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.     

The CCAAT-binding complex of eukaryotes: evolution of a second NLS in the HapB subunit of the filamentous fungus Aspergillus nidulans despite functional conservation at the molecular level between yeast, A.nidulans and human

The heterotrimeric CCAAT-binding complex is evolutionarily conserved in eukaryotic organisms, including fungi, plants and mammals. In the filamentous fungus Aspergillus nidulans, the corresponding complex was designated AnCF (A.nidulans CCAAT-binding factor). AnCF consists of the subunits HapB, HapC and HapE. All three subunits are necessary for DNA binding. HapB contains two putative nuclear localisation signal sequences (NLSs) designated NLS1 and NLS2. Previously, it was shown that only NLS2 was required for nuclear localisation of HapB. Furthermore, HapC and HapE are transported to the nucleus only in complex with HapB via a piggy back mechanism. Here, by using various GFP constructs and by establishing a novel marker gene for transformation of A.nidulans, i.e. the pabaA gene encoding p-aminobenzoic acid synthase, it was shown that the HapB homologous proteins of both Saccharomyces cerevisiae (Hap2p) and human (NF-YA) use an NLS homologous to HapB NLS1 for nuclear localisation in S.cerevisiae. Interestingly, for A.nidulans HapB, NLS1 was sufficient for nuclear localisation in S.cerevisiae. In A.nidulans, HapB NLS1 was also functional when present in a different protein context. However, in A.nidulans, both S.cerevisiae Hap2p and human NF-YA entered the nucleus only when HapB NLS2 was present in the respective proteins. In that case, both proteins Hap2p and NF-YA complemented, at least in part, the hap phenotype of A.nidulans with respect to lack of growth on acetamide. Similarly, A.nidulans HapB and human NF-YA complemented a hap2 mutant of S.cerevisiae. In summary, HapB, Hap2p and NF-YA are interchangeable. Because the A.nidulans hapB mutant was complemented, at least in part, by both the human NF-YA and S.cerevisiae Hap2p this finding suggests that the piggy-back mechanism of nuclear transport found for A.nidulans is conserved in yeast and human.     

Cross regulation of four GATA factors that control nitrogen catabolic gene expression in Saccharomyces cerevisiae.

Nitrogen catabolic gene expression in Saccharomyces cerevisiae has been reported to be regulated by three GATA family proteins, the positive regulators Gln3p and Gat1p/Nil1p and the negative regulator Dal80p/Uga43p. We show here that a fourth member of the yeast GATA family, the Dal80p homolog Deh1p, also negatively regulates expression of some, but not all, nitrogen catabolic genes, i.e., GAP1, DAL80, and UGA4 expression increases in a deh1 delta mutant. Consistent with Deh1p regulation of these genes is the observation that Deh1p forms specific DNA-protein complexes with GATAA-containing UGA4 and GAP1 promoter fragments in electrophoretic mobility shift assays. Deh1p function is demonstrable, however, only when a repressive nitrogen source such as glutamine is present; deh1 delta mutants exhibit no detectable phenotype with a poor nitrogen source such as proline. Our experiments also demonstrate that GATA factor gene expression is highly regulated by the GATA factors themselves in an interdependent manner. DAL80 expression is Gln3p and Gat1p dependent and Dal80p regulated. Moreover, Gln3p and Dal80p bind to DAL80 promoter fragments. In turn, GAT1 expression is Gln3p dependent and Dal80p regulated but is not autogenously regulated like DAL80. DEH1 expression is largely Gln3p independent, modestly Gat1p dependent, and most highly regulated by Dal80p. Paradoxically, the high-level DEH1 expression observed in a dal80::hisG disruption mutant is highly sensitive to nitrogen catabolite repression.     

The glucose repressor CRE1 from Sclerotinia sclerotiorum is functionally related to CREA from Aspergillus nidulans but not to the Mig proteins from Saccharomyces cerevisiae.

We isolated the putative glucose repressor gene cre1 from the phytopathogenic fungus Sclerotinia sclerotiorum. cre1 encodes a 429 amino acid protein 59% similar to the carbon catabolite repressor CREA from Aspergillus nidulans. In addition to the overall amino acid sequence relatedness between CRE1 and CREA proteins, cre1 can functionally complement the A. nidulans creAd30 mutation as assessed by repression of the alcohol dehydrogenase I gene expression. The CREI region carrying the two zinc fingers is also very similar to the DNA binding domains of the Saccharomyces cerevisiae glucose repressors Mig1p and Mig2p. Despite the presence in the CRE1 protein of several motifs involved in the regulation of Miglp activity, cre1 cannot complement mig deficiencies in S. cerevisiae. These data suggest that glucose repression pathways may have evolved differently in yeasts and filamentous fungi.     

