Project description:Microbial consortia consist of a multitude of prokaryotic and eukaryotic microorganisms. Their interaction is critical for the functioning of ecosystems. Until now, there is limited knowledge about the communication signals determining the interaction between bacteria and fungi and how they influence microbial consortia. Here, we discovered that bacterial low molecular weight arginine-derived polyketides trigger the production of distinct natural products in fungi. These compounds are produced by actinomycetes found on all continents except Antarctica and are characterized by an arginine-derived positively charged group linked to a linear or cyclic polyene moiety. Producer bacteria can be readily isolated from soil as well as fungi that decode the signal and respond with the biosynthesis of natural products. Both arginine-derived polyketides and the compounds produced by fungi in response shape microbial interactions.

Project description:The soft rot pathogen Janthinobacterium agaricidamnosum causes devastating damage to button mushrooms (Agaricus bisporus), one of the most cultivated and commercially relevant mushrooms. We previously discovered that this pathogen releases the membrane-disrupting lipopeptide jagaricin. This bacterial toxin, however, could not solely explain the rapid decay of mushroom fruiting bodies, indicating that J. agaricidamnosum implements a more sophisticated infection strategy. In this study, we show that secretion systems play a crucial role in soft rot disease. By mining the genome of J. agaricidamnosum, we identified gene clusters encoding a type I (T1SS), a type II (T2SS), a type III (T3SS), and two type VI secretion systems (T6SS). Through a combination of knockout studies and bioassays, we found that the T2SS and T3SS of J. agaricidamnosum are required for soft rot disease. Furthermore, comparative secretome analysis and activity-guided fractionation identified a number of secreted lytic enzymes responsible for mushroom damage. Our findings regarding the contribution of secretion systems to the disease process expand the current knowledge of bacterial soft rot pathogens and represent a significant stride towards identifying targets for their disarmament with secretion system inhibitors.

Project description:Candida albicans is a common commensal on human mucosal surfaces, but can become pathogenic, e.g. if the host is immunocompromised. While neutrophils, macrophages and T cells-driven activation of neutrophils are regarded as major players in the defence against C. albicans, the role of B cells and the protective function of their antibodies are less well characterized. In this study, we show that human serum antibodies are able to enhance the the association of human macrophages with C. albicans cells . Human serum antibodies are also capable of reducing the growth of the fungi as well as inhibiting adhesion to epithelial cells. Furthermore, human serum antibodies impair C. albicans’ invasion into human oral epithelial cells by blocking induced endocytosis and consequently host cell damage. While aspartic proteases secreted by C. albicans were able to cleave human IgG, this process does not appear to affect the protective function of human antibodies in adhesion. Thus, humans are equipped with antiC. albicans antibodies, which can enhance antifungal activities and which can prevent fungal mediated epithelial damage (even in immunocompromised settings).

Project description:Infection by the human pathogenic fungus Aspergillus fumigatus is initialized by the outgrowth of asexual spores (conidia) into the lung tissue of the immunocompromised host following an inhalation of the airborne conidia. The resident phagocytes, the alveolar macrophages are the first immune cells to encounter invading conidia. However, A. fumigatus conidia employ versatile mechanisms to evade the host immune defense and establish a severe invasive infection. Previously, we showed that depending on the presence of conidial 1,8-dihydroxynaphthalene (DHN) melanin, A. fumigatus circumvents intracellular killing by manipulating the phagolysosomal maturation process. Here, by comparative dual proteomics we analyzed proteins of phagolysosomes containing melanized wild-type or non-melanized pksP mutant conidia. Bioinformatics compiled a regulatory module of differentially abundant proteins that mirrors processes targeted by the fungus for immune evasion. Those are i.e. vATPAse-driven phagolysosomal acidification, endocytic trafficking, signal transduction, energy metabolism and immune response. In detail, we found alterations of vATPase complex assembly and impaired abundances of mTOR and MAPK signaling molecules, Rab5 and Vamp8 mediators of endosomal trafficking as well as Lamp1 and cathepsin Z lysosomal markers.

