Module-detection approaches for the integration of multilevel omics data highlight the comprehensive response of Aspergillus fumigatus to caspofungin.

BACKGROUND: Omics data provide deep insights into overall biological processes of organisms. However, integration of data from different molecular levels such as transcriptomics and proteomics, still remains challenging. Analyzing lists of differentially abundant molecules from diverse molecular levels often results in a small overlap mainly due to different regulatory mechanisms, temporal scales, and/or inherent properties of measurement methods. Module-detecting algorithms identifying sets of closely related proteins from protein-protein interaction networks (PPINs) are promising approaches for a better data integration. RESULTS: Here, we made use of transcriptome, proteome and secretome data from the human pathogenic fungus Aspergillus fumigatus challenged with the antifungal drug caspofungin. Caspofungin targets the fungal cell wall which leads to a compensatory stress response. We analyzed the omics data using two different approaches: First, we applied a simple, classical approach by comparing lists of differentially expressed genes (DEGs), differentially synthesized proteins (DSyPs) and differentially secreted proteins (DSePs); second, we used a recently published module-detecting approach, ModuleDiscoverer, to identify regulatory modules from PPINs in conjunction with the experimental data. Our results demonstrate that regulatory modules show a notably higher overlap between the different molecular levels and time points than the classical approach. The additional structural information provided by regulatory modules allows for topological analyses. As a result, we detected a significant association of omics data with distinct biological processes such as regulation of kinase activity, transport mechanisms or amino acid metabolism. We also found a previously unreported increased production of the secondary metabolite fumagillin by A. fumigatus upon exposure to caspofungin. Furthermore, a topology-based analysis of potential key factors contributing to drug-caused side effects identified the highly conserved protein polyubiquitin as a central regulator. Interestingly, polyubiquitin UbiD neither belonged to the groups of DEGs, DSyPs nor DSePs but most likely strongly influenced their levels. CONCLUSION: Module-detecting approaches support the effective integration of multilevel omics data and provide a deep insight into complex biological relationships connecting these levels. They facilitate the identification of potential key players in the organism's stress response which cannot be detected by commonly used approaches comparing lists of differentially abundant molecules.

Antigen-specific expansion of human regulatory T cells as a major tolerance mechanism against mucosal fungi.

Foxp3(+) regulatory T cells (Treg) have a central role for keeping the balance between pro- and anti-inflammatory immune responses against chronically encountered antigens at mucosal sites. However, their antigen specificity especially in humans is largely unknown. Here we used a sensitive enrichment technology for antigen-reactive T cells to directly compare the conventional vs. regulatory CD4(+) T-cell response directed against two ubiquitous mucosal fungi, Aspergillus fumigatus and Candida albicans. In healthy humans, fungus-specific CD4(+)CD25(+)CD127(-)Foxp3(+) Treg are strongly expanded in peripheral blood and possess phenotypic, epigenetic and functional features of thymus-derived Treg. Intriguingly, for A. fumigatus, the strong Treg response contrasts with minimal conventional T-cell memory, indicating selective Treg expansion as an effective mechanism to prevent inappropriate immune activation in healthy individuals. By contrast, in subjects with A. fumigatus allergies, specific Th2 cells were strongly expanded despite the presence of specific Treg. Taken together, we demonstrate a largely expanded Treg population specific for mucosal fungi as part of the physiological human T-cell repertoire and identify a unique capacity of A. fumigatus to selectively generate Treg responses as a potentially important mechanism for the prevention of allergic reactions.

Aspergillus fumigatus conidial pigment and cAMP signal transduction: significance for virulence.

The conidial pigment of Aspergillus fumigatus contains 1,8-dihydroxynaphthalene (DHN)-like pentaketide melanin. It plays a major role in the protection of the fungus against immune effector cells; for example, it is able to scavenge reactive oxygen species generated by alveolar macrophages and neutrophiles. The polyketide synthase PKSP (ALB1) is a key-enzyme of the biosynthesis pathway; its structural gene is part of a gene cluster. Furthermore, the presence of a functional pksP (albl) gene in A. fumigatus conidia is associated with an inhibition of phagolysosome fusion in human monocyte-derived macrophages. Moreover, the analysis of mutants that are defective in elements of the cAMP signaling pathway found that they are almost avirulent in an optimized low dose murine inhalation model. Taken together, our results indicate that the cAMP/PKA signal transduction pathway is required for A. fumigatus pathogenicity. In addition, we showed that the expression of the pksP gene is, at least in part, controlled by the cAMP/ PKA signal transduction pathway. Currently, we hypothesize that pentaketide melanin is important for defence against ROS. However, besides its contribution to the biosynthesis of DHN-like melanin, PKSP also appears to be involved in the formation of another compound which is immunosuppressive.

cAMP signaling in Aspergillus fumigatus is involved in the regulation of the virulence gene pksP and in defense against killing by macrophages.

