Inferring Ancestry : Mitochondrial Origins and Other Deep Branches in the Eukaryote Tree of Life

Sammanfattning: There are ~12 supergroups of complex-celled organisms (eukaryotes), but relationships among them (including the root) remain elusive. For Paper I, I developed a dataset of 37 eukaryotic proteins of bacterial origin (euBac), representing the conservative protein core of the proto-mitochondrion. This gives a relatively short distance between ingroup (eukaryotes) and outgroup (mitochondrial progenitor), which is important for accurate rooting. The resulting phylogeny reconstructs three eukaryote megagroups and places one, Discoba (Excavata), as sister group to the other two (neozoa). This rejects the reigning “Unikont-Bikont” root and highlights the evolutionary importance of Excavata.For Paper II, I developed a 150-gene dataset to test relationships in supergroup SAR (Stramenopila, Alveolata, Rhizaria). Analyses of all 150-genes give different trees with different methods, but also reveal artifactual signal due to extremely long rhizarian branches and illegitimate sequences due to horizontal gene transfer (HGT) or contamination. Removing these artifacts leads to strong consistent support for Rhizaria+Alveolata. This breaks up the core of the chromalveolate hypothesis (Stramenopila+Alveolata), adding support to theories of multiple secondary endosymbiosis of chloroplasts.For Paper III, I studied the evolution of cox15, which encodes the essential mitochondrial protein Heme A synthase (HAS). HAS is nuclear encoded (nc-cox15) in all aerobic eukaryotes except Andalucia godoyi (Jakobida, Excavata), which encodes it in mitochondrial DNA (mtDNA) (mt-cox15). Thus the jakobid gene was postulated to represent the ancestral gene, which gave rise to nc-cox15 by endosymbiotic gene transfer. However, our phylogenetic and structure analyses demonstrate an independent origin of mt-cox15, providing the first strong evidence of bacteria to mtDNA HGT.Rickettsiales or SAR11 often appear as sister group to modern mitochondria. However these bacteria and mitochondria also have independently evolved AT-rich genomes. For Paper IV, I assembled a dataset of 55 mitochondrial proteins of clear α-proteobacterial origin (including 30 euBacs). Phylogenies from these data support mitochondria+Rickettsiales but disagree on the placement of SAR11. Reducing amino-acid compositional heterogeneity (resulting from AT-bias) stabilizes SAR11 but moves mitochondria to the base of α-proteobacteria. Signal heterogeneity supporting other alternative hypotheses is also detected using real and simulated data. This suggests a complex scenario for the origin of mitochondria.