Ehrlichia ruminantium infection is associated with tissue-specific microbial community shifts in Amblyomma gemma ticks from cattle in Kenya

Tick-borne pathogens can reshape vector microbiomes in ways that influence pathogen colonisation and transmission, yet the interplay between Ehrlichia ruminantium and the microbiota of its tick vectors remains uncharacterised. We profiled bacterial communities in haemolymph, midgut, and salivary glands of infected (n = 11) and uninfected (n = 12) Am. gemma ticks, a vector of E. ruminantium in East Africa, collected from cattle in Kajiado County, Kenya, using near-full-length 16S rRNA gene amplicon sequencing on the Oxford Nanopore platform. Community composition, alpha and beta diversity, co-occurrence networks, keystone taxa, and PICRUSt2-inferred functional profiles were compared across tissue-infection status groups. We identified 226 bacterial genera dominated by Coxiella, Pseudomonas, Acinetobacter, Proteus, and Rickettsia. Infection was associated with tissue-specific shifts in community composition (PERMANOVA R{superscript 2} = 0.14, p < 0.001) and co-occurrence network structure, with midgut networks showing complete hub taxon turnover (Jaccard = 0.000, p = 0.043). Haemolymph communities converged around Luteimonas as a keystone taxon, while opportunistic Proteobacteria, including Acinetobacter and Serratia, emerged as keystones in infected midgut. Endosymbiotic Rickettsia was near-absent in infected tissues (0.3% vs 9.3% mean relative abundance in midgut), consistent with competitive exclusion. Functional inference identified FDR-significant enrichment of predicted aerobactin siderophore biosynthesis, antimicrobial efflux, and oxidative stress response gene families in infected microbiota. These findings show tissue-specific restructuring of the Am. gemma microbiome associated with E. ruminantium infection and point to candidate targets for microbiome-based interventions against heartwater. ImportanceHeartwater, caused by the bacterium Ehrlichia ruminantium and transmitted by Amblyomma ticks, kills up to 90% of susceptible ruminants and is one of the most devastating tick-borne diseases in sub-Saharan Africa. Controlling heartwater requires understanding how the pathogen interacts with the microbial communities living inside its tick vector. In this exploratory study, we show that E. ruminantium infection is associated with tissue-specific shifts in the Amblyomma tick microbiome, including reduced abundance of beneficial symbionts, elevated representation of opportunistic bacteria among community hubs, and enrichment of iron acquisition and antimicrobial resistance functions. The midgut, the first tissue colonised during infection, showed the most marked structural reorganisation. These tissue-resolved microbiome signatures point to potential targets for novel control strategies, such as anti-microbiota vaccines or approaches that reinforce natural colonisation resistance, offering new strategies to reduce heartwater transmission and protect livestock livelihoods across Africa.