Aspergillus fumigatus is an important pathogen of immunocompromised hosts, causing pneumonia and invasive disseminated disease and resulting in high mortality. In order to determine the importance of the cAMP signaling pathway for virulence, three genes encoding putative elements of the pathway have been cloned and characterized: the adenylate cyclase gene acyA, and gpaA and gpaB, both of which encode alpha subunits of heterotrimeric G proteins. The acyA and gpaB genes were each deleted in A. fumigatus. Both mutants showed reduced conidiation, with the deltaacyA mutant producing very few conidia. The growth rate of the deltaacyA mutant was also reduced, in contrast to that of the deltagpaB mutant. Addition of 10 mM dibutyryl-cAMP to the culture medium completely restored the wild-type phenotype in both mutant strains. To study the influence of GPAB on the expression of the gene pksP, which encodes a virulence factor that is involved in pathogenicity, a pksPp-lacZ gene fusion was generated and integrated as a single copy at the pyrG gene locus of both the parental strain and the deltagpaB mutant strain. The deltagpaB mutant showed reduced expression of the pksPp-lacZ reporter gene relative to that in the parental strain. In mycelia of both the parental strain and the deltagpaB mutant pksPp-lacZ expression was increased when isobutyl-methyl-xanthine, an inhibitor of intracellular phosphodiesterases, was added to the medium. The survival rate of conidia after ingestion by human monocyte-derived macrophages was also determined. The killing rate for conidia from deltaacyA and deltagpaB strains was significantly higher than that for wild-type conidia. Taken together, these findings suggest that cAMP triggers a system that protects A. fumigatus from the effects of immune effector cells of the host.

Subcellular localization of the homocitrate synthase in Penicillium chrysogenum.

There are conflicting reports regarding the cellular localization in Saccharomyces cerevisiae and filamentous fungi of homocitrate synthase, the first enzyme in the lysine biosynthetic pathway. The homocitrate synthase (HS) gene (lys1) of Penicillium chrysogenum was disrupted in three transformants (HS(-)) of the Wis 54-1255 pyrG strain. The three mutants named HS1(-), HS2(-) and HS3(-) all lacked homocitrate synthase activity and showed lysine auxotrophy, indicating that there is a single gene for homocitrate synthase in P. chrysogenum. The lys1 ORF was fused in frame to the gene for the green fluorescent protein (GFP) gene of the jellyfish Aequorea victoria. Homocitrate synthase-deficient mutants transformed with a plasmid containing the lys1-GFP fusion recovered prototrophy and showed similar levels of homocitrate synthase activity to the parental strain Wis 54-1255, indicating that the hybrid protein retains the biological function of wild-type homocitrate synthase. Immunoblotting analysis revealed that the HS-GFP fusion protein is maintained intact and does not release the GFP moiety. Fluorescence microscopy analysis of the transformants showed that homocitrate synthase was mainly located in the cytoplasm in P. chrysogenum; in S. cerevisiae the enzyme is targeted to the nucleus. The control nuclear protein StuA was properly targeted to the nucleus when the StuA (targeting domain)-GFP hybrid protein was expressed in P. chrysogenum. The difference in localization of homocitrate synthase between P. chrysogenum and S. cerevisiae suggests that this protein may play a regulatory function, in addition to its catalytic function, in S. cerevisiae but not in P. chrysogenum.

Differential expression of the Aspergillus fumigatus pksP gene detected in vitro and in vivo with green fluorescent protein.

