Unlocking Nature's Biosynthetic Power-Metabolic Engineering for the Fermentative Production of Chemicals.

Fermentation as a production method for chemicals is especially attractive, as it is based on cheap renewable raw materials and often exhibits advantages in terms of costs and sustainability. The tremendous development of technology in bioscience has resulted in an exponentially increasing knowledge about biological systems and has become the main driver for innovations in the field of metabolic engineering. Progress in recombinant DNA technology, genomics, and computational methods open new, cheaper, and faster ways to metabolically engineer microorganisms. Existing biosynthetic pathways for natural products, such as vitamins, organic acids, amino acids, or secondary metabolites, can be discovered and optimized efficiently, thereby enabling competitive commercial production processes. Novel biosynthetic routes can now be designed by the rearrangement of nature's unlimited number of enzymes and metabolic pathways in microbial strains. This expands the range of chemicals accessible by biotechnology and has yielded the first commercial products, while new fermentation technologies targeting novel active ingredients, commodity chemicals, and CO2 -fixation methods are on the horizon.

Multiplex genome editing in Ashbya gossypii using CRISPR-Cpf1.

CRISPR/Cas technologies constitute essential tools for rapid genome engineering of many organisms, including fungi. The CRISPR/Cas9 system adapted for the industrial fungus Ashbya gossypii enables efficient genome editing for the introduction of deletions, insertions and nucleotide substitutions. However, the Cas9 system is constrained by the existence of a specific 5'-NGG-3' PAM sequence in the target site. Here we present a new CRISPR/Cas system for A. gossypii that expands the molecular toolbox available for microbial engineering of this fungus. The use of Cpf1 nuclease from Lachnospiraceae bacterium allows a T-rich PAM sequence (5'-TTTN-3') to be employed and facilitates implementation of a multiplexing CRISPR/Cpf1 system adapted for A. gossypii. The system has been validated for the introduction of large deletions with five different auxotrophic markers (HIS3, ADE2, TRP1, LEU2 and URA3). The use of both crRNA and dDNA arrays in a multi-CRISPR/Cpf1 system is demonstrated to be an efficient strategy for multiplex gene deletion of up to four genes using a single multi-CRISPR/Cpf1 plasmid. Our results also suggest that the selection of the target sequence may affect significantly the editing efficiency of the system.

Construction of a Codon-Adapted Nourseotricin-Resistance Marker Gene for Efficient Targeted Gene Deletion in the Mycophenolic Acid Producer Penicillium brevicompactum.

Penicillium brevicompactum is a filamentous ascomycete used in the pharmaceutical industry to produce mycophenolic acid, an immunosuppressant agent. To extend options for genetic engineering of this fungus, we have tested two resistance markers that have not previously been applied to P. brevicompactum. Although a generally available phleomycin resistance marker (ble) was successfully used in DNA-mediated transformation experiments, we were not able to use a commonly applicable nourseothricin resistance cassette (nat1). To circumvent this failure, we constructed a new nat gene, considering the codon bias for P. brevicompactum. We then used this modified nat gene in subsequent transformation experiments for the targeted disruption of two nuclear genes, MAT1-2-1 and flbA. For MAT1-2-1, we obtained deletion strains with a frequency of about 10%. In the case of flbA, the frequency was about 4%, and this disruption strain also showed reduced conidiospore formation. To confirm the deletion, we used ble to reintroduce the wild-type genes. This step restored the wild-type phenotype in the flbA deletion strain, which had a sporulation defect. The successful transformation system described here substantially extends options for genetically manipulating the biotechnologically relevant fungus P. brevicompactum.

Improved riboflavin production with Ashbya gossypii from vegetable oil based on 13C metabolic network analysis with combined labeling analysis by GC/MS, LC/MS, 1D, and 2D NMR.

