Abstract
BackgroundThe microbiome is an integral component of many animal species, potentially affecting behavior, physiology, and other biological properties. Despite this importance, bacterial communities remain vastly understudied in many groups of invertebrates, including mites. Quill mites (Acariformes: Syringophilidae) are a poorly known group of permanent bird ectoparasites that occupy quills of feathers and feed on bird subcutaneous tissue and fluids. Most of the known species have strongly female‐biased sex ratio, and it was hypothesized that this is caused by endosymbiotic bacteria. Previously, Anaplasma phagocytophilum (Foggie) and a high diversity of Wolbachia strains were detected in quill mites via targeted PCR screens. Here, we use an unbiased 16S rRNA gene amplicon sequencing approach to determine other bacteria that potentially impact quill mite biology.ResultsWe performed 16S rRNA gene amplicon sequencing of 126 quill mite individuals from eleven species parasitizing twelve species (four families) of passeriform birds. In addition to Wolbachia, we found Spiroplasma as potential symbiont of quill mites. Consistently, high Spiroplasma titers were only found in individuals of two mite species associated with finches of the genus Carduelis, suggesting a history of horizontal transfers of Spiroplasma via the bird host. Furthermore, there was evidence for Spiroplasma negatively affecting Wolbachia titers. We found no evidence for the previously reported Anaplasma in quill mites, but detected sequences of high similarity to the potential pathogens Brucella and Bartonella at low abundances. Other amplicon sequence variants (ASVs) could be assigned to a diverse number of bacterial taxa, including several that were previously isolated from bird skin. Further, many frequently found ASVs were assigned to taxa that show a very broad distribution with no strong prior evidence for symbiotic association with animals. We interpret these findings as evidence for a scarcity of resident microbial associates (other than inherited symbionts) in quill mites.
Highlights
There is abundant evidence that microbial taxa are an essential component of many animal species (McFall-Ngai et al, 2013)
We find that the symbionts Wolbachia and Spiroplasma are among the most commonly associated taxa with quill mites
Bar plots of amplicon sequence variants (ASVs) abundance and ordination analyses with this filtered dataset revealed that the bacterial composition was relatively uniform across samples, and no clear differentiation between samples extracted from different mite species, or between Wolbachia positive and negative a1 samples could be observed (Figures 1b, 2, see Appendix Figure A1)
Summary
There is abundant evidence that microbial taxa are an essential component of many animal species (McFall-Ngai et al, 2013). Bacteriaencoded traits may significantly impact host phenotypes, for example, through providing essential nutrients (Duron et al, 2018; Hosokawa, Koga, Kikuchi, Meng, & Fukatsu, 2010), defending against pathogens (Ballinger & Perlman, 2017; King et al, 2016), and affecting ecological features of their hosts, such as mate choice (Sharon et al, 2010) and life history traits (Laughton, Fan, & Gerardo, 2013) Because of their potential importance in understanding the biology of many organisms, the number of microbiome studies has been soaring (Hird, 2017). We find that despite the detection of Bartonella and Brucella, quill mites do not seem to be major pathogen vectors in birds
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