Aspergillus fumigatus is an important pathogen of immunocompromised hosts, causing pneumonia and invasive disseminated disease with high mortality. To be able to analyze the expression of putative virulence-associated genes of A. fumigatus, the use of the enhanced green fluorescent protein (EGFP) as a reporter was established. Two 5' sequences, containing the putative promoters of the pyrG gene, encoding orotidine-5'-phosphate decarboxylase, and the pksP gene, encoding a polyketide synthase involved in both pigment biosynthesis and virulence of A. fumigatus, were fused with the egfp gene. The PpksP-egfp construct was integrated via homologous recombination into the genomic pksP locus. EGFP production was analyzed by fluorescence spectrometry, Western blot analysis, and fluorescence microscopy. Differential gene expression in A. fumigatus was observed. Fluorescence derived from the PYRG-EGFP fusion protein was detected during all developmental stages of the fungus, i.e., during germination, during vegetative growth, in conidiophores, and weakly in conidia. In addition, it was also detected in germinating conidia when isolated from the lungs of immunocompromised mice. By contrast, PKSP-EGFP-derived fluorescence was not found in hyphae or stalks of conidiophores but was found in phialides and conidia in vitro when the fungus was grown under standard conditions, indicating a developmentally controlled expression of the gene. Interestingly, pksP-egfp expression was also detected in hyphae of germinating conidia isolated from the lungs of immunocompromised mice. This finding indicates that the pksP gene can also be expressed in hyphae under certain conditions and, furthermore, that the pksP gene might also contribute to invasive growth of the fungus.

AoHapB, AoHapC and AoHapE, subunits of the Aspergillus oryzae CCAAT-binding complex, are functionally interchangeable with the corresponding subunits in Aspergillus nidulans.

Two genes, AohapB and AohapE, encoding subunits of the Aspergillus oryzae CCAAT-binding complex were cloned and sequenced. The polypeptides encoded by AohapB and AohapE were expressed in Escherichia coli and used to reconstitute a DNA-binding complex with recombinant AoHapC. The DNA-binding activity was observed only in the presence of all three subunits, indicating that AoHapB, AoHapE and AoHapC are essential for CCAAT-binding. Furthermore, introduction of the AohapB, AohapC and AohapE genes into the A. nidulans hapB delta, hapC delta and hapE delta strains, respectively, revealed that the A. oryzae Hap subunits are functionally interchangeable with the corresponding subunits in A. nidulans.

The Aspergillus nidulans homoaconitase gene lysF is negatively regulated by the multimeric CCAAT-binding complex AnCF and positively regulated by GATA sites.

In beta-lactam-antibiotic-producing fungi, such as Aspergillus (Emericella) nidulans, L-alpha-aminoadipic acid is the branching point of the lysine and penicillin biosynthesis pathways. To obtain a deeper insight into the regulation of lysine biosynthesis genes, the regulation of the A. nidulans lysF gene, which encodes homoaconitase, was studied. Band-shift assays indicated that the A. nidulans multimeric CCAAT-binding complex AnCF binds to two of four CCAAT motifs present in the lysF promoter region. AnCF consists at least of three different subunits, designated HapB, HapC, and HapE. In both a delta hapB and a delta hapC strain, the expression of a translational lysF-lacZ gene fusion integrated in single copy at the chromosomal argB gene locus was two to three-fold higher than in a wild-type strain. These data show that AnCF negatively regulates lysF expression. The results of Northern blot analysis and lysF-lacZ expression analysis did not indicate a lysine-dependent repression of lysF expression. Furthermore, mutational analysis of the lysF promoter region revealed that two GATA sites matching the GATA consensus sequence HGATAR positively affected lysF-lacZ expression. Results of Northern blot analysis also excluded that the global nitrogen regulator AreA is the responsible trans-acting GATA-binding factor.

The Aspergillus nidulans multimeric CCAAT binding complex AnCF is negatively autoregulated via its hapB subunit gene.

