PLoS PathogplosplospathPLOS Pathogens1553-73661553-7374Public Library of ScienceSan Francisco, CA USA10.1371/journal.ppat.1007606PPATHOGENS-D-18-02232PearlsBiology and life sciencesOrganismsEukaryotaFungiFungal moldsAspergillusAspergillus fumigatusBiology and life sciencesMicrobiologyMedical microbiologyMicrobial pathogensFungal pathogensAspergillus fumigatusMedicine and health sciencesPathology and laboratory medicinePathogensMicrobial pathogensFungal pathogensAspergillus fumigatusBiology and life sciencesMycologyFungal pathogensAspergillus fumigatusBiology and life sciencesBiochemistryMetabolismMetabolitesSecondary metabolitesBiology and life sciencesBiochemistryMetabolismMetabolitesBiology and life sciencesMicrobiologyMedical microbiologyMicrobial pathogensFungal pathogensMedicine and health sciencesPathology and laboratory medicinePathogensMicrobial pathogensFungal pathogensBiology and life sciencesMycologyFungal pathogensBiology and life sciencesOrganismsEukaryotaFungiPhysical sciencesMaterials scienceMaterialsPigmentsOrganic pigmentsMelaninMedicine and health sciencesPathology and laboratory medicinePathogensOpportunistic pathogensMedicine and health sciencesPharmacologyPharmacokineticsDrug metabolismA call to arms: Mustering secondary metabolites for success and survival of an opportunistic pathogenhttp://orcid.org/0000-0003-0112-5262RaffaNicholas1http://orcid.org/0000-0002-4386-9473KellerNancy P.12*Department of Medical Microbiology and Immunology, University of Wisconsin-Madison, Madison, Wisconsin, United States of AmericaDepartment of Bacteriology, University of Wisconsin-Madison, Madison, Wisconsin, United States of AmericaSheppardDonald C.EditorMcGill University, CANADA
The authors have declared that no competing interests exist.
* E-mail: npkeller@wisc.edu44201942019154e10076062019Raffa, KellerThis is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.Research reported in this publication was supported by the National Institutes of Health under Award Numbers T32GM008349 and R01AI065728-01. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.Introduction
Aspergillus fumigatus is a ubiquitous saprophytic mold able to grow on a diversity of material ranging from decayed organic matter in the environment to space station cupolas [1]. Yet this fungus is equally adept as a serious opportunistic pathogen, causing pulmonary aspergillosis and the more deadly invasive aspergillosis (IA). There are an estimated 3,000,000 cases of pulmonary aspergillosis annually and more than 200,000 cases of IA each year reaching a mortality rate of up to 90% in the most susceptible populations [2]. Difficulties in treating IA include delayed detection and increasing resistance to antifungal treatment. Like many opportunistic fungi, there is no one gene that makes A. fumigatus such a threatening pathogen. One unique feature of this pathogen is its arsenal of small molecules that impact disease development. Secondary metabolites are characterized as bioactive molecules of low molecular weight that are not required for growth of the organism but instead aid survival in harsh environments, resisting desiccation and UV stress and improving competition with other microbes. For A. fumigatus, these benefits extend to aiding growth not only in the environment but in the human body as well. Some secondary metabolites combat the host immune system by affecting immune cell function or by shielding the fungus against host attack, whereas others allow the fungus to acquire essential, scarce cofactors. The following synopsis of secondary metabolites produced by the opportunistic human pathogen A. fumigatus highlights how microbial metabolites, although undoubtedly evolved as environmental protectants, can impact infectious disease development (Fig 1). Although we delineate the roles of each metabolite by category for ease of discussion (e.g., “on the offensive,” “scavenging the battlefield,” “arms race”), the reader should note that each metabolite may have several biological roles for the fungus, in part illustrated in Fig 1.
10.1371/journal.ppat.1007606.g001
Roles of Aspergillus fumigatus secondary metabolites.
