Molecular characterization of a fungal secondary metabolism promoter: transcription of the Aspergillus nidulans isopenicillin N synthetase gene is modulated by upstream negative elements

KdmB, a Jumonji Histone H3 Demethylase, Regulates Genome-Wide H3K4 Trimethylation and Is Required for Normal Induction of Secondary Metabolism in Aspergillus nidulans

Histone posttranslational modifications (HPTMs) are involved in chromatin-based regulation of fungal secondary metabolite biosynthesis (SMB) in which the corresponding genes—usually physically linked in co-regulated clusters—are silenced under optimal physiological conditions (nutrient-rich) but are activated when nutrients are limiting. The exact molecular mechanisms by which HPTMs influence silencing and activation, however, are still to be better understood. Here we show by a combined approach of quantitative mass spectrometry (LC-MS/MS), genome-wide chromatin immunoprecipitation (ChIP-seq) and transcriptional network analysis (RNA-seq) that the core regions of silent A. nidulans SM clusters generally carry low levels of all tested chromatin modifications and that heterochromatic marks flank most of these SM clusters. During secondary metabolism, histone marks typically associated with transcriptional activity such as H3 trimethylated at lysine-4 (H3K4me3) are established in some, but not all gene clusters even upon full activation. KdmB, a Jarid1-family histone H3 lysine demethylase predicted to comprise a BRIGHT domain, a zinc-finger and two PHD domains in addition to the catalytic Jumonji domain, targets and demethylates H3K4me3 in vivo and mediates transcriptional downregulation. Deletion of kdmB leads to increased transcription of about ~1750 genes across nutrient-rich (primary metabolism) and nutrient-limiting (secondary metabolism) conditions. Unexpectedly, an equally high number of genes exhibited reduced expression in the kdmB deletion strain and notably, this group was significantly enriched for genes with known or predicted functions in secondary metabolite biosynthesis. Taken together, this study extends our general knowledge about multi-domain KDM5 histone demethylases and provides new details on the chromatin-level regulation of fungal secondary metabolite production.

In this work we monitored by proteomic analysis and ChIP-seq the genome-wide distribution of several key modifications on histone H3 in the model fungus Aspergillus nidulans cultivated either under optimal physiological conditions (active growth) or less favourable conditions which are known to promote the production of secondary metabolites (SM). When we correlated the chromatin status to transcriptional activities in actively growing cells we found that the silenced SM gene clusters are flanked by heterochromatic domains presumably contributing to silencing but that the bodies of the clusters only carry background levels of any of the investigated marks. In nutrient-depleted conditions, activating marks were invading some, but by far not all transcribed clusters, leaving open the question how activation of these regions occurs at the chromatin level. Surprisingly, a large number of these gene clusters actually depend on KdmB for normal activation and it will be interesting to see in future how this protein thought to mainly act as repressor by removing positive H3K4m3 marks switches gears to activate transcription directly or indirectly.

Direct involvement of the CreA transcription factor in penicillin biosynthesis and expression of the pcbAB gene in Penicillium chrysogenum

The transcription factor CreA is the main regulator responsible for carbon repression in filamentous fungi. CreA is a wide domain regulator that binds to regulatory elements in the promoters of target genes to repress their transcription. Penicillin biosynthesis and the expression of penicillin biosynthetic genes are subject to carbon repression. However, evidence of the participation of CreA in this regulation is still lacking, and previous studies on the promoter of the pcbC gene of Aspergillus nidulans indicated the lack of involvement of CreA in its regulation. Here we present clear evidence of the participation of CreA in carbon repression of penicillin biosynthesis and expression of the pcbAB gene, encoding the first enzyme of the pathway, in Penicillium chrysogenum. Mutations in cis of some of the putative CreA binding sites present in the pcbAB gene promoter fused to a reporter gene caused an important increase in the measured enzyme activity in glucose-containing medium, whereas activity in the medium with lactose was not affected. An RNAi strategy was used to attenuate the expression of the creA gene. Transformants expressing a small interfering RNA for creA showed higher penicillin production, and this increase was more evident when glucose was used as carbon source. These results confirm that CreA plays an important role in the regulation of penicillin biosynthesis in P. chrysogenum and opens the possibility of its utilization to improve the industrial production of this antibiotic.

Protein-DNA interactions in the promoter region of the Phycomyces carB and carRA genes correlate with the kinetics of their mRNA accumulation in response to light

Carotene biosynthesis in Phycomyces is photoinducible and carried out by phytoene dehydrogenase (encoded by carB) and a bifunctional enzyme possessing lycopene cyclase and phytoene synthase activities (carRA). A light pulse followed by periods of darkness produced similar biphasic responses in the expression of the carB and carRA genes, indicating their coordinated regulation. Specific binding complexes were formed between the carB-carRA intergenic region and protein extracts from wild type mycelia grown in the dark or 8min after irradiation. These two conditions correspond to the points at which the expression of both genes is minimal, suggesting that these binding complexes are involved in the down-regulation of photocarotenogenesis in Phycomyces. Protein extracts from carotene mutants failed to form the dark retardation complex, suggesting a role of these genes in the regulation of photocarotenogenesis. In contrast, protein extracts from phototropic mutants formed dark retardation complexes identical to that of the wild type.

Core promoters of the penicillin biosynthesis genes and quantitative RT-PCR analysis of these genes in high and low production strain of Penicillium chrysogenum

The transcription start points of the penicillin biosynthesis genes from Penicillium chrysogenum were mapped using the primer extension method. For each of the three genes consensus sequences of the core promoter elements were identified, supporting the notion that the basal transcription of these genes is mediated separately. Interestingly, transcription start of the pcbC gene is located within the potential Inr element with no TATA box-like sequence being found at expected position. This is in contrast to pcbAB and penDE genes with proposed TATA boxes or even to Aspergillus nidulans ipnA (pcbC) gene indicating possible differences in basal transcription regulation. Using the quantitative RT-PCR analysis the expression of all three biosynthesis genes was monitored in both the high and low production strain of P. chrysogenum during a 3-d cultivation under production conditions. The differences were found between the strains in time regulation and transcript levels of the biosynthesis genes. Furthermore, we showed that the effect of higher gene dosage on productivity in the production strain is amplified by more efficient transcription of the biosynthesis genes with the RNA levels approximately 37- and 12-times higher, respectively, than in a low production strain.

