of lung chloroform extracts, cleaned up by solid-phase extraction, showing the major fragment ion of gliotoxin. The extracts were from five mice lungs/strain infected by A. fumigatus ${Delta}$ laeA (TJW54.2), wild type (AF293), ${Delta}$ gliZ (TDWC5.6), and complemented ${Delta}$ gliZ (TDWC8.3). ${Delta}$ gliZ and noninfected mice lung extracts just show noise. Inset A shows the ESI⁺ spectrum of gliotoxin in TDWC8.3, and inset B shows the spectrum of the reference standard. The y axis is adjusted to show the maximum peak level for each graph. WT, wild type.

PMN death. Previously we have demonstrated that ${Delta}$ laeA supernatants (SN)were less cytotoxic to PMNs than SN from wild-type A. fumigatus(4). To test the hypothesis that gliotoxin mediates the perceiveddifferences in PMN cytotoxicity, we exposed PMNs to ${Delta}$ gliZ, ${Delta}$ gliZ-complemented,and wild-type SN and quantified propidium iodide (PI)-positivecells after 60-min incubations. Results of four different experimentswith PMNs from four different donors showed equivalent celldeath after exposure to the SNs from ${Delta}$ gliZ and ${Delta}$ gliZ-complementedstrains (Fig. 6A). Although there was a trend for decreasedcell death from the ${Delta}$ laeA SN, this decrease was not significantat P $≤$ 0.05 in this study.

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FIG. 6. A. PMN PI positivity after exposure to concentrated culture supernatants from wild-type (AF293), ${Delta}$ laeA (TJW54.2), ${Delta}$ gliZ (TDWC5.6), and complemented ${Delta}$ gliZ (TDWC8.3; designated ${Delta}$ gliZcom8.3) strains. Percentages of total cells that were PI positive are shown. Control is untreated PMN, which was <10% dead under assay conditions. Data represent means (±standard deviations) calculated from triplicate measurements in four different experiments. Wilcoxon rank-sum P values adjusted for multiple comparisons showed no difference between any treatment at P $≤$ 0.05. B. PMN apoptosis after exposure to concentrated culture supernatants from wild-type (AF293), ${Delta}$ laeA (TJW54.2), ${Delta}$ gliZ (TDWC5.6), and complemented ${Delta}$ gliZ (TDWC8.3) strains. Percentages of total cells that were Annexin V positive (apoptotic) are shown. Data represent means (±standard deviations) calculated from triplicate measurements in four different experiments. Wilcoxon-rank sum P values adjusted for multiple comparisons are shown only for treatments showing significant differences. WT, wild type.

As a more sensitive indicator of the potential impact of gliotoxinin inducing cellular apoptosis, Annexin V uptake was measuredafter exposure to the different supernatants. Results of fourdifferent experiments from four different donors demonstratedthat PMN apoptosis was significantly decreased after exposureto SNs from ${Delta}$ gliZ and ${Delta}$ laeA compared to the wild type (Fig. 6B).Complementation of gliZ appeared to restore approximately wild-typelevels of PMN apoptosis (for complemented ${Delta}$ gliZ versus the wildtype, P = 0.12).

DISCUSSION

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Discussion

Secondary metabolite production in fungi is a complex processyielding compounds with obscure or unknown functions in theproducing organism. However, many of these metabolites havetremendous importance to humankind, in that they display a broadrange of useful antibiotic and pharmaceutical activities aswell as less desirable immunosuppressant and toxic activities(49). Although several fungal toxins have been shown to be involvedin plant pathogenesis (1, 24, 45, 48), an unambiguous role offungal toxins in human disease has yet to be established, withthe exception of mycotoxin and mushroom ingestion. The presentstudy is the first to demonstrate that A. fumigatus gliotoxinplays a role in mediating human neutrophil apoptosis ex vivo.