Project description:The RNA interference (RNAi) pathway has evolved numerous functionalities in eukaryotes, with many on display in Kingdom Fungi. RNAi can regulate gene expression, facilitate drug resistance, or even be altogether lost to improve growth potential in some fungal pathogens. In the WHO fungal priority pathogen, Aspergillus fumigatus, the RNAi system is known to be intact and functional. To extend our limited understanding of A. fumigatus RNAi, we first investigated the genetic variation in RNAi-associated genes in a large collection of environmental and clinical genomes, where we found that RNAi is evolutionarily conserved even in clinical strains. Using endogenously expressed inverted-repeat transgenes complementary to both a conditionally essential gene and a nonessential gene, we determined that a subset of the RNAi componentry is active in inverted-repeat transgene silencing in conidia and mycelium. A multi-condition mRNA-seq analysis linked the A. fumigatus dicer-like enzymes and RNA-dependent RNA polymerases to regulation of conidial ribosome biogenesis genes; however, surprisingly few endogenous small RNAs were identified in conidia that could explain this broad change. Although RNAi was not clearly linked to growth or stress response defects in the RNAi knockouts, serial passaging of RNAi knockout strains for six generations resulted in lineages with diminished spore production over time, indicating that loss of RNAi can exert a fitness cost on the fungus. Cumulatively, A. fumigatus RNAi appears to play an active role in defense against double-stranded RNA species alongside a previously unappreciated housekeeping function in regulation of conidial ribosomal biogenesis genes.

Project description:Metabolic adaption to different host niches is one of the most important virulence traits of human fungal pathogens. The metabolic versatility of fungi and other cellular processes such as proliferation, morphogenesis and stress responses are tightly regulated by complex networks in which protein kinases play a crucial role. Serine-arginine (SR) protein kinases are highly conserved in all eukaryotes, but their function in pathogenic Candida spp. has not yet been investigated. C. albicans genome encodes two (Sky1, Sky2) and Candida glabrata one (Sky1) homolog of the human SR protein kinase 1 (SRPK1). We utilized deletion strains of the respective genes in both fungi in order to examine their cellular functions. C. glabrata and C. albicans strains lacking SKY1 exhibited higher resistance to osmotic stress and toxic polyamine concentrations to their ortholog in the model yeast Saccharomyces cerevisiae Sky1. Deletion of SKY2 in C. albicans resulted in impaired utilization of dipeptides as the sole nitrogen source. Subsequent phosphoproteomic analysis identified Ptr22, a transporter of di- and tri-peptides in C. albicans, as a potential Sky2 substrate. Overexpression of PTR22 in the sky2∆ restored the ability to grow on dipeptides as the sole nitrogen source and rendered the cells more susceptible to the dipeptide antibiotics Polyoxin D and Nikkomycin Z. Altogether, our results demonstrate that the two SR-like protein kinases in C. albicans have divergent functions: C. albicans and C. glabrata Sky1 is functionally similar to Sky1 in S. cerevisiae, whereas Sky2 regulates uptake of dipeptides.