The fungus Ashbya gossypii is an important industrial producer of riboflavin, i.e. vitamin B2. In order to meet the constantly increasing demands for improved production processes, it appears essential to better understand the underlying metabolic pathways of the vitamin. Here, we used a highly sophisticated set-up of parallel 13C tracer studies with labeling analysis by GC/MS, LC/MS, 1D, and 2D NMR to resolve carbon fluxes in the overproducing strain A. gossypii B2 during growth and subsequent riboflavin production from vegetable oil as carbon source, yeast extract, and supplemented glycine. The studies provided a detailed picture of the underlying metabolism. Glycine was exclusively used as carbon-two donor of the vitamin's pyrimidine ring, which is part of its isoalloxazine ring structure, but did not contribute to the carbon-one metabolism due to the proven absence of a functional glycine cleavage system. The pools of serine and glycine were closely connected due to a highly reversible serine hydroxymethyltransferase. Transmembrane formate flux simulations revealed that the one-carbon metabolism displayed a severe bottleneck during initial riboflavin production, which was overcome in later phases of the cultivation by intrinsic formate accumulation. The transiently limiting carbon-one pool was successfully replenished by time-resolved feeding of small amounts of formate and serine, respectively. This increased the intracellular availability of glycine, serine, and formate and resulted in a final riboflavin titer increase of 45%.

Sexual reproduction and mating-type-mediated strain development in the penicillin-producing fungus Penicillium chrysogenum.

Penicillium chrysogenum is a filamentous fungus of major medical and historical importance, being the original and present-day industrial source of the antibiotic penicillin. The species has been considered asexual for more than 100 y, and despite concerted efforts, it has not been possible to induce sexual reproduction, which has prevented sexual crosses being used for strain improvement. However, using knowledge of mating-type (MAT) gene organization, we now describe conditions under which a sexual cycle can be induced leading to production of meiotic ascospores. Evidence of recombination was obtained using both molecular and phenotypic markers. The identified heterothallic sexual cycle was used for strain development purposes, generating offspring with novel combinations of traits relevant to penicillin production. Furthermore, the MAT1-1-1 mating-type gene, known primarily for a role in governing sexual identity, was also found to control transcription of a wide range of genes with biotechnological relevance including those regulating penicillin production, hyphal morphology, and conidial formation. These discoveries of a sexual cycle and MAT gene function are likely to be of broad relevance for manipulation of other asexual fungi of economic importance.

Members of the Penicillium chrysogenum velvet complex play functionally opposing roles in the regulation of penicillin biosynthesis and conidiation.

A velvet multisubunit complex was recently detected in the filamentous fungus Penicillium chrysogenum, the major industrial producer of the ß-lactam antibiotic penicillin. Core components of this complex are P. chrysogenum VelA (PcVelA) and PcLaeA, which regulate secondary metabolite production, hyphal morphology, conidiation, and pellet formation. Here we describe the characterization of PcVelB, PcVelC, and PcVosA as novel subunits of this velvet complex. Using yeast two-hybrid analysis and bimolecular fluorescence complementation (BiFC), we demonstrate that all velvet proteins are part of an interaction network. Functional analyses using single- and double-knockout strains clearly indicate that velvet subunits have opposing roles in the regulation of penicillin biosynthesis and light-dependent conidiation. PcVelC, together with PcVelA and PcLaeA, activates penicillin biosynthesis, while PcVelB represses this process. In contrast, PcVelB and PcVosA promote conidiation, while PcVelC has an inhibitory effect. Our genetic analyses further show that light-dependent spore formation depends not only on PcVelA but also on PcVelB and PcVosA. The results provided here contribute to our fundamental understanding of the function of velvet subunits as part of a regulatory network mediating signals responsible for morphology and secondary metabolism and will be instrumental in generating mutants with newly derived properties that are relevant to strain improvement programs.

Molecular organization of the mating-type loci in the homothallic Ascomycete Eupenicillium crustaceum.

Eupenicillium species are the teleomorphic (sexual) forms of anamorphic (asexual) members of the genus Penicillium, which contains many species of industrial importance. Here we describe the first molecular analysis of the mating-type (MAT) locus from a homothallic (self-fertile) Eupenicillium species, E. crustaceum. This ascomycete is a sexual relative of the penicillin producer Penicillium chrysogenum, which while long considered asexual, was recently shown to possess the required genetic machinery for heterothallic breeding. The E. crustaceum genome contains two MAT loci, MAT1-1 and MAT1-2, in an arrangement characteristic of other known homothallic euascomycetes, such as Neosartorya fischeri. MAT1-1 is flanked by conserved APN2 (DNA lyase) and SLA2 (cytoskeleton assembly control) genes and encodes a homologue of the α-box domain protein MAT1-1-1. Conversely, MAT1-2 carries a HMG-domain gene MAT1-2-1, and is flanked by a degenerate SLA2 gene and an intact homologue of the P. chrysogenum ORF Pc20g08960. Here we demonstrate the transcriptional expression of both mating-type genes during vegetative development. Furthermore, the MAT1-1-1 and MAT1-2-1 sequences were used to resolve the phylogenetic relationship of E. crustaceum with other ascomycetes. Phylogenetic trees confirmed a very close relationship between the homothallic E. crustaceum and the supposedly heterothallic P. chrysogenum. This close taxonomic association makes E. crustaceum an ideal candidate for future expression and evolutionary studies of sexual reproduction, with the ultimate aim of inducing sex in P. chrysogenum.

