Studies on galactofuranose-containing glycostructures of the pathogenic mold Aspergillus fumigatus.

Galactofuranose is a hexose that is exclusively found in microbes and in particular in certain pathogenic species. In the mold Aspergillus fumigatus, it is the characteristic constituent of the cell wall component galactomannan. Detection of this carbohydrate is currently a widespread method used for diagnosis of systemic A. fumigatus infections. In this study, we raised and characterized 2 monoclonal antibodies that specifically react with galactofuranose-containing glycostructures. We investigated the distribution of surface-accessible galactomannan on different A. fumigatus morphotypes. We provide evidence that the antibodies recognize distinct antigens and are suitable to detect A. fumigatus hyphae in immunohistology. A mutant that is impaired in synthesis of galactofuranose stimulated a normal cytokine response in murine macrophages, which argues against galactomannan being a relevant PAMP, at least in mice. Purified galactomannan-specific monoclonal IgM L10-1 failed to inhibit the hyphal growth under in vitro conditions, but L10-1 binding to hyphae led to an enhanced deposition of the complement protein C1q. However, administration of purified L10-1 antibodies prior to infection was not able to protect mice. In conclusion, we have found no evidence for galactomannan being a relevant A. fumigatus PAMP and describe 2 novel galactomannan antibodies that might be valuable tools for the diagnosis of A. fumigatus infections and further analysis of the biological significance of galactomannan.

The mitA gene of Aspergillus fumigatus is required for mannosylation of inositol-phosphorylceramide, but is dispensable for pathogenicity.

GDP-mannose:inositol-phosphorylceramide (MIPC)-derived glycosphingolipids are important pathogen-associated molecular patterns (PAMP) of Candida albicans and according to recently published data also of Aspergillus fumigatus. MIPC transferases are essential for the synthesis of MIPC, but have so far been studied only in Saccharomyces cerevisiae and C. albicans. Here, we have identified MitA as the only MIPC transferase in A. fumigatus. The DeltamitA mutant lacks MIPC and MIPC-derived glycosphingolipids and accumulates the precursor IPC. The mutant grows normally, shows no defects in cell wall or membrane organization and a normal resistance to different stressors. It is, however, sensitive to high Ca(2+) concentrations, especially during germination. Germination of DeltamitA mutant conidia is also decelerated under normal growth conditions, but neither the virulence of this mutant in a systemic model of infection nor its ability to trigger a cytokine response in macrophages is impaired, arguing against a role of MIPC-derived glycosphingolipids as important A. fumigatus PAMPs.

Approaching the secrets of N-glycosylation in Aspergillus fumigatus: characterization of the AfOch1 protein.

The mannosyltransferase Och1 is the key enzyme for synthesis of elaborated protein N-glycans in yeast. In filamentous fungi genes implicated in outer chain formation are present, but their function is unclear. In this study we have analyzed the Och1 protein of Aspergillus fumigatus. We provide first evidence that poly-mannosylated N-glycans exist in A. fumigatus and that their synthesis requires AfOch1 activity. This implies that AfOch1 plays a similar role as S. cerevisiae ScOch1 in the initiation of an N-glycan outer chain. A Δafoch1 mutant showed normal growth under standard and various stress conditions including elevated temperature, cell wall and oxidative stress. However, sporulation of this mutant was dramatically reduced in the presence of high calcium concentrations, suggesting that certain proteins engaged in sporulation require N-glycan outer chains to be fully functional. A characteristic feature of AfOch1 and Och1 homologues from other filamentous fungi is a signal peptide that clearly distinguishes them from their yeast counterparts. However, this difference does not appear to have consequences for its localization in the Golgi. Replacing the signal peptide of AfOch1 by a membrane anchor had no impact on its ability to complement the sporulation defect of the Δafoch1 strain. The mutant triggered a normal cytokine response in infected murine macrophages, arguing against a role of outer chains as relevant Aspergillus pathogen associated molecular patterns. Infection experiments provided no evidence for attenuation in virulence; in fact, according to our data the Δafoch1 mutant may even be slightly more virulent than the control strains.

The putative alpha-1,2-mannosyltransferase AfMnt1 of the opportunistic fungal pathogen Aspergillus fumigatus is required for cell wall stability and full virulence.

