The soil-dwelling, filamentous bacteria of the genus Streptomyces are renowned for their production of useful secondary metabolites including antibiotics. The work described in this thesis provides... Show moreThe soil-dwelling, filamentous bacteria of the genus Streptomyces are renowned for their production of useful secondary metabolites including antibiotics. The work described in this thesis provides new insights on the role and regulation of antibiotic production and resistance in these bacteria. It shows that antibiotic resistance is already beneficial at sub-inhibitory antibiotic concentrations. Resistance can even readily evolve at such low concentrations, thereby possibly explaining the level of resistance seen in pristine environments. Antibiotic producers can benefit from spatial structure, as present in the soil, through the preferential allocation of resources and this enables invasion from low frequencies. Streptomyces do not produce all antibiotics continuously, but antibiotic production is instead tightly regulated in response to environmental cues, including those produced by competitors. Streptomyces are most likely to induce antibiotic production in response to a competitor that shares similar secondary metabolite clusters, indicating a possible role for shared signalling. Besides changes in antibiotic production, other responses to competition are revealed on a transcriptomic level, including an increased expression of developmental genes, suggesting earlier sporulation. Show less
Streptomyces are filamentous bacteria that produce more than two-thirds of known antibiotics. Due to their multicellular lifestyle as well as their prolific production of secondary metabolites, Str...Show moreStreptomyces are filamentous bacteria that produce more than two-thirds of known antibiotics. Due to their multicellular lifestyle as well as their prolific production of secondary metabolites, Streptomyces are of unique fundamental and applied importance. However, Streptomyces have unstable genomes, an attribute that can cause genomic rearrangements and dramatically alter their phenotype. Previous studies have failed to explain this phenomenon. In this dissertation, we investigate the evolutionary functions and mechanisms of genomic instability in Streptomyces coelicolor. We first find that a subpopulation of cells generated through large genomic rearrangements becomes specialized to produce antibiotics. This results in a division of labor which benefits the entire colony, while the yield and diversity of antibiotics are maximized, despite significant fitness costs to this altruistic subpopulation. Next, we show that these altruistic mutants continue to lose fitness due to the irreversible accumulation of large deletions and deleterious mutations, coupled to an increased mutation rate. Finally, we explore the molecular consequences of large genomic rearrangements for development and antibiotic production using detailed proteomics and metabolomics analyses, which highlight key pathways that are impacted by these genomic events. Overall, this dissertation provides new insights of genomic instability in Streptomyces. Show less
