This thesis spans several years of work dedicated to understanding fish genomes. In the first chapter it describes the genome of the first fish for which the entire genome was sequenced through a... Show moreThis thesis spans several years of work dedicated to understanding fish genomes. In the first chapter it describes the genome of the first fish for which the entire genome was sequenced through a large-scale international project, Fugu rubripes. the pufferfish. In particular, it highlights how this fish has a genome that contains as many genes as the human genome, although it is ten times smaller. It also shows that the majority of genes that are found in the human genome can be found in this fish genome as well. In the second chapter we compared fish genomes to the human genome to find regions that have been preserved during evolution and which are therefore likely to have a function, even though they are not genes. We showed that indeed they are functional, and they help to regulate other genes. Knowing all the genes in the genome we could then interrogate how they are expressed, i.e. if they are switched __on__ or __off__ and in particular in chapter 4 we looked at how a specific gene is in charge of gradually switching off genes that are inherited from the mother in a newborn fish embryo. Finally in the last chapter since genome sequencing is now becoming much cheaper and simpler to achieve we set out to map the genome of the common carp and we discuss the best approaches and strategies to obtain a good genome sequence for this species. The common carp is a candidate model system for high-troughput screening. Show less
The study of bacterial-fungal interactions is essential to obtain a better understanding of terrestrial microbial ecology and may lie at the basis of novel applications in agriculture, food... Show moreThe study of bacterial-fungal interactions is essential to obtain a better understanding of terrestrial microbial ecology and may lie at the basis of novel applications in agriculture, food industry and human health. Nevertheless, the incentives, the genetic determinants and the mechanisms that underlie bacterial-fungal interactions are still poorly understood. Bacterial mycophagy is a trophic behaviour that takes place when bacteria obtain nutrients from living fungal hyphae, allowing the conversion of living fungal biomass into bacterial biomass (29). This trophic behavior was demonstrated for the first time for bacteria of the genus Collimonas, based on their ability to grow at the expenses of living fungal hyphae in a soil-like microcosm (28, 30). In this thesis I addressed the following research questions: (1) Which of the mechanisms putatively involved in Collimonas mycophagy are actually activated when Collimonas interact with a fungus (2) What is the fungal response to the presence of Collimonas bacteria? (3) What is the role played by plasmid pTer331, detected in the genome of the mycophagous bacterium C. fungivorans Ter331, in the ecology of this bacterium? Are the genes encoded on plasmid pTer331 involved in mycophagy? (4) Are the putative determinants of mycophagy uniformly distributed among Collimonas species? Show less