Transcription of the Neurospora crassa 70-kDa class heat shock protein genes is modulated in response to extracellular pH changes

Heat shock proteins belong to a conserved superfamily of molecular chaperones found in prokaryotes and eukaryotes. These proteins are linked to a myriad of physiological functions. In this study, we show that the N. crassa hsp70-1 (NCU09602.3) and hsp70-2 (NCU08693.3) genes are preferentially expressed in an acidic milieu after 15 h of cell growth in sufficient phosphate at 30 degrees C. No significant accumulation of these transcripts was detected at alkaline pH values. Both genes accumulated to a high level in mycelia that were incubated for 1 h at 45 degrees C, regardless of the phosphate concentration and extracellular pH changes. Transcription of the hsp70-1 and hsp70-2 genes was dependent on the pacC (+) background in mycelia cultured under optimal growth conditions or at 45 degrees C. The pacC gene encodes a Zn-finger transcription factor that is involved in the regulation of gene expression by pH. Heat shock induction of these two hsp genes in mycelia incubated in low-phosphate medium was almost not altered in the nuc-1 (-) background under both acidic and alkaline pH conditions. The NUC-1 transcriptional regulator is involved in the derepression of nucleases, phosphatases, and transporters that are necessary for fulfilling the cell's phosphate requirements. Transcription of the hsp70-3 (NCU01499.3) gene followed a different pattern of induction-the gene was depressed under insufficient phosphate conditions but was apparently unaffected by alkalinization of the culture medium. Moreover, this gene was not induced by heat shock. These results reveal novel aspects of the heat-sensing network of N. crassa.

The bZIP-type transcription factor FlbB regulates distinct morphogenetic stages of colony formation in Aspergillus nidulans

Conidiophore formation in Aspergillus nidulans involves a developmental programme in which vegetative hyphae give rise to an ordered succession of differentiated cells: foot cell, stalk, vesicle, metulae, phialides and conidia. The developmental transition requires factors that are expressed in vegetative hyphae that activate the expression of the main regulator of conidiation, BrlA. One such element is the bZIP-type transcription factor FlbB. We found that flbB(-) mutants show defective branching patterns and are susceptible to autolysis under high sorbitol or sucrose concentrations, revealing a role in vegetative growth. In addition, FlbB plays a role in conidiophore initiation, as its upregulation reduces conidiophore vesicle swelling and generates a reduced number of metulae. FlbB was located at the tip of growing metulae, following a similar pattern as described in vegetative hyphae. In wild-type strains, the transition from metulae to phialides could be reversed to generate vegetative hyphae, indicating the existence of a specific control point at this stage of conidiophore formation. The combined evidence points to FlbB as a key factor in the transition to asexual development, playing a role at various control points in which the process could be reversed.

Establishment of the ambient pH signaling complex in Aspergillus nidulans: PalI assists plasma membrane localization of PalH

The Aspergillus nidulans ambient pH signaling pathway involves two transmembrane domain (TMD)-containing proteins, PalH and PalI. We provide in silico and mutational evidence suggesting that PalI is a three TMD (3-TMD) protein with an N-terminal signal peptide, and we show that PalI localizes to the plasma membrane. PalI is not essential for the proteolytic conversion of the PacC translation product into the processed 27-kDa form, but its absence markedly reduces the accumulation of the 53-kDa intermediate after cells are shifted to an alkaline pH. PalI and its homologues contain a predicted luminal, conserved Gly-Cys-containing motif that distantly resembles a Gly-rich dimerization domain. The Gly44Arg and Gly47Asp substitutions within this motif lead to loss of function. The Gly47Asp substitution prevents plasma membrane localization of PalI-green fluorescent protein (GFP) and leads to its missorting into the multivesicular body pathway. Overexpression of the likely ambient alkaline pH receptor, the 7-TMD protein PalH, partially suppresses the null palI32 mutation. Although some PalH-GFP localizes to the plasma membrane, it predominates in internal membranes. However, the coexpression of PalI to stoichiometrically similar levels results in the strong predominance of PalH-GFP in the plasma membrane. Thus, one role for PalI, but possibly not the only role, is to assist with plasma membrane localization of PalH. These data, considered along with previous reports for both Saccharomyces cerevisiae and A. nidulans, strongly support the prevailing model of pH signaling involving two spatially segregated complexes: a plasma membrane complex containing PalH, PalI, and the arrestin-like protein PalF and an endosomal membrane complex containing PalA and PalB, to which PacC is recruited for its proteolytic activation.

Involvement of nitrogen-containing compounds in beta-lactam biosynthesis and its control

Biosynthesis of beta-lactam antibiotics by fungi and actinomycetes is markedly affected by compounds containing nitrogen. The different processes employed by the spectrum of microbes capable of making these valuable compounds are affected differently by particular compounds. Ammonium ions, except at very low concentrations, exert negative effects via nitrogen metabolite repression, sometimes involving the nitrogen regulatory gene nre. Certain amino acids are precursors or inducers, whereas others are involved in repression and, in certain cases, as inhibitors of biosynthetic enzymes and of enzymes supplying precursors. The most important amino acids from the viewpoint of regulation are lysine, methionine, glutamate and valine. Surprisingly, diamines such as diaminopropane, putrescine and cadaverine induce cephamycin production by actinomycetes. In addition to penicillins and cephalosporins made by fungi and cephamycins made by actinomycetes, other beta-lactams are made by actinomycetes and unicellular bacteria. These include clavams (e.g., clavulanic acid), carbapenems (e.g., thienamycin), nocardicins and monobactams. Here also, amino acids are precursors and inhibitors, but only little is known about regulation. In the case of the simplest carbapenem made by unicellular bacteria, i.e., 1-carba-2-em-3-carboxylic acid, quorum sensors containing homoserine lactone are inducers.

