Roles of the Aspergillus nidulans homologues of Tup1 and Ssn6 in chromatin structure and cell viability.

For three different carbon catabolite repressible promoters, alcA, alcR and the bidirectional promoter prnD-prnB, a deletion of rcoA, the Aspergillus nidulans homologue of TUP1, does not result in carbon catabolite derepression. Surprisingly, it results in disruption of the chromatin default structure of alcR and prnD-prnB promoters. In these promoters, and at variance with the wild type, repression occurs in the absence of nucleosome positioning. For alcR, repression occurs together with a nucleosome pattern identical to that found under conditions of full expression, and for prnD-prnB it occurs with a novel pattern that does not correspond to the pattern seen under conditions of repression in a wild-type strain. Deletion of the putative RcoA partner, SsnF, is lethal in A. nidulans.

Functional analysis of alcS, a gene of the alc cluster in Aspergillus nidulans.

The ethanol utilization pathway (alc system) of Aspergillus nidulans requires two structural genes, alcA and aldA, which encode the two enzymes (alcohol dehydrogenase and aldehyde dehydrogenase, respectively) allowing conversion of ethanol into acetate via acetyldehyde, and a regulatory gene, alcR, encoding the pathway-specific autoregulated transcriptional activator. The alcR and alcA genes are clustered with three other genes that are also positively regulated by alcR, although they are dispensable for growth on ethanol. In this study, we characterized alcS, the most abundantly transcribed of these three genes. alcS is strictly co-regulated with alcA, and encodes a 262-amino acid protein. Sequence comparison with protein databases detected a putative conserved domain that is characteristic of the novel GPR1/FUN34/YaaH membrane protein family. It was shown that the AlcS protein is located in the plasma membrane. Deletion or overexpression of alcS did not result in any obvious phenotype. In particular, AlcS does not appear to be essential for the transport of ethanol, acetaldehyde or acetate. Basic Local Alignment Search Tool analysis against the A. nidulans genome led to the identification of two novel ethanol- and ethylacetate-induced genes encoding other members of the GPR1/FUN34/YaaH family, AN5226 and AN8390.

Patterns of nucleosomal organization in the alc regulon of Aspergillus nidulans: roles of the AlcR transcriptional activator and the CreA global repressor.

We have studied the chromatin organization of three promoters of the alc regulon of Aspergillus nidulans. No positioned nucleosomes are seen in the aldA (aldehyde dehydrogenase) promoter under any physiological condition tested by us. In the alcA (alcohol dehydrogenase I) and alcR (coding for the pathway-specific transcription factor) promoters, a pattern of positioned nucleosomes is seen under non-induced and non-induced repressed conditions. While each of these promoters shows a specific pattern of chromatin restructuring, in both cases induction results in loss of nucleosome positioning. Glucose repression in the presence of inducer results in a specific pattern of partial positioning in the alcA and alcR promoters. Loss of nucleosome positioning depends absolutely on the AlcR protein and it is very unlikely to be a passive result of the induction of transcription. In an alcR loss-of-function background and in strains carrying mutations of the respective AlcR binding sites of the alcA and alcR promoters, nucleosomes are fully positioned under all growth conditions. Analysis of mutant AlcR proteins establishes that all domains needed for transcriptional activation and chromatin restructuring are included within the first 241 residues. The results suggest a two-step process, one step resulting in chromatin restructuring, a second one in transcriptional activation. Partial positioning upon glucose repression shows a specific pattern that depends on the CreA global repressor. An alcR loss-of-function mutation is epistatic to a creA loss-of-function mutation, showing that AlcR does not act by negating a nucleosome positioning activity of CreA.

Relationships between the ethanol utilization (alc) pathway and unrelated catabolic pathways in Aspergillus nidulans.

The ethanol utilization pathway in Aspergillus nidulans is a model system, which has been thoroughly elucidated at the biochemical, genetic and molecular levels. Three main elements are involved: (a) high level expression of the positively autoregulated activator AlcR; (b) the strong promoters of the structural genes for alcohol dehydrogenase (alcA) and aldehyde dehydrogenase (aldA); and (c) powerful activation of AlcR by the physiological inducer, acetaldehyde, produced from growth substrates such as ethanol and l-threonine. We have previously characterized the chemical features of direct inducers of the alc regulon. These studies allowed us to predict which type of carbonyl compounds might induce the system. In this study we have determined that catabolism of different amino acids, such as L-valine, L-isoleucine, L-arginine and L-proline, produces aldehydes that are either not accumulated or fail to induce the alc system. On the other hand, catabolism of D-galacturonic acid and putrescine, during which aldehydes are transiently accumulated, gives rise to induction of the alc genes. We show that the formation of a direct inducer from carboxylic esters does not depend on alcA-encoded alcohol dehydrogenase I or on AlcR, and suggest that a cytochrome P450 might be responsible for the initial formation of a physiological aldehyde inducer.

