Diversity of the Ixodes ricinus Microbiome Across Belgian Ecoregions and Its Association with Pathogen and Symbiont Presence.
Series / Report no.
Open Access
Type
Journal Article
Article
Article
Language
en
Date
2025-07-10
Research Projects
Organizational Units
Journal Issue
Title
Diversity of the Ixodes ricinus Microbiome Across Belgian Ecoregions and Its Association with Pathogen and Symbiont Presence.
Translated Title
Published in
Microb Ecol 2025;88(1):73
Abstract
Ticks are important vectors of zoonotic pathogens, and their presence can be influenced by the composition of the tick microbiome. In turn, this microbiome is shaped by environmental and ecological factors, as demonstrated in several studies conducted under controlled conditions. However, the extent of these influences under natural ecological conditions remains underexplored. In this study, we investigated the diversity of the microbiome and the prevalence of pathogens in Ixodes ricinus nymphs across three distinct Belgian ecoregions: Sandy Loam, Condroz, and Ardennes. Using real-time quantitative PCR (qPCR) and Oxford Nanopore 16S rRNA sequencing, we assessed how geography and pathogen presence influence tick-associated microbial communities. Our results revealed significant regional differences in microbiome composition and pathogen prevalence. Borrelia burgdorferi sensu lato (s.l.) was most prevalent in the Ardennes (9% (7.4-10.9) vs 3.8% (2.8-5.2) in the Condroz and 2.1% (1.4-3.2) in Sandy Loam) while Anaplasma phagocytophilum was more common in the Sandy Loam region (21.1% (18.7-23.8) vs 4% (3-5.4) in the Condroz and 3.2% (2.2-4.4) in the Ardennes). Endosymbionts such as Midichloria mitochondrii and Spiroplasma ixodetis also exhibited distinct geographic distributions. Network analysis identified potential pathogen-microbiota interactions, with certain bacterial taxa showing positive or negative associations with specific pathogens. Moreover, microbiome composition was influenced not only by ecoregion but also by microorganisms such as Rickettsia helvetica, suggesting that its colonization may actively shape microbial community structure, potentially through competition or facilitation mechanisms. Additionally, microbiome network robustness varied across ecoregions, highlighting the role of ecological context in shaping microbial interactions within ticks. These findings underscore the complex interplay between geography, pathogen presence, and microbial diversity in ticks, highlighting the importance of integrating these interactions to inform microbiome-based strategies for vector control and disease prevention.