Alkaline pH-induced up-regulation of the afp gene encoding the antifungal protein (AFP) of Aspergillus giganteus is not mediated by the transcription factor PacC: possible involvement of calcineurin

The afp gene encoding the antifungal protein (AFP) of Aspergillus giganteus has a prototypical alkaline gene expression pattern, which suggests that the gene might be under the control of the ambient pH-dependent zinc-finger transcription factor PacC. This notion is corroborated by the presence in the upstream region of afp of two putative PacC binding sites, afpP1 and afpP2, which are specifically recognised by the PacC protein of A. nidulans in vitro. However, in this report we provide several lines of evidence to show that pH-dependent up-regulation of afp is not mediated by transcriptional activation through PacC. (1) The temporal expression pattern of the A. giganteus pacC gene does not parallel the accumulation of the afp mRNA during cultivation. (2) Inactivation of afpP1 and afpP2 did not reduce promoter activity under alkaline conditions, as determined from the relative wild-type and mutant afp::lacZ reporter activities in A. nidulans. (3) Reporter activities in acidity- and alkalinity-mimicking mutant strains are inconsistent with a positive role for PacC in afp expression. (4) In A. giganteus, the pH-dependent increase in afp mRNA and AFP levels can be completely prevented by the calcineurin inhibitor FK506, suggesting that the calcineurin signalling pathway might control the in vivo activation of the afp promoter by alkaline pH.

Role of cis-acting sites NorL, a TATA box, and AflR1 in nor-1 transcriptional activation in Aspergillus parasiticus

The transcription factor AflR is required for up-regulation of specific pathway genes involved in aflatoxin biosynthesis in the filamentous fungus Aspergillus. nor-1 encodes an early aflatoxin pathway enzyme; its promoter contains a consensus AflR binding site (AflR1). Proteins in Aspergillus parasiticus cell extracts and AflR expressed in Escherichia coli do not bind to A. parasiticus AflR1 in vitro, so it was not clear if this site was required for nor-1 expression or if other transcription factors contributed to gene regulation. In this study we defined the role of AflR1 in nor-1 expression in A. parasiticus and identified additional cis-acting sites required for maximum nor-1 transcriptional activation. Deletion and substitution of AflR1 in the nor-1 promoter in A. parasiticus nor-1::GUS reporter strains showed that this site is required for nor-1 transcriptional activation in vivo. Substitution of a putative TATA box in the nor-1 promoter resulted in nondetectable beta-glucuronidase (GUS) activity, demonstrating that this TATA box is functional in vivo. We also identified a novel cis-acting site, designated NorL, between residues -210 and -238 that was required for maximum nor-1 transcriptional activation in A. parasiticus grown in liquid medium and on solid medium. Using an electrophoretic mobility shift assay, we identified a specific NorL-dependent DNA-protein complex that relies on a functional AflR, either directly or indirectly, for maximum binding capacity. Because the NorL site appears only once in the aflatoxin gene cluster, its association with the nor-1 promoter may have important implications for the overall regulatory scheme for the aflatoxin pathway.

A novel cAMP-response element, CRE1, modulates expression of nor-1 in Aspergillus parasiticus

The level of aflatoxin accumulation in the filamentous fungus Aspergillus parasiticus is modulated by a variety of environmental cues. The presence of glucose (a preferred carbon source) in liquid and solid glucose minimal salts (GMS) growth media strongly stimulated aflatoxin accumulation. Peptone (a non-preferred carbon source) in peptone minimal salts (PMS) media stimulated only low levels of aflatoxin accumulation. Glucose stimulated transcription of the aflatoxin structural genes ver-1 and nor-1 to similar intermediate levels in liquid GMS, while on solid media, ver-1 transcription was stimulated to 20-fold higher levels than nor-1. PMS liquid and solid media stimulated very low or non-detectable levels of transcription of both genes. Electrophoretic mobility shift analysis using a nor-1 promoter fragment (norR) and A. parasiticus cell protein extracts revealed specific DNA-protein complexes of different mobility on GMS and PMS solid and liquid media. An imperfect cAMP-response element, CRE1, was identified in norR that mediated formation of the specific DNA-protein complexes. Mutation in CRE1 or AflR1 (AflR cis-acting site) caused up to a 3-fold decrease in cAMP-mediated stimulation of nor-1 promoter activity on GMS agar. South-Western blot analysis identified a 32-kDa protein that specifically bound to norR. p32 could be co-immunoprecipitated by anti-AflR antibody and co-purified with an AflR-maltose-binding protein fusion demonstrating a physical interaction between AflR and p32 in vitro. We hypothesize that p32 assists AflR in binding to the nor-1 promoter, thereby modulating nor-1 gene expression in response to environmental cues.

Characterization of AnRP-mediated negative regulation of the xylanase gene, cgxA, from Chaetomium gracile in Aspergillus nidulans

AIM

In vivo regulatory features of AnRP, a repressor for the cgxA gene, were characterized.

METHODS AND RESULTS

Titration of AnRP by introducing multiple copies of its specific binding sequence 'TTGACAAAT' into an Aspergillus nidulans strain containing the Chaetomium gracile cgxA gene enhanced the cgxA gene expression. AnRP functions independently of and cooperatively with CreA to modulate the cgxA gene expression.

CONCLUSIONS

AnRP is a CreA-independent negative regulatory factor controlling the cgxA expression.

SIGNIFICANCE AND THE IMPACT OF THE STUDY

Xylanases of filamentous fungi have received increased interest because of their potential biotechnological applications. Elucidation of the factors involved in the regulation of the xylanolytic genes in fungi will help to increase levels of xylanase production.

