Function and Evolution of Small Regulatory RNAs and their Associated Proteins : A Journey from Genome to Proteome

Abstract: Organisms throughout the tree of life have evolved distinct ways to regulate gene expression. Some of these processes involve non-coding RNAs (ncRNAs), which are not translated but functional nonetheless. These ncRNAs are of utmost importance, with dysregulation of some causing severe developmental effects or even being lethal.In order to get a better fundamental understanding of gene regulation, and the ncRNAs that evolved to regulate gene expression, we study this in Amoebozoa. Members of this taxon vary greatly in lifestyle and organismal complexity. Some are strictly unicellular, free-living, whereas others, such as the social amoeba Dictyostelium discoideum can transition between unicellular and multicellular lifestyles. D. discoideum features a variety of small ncRNAs. Among these are the microRNAs. microRNAs have mostly been studied in plants and animals, where they are believed to have evolved convergently, and hypothesized to have played a role when these taxa evolved multicellular lifestyles. At what point the D. discoideum microRNAs evolved, how they function, and if they are involved in its multicellular lifestyle are fundamental questions addressed in this thesis. Here, we studied the evolution and function of microRNAs in a broad set of species belonging to Amoebozoa. We could identify microRNAs in all studied amoebae, and concluded that they are probably not involved in the evolution of multicellularity. To in detail investigate the evolution of microRNAs, we performed comparative genomics using D. discoideum and the close relative Dictyostelium firmibasis. For this, we sequenced, assembled and annotated the genome of the latter. At this point, our findings suggest that the microRNAs evolved several times in Amoebozoa, although we cannot rule out if they have a deep evolutionary history.The Class I RNAs are another type of ncRNAs. These, on the other hand, are only present in the social amoebae. They are hypothesized to regulate the transition from unicellular to multicellular in these species, potentially in a post-transcriptional manner. In order to investigate this, it is essential to understand to what extent the proteome and transcriptome correlate. Hence, we performed paired transcriptomics and proteomics in a time-series during multicellular development. By including a strain in which a specific Class I RNA is knocked out, we have initiated studies of its role during the transition to multicellularity.In conclusion, we were able to answer broad evolutionary and functional questions about gene regulation and ncRNAs by studying Amoebozoa from genome to proteome.