C-terminal truncation of the transcriptional activator encoded by areA in Aspergillus nidulans results in both loss-of-function and gain-of-function phenotypes

Phenotypes of mutations in the 5'-UTR of a limiting transcription factor in Aspergillus nidulans can be accounted for by translational inhibition and leaky scanning

The uaY gene encodes the transcriptional activator of purine catabolism genes in Aspergillus nidulans. uaY12 results in strongly defective growth on purines as nitrogen sources and in strongly diminished transcription of UaY-regulated genes. This mutation introduces an ATG codon 64 bp upstream of the uaY ATG, generating a 68-codon open reading frame (uORFA), overlapping with the uaY ORF. uaY12 revertants fall into three categories: i. The majority eliminate the aberrant ATG. The growth and transcriptional phenotypes of these revertants are identical to those of the wild type. i. Two revertants create a stop codon in frame with the uaY12 aberrant ATG, shortening the length of the uORFA, thus uORFA no longer overlaps the uaY ORF. The latter are partial suppressors of the uaY12 mutation, while chain termination suppressors, in turn, suppress this novel phenotype. iii. Two partial suppressors are unlinked to uaY. These two mutations result in a pleiotropic phenotype usually associated with ribosomal proteins. We hypothesize that uORFA strongly diminishes translation of the uaY ORF and that revertants negate this effect by a number of different mechanisms. The first-AUG rule and the phenomena of translational inhibition and leaky scanning provide a coherent explanation of the results presented in this article.

Hansenula polymorpha NMR2 and NMR4, two new loci involved in nitrogen metabolite repression

In the yeast Hansenula polymorpha (Pichia angusta) nitrate assimilation is tightly regulated and subject to a dual control: nitrogen metabolite repression (NMR), triggered by reduced nitrogen compounds, and induction, elicited by nitrate itself. In a previous paper [Serrani, F., Rossi, B. and Berardi, E (2001) Nitrogen metabolite repression in Hansenula polymorpha: the nmrl-l mutation. Curr. Genet. 40, 243-250], we identified five loci (NMR1-NMR5) involved in NMR, and characterised one of them (NMR1), which likely identifies a regulatory factor. Here, we describe two more mutants, namely nmr2-1 and nmr4-1. The first one possibly identifies a regulatory factor involved in nitrogen metabolite repression by various nitrogen sources alternative to ammonium. The second one, apparently involved in ammonium assimilation, probably has sensor functions.

Attachment of a histidine tag to the minimal zinc finger protein of the Aspergillus nidulans gene regulatory protein AreA causes a conformational change at the DNA-binding site

Histidine (His) tags are one of the most popular fusion tags for the isolation of proteins via metal affinity chromatography. The fusion tag is routinely left attached to the protein when carrying out experiments, with the assumption that the addition has no effect on structure or function. In the present study, we have prepared four proteins of the gene regulatory protein AreA from Aspergillus nidulans for crystallization experiments: a 91-amino acid peptide encompassing the minimal DNA-binding region, both with and without the His-tag (HZFB and ZFB, respectively), and a 155-amino acid protein previously proposed to be the entire DNA-binding domain for AreA, both with and without the His-tag (HG1b and G1b, respectively). To test the integrity of the four AreA proteins, urea denaturation experiments and DNA-binding studies were performed using fluorescence spectroscopy. The DNA-binding data showed similar dissociation constants for all proteins, with Kd values in the nanomolar range. The urea denaturation data, however, clearly indicated that the HZFB protein exhibited a completely different denaturation profile when compared to the ZFB, HG1b, and G1b proteins. The HZFB protein showed a profile indicative of the presence of an altered conformation around the sole tryptophan, whereas the other proteins showed a transition point between 3 and 4 M urea concentration. These data show that, although function was not altered for any of the proteins studied, the structure of one of the His-tagged proteins was different from the native form of that protein.

