BackgroundThe fungal genus Aspergillus is of critical importance to humankind. Species include those with industrial applications, important pathogens of humans, animals and crops, a source of potent carcinogenic contaminants of food, and an important genetic model. The genome sequences of eight aspergilli have already been explored to investigate aspects of fungal biology, raising questions about evolution and specialization within this genus.ResultsWe have generated genome sequences for ten novel, highly diverse Aspergillus species and compared these in detail to sister and more distant genera. Comparative studies of key aspects of fungal biology, including primary and secondary metabolism, stress response, biomass degradation, and signal transduction, revealed both conservation and diversity among the species. Observed genomic differences were validated with experimental studies. This revealed several highlights, such as the potential for sex in asexual species, organic acid production genes being a key feature of black aspergilli, alternative approaches for degrading plant biomass, and indications for the genetic basis of stress response. A genome-wide phylogenetic analysis demonstrated in detail the relationship of the newly genome sequenced species with other aspergilli.ConclusionsMany aspects of biological differences between fungal species cannot be explained by current knowledge obtained from genome sequences. The comparative genomics and experimental study, presented here, allows for the first time a genus-wide view of the biological diversity of the aspergilli and in many, but not all, cases linked genome differences to phenotype. Insights gained could be exploited for biotechnological and medical applications of fungi.Electronic supplementary materialThe online version of this article (doi:10.1186/s13059-017-1151-0) contains supplementary material, which is available to authorized users.
In Aspergillus nidulans, purine uptake is mediated by three transporter proteins: UapA, UapC and AzgA. UapA and UapC have partially overlapping functions, are 62% identical and have nearly identical predicted topologies. Their structural similarity is associated with overlapping substrate specificities; UapA is a highaffinity, high-capacity specific xanthine/uric acid transporter. UapC is a low/moderate-capacity general purine transporter. We constructed and characterized UapA/ UapC, UapC/UapA and UapA/UapC/UapA chimeric proteins and UapA point mutations. The region including residues 378-446 in UapA (336-404 in UapC) has been shown to be critical for purine recognition and transport. Within this region, we identified: (i) one amino acid residue (A404) important for transporter function but probably not for specificity and two residues (E412 and R414) important for UapA function and specificity; and (ii) a sequence, (F/Y/S)X(Q/E/P) NXGXXXXT(K/R/G), which is highly conserved in all homologues of nucleobase transporters from bacteria to man. The UapC/UapA series of chimeras behaves in a linear pattern and leads to an univocal assignment of functional domains while the analysis of the reciprocal and 'sandwich' chimeras revealed unexpected inter-domain interactions. cDNAs coding for transporters including the specificity region defined by these studies have been identified for the first time in the human and Caenorhabditis elegans databases.
The proline utilisation gene cluster of Aspergillus nidulans can be repressed efficiently only when both repressing nitrogen and repressing carbon sources are present. We show that two cis-acting mutations in this cluster permit the efficient transcription of the prnB gene under repressing conditions, resulting in direct or indirect derepression of two other transcripts of the pathway. These mutations are transitions that define a 5'GAGACCCC3' sequence. Similar sequences are found upstream of other genes subject to carbon catabolite repression. We propose that this sequence defines the binding site for the negatively-acting CreA protein, which mediates carbon catabolite repression in this fungus.
Eisosomes are subcortical organelles implicated in endocytosis and have hitherto been described only in Saccharomyces cerevisiae. They comprise two homologue proteins, Pil1 and Lsp1, which colocalize with the transmembrane protein Sur7. These proteins are universally conserved in the ascomycetes. We identify in Aspergillus nidulans (and in all members of the subphylum Pezizomycotina) two homologues of Pil1/Lsp1, PilA and PilB, originating from a duplication independent from that extant in the subphylum Saccharomycotina. In the aspergilli there are several Sur7-like proteins in each species, including one strict Sur7 orthologue (SurG in A. nidulans). In A. nidulans conidiospores, but not in hyphae, the three proteins colocalize at the cell cortex and form tightly packed punctate structures that appear different from the clearly distinct eisosome patches observed in S. cerevisiae. These structures are assembled late during the maturation of conidia. In mycelia, punctate structures are present, but they are composed only of PilA, while PilB is diffused in the cytoplasm and SurG is located in vacuoles and endosomes. Deletion of each of the genes does not lead to any obvious growth phenotype, except for moderate resistance to itraconazole. We could not find any obvious association between mycelial (PilA) eisosome-like structures and endocytosis. PilA and SurG are necessary for conidial eisosome organization in ways that differ from those for their S. cerevisiae homologues. These data illustrate that conservation of eisosomal proteins within the ascomycetes is accompanied by a striking functional divergence.
