First experimental evidence of a zinc binuclear cluster in AlcR protein, mutational and X-ray absorption studies.

AlcR is the transcriptional activator of the ethanol utilization pathway in Aspergillus nidulans. The zinc DNA-binding domain contains ligands of zinc, six cysteines (Zn2Cys6) or five cysteines and one histidine (Zn2Cys5His). The utilisation of complementary approaches such as X-ray absorption spectroscopy, mutational analysis, zinc content evaluation, determination of specific binding connecting structural and biological data, have allowed to determine zinc environment and to analyse the involvement of amino acids. The determination by EXAFS of zinc ligands (four sulphur atoms), the Zn content in the protein (2:1), the evaluation of the distance between two zinc atoms (3.16 +/- 0.02 angstroms), together with the total loss of specific DNA-binding activity when one cysteine ligand is mutated, are in favour of a zinc cluster model in which six cysteine sulphurs ligate two zinc atoms. XANES spectra of wild type and H10A AlcR protein are virtually identical indicating that Histidine 10 does not have a direct contribution in zinc ligation but electrophoretic mobility shift assays show that His10 is involved in DNA-binding. In contrast, proline 25 does not seem to play any direct role in the DNA-binding activity but XANES spectra of Pro25A AlcR protein are slightly modified comparing to the wild type protein spectra. This suggests a role of the proline in the stabilisation of the Zn cluster structure. AlcR DNA-binding domain belongs to the zinc binuclear class family (Zn2Cys6) with unique characteristics resulting from its primary and secondary structures and its binding specificity toward direct and inverted repeat target.

Relationship between zinc content and DNA-binding activity of the DNA-binding motif of the transcription factor ALCR in Aspergillus nidulans.

The transcription factor ALCR of the ethanol utilisation pathway in Aspergillus nidulans contains a zinc binuclear motif (CysX2CysX6CysX16CysX2CysX6Cys), within the DNA-binding domain located in the N-terminal region of the ALCR protein. Specific targets have been localised in the promoter of the alcR gene, involved in the autoregulation process, and in the promoter of the structural gene alcA (encoding alcohol dehydrogenase I), which is also under the control of ALCR. The DNA-binding domain has been expressed in-Escherichia coli as a GST-ALCR (7-58*) fusion protein and also obtained as an ALCR (7-58*) peptide. Both the ALCR fusion protein and the ALCR peptide are able to bind 65Zn(II) in vitro, if reduction of cysteines occurs prior to the addition of zinc. Competition experiments showed that Cd(II), Co(II) and Cu(II) are efficient competitors for the zinc binding sites. The ALCR DNA-binding domain was shown to contain 2 mol of tightly bound Zn(II) per mole of fusion protein. Removal of the intrinsic Zn(II) requires treatment with Chelex. This treatment abolishes the ability of the protein to bind to the targets of ALCR located in the alcA and alcR promoters. The apo-ALCR DNA-binding motif could be reconstituted with Zn(II) or Cd(II), restoring specific DNA binding to both types of targets. Thus a direct relationship was shown to exist between the zinc content of ALCR and its DNA-binding activity.

Specific binding sites for the activator protein, ALCR, in the alcA promoter of the ethanol regulon of Aspergillus nidulans.

ALCR is the specific activator of the Aspergillus nidulans ethanol-utilization pathway, mediating the induction of its own transcription and that of the structural genes alcA and aldA, encoding respectively, alcohol dehydrogenase I and aldehyde dehydrogenase. ALCR is a DNA binding protein in which 6 cysteines are coordinated in a zinc binuclear cluster. This domain was fused to glutathione-S-transferase (GST) and isolated as a GST-ALCR(7-58*) fusion protein from Escherichia coli. Mobility shift assays showed that the ALCR fusion protein binds at sites upstream of the alcA promoter. DNaseI protection footprinting experiments revealed three specific binding sites, two that are direct repeats and one that is an inverted repeat with the same half-site 5'-CCGCA-3'. The half-sites are separated by a variable number of nucleotides in both types of target. The interaction of the ALCR fusion protein with direct and inverted repeats were examined by using interference and protection footprinting assays. In both binding sites, modification of the guanines in the half-sites interfered with the formation of the DNA complex, but the adjacent ones did not. Our results suggest that the ALCR protein makes contact in the major groove of the DNA helix of the half-sites. The functionality of two out of three binding sites of the GST-ALCR protein was demonstrated after their deletion. Therefore, the region encompassing these binding sites is a cis-acting element involved in the full induction of the alcA gene.

Identification of the promoter region involved in the autoregulation of the transcriptional activator ALCR in Aspergillus nidulans.