A mutant defective in sexual development produces aseptate ascogonia.

The transition from the vegetative to the sexual cycle in filamentous ascomycetes is initiated with the formation of ascogonia. Here, we describe a novel type of sterile mutant from Sordaria macrospora with a defect in ascogonial septum formation. This mutant, named pro22, produces only small, defective protoperithecia and carries a point mutation in a gene encoding a protein that is highly conserved throughout eukaryotes. Sequence analyses revealed three putative transmembrane domains and a C-terminal domain of unknown function. Live-cell imaging showed that PRO22 is predominantly localized in the dynamic tubular and vesicular vacuolar network of the peripheral colony region close to growing hyphal tips and in ascogonia; it is absent from the large spherical vacuoles in the vegetative hyphae of the subperipheral region of the colony. This points to a specific role of PRO22 in the tubular and vesicular vacuolar network, and the loss of intercalary septation in ascogonia suggests that PRO22 functions during the initiation of sexual development.

Two components of a velvet-like complex control hyphal morphogenesis, conidiophore development, and penicillin biosynthesis in Penicillium chrysogenum.

Penicillium chrysogenum is the industrial producer of the antibiotic penicillin, whose biosynthetic regulation is barely understood. Here, we provide a functional analysis of two major homologues of the velvet complex in P. chrysogenum, which we have named P. chrysogenum velA (PcvelA) and PclaeA. Data from array analysis using a DeltaPcvelA deletion strain indicate a significant role of PcVelA on the expression of biosynthesis and developmental genes, including PclaeA. Northern hybridization and high-performance liquid chromatography quantifications of penicillin titers clearly show that both PcVelA and PcLaeA play a major role in penicillin biosynthesis in a producer strain that underwent several rounds of UV mutagenesis during a strain improvement program. Both regulators are further involved in different developmental processes. While PcvelA deletion leads to light-independent conidial formation, dichotomous branching of hyphae, and pellet formation in shaking cultures, a DeltaPclaeA strain shows a severe impairment in conidiophore formation under both light and dark conditions. Bimolecular fluorescence complementation assays provide evidence for a velvet-like complex in P. chrysogenum, with structurally conserved components that have distinct developmental roles, illustrating the functional plasticity of these regulators in genera other than Aspergillus.

Application of the Saccharomyces cerevisiae FLP/FRT recombination system in filamentous fungi for marker recycling and construction of knockout strains devoid of heterologous genes.

To overcome the limited availability of antibiotic resistance markers in filamentous fungi, we adapted the FLP/FRT recombination system from the yeast Saccharomyces cerevisiae for marker recycling. We tested this system in the penicillin producer Penicillium chrysogenum using different experimental approaches. In a two-step application, we first integrated ectopically a nourseothricin resistance cassette flanked by the FRT sequences in direct repeat orientation (FRT-nat1 cassette) into a P. chrysogenum recipient. In the second step, the gene for the native yeast FLP recombinase, and in parallel, a codon-optimized P. chrysogenum flp (Pcflp) recombinase gene, were transferred into the P. chrysogenum strain carrying the FRT-nat1 cassette. The corresponding transformants were analyzed by PCR, growth tests, and sequencing to verify successful recombination events. Our analysis of several single- and multicopy transformants showed that only when the codon-optimized recombinase was present could a fully functional recombination system be generated in P. chrysogenum. As a proof of application of this system, we constructed a DeltaPcku70 knockout strain devoid of any heterologous genes. To further improve the FLP/FRT system, we produced a flipper cassette carrying the FRT sites as well as the Pcflp gene together with a resistance marker. This cassette allows the controlled expression of the recombinase gene for one-step marker excision. Moreover, the applicability of the optimized FLP/FRT recombination system in other fungi was further demonstrated by marker recycling in the ascomycete Sordaria macrospora. Here, we discuss the application of the optimized FLP/FRT recombination system as a molecular tool for the genetic manipulation of filamentous fungi.