A list of the secondary metabolites produced by A. fumigatus, flanked by their proposed roles in the environment (right) and the host (left). Metabolites with a “?” indicate that the compound has not been examined in a niche. Bracketed numerals (e.g., [22]) indicate the reference associated with the role of the metabolite. Nidulanin A is a proposed metabolite produced by A. fumigatus, whereas all other metabolites are characterized end-product metabolites from a biosynthetic gene cluster. ROS, reactive oxygen species; TNF-α, tumor necrosis factor alpha.
On the offensive: How A. fumigatus combats the immune system
Once inside the host, A. fumigatus must survive interactions with components of the immune system by avoiding, suppressing, or weakening the immune response. The following secondary metabolites have been shown to impact disease or interactions with the immune system through such mechanisms.
Dihydroxynapthalene melanin
Dihydroxynapthalene (DHN) melanin is a polymer consisting of 1,8-dihydroxynapthalene, found on the conidial surface. As an environmental benefit, DHN melanin helps to prevent desiccation of spores and confers resistance to UV radiation [3]. In the host, DHN melanin protects the conidia by scavenging reactive oxygen species [4], reducing phagosomal acidification in alveolar macrophages [5], and inhibiting apoptosis in epithelial cells [6]. When the polyketide synthase gene (pksP/alb1) responsible for the initial step of melanin production is deleted, there is a loss of spore pigment, a defect in virulence in intravenously injected immunocompetent murine models, and rapid killing spores in macrophage models [4]. Recently, DHN melanin has been described as a pathogen-associated molecular pattern, in that a C-type lectin receptor expressed in myeloid cells and CD31+ endothelial cells in humans recognizes DHN melanin and has been shown to have a protective role against disseminated infection in immunocompetent mice and recipients of stem cell transplants [7].
Gliotoxin
Gliotoxin is an epidithiodioxopiperazine that has been extensively studied in the context of infection. Gliotoxin inhibits activity of proteins that contain susceptible free thiols such as the host NADPH oxidase, a protein complex necessary for the generation of antimicrobial reactive oxygen species [8]. Gliotoxin has also been shown to inhibit nuclear factor-kappa B (NF-κB)-mediated transcription of cytokine genes and decrease cytotoxic activities of T lymphocytes [9]. A. fumigatus is resistant to its own toxin through a protective enzyme encoded in the gliotoxin cluster [10]. More recently, this metabolite has been shown to suppress the macrophage immune response by preventing integrin activation, interfering with actin dynamics, and impairing phagocytosis through affecting phosphoinositide metabolism [11]. When the gliotoxin nonribosomal peptide synthetase gene, gliP, is deleted, there is an attenuation of virulence in non-neutropenic murine models of IA but not in neutropenic murine models [12].
Endocrocin
Endocrocin is a polyketide that is localized to the conidia during growth [13]. Using an in vivo zebrafish assay, endocrocin was found to directly affect immune cells by inhibiting neutrophil chemotaxis [14]. When the polyketide synthase gene encA is deleted, there is an attenuation of virulence using the Drosophila melanogaster IA model [15]. Endocrocin belongs to a common class of anthraquinones and is closely related to emodin, a precursor in the trypacidin pathway that has been associated with mediating neutrophil apoptosis [15]. Although an exact role for endocrocin has not been established in nature, several related metabolites provide UV protection to fungi, similar to the role of DHN melanin [3].
Fumagillin
Fumagillin is a monoterpenoid, amoebicidal toxin with valuable pharmaceutical potential due to its inhibitory activity against methionine aminopeptidase-2, making it useful for the treatment of microsporidiosis [16]. The toxin has been found to suppress the immune response of Galleria mellonella by inhibiting the activity of phagocytes [17] and reduces the ability of the insect immune cells to kill opsonized Candida albicans cells and phagocytose A. fumigatus conidia [17]. In addition, fumagillin also reduces the ability of hemocytes to take up oxygen and inhibits the translocation of p47 protein [17], an essential component of the NADPH oxidase complex. Fumagillin administered to insect larvae increases the susceptibility of the larvae to A. fumigatus [18]. Recently, virulence assays with an A. fumigatus fumagillin deletion mutant strongly support a role for this toxin in epithelial cell damage during IA [19].
