Comparative genomics reveals extensive genomic conservation and limited microdiversification among Xenorhabdus bovienii isolates recovered from a single Steinernema feltiae isolation event.

Xenorhabdus bovienii is a symbiotic bacterium associated with entomopathogenic nematodes of the genus Steinernema. Comparative genomic analyses of closely related isolates provide an opportunity to investigate fine-scale diversification, genome plasticity, and the evolutionary processes shaping symbiotic bacterial populations. Here, we analyzed four X. bovienii isolates (XenUTI4.1-XenUTI4.4) recovered from a single Steinernema feltiae isolation event using comparative genomics approaches integrating average nucleotide identity (ANI), single-nucleotide polymorphism (SNP) analyses, pangenome reconstruction, biosynthetic gene cluster (BGC) prediction, and mobile element-associated annotation screening. Whole-genome comparisons revealed extremely high genomic similarity among isolates, with ANI values exceeding 99.84%. Read-based SNP analyses identified only 23-36 annotated variants relative to the XenUTI4.1 reference genome, indicating limited sequence divergence despite detectable microvariation. Functional annotation of these variants showed that most corresponded to missense or synonymous substitutions affecting a small number of coding sequences. Pangenome analysis identified 4,712 orthologous gene clusters, including a highly conserved core genome of 4,256 clusters (90.3%) shared by all isolates and a relatively small accessory genome comprising 456 clusters. antiSMASH analyses revealed broadly conserved secondary metabolite biosynthetic potential across the four genomes, whereas screening of genome annotations identified abundant phage-related, transposase-associated, and recombination-associated genes consistent with ongoing genome plasticity. Collectively, these results demonstrate that the analyzed X. bovienii isolates represent a highly conserved population exhibiting limited but detectable genomic microdiversification. The coexistence of a large core genome, a modest accessory gene complement, and numerous mobile element-associated functions suggests that localized sequence variation and mobile genetic elements contribute to genomic diversification within S. feltiae-associated X. bovienii populations.