This thesis aims to investigate the effect of tripartite interaction between microbial inoculants, the plant, and herbivore insects on the rhizosphere microbiome and volatilome. We investigated the... Show moreThis thesis aims to investigate the effect of tripartite interaction between microbial inoculants, the plant, and herbivore insects on the rhizosphere microbiome and volatilome. We investigated the rhizosphere microbiome and volatilome of tomato plants exposed to insect herbivory and/or inoculated with beneficial microbes known to trigger ISR. First, we reviewed the abiotic and biotic factors that impact the success of ISR microbial inoculants (Chapter 2). Then, we tested microbial inoculants against different stresses and experimental conditions to compare interactions in variable contexts (Chapter 3). Next, we explored the impact of insect herbivory aboveground, on the volatile and microbial belowground compartment. In Chapter 4 we explored root volatiles under stress in two tomato species to evaluate the genotype impact on the stress-induced root volatilome. In Chapter 5, we studied the impact of endosymbiotic fungi arbuscular mycorrhizal fungi (AMF) on root volatiles in an in vitro bioassay and in a greenhouse setup with herbivory-stressed plants. In Chapter 6, we compared the effect of four phylogenetically diverse bacteria and fungi, inoculated as single-species and as a synthetic community, on the rhizosphere microbiome assembly and volatilome in herbivory-stressed plants. Overall, this thesis delves into overlooked interactions providing novel data on belowground plant-microbe interactions. Show less
Actinobacteria are Gram-positive bacteria that have a complex multicellular life cycle and are well known for their ability to produce a wide range of bioactive natural products (NPs). High... Show moreActinobacteria are Gram-positive bacteria that have a complex multicellular life cycle and are well known for their ability to produce a wide range of bioactive natural products (NPs). High throughput screening has failed to deliver the new antibiotics we so desperately need to combat multidrug-resistant pathogens. Therefore, new systematic approaches are needed to further explore the rich potential of Actinobacteria. The work described in this thesis entails systems biology approaches consisting of technologies such as proteomics, genomics, metabolomics and DNA binding studies. These were then applied to identify the biosynthetic gene clusters (BGCs) that are responsible for the production of novel antibiotics. Small molecules were thereby used as elicitors to activate the expression of cryptic BGCs in Streptomyces roseifaciens. Furthermore, S. coelicolor M1152 that was optimized for heterologous expression of antibiotics, was analysed for changes in protein expression, to understand which changes correlate to optimal antibiotic production. Finally, the role of the nucleoid associated protein SCO1839 in development and antibiotic production was studied. Chip-seq technology showed that it binds to thousands of DNA sequences on the S. coelicolor chromosome, which contain the motif GATC. I hope that this thesis contributes to utilizing multi-dimensional ‘omics approaches to answer major biological questions. Show less