Promoter elements involved in the expression of the Aspergillus parasiticus aflatoxin biosynthesis pathway gene avnA.

One of the early genes in aflatoxin biosynthesis, avnA, encodes a pathway-specific cytochrome P-450 monooxygenase that catalyzes the hydroxylation of the polyketide anthraquinone, averantin. Based on beta-glucuronidase (GUS) reporter and electrophoretic mobility shift assays, promoter sites upstream of -118 bp in the 367-bp verB-avnA intergenic region are not required for avnA gene activity. Therefore, only the -100 to -110 site of the four putative binding sites for AFLR, the aflatoxin biosynthetic pathway transcription regulatory protein (consensus binding sequence: 5'-TCGN(5)CGR-3') was required for elevated avnA expression.

Characterization of the promoter for the gene encoding the aflatoxin biosynthetic pathway regulatory protein AFLR.

Most genes in the aflatoxin biosynthetic pathway in Aspergillus parasiticus are regulated by the binuclear zinc cluster DNA-binding protein AFLR. The aflR promoter was analyzed in beta-glucuronidase reporter assays to elucidate some of the elements involved in the gene's transcription control. Truncation at 118 bp upstream of the translational start site increased promoter activity 5-fold, while truncation at -100 reduced activity about 20-fold. These findings indicate the presence of an important positive regulatory element between -100 and -118 and a negative regulatory region further upstream. Electrophoretic mobility shift assays on nuclear extracts from A. parasiticus induced for aflatoxin expression suggest that AFLR and another, possibly more abundant, protein bind to the -100/-118 region. Another protein binds to a sequence at position -159 to -164 that matches the consensus binding site for the transcription factor involved in pH-dependent gene regulation, PACC.

Binding of the C6-zinc cluster protein, AFLR, to the promoters of aflatoxin pathway biosynthesis genes in Aspergillus parasiticus.

AFLR is a Zn2Cys6-type sequence-specific DNA-binding protein that is thought to be necessary for expression of most of the genes in the aflatoxin pathway gene cluster in Aspergillus parasiticus and A. flavus, and the sterigmatocystin gene cluster in A. nidulans. However, it was not known whether AFLR bound to the promoter regions of each of the genes in the cluster. Recently, A. nidulans AFLR was shown to bind to the motif 5'-TCGN5CGA-3'. In the present study, we examined the binding of AFLR to promoter regions of 11 genes in the A. parasiticus cluster. Based on electrophoretic mobility shift assays, the genes nor1, pksA, adhA, norA, ver1, omtA, ordA, and, vbs, had at least one 5'-TCGN5CGA-3' binding site within 200bp of the translation start site, and pksA and ver1 had an additional binding site further upstream. Although the promoter region of avnA lacked this motif, AFLR bound weakly to the sequence 5'-TCGCAGCCCGG-3' at -110bp. One region in the promoter of the divergently transcribed genes aflR/aflJ bound weakly to AFLR even though it contained a site with at most only 7bp of the 5'-TCGN5CGA-3' motif. This partial site may be recognized by a monomeric form of AFLR. Based on a comparison of 16 possible sites, the preferred binding sequence was 5'-TCGSWNNSCGR-3'.

An ethidium bromide-agarose plate assay for the nonradioactive detection of cDNA synthesis.

Ethidium bromide was used to determine the success of cDNA synthesis reactions. Since ethidium bromide in agarose can be used to quantitate RNA and DNA, conditions under which the greater fluorescence of double-stranded DNA (dsDNA) is utilized were devised to assay dsDNA synthesis from mRNA. Ethidium bromide at 5 micrograms/ml in agarose allowed quantitative detection of cDNA in the range of 0.03 to 0.0015 microgram. Sodium dodecyl sulfate had an adverse effect on the measurement of cDNA. Subsequent cDNA analysis by alkaline gel electrophoresis and staining in 5 micrograms/ml ethidium bromide allowed accurate and rapid sizing of cDNA and required only 0.1-0.05 microgram cDNA.

Alteration of different domains in AFLR affects aflatoxin pathway metabolism in Aspergillus parasiticus transformants.

AFLR, a zinc binuclear cluster DNA-binding protein, is required for activation of genes comprising the aflatoxin biosynthetic pathway in Aspergillus spp. Transformation of Aspergillus parasiticus with plasmids containing the intact aflR gene gave clones that produced fivefold more aflatoxin pathway metabolites than did the untransformed strain. When a 13-bp region in the aflR promoter (position -102 to -115 with respect to the ATG) was deleted, including a portion of a palindromic site previously shown to bind recombinant AFLR, metabolite production was 40% that of transformants with intact aflR. This result provides further evidence that this site may be involved in the autoregulation of aflR. Overexpression of pathway genes could also result from increased quantities of AFLR titrating out a putative repressor protein. In AFLR, a 20-amino-acid acidic region near its carboxy-terminus resembles the region in yeast GAL4 required for GAL80 repressor binding. When 3 of the acidic amino acids in this region were deleted, levels of metabolites were even higher than those produced by transformants with intact aflR, as would be expected if repressor binding was suppressed in transformants containing this altered protein. Transformation with plasmids mutated at the AFLR zinc cluster (Cys to Trp at amino acid position 49) or at a putative nuclear localization signal region (RRARK deleted) gave clones with one-fifth the metabolite production of the untransformed fungus in spite of the transformants making the same or more aflR mRNA. Since these transformants retained a copy of intact aflR, the latter results can be explained best by assuming that AFLR activates genes involved in aflatoxin production as a dimeric protein and that heterodimers containing both mutant and intact AFLR strands are inactive.