Specific induction and carbon/nitrogen repression of arginine catabolism gene of Aspergillus nidulans--functional in vivo analysis of the otaA promoter

The arginine catabolism gene otaA encoding ornithine transaminase (OTAse) is specifically induced by arginine and is under the control of the broad-domain carbon and nitrogen repression systems. Arginine induction is mediated by a product of arcA gene coding for Zn(2)C(6) activator. We have identified a region responsible for arginine induction in the otaA promoter (AnUAS(arg)). Deletions within this region result in non-inducibility of OTAse by arginine, whether in an arcA(+) strain or in the presence of the arcA(d)47 gain of function allele. AnUAS(arg) is very similar to the Saccharomyces cerevisiae UAS(arg), a sequence bound by the Zn(2)C(6) activator (ArgRIIp), acting in a complex with two MADS-box proteins (McmIp and ArgRIp). We demonstrate here that two CREA in vitro binding sites in the otaA promoter are functional in vivo. CREA is directly involved in carbon repression of the otaA gene and it also reduces its basal level of expression. Although AREA binds to the otaA promoter in vitro, it probably does not participate in nitrogen metabolite repression of the gene in vivo. We show here that another putative negatively acting GATA factor AREB participates directly or indirectly in otaA nitrogen repression. We also demonstrate that the high levels of OTAse activity are an important factor in the suppression of proline auxotrophic mutations. This suppression can be achieved neither by growing of the proline auxotroph under carbon/nitrogen derepressing conditions nor by introducing of a creA(d) mutation.

ADHII in Aspergillus nidulans is induced by carbon starvation stress

In Aspergillus nidulans there are three NAD(+)-dependent alcohol dehydrogenases (ADHs) that are capable of utilizing ethanol as a substrate. ADHI is the physiological enzyme of ethanol catabolism and ADHIII is induced under conditions of anaerobiosis. The physiological role of ADHII (structural gene alcB) is unknown. We have measured beta-galactosidase in a transformant with an alcB::lacZ fusion and have shown that alcB is maximally expressed under conditions of carbon starvation. The behavior of the alcB::lacZ transformant suggests a hierarchy of repressing carbon sources characteristic of repression by the general carbon catabolite repressor protein, CreA, but in a creA(d)30 background the transformant shows only partial derepression of beta-galactosidase on 1% glucose compared to the creA+ strain. Our results suggest that, in addition to carbon catabolite repression acting via CreA, a CreA-independent mechanism is involved in induction of alcB on carbon starvation.

On the mechanism by which alkaline pH prevents expression of an acid-expressed gene

Previous work has shown that zinc finger transcription factor PacC mediates the regulation of gene expression by ambient pH in the fungus Aspergillus nidulans. This regulation ensures that the syntheses of molecules functioning in the external environment, such as permeases, secreted enzymes, and exported metabolites, are tailored to the pH of the growth environment. A direct role for PacC in activating the expression of an alkaline-expressed gene has previously been demonstrated, but the mechanism by which alkaline ambient pH prevents the expression of any eukaryotic acid-expressed gene has never been reported. Here we show that a double PacC binding site in the promoter of the acid-expressed gabA gene, encoding gamma-aminobutyrate (GABA) permease, overlaps the binding site for the transcriptional activator IntA, which mediates omega-amino acid induction. Using bacterially expressed fusion proteins, we have shown that PacC competes with IntA for DNA binding in vitro at this site. Thus, PacC repression of GABA permease synthesis is direct and occurs by blocking induction. A swap of IntA sites between promoters for gabA and amdS, a gene not subject to pH regulation, makes gabA expression pH independent and amdS acid expressed.

A novel heptameric sequence (TTAGTAA) is the binding site for a protein required for high level expression of pcbAB, the first gene of the penicillin biosynthesis in Penicillium chrysogenum

The first two genes pcbAB and pcbC of the penicillin biosynthesis pathway are expressed from a 1.01-kilobase bidirectional promoter region. A series of sequential deletions were made in the pcbAB promoter region, and the constructions with the modified promoters coupled to the lacZ reporter gene were introduced as single copies at the pyrG locus in Penicillium chrysogenum npe10. Three regions, boxes A, B, and C, produced a significant decrease in expression of the reporter gene when deleted. Protein-DNA complexes were observed by using the electrophoretic mobility shift assay with boxes A and B (complexes AG1, BG1, BG2, and BL1) but not with box C. Uracil interference assay showed that a protein in P. chrysogenum cell extracts interacts with the thymines in a palindromic heptanucleotide TTAGTAA. Point mutations and deletion of the entire TTAGTAA sequence supported the involvement of this sequence in the binding of a transcriptional activator named penicillin transcriptional activator 1 (PTA1). In vivo studies using constructions carrying point mutations in the TTAGTAA sequence (or a deletion of the complete heptanucleotide) confirmed that this intact sequence is required for high level expression of the pcbAB gene. The TTAGTAA sequence resembles the target sequence of BAS2 (PHO2), a factor required for expression of several genes in yeasts.

Carbon catabolite repression of the Aspergillus nidulans xlnA gene

Expression of the Aspergillus nidulans 22 kDa endoxylanase gene, xlnA, is controlled by at least three mechanisms: specific induction by xylan or xylose; carbon catabolite repression (CCR); and regulation by ambient pH. Deletion analysis of xlnA upstream sequences has identified two positively acting regions: one that mediates specific induction by xylose; and another that mediates the influence of ambient pH and contains two PacC consensus binding sites. The extreme derepressed mutation creAd30 results in considerable, although not total, loss of xlnA glucose repressibility, indicating a major role for CreA in its CCR. Three consensus CreA binding sites are present upstream of the structural gene. Point mutational analysis using reporter constructs has identified a single site, xlnA.C1, that is responsible for direct CreA repression in vivo. Using the creAd30 derepressed mutant background, our results indicate the existence of indirect repression by CreA.

The optimization of penicillin biosynthesis in fungi

Penicillin production by Penicillium chrysogenum is not only commercially important but arguably the most intensively investigated secondary-metabolic pathway in fungi. Isolation of the structural genes encoding the three main penicillin-biosynthetic enzymes has stimulated the use of molecular approaches to optimize yield and permitted genetic analysis of current production strains, which are themselves the products of 50 years of strain and process improvement. Parallel studies on the penicillin-producing genetic model organism Aspergillus nidulans are now addressing questions about the genetic regulation of primary and secondary metabolism, the compartmentalization of biosynthesis and the excretion of the end products.

