Abstract
The recognition of microbiome inhabiting the healthy female bladder engendered the need for comprehensive characterization of the female urinary microbiome (FUM) in health and disease. Although previous studies reported FUM composition at different taxonomic levels, progress towards reliable identification at species level is highly required. The aim of this study was to comprehensively characterize bacterial species of FUM of healthy reproductive-age European women by two complementary methodologies i.e., extended culturomics and long-read third generation sequencing of near full-length 16S rRNA gene.
A wide diversity of bacterial species was captured (297 species) with a median of 53 species/sample, including 16 putative uropathogens. Clustering FUM into community structure types revealed high inter-individual differences. Notably, there was not a single species common to all samples, although the Lactobacillus genus was detected in all samples. Lactobacillus crispatus, Lactobacillus iners and Lactobacillus mulieris were observed in high relative abundance in several samples as well as other species (e.g., Streptococcus agalactiae, Atopobium vaginae, Gardnerella vaginalis, Gardnerella swidsinskii), while more prevalent species were often low abundant members (e.g., Finegoldia magna). We captured remarkable richness within Corynebacterium spp. (25 species) and Lactobacillaceae (4 genera, 14 species). While amplicon sequencing allowed detection of more anaerobic species (e.g., 11 Peptoniphilus spp.), culturomics enabled the identification of recently recognized Gardnerella species and putative novel Corynebacterium species.
This study provided fine-grained FUM profiling at species level and revealed detailed FUM structure, which is critical to unveil the potential relationship between specific microbiome members and urinary diseases/disorders.
IMPORTANCE Despite evidence of the resident microbial community in the female lower urinary tract, bacterial species diversity and abundance in healthy women is still unclear. This study demonstrated that complementarity between optimized culture-dependent and –independent approaches is highly beneficial for comprehensive FUM species profiling by detecting higher FUM species diversity than previously reported, including identification of unreported Lactobacillaceae species and putative novel Corynebacterium species. Although some particular species were present in high relative abundance, low-abundant members were more prevalent. FUM classification into community structure types demonstrated high inter-individual differences in urinary microbiome composition among healthy women. We also report moderate correlation between culture-dependent and -independent derived data highlighting drawbacks resulting from each methodological approach. Our findings suggest that FUM bacterial diversity reported from previous studies may be underestimated. Finally, our results contribute to the fundamental knowledge of healthy FUM required for further exploration of the urinary microbiome role in urinary tract diseases.
Competing Interest Statement
The authors have declared no competing interest.