New tools for the genetic manipulation of filamentous fungi.

Filamentous fungi have a long-standing tradition as industrial producers of primary and secondary metabolites. Initially, industrial scientists selected production strains from natural isolates that fulfilled both microbiological and technical requirements for economical production processes. Subsequently, genetically modified strains with novel properties were obtained through traditional strain improvement programs relying mostly on random mutagenesis. In recent years, however, recombinant technologies have contributed significantly to improve the capacities of production and have also allowed the design of genetically manipulated strains. These major advances were only made possible by basic research bringing deeper and novel insights into cellular and molecular fungal processes, thus allowing the design of genetically manipulated strains. This better understanding of fundamental genetic processes in model organisms has resulted in the design and generation of new experimental transformation strategies to manipulate specifically gene expression and function in diverse filamentous fungi, including those having a biotechnical significance. In this review, we summarize recent developments in the application of homologous DNA recombination and RNA interference to manipulate fungal recipients for further improvement of physiology and development in regards to biotechnical and pharmaceutical applications.

Homologous recombination in the antibiotic producer Penicillium chrysogenum: strain DeltaPcku70 shows up-regulation of genes from the HOG pathway.

In Penicillium chrysogenum, the industrial producer of the beta-lactam antibiotic penicillin, generating gene replacements for functional analyses is very inefficient. Here, we constructed a recipient strain that allows efficient disruption of any target gene via homologous recombination. Following isolation of the Pcku70 (syn. hdfA) gene encoding a conserved eukaryotic DNA-binding protein involved in non-homologous end joining (NHEJ), a Pcku70 knockout strain was constructed using a novel nourseothricin-resistance cassette as selectable marker. In detailed physiological tests, strain DeltaPcku70 showed no significant reduction in vegetative growth due to increased sensitivity to different mutagenic substances. Importantly, deletion of the Pcku70 gene had no effect on penicillin biosynthesis. However, strain DeltaPcku70 exhibits higher sensitivity to osmotic stress than the parent strain. This correlated well with comparative data from microarray analyses: Genes related to the stress response are significantly up-regulated in the Pcku70 deletion mutant. To demonstrate the applicability of strain DeltaPcku70, three genes related to beta-lactam antibiotic biosynthesis were efficiently disrupted, indicating that this strain shows a low frequency of NHEJ, thus promoting efficient homologous recombination. Furthermore, we discuss strategies to reactivate Pcku70 in strains successfully used for gene disruptions.

Evidence for Dicer-dependent RNA interference in the industrial penicillin producer Penicillium chrysogenum.

RNA interference (RNAi) is a sequence-specific post-transcriptional gene silencing system that downregulates target gene expression. Here, we provide several lines of evidence for RNA silencing in the industrial beta-lactam antibiotic producer Penicillium chrysogenum using the DsRed reporter gene under the control of the constitutive trpC promoter or the inducible xylP promoter. The functional RNAi system was verified by detection of siRNAs that hybridized exclusively with gene-specific (32)P-labelled RNA probes. Moreover, when RNAi was used to silence the endogenous PcbrlA morphogene that controls conidiophore development, a dramatic reduction in the formation of conidiospores was observed in 47 % of the corresponding transformants. Evidence that RNAi in P. chrysogenum is dependent on a Dicer peptide was provided with a strain lacking Pcdcl2. In the DeltaPcdcl2 background, silencing of the PcbrlA gene was tested. None of the transformants analysed showed a developmental defect. The applicability of the RNAi system in P. chrysogenum was finally demonstrated by silencing the Pcku70 gene to increase homologous recombination frequency. This led to the generation of single and double knockout mutants.

Asexual cephalosporin C producer Acremonium chrysogenum carries a functional mating type locus.

