A single mutation leads to loss of glutamine synthetase and relief of ammonium repression in Aspergillus

Isolation and characterization of a methylammonium resistant mutant of Neurospora crassa

A mutant of Neurospora crassa has been isolated which is resistant to methylammonium, a structural analog of ammonium. In contrast to wild type, this mutant, mea-1, has derepressed nitrate reductase and nitrite reductase activities in the presence of ammonium. However, glutamine still represses these nitrate assimilation enzymes in mea-1. The nit-2 mutant was epistatic to mea-1 since the mea-1; nit-2 double mutant has the nit-2 mutant phenotype. In addition, mea-1; nit-2 double mutants cannot utilize ammonium as a nitrogen source. We suggest therefore that nit-2 and mea-1 loci play a role in ammonia/methylamine uptake.

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.

Deletion of the Gibberella fujikuroi glutamine synthetase gene has significant impact on transcriptional control of primary and secondary metabolism

In Gibberella fujikuroi, the gibberellin (GA) and bikaverin biosynthesis are under control of nitrogen metabolite repression. However, the signalling components acting upstream of AREA are still unknown. We investigated the role of glutamine synthetase (GS) both as an enzyme and as a possible regulator in the nitrogen regulation system. We cloned and replaced the GS-encoding gene, glnA-Gf. The mutants grow with a phenotype different from the wild type in the presence of glutamine. They were unable to express nitrogen-repressed GA and bikaverin biosynthetic genes even under nitrogen starvation conditions. Complementation with the glnA-Gf wild-type copy fully restored GS activity, the expression of secondary metabolism genes, and the production of GAs and the red pigment, bikaverin. In order to find more target genes of GS, differential cDNA-screening and differential hybridization of macroarrays were performed using cDNA from the wild type and DeltaglnA mutant as probes. Several genes were dramatically up- or downregulated in the mutant. Among them are genes involved in N- and C-catabolism, and in transcriptional and translation control. Some of these genes are also under AREA control. Treatment with the GS inhibitor l-methionine sulphoximine resulted in similar expression patterns as in the glnA mutant with ammonium as nitrogen source, whereas glutamine can overcome the up- or downregulation of most but not all of the target genes. These findings suggest that not only glutamine, but also GS itself might play an important role in nitrogen metabolite repression.

Role of glutamine synthetase in nitrogen metabolite repression in Aspergillus nidulans

Glutamine synthetase (GS), EC 6.3.1.2, is a central enzyme in the assimilation of nitrogen and the biosynthesis of glutamine. We have isolated the Aspergillus nidulans glnA gene encoding GS and have shown that glnA encodes a highly expressed but not highly regulated mRNA. Inactivation of glnA results in an absolute glutamine requirement, indicating that GS is responsible for the synthesis of this essential amino acid. Even when supplemented with high levels of glutamine, strains lacking a functional glnA gene have an inhibited morphology, and a wide range of compounds have been shown to interfere with repair of the glutamine auxotrophy. Heterologous expression of the prokaryotic Anabaena glnA gene from the A. nidulans alcA promoter allowed full complementation of the A. nidulans glnADelta mutation. However, the A. nidulans fluG gene, which encodes a protein with similarity to prokaryotic GS, did not replace A. nidulans glnA function when similarly expressed. Our studies with the glnADelta mutant confirm that glutamine, and not GS, is the key effector of nitrogen metabolite repression. Additionally, ammonium and its immediate product glutamate may also act directly to signal nitrogen sufficiency.

Characterization of nitrogen metabolite signalling in Aspergillus via the regulated degradation of areA mRNA

AreA is the principal transcription factor involved in determining nitrogen utilization in Aspergillus nidulans. NH4+ and Gln are utilized preferentially but in their absence, AreA acts to facilitate the expression of genes involved in metabolizing alternative nitrogen sources. It is crucial to the function of AreA that its expression is tightly modulated by the quality and availability of nitrogen sources. One signalling mechanism involves regulated degradation of the areA transcript in response to NH4+ and Gln, which provides the first direct means of monitoring nitrogen signalling in this fungus. Here we assess the specificity of the transcript degradation response, determining that it responds qualitatively to a variety of additional nitrogen sources including Asn. Furthermore, the response to Gln and NH4+ requires the same discrete region of the areA 3'-UTR but both NH4+ and Asn need to be metabolized to Gln before they are effective as a signal. However, NH4+ signalling is independent of AreA activity, unlike Gln and Asn signalling. A mutation in the structural gene for NADP-linked glutamate dehydrogenase, gdhA, which disrupts metabolism of NH4+ to Glu, is additive with mutations in two distinct regions of areA that disrupt the previously identified signalling mechanisms. The triple mutant is both strongly derepressed and expresses very high levels of nitrate reductase activity. These data suggest nitrogen metabolism in A. nidulans is in part regulated in response to the intracellular levels of Gln via the regulated degradation of areA mRNA, but the intracellular Gln level is not the sole determinant of nitrogen metabolite repression.

