Eukaryotes have evolved highly conserved vesicle transport machinery to deliver proteins to the vacuole. In this study we show that the filamentous fungus Aspergillus parasiticus employs this delivery system to perform new cellular functions, the synthesis, compartmentalization, and export of aflatoxin; this secondary metabolite is one of the most potent naturally occurring carcinogens known. Here we show that a highly pure vesicle-vacuole fraction isolated from A. parasiticus under aflatoxin-inducing conditions converts sterigmatocystin, a late intermediate in aflatoxin synthesis, to aflatoxin B 1 ; these organelles also compartmentalize aflatoxin. The role of vesicles in aflatoxin biosynthesis and export was confirmed by blocking vesicle-vacuole fusion using 2 independent approaches. Disruption of A. parasiticus vb1 (encodes a protein homolog of AvaA, a small GTPase known to regulate vesicle fusion in A. nidulans) or treatment with Sortin3 (blocks Vps16 function, one protein in the class C tethering complex) increased aflatoxin synthesis and export but did not affect aflatoxin gene expression, demonstrating that vesicles and not vacuoles are primarily involved in toxin synthesis and export. We also observed that development of aflatoxigenic vesicles (aflatoxisomes) is strongly enhanced under aflatoxin-inducing growth conditions. Coordination of aflatoxisome development with aflatoxin gene expression is at least in part mediated by Velvet (VeA), a global regulator of Aspergillus secondary metabolism. We propose a unique 2-branch model to illustrate the proposed role for VeA in regulation of aflatoxisome development and aflatoxin gene expression.S econdary metabolites, natural products generated by filamentous fungi, plants, bacteria, algae, and animals, have an enormous impact on humans due to their application in health, medicine, and agriculture. Many secondary metabolites are beneficial (antibiotics, statins, morphine, etc.), though phytotoxins (e.g., ricin, crotin, amygdalin) and fungal poisons called mycotoxins (e.g., aflatoxin, sterigmatocystin, fumonisin) are detrimental to humans and animals. To control or customize biosynthesis of these natural products we must understand how and where secondary metabolism is orchestrated within the cell.Vacuoles and vesicles are known to sequester secondary metabolites to protect host cells from self-toxicity (1). Enzymes involved in secondary metabolism are often found in vesicles and vacuoles, including those for biosynthesis of alkaloids (e.g., berberine, sanguinarine, camptotecin, and morphine; reviewed in refs. 1 and 2) and flavonoids (e.g., aurone) (reviewed in refs. 1 and 3) in plants and the nonribosomal peptide cyclosporin (4), the -lactam antibiotic penicillin (5) (localization of ACVS is still controversial), and the polyketide aflatoxin (6-8) in fungi. However, the functional role of these compartments in secondary metabolism was unclear because these organelles potentially could be involved in synthesis, storage, protein turnover, transport, or export of...