SummaryIn Aspergillus nidulans a highly specific L-proline transporter is encoded by the prnB gene which is tightly linked to all other genes involved in proline catabolism. In mycelia, the expression of the prn structural genes is finely co-regulated in response to proline induction and nitrogen/carbon catabolite repression. In this study we establish that prnB expression is also activated during germination of conidiospores. This activation persists until the development of 6 h-old mycelia and it is independent of proline induction mediated by the pathway-specific prnA gene product. We then show that, in mycelia, prnB transcription is activated in response to proline or histidine starvation. This process has two components: a prnA-dependent and a prnA-independent component. A cis-acting element that conforms to the consensus target of the GCN4/CPC1 transcriptional activators mediating amino acid biosynthesis activation in other fungi is involved in the activation of prnB transcription in response to amino acid starvation. We also show that the stimulation of prnB expression in germinating conidiospores is not due exclusively to transient internal amino acid starvation occurring during the transition from conidiospore to mycelium. This is the first report that an amino acid transporter gene is upregulated during development and in response to amino acid starvation and specific amino acid induction.
We identified agtA, a gene that encodes the specific dicarboxylic amino acid transporter of Aspergillus nidulans. The deletion of the gene resulted in loss of utilization of aspartate as a nitrogen source and of aspartate uptake, while not completely abolishing glutamate utilization. Kinetic constants showed that AgtA is a high-affinity dicarboxylic amino acid transporter and are in agreement with those determined for a cognate transporter activity identified previously. The gene is extremely sensitive to nitrogen metabolite repression, depends on AreA for its expression, and is seemingly independent from specific induction. We showed that the localization of AgtA in the plasma membrane necessitates the ShrA protein and that an active process elicited by ammonium results in internalization and targeting of AgtA to the vacuole, followed by degradation. Thus, nitrogen metabolite repression and ammonium-promoted vacuolar degradation act in concert to downregulate dicarboxylic amino acid transport activity.Amino acids can be utilized by saprophytic fungi as nitrogen and/or carbon sources. Their uptake is mediated by transmembrane proteins belonging to the specific fungal YAT (TC 2.A.3.10, yeast amino acid transporter) family, a member of the APC (amino acid polyamine choline) superfamily (25), which shows a wide range of substrate specificities and includes representatives in all realms of life (53). In Saccharomyces cerevisiae (51), 18 YAT transporters have been functionally characterized, while only a few have been studied in other organisms (8,25,35,57,67,68,69,72,76; Saccharomyces genome database at http://www.yeastgenome.org/). The YAT family transporters share a common predicted topology, comprising 12 transmembrane domains, and show, even among proteins with completely different substrate specificities, a high degree of sequence identity (2, 25). The transporters of the dicarboxylic amino acids glutamate and aspartate have been characterized in S. cerevisiae (DIP5; 47) and Penicillium chrysogenum (PcDIP5; 68) and are members of this family. In A. nidulans, specific dicarboxylic amino acid transport activity and certain aspects of its regulation were previously reported (24, 26, 42, 51, 52), but the corresponding gene(s) was not characterized.In fungi, the genes that encode transporters and enzyme activities involved in nitrogen source utilization are subject to tight transcriptional and/or posttranscriptional controls. Preferred nitrogen sources (such as ammonium and glutamine) repress the transcription of genes involved in the utilization of metabolically less favorable nitrogen sources such as nitrate, purines, or amino acids. In A. nidulans, nitrogen metabolite repression acts by inactivating the AreA GATA transcriptional activator (30) by a number of concurring mechanisms (36, 66). In S. cerevisiae, a transcriptional repression mechanism similar but not identical to the one described above for A. nidulans is operative (see reference 33 for a review).In addition to being subject to transcriptional regulati...
In Aspergillus nidulans, the gene prnB encoding the major proline transport system is one of a cluster of four genes necessary and sufficient for the utilization of proline as sole nitrogen and/or carbon source. The prn cluster has been cloned and the sequence and transcript map of the prnB gene are presented in this paper. The predicted translated sequence consists of 570 amino acids, resulting in a molecular weight of 63,028 Daltons. Its hydropathy profile shows 10 hydrophobic segments typical of integral membrane proteins. No N-terminal hydrophobic signal peptide is present, the N-terminal and C-terminal ends of the protein being hydrophilic. Similar results were previously found for the arginine and histidine transporters of Saccharomyces cerevisiae, with which the prnB transporter shares regions of highly conserved amino acid sequences. Using S1 mapping and Northern blot analyses, we confirm the presence of a unique inducible prnB transcript of 1.9 kb.
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