Gliotoxin is an epipolythiodioxopiperazine cyclic dipeptideproduced by several fungi, including A. fumigatus; in the pastit has been implicated in the establishment of severe fungalinfections in both animals and humans (28). Although the mechanismby which gliotoxin exhibits its toxic effects is not clear,a number of studies using commercially produced gliotoxin orcrude culture filtrates have shown that exposure can have profoundimmunosuppressive effects on different mammalian cell types:for example, gliotoxin induces death by apoptosis in neutrophils(42), macrophages (43), and human hepatocytes (16). Gliotoxinalso appears to have immunomodulatory effects on human monocytes(18), mast cells (27), and T lymphocytes (37). Further, it hasbeen recently proposed that gliotoxin may provide a mechanismby which A. fumigatus can selectively suppress antigen-presentingcells (37).

In support of a possible role for gliotoxin in mediating developmentof invasive aspergillosis, we have recently described an A.fumigatus gliotoxin mutant that showed less virulence in a murinemouse model (5). Deletion of laeA, a developmentally regulatedtranscriptional regulator of multiple secondary metabolites,resulted not only in reduced mortality and growth in a pulmonarymurine model but also in increased susceptibility to macrophagephagocytosis and decreased ability to kill neutrophils ex vivo.Coupled with this phenotype was the near loss of gliotoxin production.However, the laeA mutant was also crippled in the productionof other known metabolites that could play a role in IA (5),thus leaving open the question of exactly what, if any, alteredhost-fungus interactions could be attributed to reduction ingliotoxin synthesis.

To genetically elucidate the contribution of loss of gliotoxinto the ${Delta}$ laeA phenotype, we have deleted gliZ, a putative Zn₂Cys₆transcription factor located in the gliotoxin gene cluster.Deletion of gliZ resulted in loss of gliotoxin production invivo and in vitro, as assessed by examination of murine lunghomogenates and culture extracts from several media. This losswas associated with absence of transcription of a biosyntheticgene in the gliotoxin gene cluster. Complementation of ${Delta}$ gliZwith multiple copies of gliZ resulted in strains with increasedproduction of gliotoxin compared to the wild type (Fig. 2).Metabolite profiles were notably different in cultures grownat 25 or 37°C or in liquid shake versus solid agar medium.In general, secondary metabolite production was enhanced at25°C. We saw evidence that gliZ regulated the productionof metabolites other than simply gliotoxin (Fig. 2) when thestrains were grown at 25°C in GMM liquid shake medium. Thiswas not observed in other growth conditions, with the exceptionof the unexpected production of helvolic acid in the gliZ-complementedstrains grown on solid GMM at 37°C (Table 3). However, examinationof lung extracts from the gliZ mutant and wild-type-infectedmice only showed differences in gliotoxin production.

Virulence of the gliZ mutants was assessed by the murine modeland an ex vivo assay with human PMNs. The murine model systemused in our laboratory did not support a role for gliotoxinin virulence using P = 0.05 as a cutoff score. This was similarto a recent report of two gliP disruption strains that did notshow a decrease in virulence in their mouse models (10, 20).However, there was a significant difference in virulence betweenthe ${Delta}$ laeA strain compared to the wild-type and the gliZ-complementedstrain in our model. Examination of lungs from infected miceshowed an expected profile of highest gliotoxin concentrationin the gliZ-complemented infection, followed by the wild type(Fig. 5). No gliotoxin was measured in the ${Delta}$ gliZ strain, andin contrast to our earlier report (5), this time we found considerableproduction in the ${Delta}$ laeA mutant, although it was well below thatof the wild type. Production of secondary metabolites variesin both A. fumigatus and A. nidulans ${Delta}$ laeA mutants in any givenexperiment, likely due to the mechanism of LaeA regulation ofsecondary metabolite gene clusters (7 and unpublished data).However, production is always less than that of the wild type.Our murine pulmonary results suggest that some LaeA-regulatedfactors in addition to gliotoxin may be important in IA. Wesuggest, however, that the current murine model systems usedhere and as reported in the gliP works (10, 20) may not be sensitiveenough to detect subtle differences exerted by A. fumigatusgliotoxin levels and that gliotoxin does contribute to A. fumigatuspathogenicity, although its predominant role in A. fumigatusbiology may not lie in animal pathogenesis.