Fumigaclavines
Fumigaclavines are ergot alkaloids, a class of compounds known to act as feeding deterrents and exhibit insecticidal and bactericidal activities [20]. Using the G. mellonella insect model for IA, it was found that a strain of A. fumigatus deficient in all ergot alkaloid production, ΔdmaW, resulted in a significantly reduced virulence. Strains that were still able to produce ergot alkaloids, but not fumigaclavine C, were significantly less virulent than wild type but still more virulent than the strain in which there was no production of ergot alkaloids, suggesting a role of the end product fumigaclavine C in virulence [20]. Fumigaclavine C has also been shown to inhibit the production of the pro-inflammatory cytokine tumor necrosis factor alpha (TNFα), suggesting a mechanism of action for the molecule [21].
Scavenging the battlefield: How A. fumigatus acquires essential micronutrients
Secondary metabolites regulate key aspects of micronutrient homeostasis and allow A. fumigatus to continue normal cellular function by meeting the needs for the trace elements such as copper and iron. Both are toxic in high doses but are necessary for essential cellular processes such as respiration and branched-chain amino acid biosynthesis. The ability to acquire these micronutrients is directly related to the ability of A. fumigatus to cause disease.
Siderophores
Siderophores produced by A. fumigatus are characterized by their hydrodroxamate moieties and function in high-affinity iron uptake and storage mechanisms. Extracellular siderophores fusarinine C and triacetlyfusarinine C are secreted into the environment, where they bind Fe3+ and transport it back into the cell. Intracellular siderophores ferricrocin and hydroxyferricrocin are responsible for iron storage and homeostasis. When the enzyme responsible for the first step in siderophore biosynthesis sidA is deleted, both extracellular and intracellular siderophore production is abolished. The sidA deletion grows poorly under iron-limiting conditions [22] and displays increased sensitivity to hydrogen peroxide. In addition, this mutant was found to be highly attenuated in virulence using a neutropenic murine model [23], suggesting that proper iron acquisition is essential for disease progression in the host.
Hexadehydroastechrome
Hexadehydroastechrome (HAS) is a tryptophan-derived secondary metabolite that binds to iron. Overexpressing the transcription factor present within the HAS biosynthetic gene cluster results in an increase in both siderophore and HAS production in addition to increased virulence in a neutropenic murine model [24]. HAS regulates fungal iron homeostasis circuitry, aligning iron acquisition and consumption pathways with secondary metabolite expression [25], including the newly discovered xanthocillin gene cluster [26].
Xanthocillins
Xanthocillins are tyrosine-derived metabolites that contain a characteristic isocyanide functional group and have been recently shown to be produced by the xan cluster in A. fumigatus. Overexpression of the transcription factor present within the cluster results in an increased production of isocyanides and a defect in copper-dependent pigmentation indicating a possible link of this cluster to copper homeostasis [26]. The isocyanides produced by A. fumigatus may represent a unique mechanism, on top of the canonical copper regulatory system [27], to maintaining copper homeostasis for this pathogen.
Arms race: How A. fumigatus uses secondary metabolites to compete in the environment and host
Several secondary metabolites have no known effect or have not been tested for effects on virulence or interactions with the immune system but have only been shown to provide an advantage to A. fumigatus when competing with other microbes in the environment.
Trypacidin
Trypacidin is an anthraquinone that has been found to have antiprotozoal, cytotoxic, and antiphagocytic properties. The compound displays activity against Toxoplasma gondii and Trypanosoma cruzi in vitro that causes toxoplasmosis and Chagas disease, respectively. Deleting the polyketide synthase essential for trypacidin production eliminates production of the metabolite and coincides with an increase in phagocytosis when challenged with Dictyostelium discoideum and macrophages, indicating that trypacidin acts as an antiphagocytic metabolite [28]. The trypacidin pathway shows redundant synthesis to the endocrocin pathway, where both contribute to final endocrocin synthesis in some strains of A. fumigatus [15].