Efficient gene disruption in the koji-mold Aspergillus sojae using a novel variation of the positive-negative method

When no phenotypic screen is available, gene disruption in the koji-mold Aspergillus sojae is a time-consuming process, owing to the low frequency of homologous recombination. To achieve efficient gene disruption in the koji-mold, we developed a novel positive-negative selection method to enrich for homologous recombinants. The pyrG gene from A. sojae was used as a positive selection marker for transformants, and the oliC31 gene of A. nidulans, which codes for a mutant form of subunit 9 of the F1FO-ATPase, was employed as a negative selection marker to facilitate elimination of non-homologous recombinants among the transformants. The positive-negative selection markers, in combination with a pyrG deletion strain as a host, enabled enrichment for homologous recombinants, and disruption of the genes niaD, areA and tannase was successfully demonstrated. In order to examine whether the positive-negative selection technique is effective for targeting any locus, even in the absence of information on gene function or phenotype, we attempted to disrupt the aflR gene of A. sojae, which codes for a putative transcription factor for the aflatoxin biosynthetic pathway, using the method. Despite the fact that this gene is not transcribed in A. sojae, aflR disruptants were efficiently obtained, suggesting that the method is indeed capable of targeting any locus, without additional ectopic integration, and is thus applicable for functional genomics studies in filamentous fungi, including A. sojae.

Global nutritional profiling for mutant and chemical mode-of-action analysis in filamentous fungi

We describe a method for gene function discovery and chemical mode-of-action analysis via nutrient utilization using a high throughput Nutritional Profiling platform suitable for filamentous microorganisms. We have optimized the growth conditions for each fungal species to produce reproducible optical density growth measurements in microtiter plates. We validated the Nutritional Profiling platform using a nitrogen source utilization assay to analyze 21 Aspergillus nidulans strains with mutations in the master nitrogen regulatory gene, areA. Analysis of these data accurately reproduced expected results and provided new data to demonstrate that this platform is suitable for fine level phenotyping of filamentous fungi. Next, we analyzed the differential responses of two fungal species to a glutamine synthetase inhibitor, illustrating chemical mode-of-action analysis. Finally, a comparative phenotypic study was performed to characterize carbon catabolite repression in four fungal species using a carbon source utilization assay. The results demonstrate differentiation between two Aspergillus species and two diverse plant pathogens and provide a wealth of new data on fungal nutrient utilization. Thus, these assays can be used for gene function and chemical mode-of-action analysis at the whole organism level as well as interspecies comparisons in a variety of filamentous fungi. Additionally, because uniform distribution of growth within wells is maintained, comparisons between yeast and filamentous forms of a single organism can be performed.

Structural and functional characterisation of the DNA binding domain of the Aspergillus nidulans gene regulatory protein AreA

The 876-aa protein AreA regulates the expression of numerous genes involved in nitrogen metabolism in Aspergillus nidulans, and interacts with GATA sequences upstream of the relevant genes. We have carried out limited proteolysis of the C-terminal domain of the AreA protein in order to identify possible structural domains within the protein. A stable 156-amino-acid fragment was identified that contained the zinc finger region, and this sequence was cloned and expressed in E. coli. Fluorescence spectroscopy of the purified protein showed that the proteolytic domain was folded and could be denatured by high concentrations of urea (approximately 4 M), exhibiting a sharp transition. Fluorescence spectroscopy was also used to monitor binding to a DNA duplex containing the AreA recognition site, demonstrating tight binding of the domain to its DNA recognition sequence. The DNA binding affinity of the domain is comparable with that of the native AreA protein and much higher than that of the minimal zinc finger region of AreA.