Considering that our earlier studies had shown a loss of PMNsensitivity to A. fumigatus ${Delta}$ laeA SNs ex vivo (5), we were mostinterested in the response of PMNs to SNs of the gliZ mutants.While there was no statistical difference in PMN PI positivityafter exposure to the SNs, although a trend was noted (Fig.6A), exposures to ${Delta}$ gliZ SN and ${Delta}$ laeA SN were associated with lessPMN apoptosis compared to exposure to WT SN (Fig. 6B). Thismay be an important observation given the fact that neutrophilsconstitute the primary cellular defense against invasive Aspergillushyphae. Many microorganisms including bacteria and viruses evadedestruction by neutrophils by triggering neutrophil apoptosis,thereby resulting in subacute to chronic infections (19, 41,47). Increased PMN apoptosis has been observed in the past afterexposure to A. fumigatus hyphae (3); it is also known that thepurified commercially available gliotoxin is a powerful inducerof neutrophil apoptosis, possibly exerting this effect by inhibitingNF- ${kappa}$ B (42). In keeping with these studies, results of the PMN-SNinteraction experiments emphasize a role for gliotoxin in mediatingapoptosis of neutrophils. Recently, it was suggested that A.fumigatus elaborates gliotoxin as an immunoevasive strategyby specifically targeting antigen-presenting cells such as monocytesand monocyte-derived dendritic cells (37). Induction of neutrophilapoptosis by gliotoxin production by A. fumigatus may be yetanother way for the organism to escape killing by immune cells.Given that some A. fumigatus isolates produce varying levelsof gliotoxin while some isolates do not produce any gliotoxin(23), it remains to be seen if this correlates with the extentof pathogenicity or persistence of infection caused by A. fumigatus.

Apart from indicating a role for gliotoxin in A. fumigatus pathogenesis,the present study also strongly implicates other factors regulatedby LaeA in the possible development of IA. Previously we demonstratedthat LaeA, a nuclear protein, regulated several putative fungalvirulence factors, including synthesis of gliotoxin and othersecondary metabolites as well as conidial morphology (5). A.fumigatus secretes uncharacterized and characterized secondarymetabolites, including verruculogen, fumagillin, fumitremorginC, and helvolic acid. Recently an ergot biosynthetic clusterwas identified in A. fumigatus (9), and it has been demonstratedthat A. fumigatus can produce the alkaloid festuclavine andits derivatives fumigaclavine A and fumigaclavine B2 (30), compoundswith known toxic properties. Reeves et al. (31) also reportedthe identity of a nonribosomal peptide synthetase gene, pes1,which when deleted altered conidial morphology and exhibiteda loss of virulence in the Galleria mellonella model system.Interestingly, the genes for both the ergot alkaloids and pes1are regulated by laeA (R. Perrin, J. W. Bok, N. Federova, J.Wortman, H. Kim, W. Nierman, and N. P. Keller, unpublished data).Thus, it appears likely that metabolites other than gliotoxinare involved in mediating cellular interactions ex vivo andpotentially development or outcomes of invasive infection.

ACKNOWLEDGMENTS

This research was funded by NIH R01AI051468 to K.A.M., NSF MCB-0236393to N.P.K., and NIH 1 R01 AI065728-01A1 to N.P.K. and D.A.

FOOTNOTES

* Corresponding author. Mailing address: Department of Plant Pathology, 882 Russell Labs, 1630 Linden Drive, University of Wisconsin—Madison, Madison, WI 53706. Phone: (608) 265-9795. Fax: (608) 263-2626. E-mail: npk{at}plantpath.wisc.edu.

Published ahead of print on 9 October 2006.

Editor: A. Casadevall

REFERENCES

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