Regulation by carbon and nitrogen sources of a family of cellulases in Aspergillus nidulans

The total amount of Aspergillus nidulans secreted cellulases is affected by both the carbon and nitrogen source present in the medium, and is regulated directly and/or indirectly by the carbon metabolism regulators, CreA, CreB, and CreC, and the global nitrogen metabolism regulator, AreA. We have characterized two A. nidulans genes that encode exo-cellulases, and one gene that encodes an endo-cellulase which is additional to the previously described endo-cellulase encoding gene, eglA. The putative regulatory regions 5(') of all the genes contain potential binding sites for the global carbon and nitrogen regulatory proteins, CreA and AreA. The sequences 5(') of eglA and eglB also contain potential consensus binding sites for XlnR which is involved in induction in Aspergillus niger, but none of the 5(') sequences contains an exact copy of the AceII DNA binding consensus sequence involved in induction in Trichoderma reesei, and thus it is likely that they may be induced by different pathway specific regulatory proteins.     

Sumoylation in Aspergillus nidulans: sumO inactivation, overexpression and live-cell imaging

Sumoylation, the reversible covalent attachment of small ubiquitin-like modifier (SUMO) peptides has emerged as an important regulator of target protein function. In Saccharomyces cerevisiae, but not in Schizosaccharyomes pombe, deletion of the gene encoding SUMO peptides is lethal. We have characterized the SUMO-encoding gene, sumO, in the filamentous fungus Aspergillus nidulans. The sumO gene was deleted in a diploid and sumODelta haploids were recovered. The mutant was viable but exhibited impaired growth, reduced conidiation and self-sterility. Overexpression of epitope-tagged SumO peptides revealed multiple sumoylation targets in A. nidulans and SumO overexpression resulted in greatly increased levels of protein sumoylation without obvious phenotypic consequences. Using five-piece fusion PCR, we generated a gfp-sumO fusion gene expressed from the sumO promoter for live-cell imaging of GFP-SumO and GFP-SumO-conjugated proteins. Localization of GFP-SumO is dynamic, accumulating in punctate spots within the nucleus during interphase, lost at the onset of mitosis and re-accumulating during telophase.     

Suppression of the bimC4 mitotic spindle defect by deletion of klpA, a gene encoding a KAR3-related kinesin-like protein in Aspergillus nidulans

To investigate the relationship between structure and function of kinesin-like proteins, we have identified by polymerase chain reaction (PCR) a new kinesin-like protein in the filamentous fungus Aspergillus nidulans, which we have designated KLPA. DNA sequence analysis showed that the predicted KLPA protein contains a COOH terminal kinesin-like motor domain. Despite the structural similarity of KLPA to the KAR3 and NCD kinesin-like proteins of Saccharomyces cerevisiae and Drosophila melanogaster, which also posses COOH-terminal kinesin-like motor domains, there are no significant sequence similarities between the nonmotor or tail portions of these proteins. Nevertheless, expression studies in S. cerevisiae showed that klpA can complement a null mutation in KAR3, indicating that primary amino acid sequence conservation between the tail domains of kinesin-like proteins is not necessarily required for conserved function. Chromosomal deletion of the klpA gene exerted no observable mutant phenotype, suggesting that in A. nidulans there are likely to be other proteins functionally redundant with KLPA. Interestingly, the temperature sensitive phenotype of a mutation in another gene, bimC, which encodes a kinesin-like protein involved in mitotic spindle function in A. nidulans, was suppressed by deletion of klpA. We hypothesize that the loss of KLPA function redresses unbalanced forces within the spindle caused by mutation in bimC, and that the KLPA and BIMC kinesin-like proteins may play opposing roles in spindle function.     

Mutants of Aspergillus nidulans lacking nicotinamide adenine dinucleotide-specific glutamate dehydrogenase.

Ten mutants of Aspergillus nidulans lacking nicotinamide adenine dinucleotide-specific glutamate dehydrogenase (NAD-GDH) have been isolated, and their mutations (gdhB1 through gdhB10) have been shown to lie in the gdhB gene. In addition, a temperature-sensitive gdhB mutant (gdhB11) has been isolated. A revertant (designated R-5) of the mutant gdhB1 bears an additional lesion in the gdhB gene and has altered NAD-GDH activity with altered Km values for ammonia or ammonium ions and for alpha-ketoglutarate. These results suggest that gdhB specifies a structural component for NAD-GDH. The growth characteristics of gdhB mutants indicate the routes by which amino acids are utilized as nitrogen and carbon energy sources. The properties are described of the double mutants bearing the mutations gdhB1 and gdhA1 or tamA119, which have low NADP-GDH activity.