An acid phosphatase from Aspergillus ficuum has homology to Penicillium chrysogenum PhoA.

Three secreted acid phosphatases had previously been characterized from Aspergillus ficuum grown under conditions of limited phosphate. One of these could not be readily separated from AFPhyB, a pH 2.5 optimum acid phosphatase with phytase activity. From extensive protein sequence analysis and subsequent cloning of the gene, we have shown that the AFPhyB protein fraction contains a fourth secreted acid phosphatase (AFPhoA) that has 64% homology to a phosphate-repressible acid phosphatase from Penicillium chrysogenum. Garnier plot analysis revealed that the putative phosphate catalytic domain of AFPhoA at His215Asp216 is similar to those of other acid phosphatases, but that AFPhoA lacks the phosphate-binding motif RHGXRXP of known histidine phosphatases.

Identification and cloning of a second phytase gene (phyB) from Aspergillus niger (ficuum).

An Aspergillus niger (ficuum) genomic DNA lambda EMBL3 library was probed with a 354-bp DNA fragment obtained by polymerase chain reaction of A. niger DNA with oligonucleotides based on partial amino acid sequence of a pH 2.5 optimum acid phosphatase. A clone containing a 1605 bp segment (phyB) encoding the 479 amino acid enzyme was isolated and found to contain four exons. Global alignment revealed 23.5% homology to Aspergillus niger phytase (PhyA); four regions of extensive homology were identified. Some of these regions may contain catalytic sites for phosphatase function.

adhA in Aspergillus parasiticus is involved in conversion of 5'-hydroxyaverantin to averufin.

Two routes for the conversion of 5'-hydroxyaverantin (HAVN) to averufin (AVF) in the synthesis of aflatoxin have been proposed. One involves the dehydration of HAVN to the lactone averufanin (AVNN), which is then oxidized to AVF. Another requires dehydrogenation of HAVN to 5'-ketoaverantin, the open-chain form of AVF, which then cyclizes spontaneously to AVF. We isolated a gene, adhA, from the aflatoxin gene cluster of Aspergillus parasiticus SU-1. The deduced ADHA amino acid sequence contained two conserved motifs found in short-chain alcohol dehydrogenases-a glycine-rich loop (GXXXGXG) that is necessary for interaction with NAD(+)-NADP(+), and the motif YXXXK, which is found at the active site. A. parasiticus SU-1, which produces aflatoxins, has two copies of adhA (adhA1), whereas A. parasiticus SRRC 2043, a strain that accumulates O-methylsterigmatocystin (OMST), has only one copy. Disruption of adhA in SRRC 2043 resulted in a strain that accumulates predominantly HAVN. This result suggests that ADHA is involved in the dehydrogenation of HAVN to AVF. Those adhA disruptants that still made small amounts of OMST also accumulated other metabolites, including AVNN, after prolonged culture.

Characterization of the critical amino acids of an Aspergillus parasiticus cytochrome P-450 monooxygenase encoded by ordA that is involved in the biosynthesis of aflatoxins B1, G1, B2, and G2.

The conversion of O-methylsterigmatocystin (OMST) and dihydro-O-methylsterigmatocystin to aflatoxins B1, G1, B2, and G2 requires a cytochrome P-450 type of oxidoreductase activity. ordA, a gene adjacent to the omtA gene, was identified in the aflatoxin-biosynthetic pathway gene cluster by chromosomal walking in Aspergillus parasiticus. The ordA gene was a homolog of the Aspergillus flavus ord1 gene, which is involved in the conversion of OMST to aflatoxin B1. Complementation of A. parasiticus SRRC 2043, an OMST-accumulating strain, with the ordA gene restored the ability to produce aflatoxins B1, G1, B2, and G2. The ordA gene placed under the control of the GAL1 promoter converted exogenously supplied OMST to aflatoxin B1 in Saccharomyces cerevisiae. In contrast, the ordA gene homolog in A. parasiticus SRRC 2043, ordA1, was not able to carry out the same conversion in the yeast system. Sequence analysis revealed that the ordA1 gene had three point mutations which resulted in three amino acid changes (His-400-->Leu-400, Ala-143-->Ser-143, and Ile-528-->Tyr-528). Site-directed mutagenesis studies showed that the change of His-400 to Leu-400 resulted in a loss of the monooxygenase activity and that Ala-143 played a significant role in the catalytic conversion. In contrast, Ile-528 was not associated with the enzymatic activity. The involvement of the ordA gene in the synthesis of aflatoxins G1, and G2 in A. parasiticus suggests that enzymes required for the formation of aflatoxins G1 and G2 are not present in A. flavus. The results showed that in addition to the conserved heme-binding and redox reaction domains encoded by ordA, other seemingly domain-unrelated amino acid residues are critical for cytochrome P-450 catalytic activity. The ordA gene has been assigned to a new cytochrome P-450 gene family named CYP64 by The Cytochrome P450 Nomenclature Committee.