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.

In situ detection of protein-DNA interactions in filamentous fungi by in vivo footprinting

The method described here allows the detection of protein-DNA interactions in vivo in filamentous fungi. We outline culture conditions and conditions of in vivo methylation that permit uniform modification of all cells in an apically growing, non-uniform organism, and subsequent visualization of protected areas by ligation-mediated PCR.

The essential Aspergillus nidulans gene pmaA encodes an homologue of fungal plasma membrane H(+)-ATPases

pmaA, an Aspergillus nidulans gene encoding a P-ATPase, has been cloned by heterologous hybridization with the yeast PMA1 gene. The putative 990-residue PmaA polypeptide shows 50% identity to Saccharomyces cerevisiae and Neurospora crassa plasma membrane H(+)-ATPases and weak (19-26%) identity to other yeast P-type cation-translocating ATPases. PmaA contains all catalytic domains characterizing H(+)-ATPases. pmaA transcript levels are not regulated by PacC, the transcription factor mediating pH regulation, and were not significantly affected by an extreme creAd mutation resulting in carbon catabolite derepression. Deletion of pmaA causes lethality, but a single copy of the gene is sufficient to support normal growth rate in pmaA hemizygous diploids, even under acidic growth conditions. As compared to other fungal H(+)-ATPases, PmaA presents three insertions, 39, 7, and 16 residues long, in the conserved central region of the protein. Two of these insertions are predicted to be located in extracellular loops and might be of diagnostic value for the identification of Aspergillus species. Their absence from most mammalian P-type ATPases may have implications for antifungal therapy.

Regulation of the Aspergillus nidulans penicillin biosynthesis gene acvA (pcbAB) by amino acids: implication for involvement of transcription factor PACC

The beta-lactam antibiotic penicillin is produced as an end product by some filamentous fungi only. It is synthesized from the amino acid precursors L-alpha-aminoadipic acid, L-cysteine, and L-valine. Previous data suggested that certain amino acids play a role in the regulation of its biosynthesis. Therefore, in this study the effects of externally added amino acids on both Aspergillus (Emericella) nidulans penicillin production and expression of the bidirectionally oriented biosynthesis genes acvA (pcbAB) and ipnA (pcbC) were comprehensively investigated. Different effects caused by amino acids on the expression of penicillin biosynthesis genes and penicillin production were observed. Amino acids with a major negative effect on the expression of acvA-uidA and ipnA-lacZ gene fusions, i.e., histidine, valine, lysine, and methionine, led to a decreased ambient pH during cultivation of the fungus. An analysis of deletion clones lacking binding sites for the pH-dependent transcriptional factor PACC in the intergenic regions between acvA-uidA and ipnA-lacZ gene fusions and in a pacC5 mutant (PacC5-5) suggested that the negative effects of histidine and valine on acvA-uidA expression were due to reduced activation by PACC under acidic conditions. These data also implied that PACC regulates the expression of acvA, predominantly through PACC binding site ipnA3. The repressing effect caused by lysine and methionine on acvA expression, however, was even enhanced in one of the deletion clones and the pacC5 mutant strain, suggesting that regulators other than PACC are also involved.

Null alleles of creA, the regulator of carbon catabolite repression in Aspergillus nidulans

CreA is the major regulatory protein involved in carbon catabolite repression in Aspergillus nidulans. Previously we have reported the molecular characterization of a number of in vivo selected mutant alleles and showed that they were unlikely to represent total loss of function alleles (Shroff et al., 1996) and that a deletion of the creA gene and surrounding DNA has an extremely severe effect on morphology under both carbon catabolite repressing and carbon catabolite nonrepressing conditions (Dowzer and Kelly, 1991). Here we present an analysis of in vivo selected creA mutations with an extreme morphological phenotype and show that some of these alleles would be predicted to result in no functional CreA. The most extreme of these alleles resulted in a truncation of the protein within the first zinc finger. Precise gene disruptions, leaving the flanking sequences intact, show essentially the same phenotype as this truncated allele. Thus, a strain containing a null allele is viable, and the leaky-lethal phenotype of previous deletion alleles (Dowzer and Kelly, 1991) must be due to the deletion of additional 3' genomic sequence. A strain containing an allele that results in a deletion of the final 80 amino acids shows reduced sensitivity to carbon catabolite repression for a number of systems, thus localizing a region of the protein involved in repression. Surprisingly, the phenotypically most extreme allele studied is not a null allele, but results in an amino acid substitution that would disrupt the zinc finger region and abolish binding to DNA. This is the only allele that produces a full-length protein, predicted to be nuclear localized, but which completely abolishes DNA binding. The phenotype may be more extreme than the null alleles due to the nuclear located CreA protein titrating interacting proteins.

Sequence determination and molecular characterization of gigantin, a cytotoxic protein produced by the mould Aspergillus giganteus IFO 5818

Gigantin is a 17-kDa ribonuclease secreted by Aspergillus giganteus IFO 5818. The sequence of the genomic DNA coding for this protein is reported. The deduced amino acid sequence reveals nine amino acid variations with respect to alpha-sarcin, a well-characterized ribosome-inactivating protein from A. giganteus MDH 18894. The peptides obtained after tryptic digestion of reduced and carboxyamidomethylated gigantin have been chromatographically separated. The analysis of these peptides in comparison to those originating from alpha-sarcin corroborates the above sequence differences. These do not sensibly modify the conformation of the protein, based on the coincidence of the circular dichroism and fluorescence emission spectra of the two proteins. The obtained results are discussed in terms of the involvement of the distinctive residues in the immunological and catalytic properties that distinguish gigantin from alpha-sarcin.