The DNA-binding domain of the gene regulatory protein AreA extends beyond the minimal zinc-finger region conserved between GATA proteins

The AreA protein of Aspergillus nidulans regulates the activity of over 100 genes involved in the utilisation of nitrogen, and has a limited region of homology with the vertebrate family of GATA proteins around a zinc finger (Zf) motif. A 66 amino acid (a.a.) residue fragment (Zf(66)) corresponding to the zinc finger, a 91 a.a fragment (Zf(91)) containing an additional 25 a.a. at the C-terminus, and a much larger 728 a.a. sequence (3'EX) corresponding to the 3'exon have been over-expressed as fusion proteins in E. coli and purified. The DNA-protein complexes formed by these proteins have been examined by gel retardation analysis. The 91 a.a. protein forms a discrete shifted species with a GATA-containing DNA fragment with high affinity (K(d)=0.15 nM), whereas the 66 a.a. protein has very low ( approximately microM) affinity for the same sequence. The results show that the region of AreA required for high affinity DNA binding extends beyond the zinc finger motif that is homologous to GATA-1, requiring in addition a region within the 25 a.a. sequence C-terminal to the zinc finger. Using hydroxyl radical and ethylation interference footprinting, the minimal Zinc finger protein (Zf(66)) shows no appreciable interference effects whereas Zf(91) shows much stronger interference effects, identical to those of the larger protein. These effects extend over sequences up to two nucleotides either side of the GATA site, and indicate contacts additional to those observed in the three-dimensional structure of the complex of the minimal zinc-finger protein with DNA. We suggest that these additional contacts are responsible for the enhanced DNA binding affinity of the extended zinc-finger protein Zf(91).

Deletion of the 389 N-terminal residues of the transcriptional activator AREA does not result in nitrogen metabolite derepression in Aspergillus nidulans

Utilizing a homologous gene replacement in order to retain the native promoter and 5' and 3' untranslated messenger regions (and thereby ensure physiological validity), we have shown that deletion of the N-terminal 389 amino acids of the transcriptional activator AREA does not result in nitrogen metabolite derepression in Aspergillus nidulans. Our results provide no evidence for a modulating interaction involving the N terminus of AREA and contrast with those of H. K. Lamb, A. L. Dodds, D. R. Swatman, E. Cairns, and A. R. Hawkins (J. Bacteriol. 179:6649-6656, 1997), who used nontargeted ectopic copies of a construct containing a heterologous promoter and untranslated regions. Results obtained with this deletion mutant, nevertheless, provide further evidence for the dispensability of large portions of AREA.

Isolation of a nitrogen response regulator gene (nrr1) from Metarhizium anisopliae

Attempts to improve the effectiveness of entomopathogenic fungi as biological control agents require a clear understanding of the pathogenicity determinants at both the biochemical and molecular level. Proteases play a key role in entomopathogenicity, allowing the fungus to penetrate the insect cuticle and rapidly invade the host. The most extensively studied of these protease activities, PR1A and PR2, are both subject to nitrogen derepression. The Metarhizium anisopliae nrr1 (nitrogen response regulator 1) gene was identified using a PCR-based strategy; it encodes a putative DNA-binding protein with a single zinc finger motif defined by the C-X2-C-X17-C-X2-C sequence. M. anisopliae NRR1 shows a significant sequence similarity to Neurospora crassa NIT2. Sequence analysis identified the presence of two introns, suggesting a greater degree of similarity to N. crassa nit2 than to the areA-like genes that have been identified. However, functional equivalence of nrr1 to areA was demonstrated, by co-transformation and complementation of an A. nidulans areA loss-of-function mutant (areA18 argB2 pabaA1 inoB2) with the M. anisopliae nrr1 gene. The areA-/nrr1+ Aspergillus transformants were able to grow on media with nitrate and glutamate as the sole nitrogen source, whereas the areA- strain is unable to grow under these conditions. The possible relevance of nitrogen regulation to pathogenicity is discussed.