Proteins entering the eukaryotic secretory pathway commonly are glycosylated. Important steps in this posttranslational modification are carried out by mannosyltransferases. In this study, we investigated the putative alpha-1,2-mannosyltransferase AfMnt1 of the human pathogenic mold Aspergillus fumigatus. AfMnt1 belongs to a family of enzymes that comprises nine members in Saccharomyces cerevisiae but only three in A. fumigatus. A Deltaafmnt1 mutant is viable and grows normally at 37 degrees C, but its hyphal cell wall appears to be thinner than that of the parental strain. The lack of AfMnt1 leads to a higher sensitivity to calcofluor white and Congo red but not to sodium dodecyl sulfate. The growth of the mutant is abrogated at 48 degrees C but can be restored by osmotic stabilization. The resulting colonies remain white due to a defect in the formation of conidia. Electron and immunofluorescence microscopy further revealed that the observed growth defect of the mutant at 48 degrees C can be attributed to cell wall instability resulting in leakage at the hyphal tips. Using a red fluorescence fusion protein, we localized AfMnt1 in compact, brefeldin A-sensitive organelles that most likely represent fungal Golgi equivalents. The tumor necrosis factor alpha response of murine macrophages to hyphae was not affected by the lack of the afmnt1 gene, but the corresponding mutant was attenuated in a mouse model of infection. This and the increased sensitivity of the Deltaafmnt1 mutant to azoles, antifungal agents that currently are used to treat Aspergillus infections, suggest that alpha-1,2-mannosyltransferases are interesting targets for novel antifungal drugs.

Characterisation of the phagocytic uptake of Aspergillus fumigatus conidia by macrophages.

Aspergillus fumigatus is an opportunistic fungal pathogen responsible for severe, life-threatening infections in immunocompromised patients. Airborne conidia are the infectious agent and can reach the lower parts of the respiratory system. In the lung, phagocytes represent the first line of defence. Resident macrophages are able to track down, engulf and kill the invading spores. Phagocytosis of the conidia is therefore a prerequisite for their efficient elimination. Using human and murine macrophages we analysed the phagocytic uptake of A. fumigatus conidia. We found that conidial phagocytosis is an actin-depending process that additionally requires myosin motor, phosphoinositide-3-phosphate kinase and tyrosine kinase activity. Both broad range tyrosine kinase inhibitors and inhibitors that specifically block src kinases had a strong impact on the conidial uptake. Immunofluorescence data demonstrate the recruitment of tyrosine-phosphorylated proteins to the vicinity of engulfed conidia. Uptake of the conidia was accompanied by a strong and local reorganisation of the actin cytoskeleton, whereas no prominent reorganisation was apparent for the microtubules. Both confocal immunofluorescence and electron microscopic data revealed the presence of large ruffle-like structures engaged in the uptake of conidia. This suggests that the internalisation of A. fumigatus spores can be mediated by a process resembling macropinocytosis, which is furthermore supported by the detection of intracellular conidia within spacious vacuoles. Taken together, our data provide new insights into the internalisation of A. fumigatus spores by macrophages, a key process in the early immune defence against an Aspergillus infection.

Effects of plant biomass, plant diversity, and water content on bacterial communities in soil lysimeters: implications for the determinants of bacterial diversity.

Soils may comprise tens of thousands to millions of bacterial species. It is still unclear whether this high level of diversity is governed by functional redundancy or by a multitude of ecological niches. In order to address this question, we analyzed the reproducibility of bacterial community composition after different experimental manipulations. Soil lysimeters were planted with four different types of plant communities, and the water content was adjusted. Group-specific phylogenetic fingerprinting by PCR-denaturing gradient gel electrophoresis revealed clear differences in the composition of Alphaproteobacteria, Betaproteobacteria, Bacteroidetes, Chloroflexi, Planctomycetes, and Verrucomicrobia populations in soils without plants compared to that of populations in planted soils, whereas no influence of plant species composition on bacterial diversity could be discerned. These results indicate that the presence of higher plant species affects the species composition of bacterial groups in a reproducible manner and even outside of the rhizosphere. In contrast, the environmental factors tested did not affect the composition of Acidobacteria, Actinobacteria, Archaea, and Firmicutes populations. One-third (52 out of 160) of the sequence types were found to be specifically and reproducibly associated with the absence or presence of plants. Unexpectedly, this was also true for numerous minor constituents of the soil bacterial assemblage. Subsequently, one of the low-abundance phylotypes (beta10) was selected for studying the interdependence under particular experimental conditions and the underlying causes in more detail. This so-far-uncultured phylotype of the Betaproteobacteria species represented up to 0.18% of all bacterial cells in planted lysimeters compared to 0.017% in unplanted systems. A cultured representative of this phylotype exhibited high physiological flexibility and was capable of utilizing major constituents of root exudates. Our results suggest that the bacterial species composition in soil is determined to a significant extent by abiotic and biotic factors, rather than by mere chance, thereby reflecting a multitude of distinct ecological niches.