Molecular regulation of penicillin biosynthesis in Aspergillus (Emericella) nidulans

The beta-lactam antibiotic penicillin is produced as end product by only some filamentous fungi, most notably by Aspergillus nidulans and Penicillium chrysogenum. The biosynthesis of this secondary metabolite is catalyzed by three enzymes which are encoded by the following three genes: acvA (pcbAB), ipnA (pcbC) and aat (penDE). The genes are organized into a gene cluster. In A. nidulans, several studies have indicated that the genes are controlled by a complex regulatory network. The wide-domain regulatory protein PACC binds to the intergenic region between acvA and ipnA and, at alkaline pH, increases at least ipnA gene transcription. An additional DNA binding protein (PENR1) was suggested to repress acvA and to activate ipnA and aat expression. Furthermore, three recessive trans-acting mutations have been characterized (prgA1, prgB1, npeE1) which most likely correspond to positively acting regulatory genes of the penicillin biosynthesis genes.

Analysis of Cre1 binding sites in the Trichoderma reesei cbh1 upstream region

A 1.5-kb XbaI-SacII fragment containing the upstream region of the Trichoderma reesei cellobiohydrolase I gene (cbh1) has been sequenced. The 1.5-kb fragment contains eight 6-bp sites having an identical or similar sequence to the consensus sequence for binding a catabolite repressor, Aspergillus nidulans CreA. Results of binding assays with the maltose-binding protein::Cre1(10-131) fusion protein (Cre1 is a catabolite repressor of T. reesei) and the cbh1 upstream region revealed that a 504-bp XbaI-NspV fragment (nucleotide position -1496 to -993) bearing three 6-bp sites, A1, A2, and A3, and a 356-bp NspV-MunI fragment (nucleotide position -994 to -639) bearing three 6-bp sites, B1, B2, and B3, were shifted in the electrophoretic mobility shift assay. DNase I footprinting experiments showed that the 6-bp sites A2, B1, B2, and B3 were protected from DNase I digestion.

Three binding sites for the Aspergillus nidulans PacC zinc-finger transcription factor are necessary and sufficient for regulation by ambient pH of the isopenicillin N synthase gene promoter

The isopenicillin N synthase (ipnA) gene, encoding a key penicillin biosynthetic enzyme in Aspergillus nidulans, represents a prototype of an alkaline-expressed gene. ipnA is under ambient pH regulation, and its promoter (ipnAp) contains binding sites for the zinc-finger transcription factor PacC. We show here that three of these sites, denoted ipnA2, ipnA3, and ipnA4AB, are efficiently recognized by the protein in an isolated sequence context. Single, double, and triple inactivation of these sites in any possible combination reduced promoter activity under alkaline conditions but had no effect under acidic conditions (under which promoter activity was low), as measured by the expression of wild-type and mutant ipnAp::lacZ fusion genes integrated in single copy into a common chromosomal location. This establishes a physiological role for these PacC binding sites and demonstrates a direct role for PacC in ambient pH regulation of ipnA gene expression. In addition, this confirms our previous proposal that PacC is an activator for alkaline-expressed genes. Notably, our experiments show that ipnA2, the highest affinity site for PacC in the ipnAp, contributes relatively modestly to PacC-mediated activation. By contrast, the lower affinity sites ipnA3 and ipnA4AB contribute more substantially to regulation by ambient pH. Inactivation of these three binding sites reduced promoter activity under alkaline conditions to that observed under acidic conditions, showing that these three PacC sites at ipnAp are sufficient to account for its activation by alkaline ambient pH.

Analysis of mutations in the creA gene involved in carbon catabolite repression in Aspergillus nidulans

The molecular nature of a number of creA mutant alleles has been determined. Three alleles analysed are missense mutations in the DNA binding domain and predicted to reduce but not abolish binding. Of the other four alleles, two result from frameshifts: one has a nonsense mutilation and the other has an inversion. All four alleles result in truncations of the protein after the zinc finger domain, such that the protein no longer contains at least the carboxy terminal 145 amino acids, so identifying a region required for repression. Transcriptional analysis of creA indicates that the transcript is autoregulated and analysis using 5' rapid amplification of cDNA ends indicates that transcriptional start points exist in clusters over a region of 200 bp located up to 595 bp 5' of the translational start point. The two major clusters have potential CREA-binding sites (SYGGRG) at appropriate positions to allow autoregulation. Autoregulation leads to the creA transcript being most abundant in carbon catabolite nonrepressing conditions, and this, together with the phenotypes of the mutant alleles, has led to the suggestion that CREA has effects under conditions generally not considered as carbon catabolite repressing, as well as in carbon catabolite repressing conditions.

Identification of a major cis-acting DNA element controlling the bidirectionally transcribed penicillin biosynthesis genes acvA (pcbAB) and ipnA (pcbC) of Aspergillus nidulans

The beta-lactam antibiotic penicillin is produced as a secondary metabolite by some filamentous fungi. In this study, the molecular regulation of the Aspergillus (Emericella) nidulans penicillin biosynthesis genes acvA (pcbAB) and ipnA (pcbC) was analyzed. acvA and ipnA are divergently oriented and separated by an intergenic region of 872 bp. Translational fusions of acvA and ipnA with the two Escherichia coli reporter genes lacZ and uidA enabled us to measure the regulation of both genes simultaneously. A moving-window analysis of the 872-bp intergenic region indicated that the divergently oriented promoters are, at least in part, overlapping and share common regulatory elements. Removal of nucleotides -353 to -432 upstream of the acvA gene led to a 10-fold increase of acvA-uidA expression and simultaneously to a reduction of ipnA-lacZ expression to about 30%. Band shift assays and methyl interference analysis using partially purified protein extracts revealed that a CCAAT-containing DNA element within this region was specifically bound by a protein (complex), which we designated PENR1, for penicillin regulator. Deletion of 4 bp within the identified protein binding site caused the same contrary effects on acvA and ipnA expression as observed for all of the deletion clones which lacked nucleotides -353 to -432. The PENR1 binding site thus represents a major cis-acting DNA element. The intergenic regions of the corresponding genes of the beta-lactam-producing fungi Penicillium chrysogenum and Acremonium chrysogenum also diluted the complex formed between the A. nidulans probe and PENR1 in vitro, suggesting that these beta-lactam biosynthesis genes are regulated by analogous DNA elements and proteins.