Mutational analysis of AREA, a transcriptional activator mediating nitrogen metabolite repression in Aspergillus nidulans and a member of the "streetwise" GATA family of transcription factors

The transcriptional activator AREA is a member of the GATA family of transcription factors and mediates nitrogen metabolite repression in the fungus Aspergillus nidulans. The nutritional versatility of A. nidulans and its amenability to classical and reverse genetic manipulations make the AREA DNA binding domain (DBD) a useful model for analyzing GATA family DBDs, particularly as structures of two AREA-DNA complexes have been determined. The 109 extant mutant forms of the AREA DBD surveyed here constitute one of the highest totals of eukaryotic transcription factor DBD mutants, are discussed in light of the roles of individual residues, and are compared to corresponding mutant sequence changes in other fungal GATA factor DBDs. Other topics include delineation of the DBD using both homology and mutational truncation, use of frameshift reversion to detect regions of tolerance to mutational change, the finding that duplication of the DBD can apparently enhance AREA function, and use of the AREA system to analyze a vertebrate GATA factor DBD. Some major points to emerge from work on the AREA DBD are (i) tolerance to sequence change (with retention of function) is surprisingly great, (ii) mutational changes in a transcription factor can have widely differing, even opposing, effects on expression of different structural genes so that monitoring expression of one or even several structural genes can be insufficient and possibly misleading, and (iii) a mutational change altering local hydrophobic packing and DNA binding target specificity can markedly influence the behavior of mutational changes elsewhere in the DBD.

The solution structure of a fungal AREA protein-DNA complex: an alternative binding mode for the basic carboxyl tail of GATA factors

The solution structure of a complex between the DNA binding domain of a fungal GATA factor and a 13 base-pair oligonucleotide containing its physiologically relevant CGATAG target sequence has been determined by multidimensional nuclear magnetic resonance spectroscopy. The AREA DNA binding domain, from Aspergillus nidulans, possesses a single Cys2-Cys2 zinc finger module and a basic C-terminal tail, which recognize the CGATAG element via an extensive network of hydrophobic interactions with the bases in the major groove and numerous non-specific contacts along the sugar-phosphate backbone. The zinc finger core of the AREA DNA binding domain has the same global fold as that of the C-terminal DNA binding domain of chicken GATA-1. In contrast to the complex with the DNA binding domain of GATA-1 in which the basic C-terminal tail wraps around the DNA and lies in the minor groove, the structure of complex with the AREA DNA binding domain reveals that the C-terminal tail of the fungal domain runs parallel with the sugar phosphate backbone along the edge of the minor groove. This difference is principally attributed to amino acid substitutions at two positions of the AREA DNA binding domain (Val55, Asn62) relative to that of GATA-1 (Gly55, Lys62). The impact of the different C-terminal tail binding modes on the affinity and specificity of GATA factors is discussed.

Characterization of the Aspergillus nidulans nmrA gene involved in nitrogen metabolite repression

The gene nmrA of Aspergillus nidulans has been isolated and found to be a homolog of the Neurospora crassa gene nmr-1, involved in nitrogen metabolite repression. Deletion of nmrA results in partial derepression of activities subject to nitrogen repression similar to phenotypes observed for certain mutations in the positively acting areA gene.

Identification, cloning and sequence of the Aspergillus niger areA wide domain regulatory gene controlling nitrogen utilisation

The gene encoding the positive-acting regulator of nitrogen metabolite repression (AREA) has been cloned and characterised from the industrially important filamentous fungus Aspergillus niger. The deduced amino acid sequence has an overall level of identity with its homologues from other fungal species which varies between 32 and 72%. This gene (areAnig) complements the A. nidulans areAr-18 loss-of-function mutation. Sequences upstream of the structural gene contain several putative GATA-type zinc finger protein-binding motifs. Northern analysis indicates the synthesis of multiple transcripts, the major species being approximately 2.95 kb and 3.1 kb. Maximal expression of areAnig is observed under conditions of nitrogen starvation and is mainly due to an increase in the level of the shorter transcript.

