Loss-of-function Aspergillus nidulans CclA, a Bre2 ortholog involved in histone 3 lysine 4 methylation, activated the expression of cryptic secondary metabolite (SM) clusters in A. nidulans. One novel cluster generated monodictyphenone, emodin and emodin derivatives while a second encoded two anti-osteoporosis polyketides, F9775A and F9775B. Modification of the chromatin landscape in fungal SM clusters allows for a simple technological means to express silent fungal secondary metabolite gene clusters.Aspergilli are ubiquitous filamentous fungi whose members include human and plant pathogens and industrial fungi with tremendous medical, agricultural and biotechnological importance. Although demonstrating synteny along large tracks of their sequenced genomes, * Corresponding authors: phone: (323) 442-1670; fax: (323) 442-1390, clayw@usc.edu, phone: (608) 262-9795; fax: (608) (2) clusters 3 . Yet the expression of most SM clusters and their concomitant products remain veiled. Two approaches for activating otherwise silent clusters were recently described. One strategy, utilizing the knowledge that many SM clusters contain a pathway specific transcription factor, fused an inducible promoter to a cluster transcription factor leading to the production of hybrid polyketide-nonribosomal peptide metabolites, the cytotoxic aspyridones A (3) and B (4) 4 . A second approach, based on genomic mining of microarrays generated from mutants of the global regulator of secondary metabolism LaeA 5, 6, 7 , led to the identification of the anti-tumor compound terrequinone A (5) 8 . Efforts to uncover the regulatory role of LaeA revealed that some subtelomeric SM clusters were located in heterochromatic regions of the genome where suppression was relieved by deletion of a key histone deacetylase 9 . The importance of histone modifications in SM clusters was further reflected in the initiation and spread of histone H4 acetylation concurrent with transcriptional activation of the subtelomeric A. parasiticus aflatoxin (6) gene cluster 10 .A consideration of the accruing evidence linking chromatin modifications with SM cluster regulation led us to examine the hypothesis that additional chromatin modifying proteins were important in SM cluster regulation. In particular, we examined a member of the COMPASS (complex associated with Set1) complex for possible regulatory roles in SM silencing. The COMPASS complex is a conserved eukaryotic transcriptional effector both facilitating and repressing chromatin-mediated processes through methylation of lysine 4 of histone 3 (H3K4) 11,12 . While H3K4me2 and H3K4me3 are found predominantly on active loci 12 , the COMPASS complex also regulates homothallic mating silencing, ribosomal DNA silencing, telomere length, and subtelomeric gene expression in yeast [13][14][15] .A critical member of the COMPASS complex is the SPRY domain protein designated Bre2 in Saccharomyces cerevisiae 11 . Analysis of the A. nidulans genome revealed a putative ortholog, here named CclA. Extracts of cclA delet...
Fungal secondary metabolites are important bioactive compounds but the conditions leading to expression of most of the putative secondary metabolism (SM) genes predicted by fungal genomics are unknown. Here we describe a novel mechanism involved in SM-gene regulation based on the finding that, in Aspergillus nidulans, mutants lacking components involved in heterochromatin formation show de-repression of genes involved in biosynthesis of sterigmatocystin (ST), penicillin and terrequinone A. During the active growth phase, the silent ST gene cluster is marked by histone H3 lysine 9 trimethylation and contains high levels of the heterochromatin protein-1 (HepA). Upon growth arrest and activation of SM, HepA and trimethylated H3K9 levels decrease concomitantly with increasing levels of acetylated histone H3. SM-specific chromatin modifications are restricted to genes located inside the ST cluster, and constitutive heterochromatic marks persist at loci immediately outside the cluster. LaeA, a global activator of SM clusters in fungi, counteracts the establishment of heterochromatic marks. Thus, one level of regulation of the A. nidulans ST cluster employs epigenetic control by H3K9 methylation and HepA binding to establish a repressive chromatin structure and LaeA is involved in reversal of this heterochromatic signature inside the cluster, but not in that of flanking genes.