Characterization of the role of the FluG protein in asexual development of Aspergillus nidulans

We showed previously that a DeltafluG mutation results in a block in Aspergillus nidulans asexual sporulation and that overexpression of fluG activates sporulation in liquid-submerged culture, a condition that does not normally support sporulation of wild-type strains. Here we demonstrate that the entire N-terminal region of FluG ( approximately 400 amino acids) can be deleted without affecting sporulation, indicating that FluG activity resides in the C-terminal half of the protein, which bears significant similarity with GSI-type glutamine synthetases. While FluG has no apparent role in glutamine biosynthesis, we propose that it has an enzymatic role in sporulation factor production. We also describe the isolation of dominant suppressors of DeltafluG(dsg) that should identify components acting downstream of FluG and thereby define the function of FluG in sporulation. The dsgA1 mutation also suppresses the developmental defects resulting from DeltaflbA and dominant activating fadA mutations, which both cause constitutive induction of the mycelial proliferation pathway. However, dsgA1 does not suppress the negative influence of these mutations on production of the aflatoxin precursor, sterigmatocystin, indicating that dsgA1 is specific for asexual development. Taken together, our studies define dsgA as a novel component of the asexual sporulation pathway.

The Aspergillus nidulans fluG gene is required for production of an extracellular developmental signal and is related to prokaryotic glutamine synthetase I

Mutations in the Aspergillus nidulans fluG gene disrupt the programmed induction of asexual sporulation and result in formation of fluffy colonies that are characterized by undifferentiated cotton-like masses of vegetative cells. We show that the fluG mutant phenotype is suppressed when fluG mutant colonies are grown next to wild-type colonies even if the two strains are separated by dialysis membrane with a 6000- to 8000-dalton pore size. fluG encodes a cytoplasmically localized approximately 96,000-dalton polypeptide that is present at relatively constant levels during vegetative growth and following developmental induction. Sequence analysis of fluG demonstrated that the carboxy-terminal 436 amino acids predicted by the 864-codon FluG open reading frame shares approximately 28% identity with GSI-type prokaryotic glutamine synthetases. We consider it unlikely that FluG functions in synthesis of glutamine but instead propose that FluG functions as a GSI-related enzyme in synthesizing an extracellular signal directing asexual sporulation and perhaps other aspects of colony growth. The relationships between fluG and other genes identified by fluffy mutants are discussed.

Isolation of a DNA fragment which complements glutamine synthetase deficient strains of S. pombe

From a gene bank of S. pombe DNA, a 5.6 kb clone was isolated which complemented mutants defective in glutamine synthetase (GS) activity. Sub-cloning fragments of this 5.6 kb clone showed that the complementing activity was localised in a 1.6 kb HindIII-AvaI fragment and a partial DNA sequence revealed an open reading frame preceded by TATA sequences and a TGACTA sequence. Plasmid constructs carrying up to 3.4 kb of DNA used to transform gln- strains gave transformants which showed a wide range of GS activity, in some cases 100 times the wild-type level. These constructs identify DNA sequences lying downstream from the putative coding sequence which have effects on the total amount of enzyme activity, but do not affect the control imposed by the nitrogen source on which the cells are grown.

Multiple copies of the amdS gene of Aspergillus nidulans cause titration of trans-acting regulatory proteins

It has been established that a plasmid containing the amdS gene of Aspergillus nidulans may be used to transform amdS+ strains by selecting for increased utilization of acetamide as sole nitrogen source. Analysis of transformants has shown that multiple tandem copies of the plasmid can be integrated into the chromosome, commonly at sites other than the amdS locus. While the transformed phenotype was relatively stable through mitotic and meiotic divisions evidence was found for variation in plasmid copy number presumably due to unequal recombination events. Expression of the integrated amdS genes was related to copy number, and the amdS RNA produced was similar in size to wild-type RNA. Evidence for titration of the product of the regulatory gene amdR by multiple copies of amdS was found. No titration of the product of the areA gene was observed, and amdS expression was still dependent on areA function. Multiple copies of the amdI9 mutation resulted in poor growth on acetate. This was not observed in the case of the amdS+ gene. The cis-acting amdI9 mutation causes increased facB dependent acetate induction of amdS expression. Titration of the facB gene produce by amdI9 DNA, but not by amdS+ DNA, therefore suggested that the mutation results in increased affinity for the facB gene product.

Regulation of amino acid utilization in Neurospora crassa: effect of nmr-1 and ms-5 mutations

The effect of the nmr-1 and ms-5 mutations, which lead to insensitivity to glutamine-mediated nitrogen metabolite repression, was examined with respect to extracellular deaminase production by Neurospora crassa. Deaminase production normally requires nitrogen limitation, but these mutations eliminated this requirement and allowed production of deaminase activity under nitrogen metabolite repressing conditions. Demonstration of normal glutamine transport by both strains eliminated the possibility that these mutations exerted their effects through repressor exclusion. We have proposed a new working model for nitrogen regulation in Neurospora based on the findings that these mutations affected a nitrogen-regulated activity in addition to those activities originally reported and that the mutations are genetically very closely linked and likely allelic.