Protoplast-mediated transformation of Madurella mycetomatis using hygromycin resistance as a selection marker.

Madurella mycetomatis is the main cause of mycetoma, a chronic granulomatous infection for which currently no adequate therapy is available. To improve therapy, more knowledge on a molecular level is required to understand how M. mycetomatis is able to cause this disease. However, the genetic toolbox for M. mycetomatis is limited. To date, no method is available to genetically modify M. mycetomatis. In this paper, a protoplast-mediated transformation protocol was successfully developed for this fungal species, using hygromycin as a selection marker. Furthermore, using this method, a cytoplasmic-GFP-expressing M. mycetomatis strain was created. The reported methodology will be invaluable to explore the pathogenicity of M. mycetomatis and to develop reporter strains which can be useful in drug discovery as well as in genetic studies.

Aspergillus fumigatus establishes infection in zebrafish by germination of phagocytized conidia, while Aspergillus niger relies on extracellular germination.

Among opportunistically pathogenic filamentous fungi of the Aspergillus genus, Aspergillus fumigatus stands out as a drastically more prevalent cause of infection than others. Utilizing the zebrafish embryo model, we applied a combination of non-invasive real-time imaging and genetic approaches to compare the infectious development of A. fumigatus with that of the less pathogenic A. niger. We found that both species evoke similar immune cell migratory responses, but A. fumigatus is more efficiently phagocytized than A. niger. Though efficiently phagocytized, A. fumigatus conidia retains the ability to germinate and form hyphae from inside macrophages leading to serious infection even at relatively low infectious burdens. By contrast, A. niger appears to rely on extracellular germination, and rapid hyphal growth to establish infection. Despite these differences in the mechanism of infection between the species, galactofuranose mutant strains of both A. fumigatus and A. niger display attenuated pathogenesis. However, deficiency in this cell wall component has a stronger impact on A. niger, which is dependent on rapid extracellular hyphal growth. In conclusion, we uncover differences in the interaction of the two fungal species with innate immune cells, noticeable from very early stages of infection, which drive a divergence in their route to establishing infections.

Expanding the chemical space for natural products by Aspergillus-Streptomyces co-cultivation and biotransformation.

Actinomycetes and filamentous fungi produce a wide range of bioactive compounds, with applications as antimicrobials, anticancer agents or agrochemicals. Their genomes contain a far larger number of gene clusters for natural products than originally anticipated, and novel approaches are required to exploit this potential reservoir of new drugs. Here, we show that co-cultivation of the filamentous model microbes Streptomyces coelicolor and Aspergillus niger has a major impact on their secondary metabolism. NMR-based metabolomics combined with multivariate data analysis revealed several compounds that correlated specifically to co-cultures, including the cyclic dipeptide cyclo(Phe-Phe) and 2-hydroxyphenylacetic acid, both of which were produced by A. niger in response to S. coelicolor. Furthermore, biotransformation studies with o-coumaric acid and caffeic acid resulted in the production of the novel compounds (E)-2-(3-hydroxyprop-1-en-1-yl)-phenol and (2E,4E)-3-(2-carboxy-1-hydroxyethyl)-2,4-hexadienedioxic acid, respectively. This highlights the utility of microbial co-cultivation combined with NMR-based metabolomics as an efficient pipeline for the discovery of novel natural products.

Galactofuranose-coated gold nanoparticles elicit a pro-inflammatory response in human monocyte-derived dendritic cells and are recognized by DC-SIGN.

Galactofuranose (Galf) is the five-membered ring form of galactose exclusively found in nonmammalian species, among which several are pathogens. To determine the putative role of this carbohydrate in host-pathogen interactions, we synthesized multivalent gold nanoparticles carrying Galf (Galf-GNPs) and show that they are recognized by the EB-A2 antibody, which is widely used to detect Galf-containing galactomannan in the serum of Aspergillosis patients. We demonstrated that human monocyte-derived dendritic cells bound Galf-GNPs via interaction with the lectin DC-SIGN. Moreover, interaction of dendritic cells with Galf-GNPs resulted in increased expression of several maturation markers on these cells and induced secretion of the pro-inflammatory cytokines IL-6 and TNF-α. These data indicate that Galf is able to modulate the innate immune response via dendritic cells. In conclusion, Galf-GNPs are a versatile tool that can be applied in multiple functional studies to gain a better understanding of the role of Galf in host-pathogen interaction.

Analysis of the role of the Aspergillus niger aminolevulinic acid synthase (hemA) gene illustrates the difference between regulation of yeast and fungal haem- and sirohaem-dependent pathways.

To increase knowledge on haem biosynthesis in filamentous fungi like Aspergillus niger, pathway-specific gene expression in response to haem and haem intermediates was analysed. This analysis showed that iron, 5'-aminolevulinic acid (ALA) and possibly haem control haem biosynthesis mostly via modulating expression of hemA [coding for 5'-aminolevulinic acid synthase (ALAS)]. A hemA deletion mutant (ΔhemA) was constructed, which showed conditional lethality. Growth of ΔhemA was supported on standard nitrate-containing media with ALA, but not by hemin. Growth of ΔhemA could be sustained in the presence of hemin in combination with ammonium instead of nitrate as N-source. Our results suggest that a branch-off within the haem biosynthesis pathway required for sirohaem synthesis is responsible for lack of growth of ΔhemA in media containing nitrate as sole N-source, because of the requirement of sirohaem for nitrate assimilation, as a cofactor of nitrite reductase. In contrast to the situation in Saccharomyces cerevisiae, cysteine, but not methionine, was found to further improve growth of ΔhemA. These results demonstrate that A. niger can use exogenous hemin for its cellular processes. They also illustrate important differences in regulation of haem biosynthesis and in the role of haem and sirohaem in A. niger compared to S. cerevisiae.

Vacuolar H(+)-ATPase plays a key role in cell wall biosynthesis of Aspergillus niger.

The identification of suitable targets is crucial for the discovery and development of new antifungals. Since the fungal cell wall is an essential organelle, the identification of genes involved in cell wall biosynthesis is expected to help discover new antifungal targets. From our previously obtained collection of cell wall mutants with a constitutively active cell wall stress response pathway, we selected a thermosensitive, osmotic-remediable mutant with decreased resistance to SDS for complementation analysis. The phenotypes of this mutant were complemented by a gene encoding a protein with high sequence similarity to subunit d of the eukaryotic Vacuolar-H(+)-ATPase (VmaD). Genetic analysis of this thermosensitive mutant revealed that the conditional mutant allele encodes a protein that lacks 12 amino acids at the C-terminus due to a point mutation that introduces a stop codon. Deletion of the entire gene resulted in very poor growth. The conditional mutant displayed several phenotypes that are typical for V-ATPase mutants, including increased sensitivity to zinc ions and reduced acidification of the vacuole as observed by quinacrine staining. Treatment of Aspergillus niger with the V-ATPase inhibitor bafilomycinB(1) induced the expression of agsA and other cell wall related genes. Furthermore genes involved in cell wall reassembly like fksA, agsA and phiA were clearly up-regulated in the conditional mutant. Our results indicate that the ATP-driven transport of protons and acidification of the vacuole is crucial for the strength of the fungal cell wall and that reduced activity of the V-ATPase induces the cell wall stress response pathway.