In filamentous fungi, several lines of experimental evidence indicate that secondary metabolism is triggered by oxidative stress; however, the functional and molecular mechanisms that mediate this association are unclear. The basic leucine zipper (bZIP) transcription factor AtfB, a member of the bZIP/CREB family, helps regulate conidial tolerance to oxidative stress. In this work, we investigated the role of AtfB in the connection between oxidative stress response and secondary metabolism in the filamentous fungus Aspergillus parasiticus. This well characterized model organism synthesizes the secondary metabolite and carcinogen aflatoxin. Cellular response to oxidative stress in vertebrates, plants, and fungi is of fundamental importance; it enables the cell to survive a variety of extra-and intracellular oxidative stressors. An uncontrolled increase in reactive oxygen species (ROS) 4 in mammalian cells is associated with various pathological conditions such as inflammation and cardiovascular and neurodegenerative disorders, including hypertension, atherosclerosis, Parkinson disease, and Alzheimer disease; oxidative stress is also linked to premature aging and cancer (1-10). A detailed understanding of the regulatory network that coordinates the cellular response to oxidative stress will enable better control over its detrimental impacts on humans.As a part of the response to oxidative stress, transcription factors activated directly or indirectly by ROS bind to the promoters of specific genes that trigger defense and signaling related activities. In mammalian cells, Drosophila, Caenorhabditis elegans, and yeast, response to oxidative stress is mediated by an evolutionarily conserved bZIP transcription factor Nrf2 that binds as a heterodimer with Maf or ATF4 to antioxidantresponse elements in the promoters of more than 200 mammalian genes (11-16). Signaling pathways that involve PKC, PI3K, and MAPK participate in Nrf2 activation under ROS exposure. In Arabidopsis, 175 genes were demonstrated to be regulated by hydrogen peroxide, including genes with MYB and AP-1-response elements (17). 140 core stress-related genes were identified in Schizosaccharomyces pombe (18,19).Filamentous fungi in the genus Aspergillus must cope with ROS during their growth and development. Genetic and biochemical studies shed light on the role of ROS in fungal defense, pathogenicity, and development and suggest that fungi use similar stress response pathways as mammalian and plant cells (20 -24). The transcription factors AP-1, AtfA, and AtfB (all members of the basic leucine zipper (bZIP) transcription factor family) have been identified as major players in providing conidia with resistance to oxidative stress in aspergilli. Saccharomyces cerevisiae yap-1 is an ortholog of mammalian AP-1 (25-27). A yap-1 ortholog in Aspergillus parasiticus (ApyapA) is reported to regulate the timing of ROS accumulation, conidiospore development, and stress tolerance in conidiospores (26,27). AtfA, an ortholog of S. pombe Atf1, controls conidial respon...
Compartmentalization and molecular traffic in secondary metabolism: A new understanding of established cellular processes
Great progress has been made in understanding the regulation of expression of genes involved in secondary metabolism. Less is known about the mechanisms that govern the spatial distribution of the enzymes, cofactors, and substrates that mediate catalysis of secondary metabolites within the cell. Filamentous fungi in the genus Aspergillus synthesize an array of secondary metabolites and provide useful systems to analyze the mechanisms that mediate the temporal and spatial regulation of secondary metabolism in eukaryotes. For example, aflatoxin biosynthesis in A. parasiticus has been studied intensively because this mycotoxin is highly toxic, mutagenic, and carcinogenic in humans and animals. Using aflatoxin synthesis to illustrate key concepts, this review focuses on the mechanisms by which sub-cellular compartmentalization and intra-cellular molecular traffic contribute to the initiation and completion of secondary metabolism within the cell. We discuss the recent discovery of aflatoxisomes, specialized trafficking vesicles that participate in the compartmentalization of aflatoxin synthesis and export of the toxin to the cell exterior; this work provides a new and clearer understanding of how cells integrate secondary metabolism into basic cellular metabolism via the intracellular trafficking machinery.
SummaryThe 27 genes involved in aflatoxin biosynthesis are clustered within a 70 kb region in the Aspergillus parasiticus genome. Using chromatin immunoprecipitation, we demonstrated a positive correlation between the initiation and spread of histone H4 acetylation in aflatoxin promoters and the onset of accumulation of aflatoxin proteins and aflatoxin. Histone H4 acetylation in the pksA (encodes an 'early' biosynthetic pathway enzyme) promoter peaked at 30 h, prior to the increased acetylation in the omtA and ordA (encode 'late' enzymes) promoters detected at 40 h. The specific order in which pksA, ver-1 (encodes a 'middle' enzyme) and omtA transcripts accumulated in cells paralleled the pattern of spread of histone H4 acetylation. Binding of AflR, a positive regulator of aflatoxin biosynthesis, to the ordA promoter showed a positive correlation with the spread of histone H4 acetylation. The data suggest that the order of genes within the aflatoxin cluster determines the timing and order of transcriptional activation, and that the site of initiation and spread of histone H4 acetylation mediate this process. Our data indicate that the aflatoxin and adjacent sugar utilization clusters are part of a larger 'regulatory unit'.
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