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Fungi indirectly affect plant root architecture by modulating soil volatile organic compounds
(2018)
The plant-growth modulating effect of microbial volatile organic compounds (VOCs) has been demonstrated repeatedly. This has most often been performed by exposing plants to VOC released by microbes grown on nutrient rich media. Here, we used soil instead to grow fungi of the Fusarium genus and investigate how VOCs emitted by this system influenced the development of Arabidopsis plants. The volatile profiles of Fusarium strains grown in soil and malt extract were also compared. Our results demonstrate that distinct volatile signatures can be attributed to different Fusarium genetic clades but also highlight a major influence of the growth medium on volatile emission. Furthermore, all soil-grown Fusarium isolates increased primary root length in Arabidopsis by decreasing VOC concentrations in soil. This result represents a major paradigm shift in plant-microbe interactions since growth modulating effects have been attributed so far to the emission and not the consumption of volatile signals.
Invasive fungal disease (IFD) in hematopoietic stem cell transplantation is associatedwith high morbidity and mortality. As the antifungal host response determines risk and outcomeof IFD, there is growing interest in adoptive immunotherapy using T cells or natural killer (NK)cells. Although the NK-92 cell line has been tested as anticancer therapy in clinical trials, data onthe antifungal activity of NK-92 cells are lacking. Here, we show that the NK-92 cell line exhibitsconsiderable fungal damage on all medically important fungi tested, such as different species ofAspergillus,Candida, mucormycetes, andFusarium. The extent of fungal damage differs acrossvarious species of mucormycetes andFusarium, whereas it is comparable across different species ofAspergillusandCandida. Interferon (IFN)-γlevels in the supernatant were lower when NK-92 cells areco-incubated withAspergillus fumigatus,Candida albicans, orRhizopus arrhizuscompared to the levelswhen NK-92 cells are incubated alone. Different to primary human NK cells, no increase of perforinlevels in the supernatant was observed when the fungi were added to NK-92 cells. Ourin vitrodatademonstrated that the NK-92 cell line could be a feasible tool for antifungal immunotherapy, butdata of animal models are warranted prior to clinical trials.