Evolutionary dynamics of type VI secretion systems in fruit fly-associated Enterobacter
Naima Bel Mokhtar, Panagiota Stathopoulou, Elias Asimakis, Antonios Augustinos, Julieta Salgueiro, Malini Alleck, Preeaduth Sookar, Óscar Dembilio, Diego F. Segura, George Tsiamis

TL;DR
This study explores how Enterobacter bacteria interact with fruit flies, revealing genetic differences and adaptations that could help control pest populations.
Contribution
The study identifies distinct T6SS gene clusters and host-specific adaptations in Enterobacter strains associated with fruit flies.
Findings
Different fruit fly species host distinct Enterobacter species, with Enterobacter hormaechei being the most prevalent.
Three subtypes of T6SS gene clusters were identified, differing in gene content and potentially in function.
Genomic plasticity and host-specific adaptations are indicated by differences in core and accessory genome composition.
Abstract
Species in the genus Enterobacter are widely distributed and occupy diverse ecological niches. Although many species within this genus have been extensively isolated and characterized, their symbiotic associations with Tephritidae fruit flies remain understudied, particularly through comparative genomic analyses. To address this gap, we conducted a whole-genome comparative analysis of thirteen Enterobacter strains isolated from the most economically significant fruit fly species: Anastrepha fraterculus, Bactrocera dorsalis, Bactrocera zonata, Ceratitis capitata, and Zeugodacus cucurbitae. The results revealed that different fruit flies harbor distinct Enterobacter species, with Enterobacter hormaechei being the most prevalent across hosts. Notably, distinct E. hormaechei subspecies were associated with specific hosts, suggesting a potential host-driven adaptation and coevolution.…
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Taxonomy
TopicsInsect behavior and control techniques · Insect symbiosis and bacterial influences · Forensic Entomology and Diptera Studies
