Infection by Crithidia bombi increases relative abundance of Lactobacillus spp. in the gut of Bombus terrestris.

Gut microbial communities confer protection against natural pathogens in important pollinators from the genera Bombus and Apis. In commercial species B. terrestris and B. impatiens, the microbiota increases their resistance to the common and virulent trypanosomatid parasite Crithidia bombi. However, the mechanisms by which gut microorganisms protect the host are still unknown. Here, we test two hypotheses: microbiota protect the host (1) through stimulation of its immune response or protection of the gut epithelium and (2) by competing for resources with the parasite inside the gut. To test them, we reduced the microbiota of workers and then rescued the microbial community by feeding them with microbiota supplements. We then exposed them to an infectious dose of C. bombi and characterised gene expression and gut microbiota composition. We examined the expression of three antimicrobial peptide genes and Mucin-5AC, a gene with a putative role in gut epithelium protection, using qPCR. Although a protective effect against C. bombi was observed in bumblebees with supplemented microbiota, we did not observe an effect of the microbiota on gene expression that could explain alone the protective effect observed. On the other hand, we found an increased relative abundance of Lactobacillus bacteria within the gut of infected workers and a negative correlation of this genus with Gilliamella and Snodgrassella genera. Therefore, our results point to a displacement of bumblebee endosymbionts by C. bombi that might be caused by competition for space and nutrients between the parasite and the microbiota within the gut.

La microbiota intestinal confiere protección frente a los patógenos naturales en polinizadores importantes de los géneros Bombus y Apis. En concreto, la microbiota de las especies comerciales B. terrestris y B. impatients, incrementa su resistencia frente al parásito tripanosomátido común y virulento Crithidia bombi. Sin embargo, los mecanismos por los cuales los microorganismos protegen al hospedador todavía se desconocen. Aquí probamos dos hipótesis: la microbiota protege al hospedador (1) a través de la estimulación de la respuesta inmunitaria o la protección del epitelio y (2) por competición por los recursos con el parásito dentro del intestino. Para probar estas hipótesis, redujimos la microbiota de obreras y dimos suplementos de microbiota a una parte de ellas. Las expusimos a una dosis infecciosa de C. bombi y caracterizamos la expresión génica y la composición de la microbiota intestinal. Examinamos la expresión de los genes de tres péptidos antimicrobianos (AMPs) y de Mucin­5AC, un gen con un rol putativo en la protección del epitelio intestinal, usando la qPCR. Aunque observamos un efecto protector contra C. bombi en los abejorros suplementados con microbiota, no vimos un efecto en la expresión génica que pudiese explicar por sí solo la protección observada. Por otro lado, encontramos un incremento en la abundancia relativa de bacterias del género Lactobacillus en el intestino de obreras infectadas y una correlación negativa de este género con los géneros Gilliamella y Snodgrassella. Por tanto, nuestros resultados apuntan a un desplazamiento de los endosimbiontes por parte de C. bombi, que podría estar causado por la competición por espacio y nutrientes entre el parásito y la microbiota dentro del intestino.

"Everything is not everywhere": Time-calibrated phylogeography of the genus Milnesium (Tardigrada).

There is ample evidence that macroscopic animals form geographic clusters termed as zoogeographic realms, whereas distributions of species of microscopic animals are still poorly understood. The common view has been that micrometazoans, thanks to their putatively excellent dispersal abilities, are subject to the "Everything is everywhere but environment selects" hypothesis (EiE). One of such groups, <1 mm in length, are limnoterrestrial water bears (Tardigrada), which can additionally enter cryptobiosis that should further enhance their potential for long distance dispersion (e.g., by wind). However, an increasing number of studies, including the most recent phylogeny of the eutardigrade genus Milnesium, seem to question the general applicability of the EiE hypothesis to tardigrade species. Nevertheless, all Milnesium phylogenies published to date were based on a limited number of populations, which are likely to falsely suggest limited geographic ranges. Thus, in order to test the EiE hypothesis more confidently, we considerably enlarged the Milnesium data set both taxonomically and geographically, and analysed it in tandem with climate type and reproductive mode. Additionally, we time-calibrated our phylogeny to align it with major geological events. Our results show that, although cases of long distance dispersal are present, they seem to be rare and mostly ancient. Overall, Milnesium species are restricted to single zoogeographic realms, which suggests that these tardigrades have limited dispersal abilities. Finally, our results also suggest that the breakdown of Gondwana may have influenced the evolutionary history of Milnesium. In conclusion, phylogenetic relationships within the genus seem to be determined mainly by paleogeography.

The mitogenome phylogeny of Adephaga (Coleoptera).

The beetle suborder Adephaga consists of several aquatic ('Hydradephaga') and terrestrial ('Geadephaga') families whose relationships remain poorly known. In particular, the position of Cicindelidae (tiger beetles) appears problematic, as recent studies have found them either within the Hydradephaga based on mitogenomes, or together with several unlikely relatives in Geadephaga based on 18S rRNA genes. We newly sequenced nine mitogenomes of representatives of Cicindelidae and three ground beetles (Carabidae), and conducted phylogenetic analyses together with 29 existing mitogenomes of Adephaga. Our results support a basal split of Geadephaga and Hydradephaga, and reveal Cicindelidae, together with Trachypachidae, as sister to all other Geadephaga, supporting their status as Family. We show that alternative arrangements of basal adephagan relationships coincide with increased rates of evolutionary change and with nucleotide compositional bias, but these confounding factors were overcome by the CAT-Poisson model of PhyloBayes. The mitogenome + 18S rRNA combined matrix supports the same topology only after removal of the hypervariable expansion segments. Densely sampled mitogenomes, analyzed with site heterogeneous mixture models, support a plausible hypothesis of basal relationships in the Adephaga.

Islands in the desert: Species delimitation and evolutionary history of Pseudotetracha tiger beetles (Coleoptera: Cicindelidae: Megacephalini) from Australian salt lakes.

The Australian salt lakes are a natural archipelago-like laboratory for investigating evolutionary and population processes. Their environmental conditions have not undergone relevant changes since the aridification of Australia 10-5 million years ago. The genus Pseudotetracha, a group of nocturnal tiger beetles found on these remote salt lakes, includes 20 described species. Recent studies based on molecular markers and cytogenetics hinted at the existence of cryptic species within this group. Here we use various species delimitation algorithms to detect a high number of cryptic and undescribed taxa, and challenge the validity of the taxonomic characters traditionally used for discerning species in this group. Our analyses show that the divergence dates of the clades, between 10 and 5 million years ago, correspond to the period in which Australia was undergoing an aridification process that probably isolated the ancestral Pseudotetracha populations to individual lakes or palaeodrainage basins. This implies an important role of the isolation, produced by the aridification of Australia, in the speciation and divergence of Pseudotetracha, which underwent a remarkable radiation as the populations became geographically restricted.