Sequence analyses of fungal genomes have revealed that the potential of fungi to produce secondary metabolites is greatly underestimated. In fact, most gene clusters coding for the biosynthesis of antibiotics, toxins, or pigments are silent under standard laboratory conditions. Hence, it is one of the major challenges in microbiology to uncover the mechanisms required for pathway activation. Recently, we discovered that intimate physical interaction of the important model fungus Aspergillus nidulans with the soil-dwelling bacterium Streptomyces rapamycinicus specifically activated silent fungal secondary metabolism genes, resulting in the production of the archetypal polyketide orsellinic acid and its derivatives. Here, we report that the streptomycete triggers modification of fungal histones. Deletion analysis of 36 of 40 acetyltransferases, including histone acetyltransferases (HATs) of A. nidulans, demonstrated that the Saga/Ada complex containing the HAT GcnE and the AdaB protein is required for induction of the orsellinic acid gene cluster by the bacterium. We also showed that Saga/Ada plays a major role for specific induction of other biosynthesis gene clusters, such as sterigmatocystin, terrequinone, and penicillin. Chromatin immunoprecipitation showed that the Saga/Ada-dependent increase of histone 3 acetylation at lysine 9 and 14 occurs during interaction of fungus and bacterium. Furthermore, the production of secondary metabolites in A. nidulans is accompanied by a global increase in H3K14 acetylation. Increased H3K9 acetylation, however, was only found within gene clusters. This report provides previously undescribed evidence of Saga/Ada dependent histone acetylation triggered by prokaryotes.
GALl, GAL4 and GALIO transcription [5,6]. The sequence 5'-SYGGRG-Y been proposed as a consensus for CreA-binding [7]. Unlike MIG1, however, CreA contains an additional domain downstream of the zinc-finger, which has been reported to bear high similarity to S. cerevisiae RGR1 [8,9], and whose function is unknown. Since its cloning and sequencing, molecular evidence has been presented for an involvement of CreA in the catabolite repression of transcription of genes involved in proline utilization [7], ethanol metabolism [10,11] and polysaccharide hydrolysis [12] in A. nidulans.Nothing is known as yet on the mechanism of carbon catabolite repression in other fungi. The filamentous fungus Trichoderma reesei is an industrially important producer of several extracellular enzymes, including a highly active cellulase [13] and hemicellulase enzyme system [14]. The formation of some of these enzymes (e.g. cellobiohydrolase I; endo-fl-l,4-xylanase I) is repressed by glucose [15,16]. It has been reported that the 5'-upstream nt-sequence of the T. reesei gene encoding cellobiohydrolase I (cbhl) shows consensus sequences for binding of a potential CreA-homologue [17]. Deletion of these sequences resulted in glucose derepressed transcription of cbhl [17]. It is therefore possible that carbon catabolite repression in T. reesei occurs by a mechanism similar to that existant in Aspergillus. However, the presence of a DNA-binding protein in T. reesei similar to CreA has not yet been published. As a first step towards understanding the mechanisms and cloning of the genes involved in carbon catabolite repression in T. reesei, we demonstrate here the presence of a creA homologue in T. reesei Crel --and provide evidence that the native gene product is a DNA-binding protein, thereby showing that the mechanisms of carbon catabolite repression have been basically conserved in the ascomycetous classes of Pyrenomycetes and Plectomycetes.Carbon catabolite repression in microorganisms is a means I~) control the synthesis of a range of enzymes required for the t~tilization of less favoured carbon sources when more readily t~tilized carbon sources are present in the medium. Several genes participating in this process have been identified in Sactzaromyces cerevisiae [1,2]. In the multicellular fungi, the creA gene cloned from Aspergillus nidulans [3] and A. niger [4] is the ~nly hitherto regulatory gene known to mediate carbon cat~l bolite repression. It encodes a DNA-binding protein containi Mlg a two-zinc-finger domain of the C2H2 class, which mediates ,~4% similarity to MIG1 from S. cerevisiae, which is also *Corresponding author. Fax: (43)(1) 581-6266. l-mail: jos@eichow.tuwien.ac.at Experimental Strain, cloning vector and plasmidTrichoderma reesei strain QM 9414 (ATCC 26921 ) was used throughout this study and maintained on malt agar. Bluescript II/SK+ (Stratagene, La Jolla, CA) and E. coli LC 137 (Pharmacia-LKB, Uppsala, Sweden) were used as cloning and plasmid vectors, respectively. Cloning of the T. reesei crel geneFungal genomic DNA...
The carbon-use-efficiency (CUE) of microorganisms is an important parameter in determining ecosystem-level carbon (C) cycling; however, little is known about how variance in resources affects microbial CUE. To elucidate how resource quantity and resource stoichiometry affect microbial CUE, we cultured four microorganisms - two fungi (Aspergillus nidulans and Trichoderma harzianum) and two bacteria (Pectobacterium carotovorum and Verrucomicrobium spinosum) - under 12 unique C, nitrogen (N) and phosphorus (P) ratios. Whereas the CUE of A. nidulans was strongly affected by C, bacterial CUE was more strongly affected by mineral nutrients (N and P). Specifically, CUE in P. carotovorum was positively correlated with P, while CUE of V. spinosum primarily depended on N. This resulted in a positive relationship between fungal CUE and resource C : nutrient stoichiometry and a negative relationship between bacterial CUE and resource C : nutrient stoichiometry. The difference in the direction of the relationship between CUE and C : nutrient for fungi vs. bacteria was consistent with differences in biomass stoichiometry and suggested that fungi have a higher C demand than bacteria. These results suggest that the links between biomass stoichiometry, resource demand and CUE may provide a mechanism for commonly observed temporal and spatial patterns in microbial community structure and function in natural habitats.