Cis-acting CCAAT elements are frequently found in eukaryotic promoter regions. Many of them are bound by conserved multimeric complexes. In the fungus Aspergillus nidulans the respective complex was designated AnCF (A. nidulans CCAAT binding factor). AnCF is composed of at least three subunits designated HapB, HapC and HapE. Here, we show that the promoter regions of the hapB genes in both A. nidulans and Aspergillus oryzae contain two inversely oriented, conserved CCAAT boxes (box alpha and box beta). Electrophoretic mobility shift assays (EMSAs) using both nuclear extracts and the purified, reconstituted AnCF complex indicated that AnCF binding in vitro to these boxes occurs in a non-mutually exclusive manner. Western and Northern blot analyses showed that steady-state levels of HapB protein as well as hapB mRNA were elevated in hapC and hapE deletion mutants, suggesting a repressing effect of AnCF on hapB expression. Consistently, in a hapB deletion background the hapB-lacZ expression level was elevated compared with the expression in the wild-type. This was further supported by overexpression of hapB using an inducible alcA-hapB construct. Induction of alcA-hapB expression strongly repressed the expression of a hapB-lacZ gene fusion. However, mutagenesis of box beta led to a fivefold reduced expression of a hapB-lacZ gene fusion compared with the expression derived from a wild-type hapB-lacZ fusion. These results indicate that (i) box beta is an important positive cis-acting element in hapB regulation, (ii) AnCF does not represent the corresponding positive trans-acting factor and (iii) that AnCF is involved in repression of hapB.

Molecular responses to changes in the environmental pH are conserved between the fungal pathogens Candida dubliniensis and Candida albicans.

In this work we cloned CdPHR1 and CdPHR2 from the human fungal pathogen Candida dubliniensis. The two genes are homologues to the pH-regulated genes PHR1 and PHR2 from Candida albicans. The pH-dependent pattern of expression of CdPHR1 and CdPHR2 was conserved in C. dubliniensis. CdPHR1 could be shown to be functionally equivalent to PHR1. The pH-regulated mode of expression was maintained when CdPHR1 was integrated in C. albicans. This indicates a fundamentally similar mode of expressional regulation in the two species. CdPHR1 was furthermore capable of reversing the aberrant phenotype of a Saccharomyces cerevisiae GAS1 deletion mutant. In this species, however, expression of CdPHR1 was no longer under control of the external pH. Expression of CdPHR1 was not detected when it was introduced into Aspergillus nidulans. In conclusion, C. dubliniensis and C. albicans respond to changes in the environmental pH with a change in cell shape and differential gene expression.

Interaction of human phagocytes with pigmentless Aspergillus conidia.

A defect in the pksP gene of Aspergillus fumigatus is associated with the loss of conidial pigmentation, a profound change of the conidial surface structure, and reduced virulence. The structural change of the conidial surface structure was not observed in similar A. nidulans wA mutants. Our data indicate that the pigment of both species is important for scavenging reactive oxygen species and for protection of conidia against oxidative damage.

Cloning and characterization of an Aspergillus nidulans gene involved in the regulation of penicillin biosynthesis.

To identify regulators of penicillin biosynthesis, a previously isolated mutant of Aspergillus nidulans (Prg-1) which carried the trans-acting prgA1 mutation was used. This mutant also contained fusions of the penicillin biosynthesis genes acvA and ipnA with reporter genes (acvA-uidA and ipnA-lacZ) integrated in a double-copy arrangement at the chromosomal argB gene. The prgA1 mutant strain exhibited only 20 to 50% of the ipnA-lacZ and acvA-uidA expression exhibited by the wild-type strain and had only 20 to 30% of the penicillin produced by the wild-type strain. Here, using complementation with a genomic cosmid library, we isolated a gene (suAprgA1) which complemented the prgA1 phenotype to the wild-type phenotype; i.e., the levels of expression of both gene fusions and penicillin production were nearly wild-type levels. Analysis of the suAprgA1 gene in the prgA1 mutant did not reveal any mutation in the suAprgA1 gene or unusual transcription of the gene. This suggested that the suAprgA1 gene is a suppressor of the prgA1 mutation. The suAprgA1 gene is 1,245 bp long. Its five exons encode a deduced protein that is 303 amino acids long. The putative SUAPRGA1 protein was similar to both the human p32 protein and Mam33p of Saccharomyces cerevisiae. Analysis of the ordered gene library of A. nidulans indicated that suAprgA1 is located on chromosome VI. Deletion of the suAprgA1 gene resulted in an approximately 50% reduction in ipnA-lacZ expression and in a slight reduction in acvA-uidA expression. The DeltasuAprgA1 strain produced about 60% of the amount of penicillin produced by the wild-type strain.

HAP-Like CCAAT-binding complexes in filamentous fungi: implications for biotechnology.