Analysis of the regulation of the Aspergillus nidulans penicillin biosynthesis gene aat (penDE), which encodes acyl coenzyme A:6-aminopenicillanic acid acyltransferase

The regulation of the Aspergillus nidulans penicillin biosynthesis gene aat (penDE), which encodes acyl coenzyme A:6-aminopenicillanic acid acyltransferase (AAT), was analysed. Major transcriptional start sites map within 100 nucleotides upstream from the aat initiation codon. To study the regulation of aat expression, various aat-lacZ gene fusions were constructed, in which the aat promoter region was fused in frame with the Escherichia coli lacZ reporter gene. A. nidulans strains carrying recombinant plasmids integrated as single copies at the chromosomal argB locus were identified. In both fermentation and minimal media, aat-lacZ expression was maximal during the first 24 h of a fermentation run. Compared with minimal medium, aat-lacZ expression was increased two-fold in fermentation medium. Although AAT specific activity was reduced in mycelia grown on glucose instead of lactose, expression of aat-lacZ gene fusions was not repressed on glucose, suggesting that the glucose effect is mediated posttranscriptionally. The effect of glucose on AAT activity was reversed by further incubation of glucose-grown mycelia on lactose. Neither the inclusion of the first intron of the aat gene in the aat-lacZ fusion integrated at the chromosomal argB locus, nor the disruption of the acvA gene had any regulatory effect on aat-lacZ expression. In the heterologous, nonpenicillin producer A. niger, basal expression of aat-lacZ gene fusions was observed at about the same level as in A. nidulans.

A lacZ reporter fusion method for the genetic analysis of regulatory mutations in pathways of fungal secondary metabolism and its application to the Aspergillus nidulans penicillin pathway

Secondary metabolism, usually superfluous under laboratory conditions, is intrinsically elusive to genetic analysis of its regulation. We describe here a method of analyzing regulatory mutations affecting expression of secondary metabolic genes, with an Aspergillus nidulans penicillin structural gene (ipnA [encoding isopenicillin N-synthase]) as a model. The method is based on a targeted double integration of a lacZ fusion reporter gene in a chromosome different from that containing the penicillin gene cluster. The trans-acting regulatory mutations simultaneously affect lacZ expression and penicillin biosynthesis. One of these mutations (npeE1) has been analyzed in detail. This mutation is recessive, prevents penicillin production and ipnA'::'lacZ expression, and results in very low levels of the ipnA message at certain times of growth. This indicates that npeE positively controls ipnA transcription. We also show that this tandem reporter fusion allows genetic analysis of npeE1 by using the sexual and parasexual cycles and that lacZ expression is an easily scorable phenotype. Haploidization analysis established that npeE is located in chromosome IV, but npeE1 does not show meiotic linkage to a number of known chromosome IV markers. This method might be of general applicability to genetic analysis of regulation of other fungal secondary metabolic pathways.

NRE, the major nitrogen regulatory protein of Penicillium chrysogenum, binds specifically to elements in the intergenic promoter regions of nitrate assimilation and penicillin biosynthetic gene clusters

NRE, the nitrogen regulatory protein of Penicillium chrysogenum, contains a single Cys2/Cys2-type zinc-finger motif followed immediately by a highly basic region. The zinc-finger domain was expressed to Escherichia coli as a fusion protein with beta-galactosidase. In order to test the putative DNA-binding ability of NRE, the intergenic promoter region of the nitrate reductase/nitrite reductase gene cluster (niiA-niaD) of Penicillium was sequenced. Our results show that NRE is a DNA-binding protein and binds to the intergenic promoter regions of the P. chrysogenum niiA-niaD and acvA-pcbC gene cluster, encoding the first two enzymes in penicillin biosynthesis. Three of the four high-affinity NRE-binding sites contained two GATA core elements. In one of the recognition sites for NRE, one GATA motif was replaced by GATT. The two GATA elements showed all possible orientations, head-to-head, head-to-tail and tail-to-tail, and were separated by between 4 and 27 bp. Missing-contact analysis showed that all three purines in both of the GATA core sequences and the single adenine residue in each of the complementary TATC sequences were involved in the binding of NRE. Moreover, loss of purines in the flanking regions of the GATA elements also affect binding of NRE, as their loss causes reduced affinity.

Detection of a protein which binds specifically to the upstream region of the pcbAB gene in Penicillium chrysogenum

The upstream region of the pcbAB gene from Penicillium chrysogenum was screened for protein-binding sites using an electromobility shift assay. A specific protein/DNA interaction was detected within a fragment covering the region -387 to -242 relative to the pcbAB translational start codon. The appearance of this protein and pcbAB mRNA in culture extracts occurred at the same time point in fermentations, suggesting that the protein might be a transcription activator. The putative upstream activating sequence was located more precisely using cross-competition assays. These indicated the involvement of the 7-bp motif TGCCAAG in the binding of the protein.

Activation of the Aspergillus PacC transcription factor in response to alkaline ambient pH requires proteolysis of the carboxy-terminal moiety

Extremes of pH are an occupational hazard for many microorganisms. In addition to efficient pH homeostasis, survival effectively requires a regulatory system tailoring the syntheses of molecules functioning beyond the cell boundaries (permeases, secreted enzymes, and exported metabolites) to the pH of the growth environment. Our previous work established that the zinc finger PacC transcription factor mediates such pH regulation in the fungus Aspergillus nidulans in response to a signal provided by the products of the six pal genes at alkaline ambient pH. In the presence of this signal, PacC becomes functional, activating transcription of genes expressed at alkaline pH and preventing transcription of genes expressed at acidic pH. Here we detect two forms of PacC in extracts, both forming specific retardation complexes with a PacC-binding site. Under acidic growth conditions or in acidity-mimicking pal mutants (defective in ambient pH signal transduction), the full-length form of PacC predominates. Under alkaline growth conditions or in alkalinity-mimicking pacCc mutants (independent of the ambient pH signal), a proteolysed version containing the amino-terminal approximately 40% of the protein predominates. This specifically cleaved shorter version is clearly functional, both as an activator for alkaline-expressed genes and as a repressor for acid-expressed genes, but the full-length form of PacC must be inactive. Thus, PacC proteolysis is an essential and pH-sensitive step in the regulation of gene expression by ambient pH. Carboxy-terminal truncations, resulting in a gain-of-function (pacCc) phenotype, bypass the requirement for the pal signal transduction pathway for conversion of the full-length to the proteolyzed functional form.

