Vaginal microbes alter epithelial transcriptome and induce epigenomic modifications providing insight into mechanisms for susceptibility to adverse reproductive outcomes.
Michal ElovitzLauren AntonAna G CristanchoBriana FergusonAndrea JosephJacques RavelPublished in: Research square (2024)
The cervicovaginal microbiome is highly associated with women's health, with microbial communities dominated by Lactobacillus species considered optimal. Conversely, a lack of lactobacilli and a high abundance of strict and facultative anaerobes, including Gardnerella vaginalis , have been associated with adverse reproductive outcomes. However, how host-microbial interactions alter specific molecular pathways and impact cervical and vaginal epithelial function remains unclear. Using RNA-sequencing, we characterized the in vitro cervicovaginal epithelial transcriptional response to different vaginal bacteria and their culture supernatants. We showed that G. vaginalis upregulates genes associated with an activated innate immune response. Unexpectedly, G. vaginalis specifically induced inflammasome pathways through activation of NLRP3-mediated increases in caspase-1, IL-1β and cell death, while live L. crispatus had minimal transcriptomic changes on epithelial cells. L. crispatus culture supernatants resulted in a shift in the epigenomic landscape of cervical epithelial cells that was confirmed by ATAC-sequencing showing reduced chromatin accessibility. This study reveals new insights into host-microbe interactions in the lower reproductive tract and suggests potential therapeutic strategies leveraging the vaginal microbiome to improve reproductive health.
Keyphrases
- single cell
- immune response
- cell death
- rna seq
- gene expression
- healthcare
- transcription factor
- public health
- genome wide
- mental health
- toll like receptor
- dna damage
- dendritic cells
- type diabetes
- microbial community
- emergency department
- diabetic rats
- metabolic syndrome
- cell proliferation
- pregnant women
- oxidative stress
- high glucose
- dna methylation
- risk assessment
- induced apoptosis
- cell cycle arrest
- social media
- stress induced