Regulatory CCAAT boxes are found frequently in eukaryotic promoter regions. They are bound by different CCAAT-binding factors. Until now, a single CCAAT-binding complex has been reported in fungi. It is also found in higher eukaryotes and is highly conserved among eukaryotic organisms. This multimeric protein complex is designated HAP, AnCF, CBF, or NF-Y. The complex consists of at least three subunits. In fungi, only the HAP complex of Saccharomyces cerevisiae had been known for a long time. The recent cloning of genes encoding the components of the corresponding complex (AnCF/PENR1) of Aspergillus nidulans and characterization of CCAAT-regulated genes in A. nidulans, as well as other filamentous fungi, led to a deeper insight into the role of this transcription complex, in particular in aerobically growing fungi. An overview of the function of HAP-like complexes in gene regulation in filamentous fungi is presented. Some of the genes that have been found to be regulated by HAP-like complexes encode enzymes of biotechnological interest, like taka-amylase, xylanases, cellobiohydrolase, and penicillin biosynthesis enzymes. The importance of HAP-like complexes in controlling the expression of biotechnologically important genes is discussed.

Transcriptional control of expression of fungal beta-lactam biosynthesis genes.

The most commonly used beta-lactam antibiotics for the therapy of infectious diseases are penicillin and cephalosporin. Penicillin is produced as end product by some fungi most notably by Aspergillus (Emericella) nidulans and Penicillium chrysogenum. Cephalosporins are synthesised by several bacteria and fungi, e.g. by the fungus Acremonium chrysogenum (syn. Cephalosporium acremonium). The biosynthetic pathways leading to both secondary metabolites start from the same three amino acid precursors and have the first two enzymatic reactions in common. The penicillin biosynthesis is catalysed by three enzymes encoded by acvA (pcbAB), ipnA (pcbC) and aatA (penDE). The genes are organised into a cluster. In A. chrysogenum, in addition to acvA and ipnA, which are also clustered, a second cluster contains the genes for enzymes catalysing the reactions of the later steps of the cephalosporin pathway (cefEF, cefG). Transcription of biosynthesis genes is subject to sophisticated control by nutritional factors (e.g. glucose, nitrogen), amino acids such as lysine and methionine, and ambient pH. Some regulators have been identified such as the A. nidulans pH regulatory protein PACC and the transcriptional complex PENR1. PENR1 is a HAP-like transcriptional complex similar or identical to AnCF. Additional positive regulatory factors seem to be represented by recessive trans-acting mutations of A. nidulans (prgA1, prgB1, npeE1) and P. chrysogenum (carried by mutants Npe2 and Npe3). The GATA-binding factor NRE appears to be involved in the regulation of the penicillin biosynthesis genes by the nitrogen source in P. chrysogenum. Formal genetic evidence suggests the existence of transcriptional repressors as well.

AnCF, the CCAAT binding complex of Aspergillus nidulans, contains products of the hapB, hapC, and hapE genes and is required for activation by the pathway-specific regulatory gene amdR.

CCAAT binding factors (CBFs) positively regulating the expression of the amdS gene (encoding acetamidase) and two penicillin biosynthesis genes (ipnA and aatA) have been previously found in Aspergillus nidulans. The factors were called AnCF and PENR1, respectively. Deletion of the hapC gene, encoding a protein with significant similarity to Hap3p of Saccharomyces cerevisiae, eliminated both AnCF and PENR1 binding activities. We now report the isolation of the genes hapB and hapE, which encode proteins with central regions of high similarity to Hap2p and Hap5p of S. cerevisiae and to the CBF-B and CBF-C proteins of mammals. An additional fungus-specific domain present in HapE was revealed by comparisons with the homologs from S. cerevisiae, Neurospora crassa, and Schizosaccharomyces pombe. The HapB, HapC, and HapE proteins have been shown to be necessary and sufficient for the formation of a CCAAT binding complex in vitro. Strains with deletions of each of the hapB, hapC, and hapE genes have identical phenotypes of slow growth, poor conidiation, and reduced expression of amdS. Furthermore, induction of amdS by omega amino acids, which is mediated by the AmdR pathway-specific activator, is abolished in the hap deletion mutants, as is growth on gamma-aminobutyric acid as a sole nitrogen or carbon source. AmdR and AnCF bind to overlapping sites in the promoters of the amdS and gatA genes. It is known that AnCF can bind independently of AmdR. We suggest that AnCF binding is required for AmdR binding in vivo.

Identification of a polyketide synthase gene (pksP) of Aspergillus fumigatus involved in conidial pigment biosynthesis and virulence.