Project description:Mucormycosis is a life-threatening disease especially in immunocompromised patients that was caused my mucoralean fungi. The rate of mortality is tremendously increased in the last decades due to the lack of appropriate diagnostic tools, insufficient knowledge about the immune response toward the mucormycosis and unavailability of specific antifungal drugs. Several species of mucoralean fungi cause mucormycosis such as Lichtheimia, Rhizopus, and Mucor. Lichtheimia species ranks the second and third cause of mucormycosis in Europe and the USA, respectively. In this study, we investigated the receptors present on the surface of immune cells that bind to the spores of Lichtheimia. We focus on two strains of L. corymbifera (FSU:9682 and FSU:10164) using resting and heat-killed spores. Additionally, we choose alveolar macrophages (MH-S) to carry out our experiment. MH-S is the first line of defense in the lung and the major component in the innate immune system. MH-S surface proteins were biotinylated and incubated with Lichtheimia spores. The surface proteins and putative binding partners were enriched by streptavidin. LC-MS/MS analysis showed that several proteins are highly expressed in presence of Lichtheimia spores, of which the heat shock protein family A (HSPA8) was one of the most abundant proteins. FACS analysis and immunofluorescence examination confirmed that HSPA8 is highly abundant on the surface of the MH-S, but not on the surface of Lichtheimia spores. Moreover, our study showed that the intensity of HSPA8 on the surface of MH-S depends on the multiplicity of infection (MOI). Additionally, the blocking with anti-HSPA8 antibody reduced the capability of MH-S to engulf the Lichtheimia spores, but not Aspergillus fumigatus spores. This confirms that HSPA8 is specific to Lichtheimia. THis is the first study addressing the determination of surface receptors of alveolar macrophages that in the context of Mucoralean fungi.

Project description:Through transcriptome profiling using RNA-seq, we investigated the mechanisms behind bacterial endosymbiont (Burkholderia rhizoxinica) control over host (Rhizopus microsporus) reproductive biology. By analyzing differential expression across six different conditions, including fungal opposite mates growing independently with or without endosymbionts, as well as opposite mates growing together with endosymbionts (mating) or without endosymbionts (no mating), we were able to identify that endosymbionts control expression of a Ras signaling protein critical for sexual reproduction in many fungi (Ras2). As little is known regarding sexual reproduction in Mucoromycotina, we also used these data to investigate conservation of sex-related genes across all fungi, as well as predict potential genes involved in sensing of trisporic acid, the mating pheromone used by these fungi.

Project description:Predatory interactions among microbes are a major evolutionary driving force for biodiversity. The fungivorous amoeba Protostelium aurantium has a wide fungal food spectrum including major pathogenic members of the genus Candida. Phagocytic feeding by P. aurantium is highly effective with C. parapsilosis, a major pathogenic yeast. Here we show that upon ingestion by the amoeba C. parapsilosis is confronted with an oxidative burst and undergoes phagosomal lysis within minutes. On the fungal side, a functional genomic approach identified the fungal copper and redox homeostasis as primary targets of amoeba predation with the highly expressed copper exporter Crp1 and the peroxiredoxin Prx1 contributing to survival when encountering P. aurantium. The fungolytic activity was largely retained in intracellular vesicles of the amoebae. Following their isolation, the content of these vesicles induced immediate killing and lysis of C. parapsilosis. A proteomic analyses identified 56 vesicular proteins. Although fully unknown proteins were dominant, many of them could be categorized as hydrolytic enzymes presumably targeting the fungal cell wall, indicating that fungal cell wall structures are under predatory selection pressure in natural environments.

Project description:Plants interact with a wide variety of fungi in a mutualistic, parasitic or neutral way. The associations formed depend on the exchange of nutrients and signalling molecules between the partners. The latter include a diverse set of protein classes, of which some have been demonstrated to be functionally implicated in defence, nutrient uptake and establishing a symbiotic relationship. Here, we have analysed the secretomes of the mutualistic, root-endophytic fungus Piriformospora indica and Arabidopsis thaliana when cultivated alone or in a co-culture. More than one hundred proteins were identified as differentially secreted, including proteins associated with growth, development, abiotic and biotic stress response and mucilage. One protein found in the co-culture is PLAT1 (Polycystin, Lipoxygenase, Alpha-toxin and Triacylglycerol lipases). PLAT1 has not been associated with plant-fungal-interaction before and is known to play a role in abiotic stress responses. It co-localizes with Brassicaceae-specific endoplasmic reticulum bodies (ER bodies), which are involved in the formation of the defence compound scopolin. We observed degraded ER bodies in P. indica infected Arabidopsis roots and plat1 mutants were stronger colonised than wild tyype (WT) plants. Furthermore, PLAT1 RNA (ribonucleic acid) and scopolin levels were detected to be regulated by the fungus in a stage-specific manner.