Helvolic acid
Helvolic acid is a fusidane antibiotic that exhibits in vitro antiprotozoal activity against the trypanosome Trypanosoma brucei brucei GUTat3.1, the causative agent of African sleeping sickness [29], and helvolic acid derivatives exhibit antibacterial activity against Streptococcus agalactiae and Staphylococcus aureus [30]. In addition, helvolic acid also affects mammalian cell lines, decreasing the beat frequency of ciliated respiratory epithelium, a process important in preventing colonization by A. fumigatus [31].
Fumiquinazolines
Fumiquinazolines are tryptophan-derived peptidyl alkaloids that have a broad range of activity and accumulate in A. fumigatus conidia [32]. Fumiquinazoline F isolated from cultures of Penicillium coryphilum exhibited activity against S. aureus and Micrococcus luteus [33]. Fumiquinazolines also exhibit antifungal activity with fumiquinazoline H and I isolated from Acremonium sp. showing weak antifungal activity against C. albicans [34].
Fumitremorgins
Fumitremorgins belong to the diketopiperazine alkaloids class of compounds and contain a unique, 8-membered endoperoxide ring. Fumitremorgin B has been found to have in vitro antifungal activity against a variety of phytopathogenic of fungi [35]. In addition, fumitremorgin B was found to be lethal to brine shrimp and displayed antifeedant activity towards armyworm larvae [35]. Fumitremorgins have also been shown to affect mammalian cells. Fumitremorgin C displays inhibitory activity towards the breast cancer resistance protein, an ATP-binding cassette transporter that is implicated in cellular resistance to anticancer drugs [36].
Pyripyropene A
Pyripyropene A was discovered during an investigation into inhibitors of acyl-coenzyme A (CoA):cholesterol acyltransferase, a mechanism by which to treat hypercholesterolemia and atherosclerosis [37]. Pyripyropenes were further shown to exhibit in vivo aphicidal activity against the green peach aphid (Myzus persicae) during a screen of compounds that act as insecticides [38]. How these activities may relate to aspergillosis has not been assessed.
Pseurotin
Pseurotin has been shown to be have several antimicrobial and cytotoxic properties. It has been demonstrated to have antibacterial properties when screened against both gram-positive and gram-negative organisms [39]. This metabolite is encoded by an intertwined biosynthetic gene cluster with fumagillin [40] but, unlike fumagillin, was not implicated in epithelial tissue damage [19].
Neosartoricin
Neosartoricin is a prenylated anthracenone and was discovered following activation of the gene cluster from A. fumigatus and Neosartorya fischeri [41]. The compound was found to have T-cell antiproliferative activity suggesting that the compound functions as an immunosuppressive [41]. Like several metabolites synthesized by A. fumigatus, the biosynthetic gene cluster is conserved in several pathogenic fungi [42].
Fumisoquin
Fumisoquin is an isoquinolone alkaloid with biosynthetic machinery that bears a striking similarity to plant berberine bridge enzyme and tetrahydrocannabinol biosynthesis [43]. Deletion of the fumisoquin transcription factor did not impact virulence in a murine infection model [44]. A related isoquinalone metabolite produced by Aspergillus flavus stimulates Aspergillus species spore germination while inhibiting bacterial growth [45], possibly hinting at a function for fumisoquin.
Nidulanin A
Nidulanin A is a tetracyclopeptide/isoprene isolated from Aspergillus nidulans [46]. The nidulanin A gene cluster is conserved in all Aspergillus spp., including A. fumigatus, although it has not been detected in this fungus [42]. At present, nidulanin A has yet to be tested for any antimicrobial or virulence-related properties.
Prospective
A. fumigatus produces a wide variety of small molecules, many of which are demonstrated to impact virulence, others of which have not been investigated, and likely still some of which have yet to be discovered. These molecules are the weapons that A. fumigatus uses to do battle with the immune system, facilitate the acquisition of essential micronutrients in their environment, and compete with other microbes. It is important to note, however, that A. fumigatus isn’t alone in producing secondary metabolites that affect virulence. Many of these secondary metabolites are conserved in other pathogenic fungi [38]. Studying secondary metabolites produced by A. fumigatus will provide insight into understanding not only the chemical arsenal of A. fumigatus but the chemical arsenal of other pathogenic fungi as well.
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