Aspergillus fumigatus is an important pathogen of the immunocompromised host causing pneumonia and invasive disseminated disease with high mortality. Previously, we identified a mutant strain (white, W) lacking conidial pigmentation and, in addition, the conidia showed a smooth surface morphology, whereas wild-type (WT) conidia are grey-green and have a typical ornamentation. W conidia appeared to be less protected against killing by the host defence, e.g., were more susceptible to oxidants in vitro and more efficiently damaged by human monocytes in vitro than WT conidia. When compared to the WT, the W mutant strain showed reduced virulence in a murine animal model. Genetic analysis suggested that the W mutant carried a single mutation which caused all of the observed phenotypes. Here. we report the construction of a genomic cosmid library of A. fumigatus and its use for complementation of the W mutant. Transformation of the W mutant was facilitated by co-transformation with plasmid pHELP1 carrying the autonomously replicating ama1 sequence of A. nidulans which also increased the transformation efficiency of A. fumigatus by a factor of 10. Using this cosmid library a putative polyketide synthase gene, designated pksP (polyketide synthase involved in pigment biosynthesis) was isolated. The pksP gene has a size of 6660 bp. pksP consists of five exons separated by short (47-73 bp) introns. Its deduced open reading frame is composed of 2146 amino acids. The pksP gene complemented both the white phenotype and the surface morphology of the W mutant conidia to wild type. Whereas W mutant conidia caused a strong reactive oxygen species (ROS) release by polymorphonuclear leukocytes, the ability of pksP-complemented W mutant conidia to stimulate ROS release was significantly reduced and comparable to that of WT conidia. In addition, the complemented strains showed restored virulence in a mouse model.

Molecular regulation of beta-lactam biosynthesis in filamentous fungi.

The most commonly used beta-lactam antibiotics for the therapy of infectious diseases are penicillin and cephalosporin. Penicillin is produced as an end product by some fungi, most notably by Aspergillus (Emericella) nidulans and Penicillium chrysogenum. Cephalosporins are synthesized by both bacteria and fungi, e.g., by the fungus Acremonium chrysogenum (Cephalosporium acremonium). The biosynthetic pathways leading to both secondary metabolites start from the same three amino acid precursors and have the first two enzymatic reactions in common. Penicillin biosynthesis is catalyzed by three enzymes encoded by acvA (pcbAB), ipnA (pcbC), and aatA (penDE). The genes are organized into a cluster. In A. chrysogenum, in addition to acvA and ipnA, a second cluster contains the genes encoding enzymes that catalyze the reactions of the later steps of the cephalosporin pathway (cefEF and cefG). Within the last few years, several studies have indicated that the fungal beta-lactam biosynthesis genes are controlled by a complex regulatory network, e. g., by the ambient pH, carbon source, and amino acids. A comparison with the regulatory mechanisms (regulatory proteins and DNA elements) involved in the regulation of genes of primary metabolism in lower eukaryotes is thus of great interest. This has already led to the elucidation of new regulatory mechanisms. Furthermore, such investigations have contributed to the elucidation of signals leading to the production of beta-lactams and their physiological meaning for the producing fungi, and they can be expected to have a major impact on rational strain improvement programs. The knowledge of biosynthesis genes has already been used to produce new compounds.

Development of a homologous transformation system for the human pathogenic fungus Aspergillus fumigatus based on the pyrG gene encoding orotidine 5'-monophosphate decarboxylase.

A homologous transformation system for the opportunistic fungal pathogen Aspergillus fumigatus was developed. It is based on the A. fumigatus pyrG gene, encoding orotidine 5'-monophosphate decarboxylase, which was cloned and sequenced. Transformation of both Aspergillus (Emericella) nidulans and A. fumigatus pyrG mutant strains by the use of protoplasts or electroporation established the functionality of the cloned gene. DNA sequencing of the A. fumigatus pyrG1 mutant allele revealed that it encodes a truncated, non-functional, PyrG protein. Transformation of an A. fumigatus pyrG1 mutant with a plasmid carrying the novel pyrG2 allele constructed by in vitro mutagenesis yielded prototrophic transformants following recombination between both mutation sites. Analysis of transformants carrying the entire plasmid showed that up to 45% of integration had occurred at the pyrG locus. This provides a tool to target defined genetic constructs at a specific locus in the A. fumigatus genome in order to study gene regulation and function.