Chromosome rearrangements in Neurospora and other filamentous fungi

Knowledge of fungal chromosome rearrangements comes primarily from N. crassa, but important information has also been obtained from A. nidulans and S. macrospora. Rearrangements have been identified in other Sordaria species and in Cochliobolus, Coprinus, Magnaporthe, Podospora, and Ustilago. In Neurospora, heterozygosity for most chromosome rearrangements is signaled by the appearance of unpigmented deficiency ascospores, with frequencies and ascus types that are characteristic of the type of rearrangement. Summary information is provided on each of 355 rearrangements analyzed in N. crassa. These include 262 reciprocal translocations, 31 insertional translocations, 27 quasiterminal translocations, 6 pericentric inversions, 1 intrachromosomal transposition, and numerous complex or cryptic rearrangements. Breakpoints are distributed more or less randomly among the seven chromosomes. Sixty of the rearrangements have readily detected mutant phenotypes, of which half are allelic with known genes. Constitutive mutations at certain positively regulated loci involve rearrangements having one breakpoint in an upstream regulatory region. Of 11 rearrangements that have one breakpoint in or near the NOR, most appear genetically to be terminal but are in fact physically reciprocal. Partial diploid strains can be obtained as recombinant progeny from crosses heterozygous for insertional or quasiterminal rearrangements. Duplications produced in this way precisely define segments that cover more than two thirds of the genome. Duplication-producing rearrangements have many uses, including precise genetic mapping by duplication coverage and alignment of physical and genetic maps. Typically, fertility is greatly reduced in crosses parented by a duplication strain. The finding that genes within the duplicated segment have undergone RIP mutation in some of the surviving progeny suggests that RIP may be responsible for the infertility. Meiotically generated recessive-lethal segmental deficiencies can be rescued in heterokaryons. New rearrangements are found in 10% or more of strains in which transforming DNA has been stably integrated. Electrophoretic separation of rearranged chromosomal DNAs has found useful applications. Synaptic adjustment occurs in inversion heterozygotes, leading progressively to nonhomologous association of synaptonemal complex lateral elements, transforming loop pairing into linear pairing. Transvection has been demonstrated in Neurospora. Beginnings have been made in constructing effective balancers. Experience has increased our understanding of several phenomena that may complicate analysis. With some rearrangements, nondisjunction of centromeres from reciprocal translocation quadrivalents results in 3:1 segregation and produces asci with four deficiency ascospores that occupy diagnostic positions in linear asci. Three-to-one segregation is most frequent when breakpoints are near centromeres. With some rearrangements, inviable deficiency ascospores become pigmented. Diagnosis must then depend on ascospore viability. In crosses between highly inbred strains, analysis may be handicapped by random ascospore abortion. This is minimized by using noninbred strains as testers.

Evolution of transcription-regulating proteins: caveat lector!

The paper of Hawkins et al. [Gene 146 (1994) 145-158] reports incorrect descriptions of mutant phenotypes, omits mention of the absence of a highly relevant glutamine-binding site and contains sequence alignments which might mislead the reader. Extensive sequence analysis reveals as untenable a central hypothesis of the paper concerning a possible evolutionary relationship between anthranilate synthetases and the transcription factors mediating nitrogen metabolite repression in fungi.

Subtle hydrophobic interactions between the seventh residue of the zinc finger loop and the first base of an HGATAR sequence determine promoter-specific recognition by the Aspergillus nidulans GATA factor AreA

A change of a universally conserved leucine to valine in the DNA-binding domain of the GATA factor AreA results in inability to activate some AreA-dependent promoters, including that of the uapA gene encoding a specific urate-xanthine permease. Some other AreA-dependent promoters become able to function more efficiently than in the wild-type context. A methionine in the same position results in a less extreme, but opposite effect. Suppressors of the AreA(Val) mutation mapping in the uapA promoter show that the nature of the base in the first position of an HGATAR (where H stands for A, T or C) sequence determines the relative affinity of the promoter for the wild-type and mutant forms of AreA. In vitro binding studies of wild-type and mutant AreA proteins are completely consistent with the phenotypes in vivo. Molecular models of the wild-type and mutant AreA-DNA complexes derived from the atomic coordinates of the GATA-1-AGATAA complex account both for the phenotypes observed in vivo and the binding differences observed in vitro. Our work extends the consensus of physiologically relevant binding sites from WGATAR to HGATAR, and provides a rationale for the almost universal evolutionary conservation of leucine at the seventh position of the Zn finger of GATA factors. This work shows inter alia that the sequence CGATAGagAGATAA, comprising two almost adjacent AreA-binding sites, is sufficient to ensure activation of transcription of the uapA gene.