The filamentous fungus Trichoderma reesei forms two specific, xylan-inducible xylanases encoded by xyn1 and xyn2 to degrade the beta-1,4-D-xylan backbone of hemicelluloses. This enzyme system is formed in the presence of xylan, but not glucose. The molecular basis of the absence of xylanase I formation on glucose was the purpose of this study. Northern blotting of the xyn1 transcript as well as the use of the Escherichia coli hygromycin B phosphotransferase-encoding gene (hph) as a reporter consistently showed that the basal expression of xyn1 was affected by glucose, whereas its induction by xylan remained uninfluenced. The repression of basal xyn1 transcription is mediated by the carbon catabolite repressor protein Cre1, which in vivo binds to two of four consensus sites (5'-SYG-GRG-3') in the xyn1 promoter, which occurred in the form of an inverted repeat. T. reesei strains, bearing a xyn1::hph reporter construct, in which four nucleotides from the middle of the inverted repeat had been removed, expressed hph on glucose at a level comparable to that observed during growth on a carbon catabolite derepressing carbon source. Northern analysis of xyn1 expression in a T. reesei mutant strain (RUT C-30), which contains a truncated, non-functional cre1 gene, also confirmed basal transcription of xyn1. In this strain, xyn1 transcription was still inducible by xylose or xylan to an even higher degree than in the wild-type strain, suggesting that induction overcomes glucose repression at the level of xyn1 expression. Based on these data, we postulate that basal transcription of xyn1 is repressed by glucose and mediated by an inverted repeat of the consensus motif for Cre1-mediated carbon catabolite repression.
The linked niiA and niaD genes of Aspergillus nidulans are transcribed divergently. The expression of these genes is subject to a dual control system. They are induced by nitrate and repressed by ammonium. AreA mediates derepression in the absence of ammonium and NirA supposedly mediates nitrate induction. Out of 10 GATA sites, a central cluster (sites 5-8) is responsible for~80% of the transcriptional activity of the promoter on both genes. We show occupancy in vivo of site 5 by the AreA protein, even under conditions of repression. Sites 5-8 are situated in a pre-set nucleosome-free region. Under conditions of expression, a drastic nucleosomal rearrangement takes place and the positioning of at least five nucleosomes flanking the central region is lost. Remodelling is strictly dependent on the presence of an active areA gene product, and independent from the NirA-specific and essential transcription factor. Thus, nucleosome remodelling is independent from the transcriptional activation of the niiA-niaD promoter. The results presented cast doubts on the role of NirA as the unique transducer of the nitrate induction signal. We demonstrate, for the first time in vivo, that a GATA factor is involved directly in chromatin remodelling.
The major laccase isoenzyme LAP2 secreted by the white-rot basidiomycete Trametes pubescens in response to high copper concentrations was purified to apparent electrophoretic homogeneity using anion-exchange chromatography and gel filtration. The monomeric protein has a molecular mass of 65 kDa, of which 18 % is glycosylation, and a pI value of 2 6. The pH optima of the laccase depend on the substrates oxidized and show bell-shaped pH activity profiles with an optimum of 3-4 5 for phenolic substrates such as 2,6-dimethoxyphenol or syringaldazine, while the non-phenolic substrates ABTS [2,2'-azino-bis(3-ethylbenzthiazoline-6-sulfonic acid)] and ferrocyanide show a monotonic pH profile with a rate increasing with decreasing pH. The catalytic efficiencies k cat /K m determined for some of its substrates were 48W10 6 , 47W10 6 , 20W10 6 and 7W10 6 M N1 s N1 for ABTS, syringaldazine, ferrocyanide and oxygen, respectively. Furthermore, the gene lap2 encoding the purified laccase was cloned and its nucleotide sequence determined. The gene consists of 1997 bp, with the coding sequence interrupted by eight introns and flanked by an upstream region in which putative CAAT, TATA, MRE and CreA consensus sequences were identified. Based on Northern analysis containing total RNA from both induced and uninduced cultures, expression of lap2 is highly induced by copper, which is also corroborated by an increase in laccase activity in response to copper. A stimulating effect of various other heavy metal ions on laccase synthesis was also observed. In addition to induction, a second regulatory mechanism seems to be repression of lap2 transcription by glucose.
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