The ALCR protein is the transcriptional activator of the ethanol utilization pathway in the filamentous fungus Aspergillus nidulans. This activator belongs to a family of fungal proteins having a conserved DNA-binding domain containing six cysteines (C6 class) with some striking features. At variance with other motifs of this class, the binding domain of ALCR is strongly asymmetrical in relation to the central cysteines and moreover was predicted to adopt a helix-turn-helix structure. This domain of ALCR was synthesized in Escherichia coli and purified as a glutathione-S-transferase fusion protein. Our results show that the transcriptional activator ALCR is a DNA-binding protein. The DNA-binding motif contains zinc that is necessary for the specific DNA binding. The ALCR peptide binds upstream of the coding region of alcR to two specific targets with different affinities that are characterized by a conserved 5-nucleotide core, 5'-CCGCA-3' (or its reverse). One site, the lower-affinity binding site, is a direct repeat, and the other, the higher-affinity binding site, is a palindromic sequence with dyad symmetry. Therefore, the ALCR binding protein is able to recognize one DNA sequence in two different configurations. An alcR mutant obtained by deletion of the two specific targets in the cis-acting region of the alcR gene is unable to grow on ethanol and does not express any alcohol dehydrogenase activity. These results demonstrate that the binding sites are in vivo functional targets (UASalc) for the ALCR protein in A. nidulans. They corroborate prior evidence that alcR is autoregulated.

Correct intron splicing generates a new type of a putative zinc-binding domain in a transcriptional activator of Aspergillus nidulans.

alcR is the pathway-specific transcriptional activator of the ethanol regulon in the filamentous fungus, Aspergillus nidulans. The deduced amino acid sequence of a cDNA clone, including the 5' part of the alcR-mRNA, shows that a putative Zn-binding domain of the all-cysteine class, exemplified by GAL4 is present. This structure presents some striking features. At variance with other structures of this class, the binding domain is strongly asymmetrical. Model building indicates that the zinc-binding motif of alcR could adopt an helix-turn-helix structure. We propose that the DNA-binding motif of alcR could participate in two types of DNA-binding structures: the zinc-cluster and the helix-turn-helix.

The ethanol regulon in Aspergillus nidulans: characterization and sequence of the positive regulatory gene alcR.

The regulatory gene, alcR, of Aspergillus nidulans, encodes a protein that induces the expression of the alcA and aldA genes. The alcR gene is inducible, autoregulated, and subject to carbon catabolite repression. We report the complete nucleotide sequence of the alcR gene and its 5' and 3' non-coding regions. In the 5' flanking region of the alcR gene, several repeats and inverted repeats were found, and small sequence similarities were also found with the 5' flanking regions of the alcA and aldA genes. One intron of small size interrupts the open reading frame. The start point of transcription was mapped 50 nucleotides upstream from the putative start codon, and a sequence CAATG was found 5' to the polyadenylation site of the transcript that could play a role in selection of the polyadenylation site. The putative alcR-encoded protein was identified in vivo as an inducible polypeptide of 96 kDa in a transformant carrying multiple copies of the alcR gene.

Regulation of alcR, the positive regulatory gene of the ethanol utilization regulon of Aspergillus nidulans.

The alcR positive control gene is necessary for the expression of both alcA (coding for alcohol dehydrogenase ADH I), and aldA (coding for aldehyde dehydrogenase, AldDH) in Aspergillus nidulans. Using a cloned alcR probe and Northern blots analysis we show that: (1) alcR itself is inducible; (2) alcR inducibility depends on the expression of the alcR gene itself; and (3) alcR is subject to carbon catabolite repression and its expression is controlled by the negatively acting creA wide specificity gene. The repression of alcR is sufficient to explain the carbon catabolite repression of ADH I and AldDH.

Expression of a spore-specific gene in Dictyostelium discoideum.

The expression of a previously cloned Dictyostelium discoideum spore-specific gene (Julien et al., EMBO J. 1, 1089-1093 (1982)) was investigated in wild type and mutant strains. In vitro translation of this spore-specific mRNA gave a protein of a molecular weight consistent with the mRNA size. Expressed at a low level during vegetative growth development and in stalk cells, the accumulation of this mRNA reached high values only in spore cells.

Induction by 3, 5, 3' L-triiodothyronine of L-ornithine decarboxylase in rat heart muscle.

Injection of 3,5,3' L-triiodothyronine (15 micrograms/100 g) induces a biphasic enhancement of rat heart ornithine decarboxylase (EC. 4.1.17) activity after 4 and 21 hours. This induction is observed after each daily injection, but to a lesser extent. The properties of partially purified basal enzyme and induced enzyme, at 21h, after single injections have been compared. 1) Affinity for ornithine is the same for both enzymes, but affinity for pyridoxal-phosphate is 40-fold higher for the induced one. 2) Thermostability studies suggest that basal and induced enzymes have different conformations. 3) The two enzymes have similar immuno-reactivity. 4) The comparisons of the time-dependent activity curve after injection and of the antigen/activity ratio suggests that triiodothyronine induces the synthesis of new molecules of enzymes and that an inhibition of the enzyme activity also occurs which explains the biphasic induction.