Genetic regulation of nitrogen metabolism in the fungi

In the fungi, nitrogen metabolism is controlled by a complex genetic regulatory circuit which ensures the preferential use of primary nitrogen sources and also confers the ability to use many different secondary nitrogen sources when appropriate. Most structural genes encoding nitrogen catabolic enzymes are subject to nitrogen catabolite repression, mediated by positive-acting transcription factors of the GATA family of proteins. However, certain GATA family members, such as the yeast DAL80 factor, act negatively to repress gene expression. Selective expression of the genes which encode enzymes for the metabolism of secondary nitrogen sources is often achieved by induction, mediated by pathway-specific factors, many of which have a GAL4-like C6/Zn2 DNA binding domain. Regulation within the nitrogen circuit also involves specific protein-protein interactions, as exemplified by the specific binding of the negative-acting NMR protein with the positive-acting NIT2 protein of Neurospora crassa. Nitrogen metabolic regulation appears to play a significant role in the pathogenicity of certain animal and plant fungal pathogens.

The tamA gene of Aspergillus nidulans contains a putative zinc cluster motif which is not required for gene function

Expression of many nitrogen catabolic enzymes is controlled by nitrogen metabolite repression in Aspergillus nidulans. Although the phenotypes of tamA mutants have implicated this gene in nitrogen regulation, its function is unknown. We have cloned the tamA gene by complementation of a new tamA allele. The tamA sequence shares significant homology with the UGA35/DAL81/DURL gene of Saccharomyces cerevisiae. In vitro mutagenesis of sequences encoding a putative zinc cluster DNA binding domain indicated that this motif is not required for in vivo TamA function.

Mutational analysis of the C-terminal region of AREA, the transcription factor mediating nitrogen metabolite repression in Aspergillus nidulans

In Aspergillus nidulans the positive-acting, wide domain regulatory gene areA mediates nitrogen metabolite repression. Previous analysis demonstrated that the C-terminal 153 residues of the areA product (AREA) are inessential for at least partial expression of most genes subject to regulation by areA. Paradoxically, areAr2, a -1 frameshift replacing the wild-type 122 C-terminal residues with a mutant peptide of 117 amino acids, leads to general loss of function. To determine the basis for the areAr2 mutant phenotype, and as a means of delineating functional domains within the C-terminal region of AREA, we have selected and characterised areAr2 revertants. Deletion analysis, utilising direct gene replacement, extended this analysis. A mutant areA product truncated immediately after the last residue of the highly conserved GATA (DNA-binding) domain retains partial function. The areAr2 product retains some function with respect to the expression of uaZ (encoding urate oxidase) and the mutant allele is partially dominant with respect to nitrate reductase levels. Consistent with the areAr2 product having a debilitating biological activity, we have demonstrated that a polypeptide containing both the wild-type DNA-binding domain and the mutant C-terminus of AREA2 is able to bind DNA in vitro but no longer shows specificity for GATA sequences.

Nitrogen metabolite repression inAspergillus nidulans: an historical perspective

The paper of Arst and Cove (Mol. Gen. Genet. 126: 111 – 141, 1973) on "Nitrogen metabolite repression in Aspergillus nidulans" has influenced studies and perceptions of gene regulation in filamentous fungi during the past 21 years. Here I attempt to appraise the contributions of that paper and assess its role in further developments. Nitrogen metabolite repression, carbon catabolite repression, pathway-specific and integrated induction, as-acting regulatory mutations, a useful class of growth inhibitors, and a homologous Neurospora crassa gene are all discussed. Key words: Aspergillus nidulans, carbon catabolite repression, nitrogen metabolite repression.