Acremonium chrysogenum, the fungal producer of the pharmaceutically relevant beta-lactam antibiotic cephalosporin C, is classified as asexual because no direct observation of mating or meiosis has yet been reported. To assess the potential of A. chrysogenum for sexual reproduction, we screened an expressed sequence tag library from A. chrysogenum for the expression of mating type (MAT) genes, which are the key regulators of sexual reproduction. We identified two putative mating type genes that are homologues of the alpha-box domain gene, MAT1-1-1 and MAT1-1-2, encoding an HPG domain protein defined by the presence of the three invariant amino acids histidine, proline, and glycine. In addition, cDNAs encoding a putative pheromone receptor and pheromone-processing enzymes, as well as components of a pheromone response pathway, were found. Moreover, the entire A. chrysogenum MAT1-1 (AcMAT1-1) gene and regions flanking the MAT region were obtained from a genomic cosmid library, and sequence analysis revealed that in addition to AcMAT1-1-1 and AcMAT1-1-2, the AcMAT1-1 locus comprises a third mating type gene, AcMAT1-1-3, encoding a high-mobility-group domain protein. The alpha-box domain sequence of AcMAT1-1-1 was used to determine the phylogenetic relationships of A. chrysogenum to other ascomycetes. To determine the functionality of the AcMAT1-1 locus, the entire MAT locus was transferred into a MAT deletion strain of the heterothallic ascomycete Podospora anserina (the PaDeltaMAT strain). After fertilization with a P. anserina MAT1-2 (MAT(+)) strain, the corresponding transformants developed fruiting bodies with mature ascospores. Thus, the results of our functional analysis of the AcMAT1-1 locus provide strong evidence to hypothesize a sexual cycle in A. chrysogenum.

Eighty years after its discovery, Fleming's Penicillium strain discloses the secret of its sex.

Eighty years ago, Alexander Fleming discovered antibacterial activity in the asexual mold Penicillium, and the strain he studied later was replaced by an overproducing isolate still used for penicillin production today. Using a heterologous PCR approach, we show that these strains are of opposite mating types and that both have retained transcriptionally expressed pheromone and pheromone receptor genes required for sexual reproduction. This discovery extends options for industrial strain improvement programs using conventional genetical approaches.

The WW domain protein PRO40 is required for fungal fertility and associates with Woronin bodies.

Fruiting body formation in ascomycetes is a highly complex process that is under polygenic control and is a fundamental part of the fungal sexual life cycle. However, the molecular determinants regulating this cellular process are largely unknown. Here we show that the sterile pro40 mutant is defective in a 120-kDa WW domain protein that plays a pivotal role in fruiting body maturation of the homothallic ascomycete Sordaria macrospora. Although WW domains occur in many eukaryotic proteins, homologs of PRO40 are present only in filamentous ascomycetes. Complementation analysis with different pro40 mutant strains, using full-sized or truncated versions of the wild-type pro40 gene, revealed that the C terminus of PRO40 is crucial for restoring the fertile phenotype. Using differential centrifugation and protease protection assays, we determined that a PRO40-FLAG fusion protein is located within organelles. Further microscopic investigations of fusion proteins with DsRed or green fluorescent protein polypeptides showed a colocalization of PRO40 with HEX-1, a Woronin body-specific protein. However, the integrity of Woronin bodies is not affected in mutant strains of S. macrospora and Neurospora crassa, as shown by fluorescence microscopy, sedimentation, and immunoblot analyses. We discuss the function of PRO40 in fruiting body formation.

An efficient fungal RNA-silencing system using the DsRed reporter gene.

In filamentous fungi, RNA silencing is an attractive alternative to disruption experiments for the functional analysis of genes. We adapted the gene encoding the autofluorescent DsRed protein as a reporter to monitor the silencing process in fungal transformants. Using the cephalosporin C producer Acremonium chrysogenum, strains showing a high level of expression of the DsRed gene were constructed, resulting in red fungal colonies. Transfer of a hairpin-expressing vector carrying fragments of the DsRed gene allowed efficient silencing of DsRed expression. Monitoring of this process by Northern hybridization, real-time PCR quantification, and spectrofluorometric measurement of the DsRed protein confirmed that downregulation of gene expression can be observed at different expression levels. The usefulness of the DsRed silencing system was demonstrated by investigating cosilencing of DsRed together with pcbC, encoding the isopenicillin N synthase, an enzyme involved in cephalosporin C biosynthesis. Downregulation of pcbC can be detected easily by a bioassay measuring the antibiotic activity of individual strains. In addition, the presence of the isopenicillin N synthase was investigated by Western blot hybridization. All transformants having a colorless phenotype showed simultaneous downregulation of the pcbC gene, albeit at different levels. The RNA-silencing system presented here should be a powerful genetic tool for strain improvement and genome-wide analysis of this biotechnologically important filamentous fungus.

CPCR1, but not its interacting transcription factor AcFKH1, controls fungal arthrospore formation in Acremonium chrysogenum.