Nuclear DNA-binding proteins which recognize the intergenic control region of penicillin biosynthetic genes

The biosynthesis of penicillin, a secondary metabolite produced by Penicillium chrysogenum, is subject to sophisticated genetic and metabolic regulation. The structural genes, pcbC and pcbAB, which encode two of the penicillin biosynthetic enzymes are separated by a 1.16-kb intergenic region and transcribed divergently from one another. To identify and characterize nuclear proteins which interact with the pcbAB-pcbC intergenic promoter region, crude and partially purified nuclear extracts were used in mobility shift and DNA footprinting assays. Multiple DNA-binding proteins appear to bind to different regions of this DNA segment. An abundant nuclear protein, nuclear factor A (NF-A), binds at a single site in the intergenic promoter region and recognizes an 8-bp sequence, GCCAAGCC. Penicillin production is sensitive to nitrogen catabolite repression. The global-acting nitrogen regulatory protein NIT2 of Neurospora crassa binds strongly to the intergenic promoter region of the pcbAB and pcbC genes at a single site that contains two closely spaced GATA sequences.

Overexpression of two penicillin structural genes in Aspergillus nidulans

We have placed two different penicillin structural genes from Aspergillus nidulans, ipnA (encoding isopenicillin N synthetase, IPNS) and acyA (encoding acyl-CoA:6-aminopenicillanic acid acyltransferase, AAT), under the control of the strong alcA promoter [alcA(p)]. Single copies of these transcriptional fusions were targeted to the same chromosomal location and conditions have been worked out which simultaneously allow induction of the alcA(p) and support penicillin biosynthesis. Transcriptional induction of the chimeric genes alcA(p)::ipnA or alcA(p)::acyA(cdna) in the relevant recombinant strains results in 10-fold higher levels of the ipnA or acyA transcripts than those resulting from transcription of the corresponding endogenous genes. This increase causes a 40-fold rise in IPNS activity or a 8-fold rise in AAT activity. Despite this rise in enzyme levels, forced expression of the ipnA gene results in only a modest increase in levels of exported penicillin, whereas forced expression of the acyA gene reduces penicillin production, showing that neither of these enzymes is rate-limiting for penicillin biosynthesis in A. nidulans. A genomic version of the alcA(p)::acyA fusion in which the acyA gene is interrupted by three small introns, is inducible by threonine to a lesser extent (as determined by both acyA mRNA levels and AAT enzyme levels) than the corresponding cDNA version, suggesting that processing of the introns present in the primary transcript may limit acyA expression.

Direct analysis of native and chimeric GATA specific DNA binding proteins from Aspergillus nidulans

In Aspergillus nidulans the regulatory gene areA is responsible for mediating nitrogen metabolite repression. The areA product (AREA) represents an example of the GATA family of DNA binding proteins, which are characterised by the presence of a GATA domain consisting of a zinc finger within a highly conserved region of 52 amino acids. Among the other transcription factors included in this family is the principal erythroid transcription factor, GATA-1, which contains two GATA domains. In order to demonstrate high specificity binding of native AREA to DNA containing the sequence -GATA-, and investigate the presence in A.nidulans of other proteins with related specificities, we have used gel mobility shift assays. Both AREA-dependent and independent complexes have been identified. Two strains bearing chimeric genes were also characterised. In these, the region encoding the native GATA domain of AREA was replaced by sequences from murine GATA-1 cDNA encoding either the equivalent C-terminal domain or both the N and C-terminal domains. Strains bearing the areA::NC-GATA construct, which includes the sequence encoding both the N and C-terminal domains of GATA-1, leads to a pronounced increase in one of two AREA-dependent complexes and implicates the N-terminal domain of GATA-1 in mediating protein-protein interactions.

A reporter gene analysis of penicillin biosynthesis gene expression in Penicillium chrysogenum and its regulation by nitrogen and glucose catabolite repression

Vectors which possess a truncated niaD gene encoding nitrate reductase were developed to allow targeted gene integration during transformation of an niaD mutant Penicillium chrysogenum host. The Penicillium genes pcbC and penAB are immediately adjacent to each other and are divergently transcribed, with an intergenic control region serving as their promoters. Gene fusions were constructed with a reporter gene, uidA, which encodes beta-glucuronidase. The pcbC-penAB intergenic region was fused to the uidA gene in both orientations so that regulated expression of each structural gene could be investigated. These fusion genes were targeted to the chromosomal site of the niaD locus of P. chrysogenum, and their expression was examined under different growth conditions. The expression of each of these penicillin biosynthesis genes was found to be regulated by nitrogen repression, glucose repression, and growth stage control.

In vitro binding of the two-finger repressor CreA to several consensus and non-consensus sites at the ipnA upstream region is context dependent

The two zinc-fingers of the Aspergillus nidulans repressor CreA recognize the consensus hexanucleotide 5'-SYGGRG-3'. We have determined all the CreA binding sites in a approximately 2 kb region upstream the ipnA gene. Our analysis shows that (i) CreA binds to certain consensus sites in a context-dependent manner; (ii) five non-consensus 6-bp sequences are also recognized by CreA; this non-canonical binding correlates with the presence of a second, neighbouring CreA binding site, suggesting that recognition of two linked sites stabilizes CreA binding. Our results suggest that the binding possibilities of CreA might be more complex than originally envisaged.