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Marlies Monnens

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The transition from a free-living lifestyle to endosymbiosis represents a large evolutionary shift, impacting various aspects of any organism’s biology, including its molecular basis. So far, it has been impossible to generalise the impact this lifestyle shift has on genomic architecture. This study explores this phenomenon using a new model system: neodalyellid flatworms (Rhabdocoela), a diverse assemblage of free-living and independently evolved endosymbiotic lineages. A uniquely comprehensive mitochondrial genomic dataset, consisting of 50 complete or partial mitogenome sequences (47 of which are new to science), is constructed, increasing the genomic resources available for rhabdocoel flatworms over tenfold. A robust phylogenomic framework is built, enabling an in-depth exploration of the molecular-genetic signatures associated with evolutionary shifts towards endosymbiosis. To understand speciation influenced by host phylogeny, first steps are taken to unravel the host-switching history of the largest endosymbiotic group of neodalyellids. We test several hypotheses regarding the potential consequences of a symbiotic lifestyle, and find heightened AT content, more pronounced AT skew, and relaxed selection on specific protein-coding genes in endosymbionts compared to their free-living counterparts. Numerous substitutions have accumulated in certain endosymbiotic lineages; however, the correlation with lifestyle remains uncertain. A high frequency of genetic rearrangements across all studied lineages is observed. Our findings affirm the variable nature of rhabdocoel mitogenomes and, for the first time, reveal distinct signatures of an endosymbiotic lifestyle in neodalyellid flatworms. This effort lays the groundwork for future research into the evolutionary and genomic consequences of a symbiotic lifestyle in this and other animal systems.

Inês Matos

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Phoretic mites have been found attached to different body parts of red palm weevil (RPW), Rhynchophorus ferrugineus (Olivier, 1790), to disperse. However, the question of how the patterns of attachment sites are formed remains intriguing. Here, we conducted the first study of RPW-associated phoretic mites in Portugal, particularly in the districts of Viana do Castelo, Braga, Porto and Aveiro in Northern Portugal (macrohabitat), and investigated the patterns of mite distribution on six body parts of RPW (microhabitat). At the macrohabitat level, we detected seven phoretic mite taxa actively using RPW host in each of the four studied districts, all documented for the first time in association with this invasive exotic species in Portugal. However, their relative abundance (species evenness) varied between districts, as did species diversity. All examined weevils carried mites, and the prevalence of the different taxa did not differ between districts or sex of weevils. Measured by mean abundance and degree of aggregation, Centrouropoda sp. proved to be the common dominant taxon, while Acarus sp. and C. rhynchoporus were considered common subordinate taxa and Uroovobella sp., Mesostigmata, N. extremica and Dendrolaelaps sp. sparse taxa. At the microhabitat level, all taxa were present in all body parts of the RPW; the highest abundance was in a region encompassing the inner surface of the elytra and the membranous hind wings (subelytral space). Analysis of niche overlap revealed that the distribution patterns of phoretic mite taxa on the RPW were not randomly structured. In the subelytral space, interspecific coexistence of mites increased as a function of body size difference with the dominant Centrouropoda sp. We conclude that the distribution patterns of RPW-associated phoretic mites show body size-dependent effects that resulted in the dominant taxon displacing similar size taxa and accepting taxa with which it has the greatest size difference as co-habitants.