Nuclear import of zinc binuclear cluster proteins proceeds through multiple, overlapping transport pathways.

In Aspergillus nidulans, the high transcriptional level of the ethanol utilization pathway genes (alc) is regulated by the specific activator AlcR. Here we have analyzed the mechanism of the nuclear import of AlcR, as well as that of other proteins belonging to the Zn(2)Cys(6) binuclear cluster family. The nuclear localization signal of AlcR maps within the N-terminal 75 amino acid residues and overlaps with its DNA-binding domain. It consists of five clusters rich in basic residues. Four of them are necessary and sufficient for nuclear targeting. The first two basic regions are crucial for both nuclear localization and recognition of AlcR-specific DNA targets. This nuclear localization signal (NLS) motif is recognized by the nuclear transport machinery of Saccharomyces cerevisiae and requires both Ran/Gsp1p activity and specific transport receptors. AlcR can be imported into nuclei via multiple transport pathways mediated by a distinct set of karyopherins composed of Kap104p, Sxm1p, and Nmd5p transport receptors. The two former karyopherins interact with the NLS of AlcR directly. Other Zn binuclear cluster proteins from S. cerevisiae, such as Gal4p and Pdr3p, also appear to be transported to the nuclei in a nonclassical, importin-alpha-independent manner and can share common importin beta receptors.

Onset of carbon catabolite repression in Aspergillus nidulans. Parallel involvement of hexokinase and glucokinase in sugar signaling.

The role of hexose phosphorylating enzymes in the signaling of carbon catabolite repression was investigated in the filamentous fungus Aspergillus nidulans. A d-fructose non-utilizing, hexokinase-deficient (hxkA1, formerly designated frA1) strain was utilized to obtain new mutants lacking either glucokinase (glkA4) or both hexose kinases (hxkA1/glkA4). d-Glucose and d-fructose phosphorylation is completely abolished in the double mutant, which consequently cannot grow on either sugar. The glucokinase single mutant exhibits no nutritional deficiencies. Three repressible diagnostic systems, ethanol utilization (alcA and alcR genes), xylan degradation (xlnA), and acetate catabolism (facA), were analyzed in these hexose kinase mutants at the transcript level. Transcriptional repression by d-glucose is fully retained in the two single kinase mutants, whereas the hexokinase mutant is partially derepressed for d-fructose. Thus, hexokinase A and glucokinase A compensate each other for carbon catabolite repression by d-glucose in the single mutants. In contrast, both d-glucose and d-fructose repression are severely impaired for all three diagnostic systems in the double mutant. Unlike the situation in Saccharomyces cerevisiae, the hexose phosphorylating enzymes play parallel roles in glucose repression in A. nidulans.

Characteristics of physiological inducers of the ethanol utilization (alc) pathway in Aspergillus nidulans.

The ethanol utilization (alc) pathway in Aspergillus nidulans is one of the strongest expressed gene systems in filamentous fungi. The pathway-specific activator AlcR requires the presence of an inducing compound to activate transcription of genes under its control. We have demonstrated recently that acetaldehyde is the sole physiological inducer of ethanol catabolism. In the present study we show that compounds with catabolism related to that of ethanol, i.e. primary alcohols, primary monoamines and l-threonine, act as inducers because their breakdown results in the production of inducing aliphatic aldehydes. Such aldehydes were shown to induce the alc genes efficiently at low external concentrations. When ethanol is mixed with representatives of another class of strong direct inducers, ketones, the physiological inducer, acetaldehyde, prevails as effector. Although direct inducers essentially carry a carbonyl function, not all aldehydes and ketones act as inducers. Structural features discriminating non-inducing from inducing compounds concern: (i) the length of the aliphatic side group(s); (ii) the presence and nature of any non-aliphatic substituent. These characteristics enable us to predict whether or not a given carbonyl compound will induce the alc genes.