Molecular cloning and analysis of nre, the major nitrogen regulatory gene of Penicillium chrysogenum

We have isolated the Penicillium chrysogenum nre gene which is homologous to the major nitrogen regulatory genes areA from Aspergillus nidulans and nit-2 from Neurospora crassa. Overall, nre shows 60% identity to areA and 30% identity to nit-2 at the amino-acid level. The gene encodes a protein of 835 amino-acid residues and contains a single Cys2/Cys2-type zinc finger with an adjacent basic region and a putative acidic activation region. In the DNA-binding domain, 98% of the amino-acid residues are identical in nre, areA and nit-2. The nre gene has been shown to be functional in N. crassa by heterologous complementation of a nit-2 mutant. Growth tests indicated that transformants could utilize nitrate, amino-acids, purines and amides as sole nitrogen sources. Nitrate reductase activity assays performed with transformants demonstrated that nitrogen control was completely normal. Complementation of N. crassa nit-2 mutants with 5'-deletion clones of nre suggests the possible presence of an internal promoter within the coding region. Northern analysis and ribonuclease protection assays of total cellular RNA indicated that nre encodes a 3.2-kb transcript which is reduced in content under conditions of nitrogen repression.

Two new genes involved in signalling ambient pH in Aspergillus nidulans

Two new genes, palH and palI, where mutations mimic the effects of acidic growth pH have been identified in Aspergillus nidulans. A palH mutation is phenotypically indistinguishable from mutations in the palA, palB, palC, and palF genes, whereas palI mutations differ only in that they allow some growth at pH 8. Mutations in palA, B, C, F, and H are epistatic to a palI mutation and the significance of this epistasis is discussed. Additionally, palE and palB mutations have been shown to be allelic. Thus, a total of six genes where mutations mimic acidic growth conditions has been identified.

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.

Evolution of transcription-regulating proteins by enzyme recruitment: molecular models for nitrogen metabolite repression and ethanol utilisation in eukaryotes

Studies on the quinic acid utilisation gene (qut) cluster in Aspergillus nidulans showed that the genes encoding transcriptional activator and repressor proteins evolved by co-opting duplicated copies of genes encoding metabolic enzymes. In order to test the hypothesis that this was a general route for the genesis of regulatory proteins, the origins of the major control protein mediating nitrogen metabolite repression (an example of inter-pathway regulation) and ethanol utilisation (an example of intra-pathway regulation) in filamentous fungi were sought. The regulatory proteins mediating nitrogen metabolite repression were deduced to have originated in a duplication of genes encoding the anthranilate synthase complex which is active in the shikimate pathway. The major protein regulating ethanol utilisation was deduced to have its origin in the fusion of duplicated genes encoding the aldehyde and alcohol dehydrogenases (ALDA and ALCA). These data strongly support the view that transcriptional regulatory proteins evolve by the recruitment of functional domains provided by metabolic enzymes.

Nitrogen regulation in fungi

Nitrogen regulation has been extensively studied in fungi revealing a complex array of interacting regulatory genes. The general characterisation of the systems in Aspergillus nidulans and Neurospora crassa shall be briefly described, but much of this paper will concentrate specifically on the recent molecular characterisation of areA, the principle regulatory gene from A. nidulans which mediates nitrogen metabolite repression. Three areas shall be explored in detail, firstly the DNA binding domain, which has been characterised extensively by both molecular and genetic analysis. Secondly we shall report recent analysis which has revealed the presence of related DNA binding activities in A. nidulans. Finally we shall discuss the mechanism by which the nitrogen state of the cell is monitored by the areA product, in particular localisation of the domain within the areA product which mediates the regulatory response within the protein.

Regulatory circuits of the amdS gene of Aspergillus nidulans

The amdS gene codes for an acetamidase enzyme that hydrolyses acetamide to acetate and ammonium thus providing A. nidulans with a source of carbon and nitrogen. The exceptionally favourable genetics of this system combined with molecular analysis have enabled many regulatory circuits affecting amdS to be identified genetically. Characterization of the regulatory genes and the definition of the cis-acting sites involved have been done using both in vivo and in vitro mutagenesis. Recent results on the analysis of the system are presented.