Fungal morphogenesis and secondary metabolism are frequently associated; however, the molecular determinants connecting both processes remain largely undefined. Here we demonstrate that CPCR1 (cephalosporin C regulator 1 from Acremonium chrysogenum), a member of the winged helix/regulator factor X (RFX) transcription factor family that regulates cephalosporin C biosynthesis, also controls morphological development in the beta-lactam producer A. chrysogenum. The use of a disruption strain, multicopy strains as well as several recombinant control strains revealed that CPCR1 is required for hyphal fragmentation, and thus the formation of arthrospores. In a DeltacpcR1 disruption strain that exhibits only hyphal growth, the wild-type cpcR1 gene was able to restore arthrospore formation; a phenomenon not observed for DeltacpcR1 derivatives or non-related genes. The intracellular expression of cpcR1, and control genes (pcbC, egfp) was determined by in vivo monitoring of fluorescent protein fusions. Further, the role of the forkhead transcription factor AcFKH1, which directly interacts with CPCR1, was studied by generating an Acfkh1 knockout strain. In contrast to CPCR1, AcFKH1 is not directly involved in the fragmentation of hyphae. Instead, the presence of AcFKH1 seems to be necessary for CPCR1 function in A. chrysogenum morphogenesis, as overexpression of a functional cpcR1 gene in a DeltaAcfkh1 background has no effect on arthrospore formation. Moreover, strains lacking Acfkh1 exhibit defects in cell separation, indicating an involvement of the forkhead transcription factor in mycelial growth of A. chrysogenum. Our data offer the potential to control fungal growth in biotechnical processes that require defined morphological stages for optimal production yields.

Use of bimolecular fluorescence complementation to demonstrate transcription factor interaction in nuclei of living cells from the filamentous fungus Acremonium chrysogenum.

Using bimolecular fluorescence complementation assays, we were able to demonstrate protein-protein interaction of the transcription factors AcFKH1 and CPCR1 in living cells from the filamentous fungus Acremonium chrysogenum. This was accomplished by splitting the gene for the enhanced yellow fluorescent protein (EYFP) into two parts encoding the N- and C-terminus. Both fragments were fused to different gene derivatives of the fungal transcription factors. The recombinant plasmids were used to generate transgenic fungal strains for subsequent confocal laser microscopy. Only when the full-length transcription factors were fused to EYFP fragments yellow fluorescence was observed due to the bimolecular complementation of both chimeric proteins. The nuclear localization of the protein-protein interaction was verified by staining fungal cells with the nucleic acid dye TOTO-3.

AcFKH1, a novel member of the forkhead family, associates with the RFX transcription factor CPCR1 in the cephalosporin C-producing fungus Acremonium chrysogenum.

In the filamentous fungus Acremonium chrysogenum, a complex regulatory network of transcription factors controls the expression of at least seven cephalosporin C biosynthesis genes. The RFX transcription factor CPCR1 binds to regulatory sequences in the promoter region of cephalosporin C biosynthesis genes, and is involved in the transcriptional regulation of the pcbC gene which encodes isopenicillin N synthase. In this study, we used CPCR1 in a yeast two-hybrid screen to identify potential protein interaction partners. A cDNA was identified, encoding the C-terminal part (pos. 438-665) of the novel forkhead protein, AcFKH1. The full-length AcFKH1 amino acid sequence is 665 residues and shares between 31% and 60% identity with forkhead protein sequences in the genomes of Aspergillus nidulans, Fusarium graminearum, and Neurospora crassa. AcFKH1 is characterized by two conserved domains, the N-terminal forkhead-associated domain (FHA), which might be involved in phospho-protein interactions, and the C-terminal DNA-binding domain (FKH) of the winged helix/forkhead type. The two-hybrid system was also used to map the protein domains required for the interaction of transcription factors CPCR1 and AcFKH1. The observed interaction between CPCR1 and the C-terminus of AcFKH1 in the yeast system was verified in vitro in a GST pulldown assay. Using gel retardation analysis, the DNA-binding properties of the fungal forkhead protein AcFKH1 were investigated. AcFKH1 recognizes two forkhead consensus binding sites within the 1.2 kb promoter region of the divergently oriented cephalosporin biosynthesis gene pair pcbAB-pcbC from A. chrysogenum. Additionally, AcFKH1 is able to bind with high affinity to the SWI5-binding site of the yeast FKH2 protein.