Project description:Group B Streptococcus (GBS) is an opportunistic pathogen that colonizes the vaginal tract and can be transmitted to the fetus or newborn resulting in infection. Previously we identified that Akkermansia muciniphila alters the dynamics of GBS vaginal colonization. Here we determine that A. muciniphila promotes GBS aggregation and attachment to human vaginal epithelial cells (hVECs). RNA-sequencing analysis revealed that A. muciniphila changed expression of 258 unique GBS genes during hVEC colonization, with many involved in cell wall/membrane/envelope biogenesis. We demonstrate that A. muciniphila-mediated increases in GBS aggregation and attachment to hVECs are dependent on GBS capsule and pili, respectively. Lastly, we found that A. muciniphila promoted GBS aggregation in the murine vaginal lumen and continual treatment with A. muciniphila reduced GBS vaginal persistence. Our results highlight the dynamic impact of a commensal organism on GBS colonization, as well as demonstrate the probiotic potential of A. muciniphila in the vaginal environment.

Project description:Streptococcus agalactiae (Group B Streptococcus, GBS) can colonize the human vaginal tract leading to both superficial and serious infections in adults and neonates. To study bacterial colonization of the reproductive tract in a mammalian system, we employed a murine vaginal carriage model. Using RNASeq, the transcriptome of GBS growing in vivo during vaginal carriage was determined. Over one-quarter of the genes in GBS were found to be differentially regulated during in vivo colonization as compared to laboratory cultures. A two-component system (TCS) homologous to the staphylococcal virulence regulator SaeRS was identified as being up-regulated in vivo. One of the SaeRS targets, pbsP, a proposed GBS vaccine candidate, was shown to be important for colonization of the vaginal tract. A component of vaginal lavage fluid acted as a signal to turn on pbsP expression via SaeRS. These data demonstrate the ability to quantify RNA expression directly from the murine vaginal tract and identify novel genes involved in vaginal colonization by GBS. They also provide more information about the regulation of an important virulence and colonization factor of GBS, pbsP, by the TCS SaeRS.

Project description:Streptococcus pyogenes (Group A Strep, GAS) is a serious human pathogen with the ability to colonize mucosal surfaces such as the nasopharynx and vaginal tract, often leading to infections such as pharyngitis and vulvovaginitis. We present genome-wide RNASeq data showing the transcriptomic changes GAS undergoes during vaginal colonization. These data reveal that the regulon controlled by MtsR, a master metal regulator, is activated during vaginal colonization. This regulon includes two genes highly expressed during vaginal colonization, hupYZ. Here we show that HupY binds heme in vitro, affects intracellular concentrations of iron, and is essential for proper growth of GAS using hemoglobin or serum as the sole iron source. HupY is also important for murine vaginal colonization of both GAS and the related vaginal colonizer and pathogen, Streptococcus agalactiae (Group B Strep, GBS). These data provide essential information on the link between metal regulation and mucosal colonization in both GAS and GBS.

Project description:Group B Streptococcus (GBS) is a pervasive perinatal pathogen, yet factors driving GBS dissemination in utero are poorly defined. Gestational diabetes mellitus (GDM), a complication marked by dysregulated immunity and maternal microbial dysbiosis, increases risk for GBS perinatal disease. We interrogated host-pathogen dynamics in a novel murine GDM model of GBS colonization and perinatal transmission. GDM mice had greater GBS in utero dissemination and subsequently worse neonatal outcomes. Dual-RNA sequencing revealed differential GBS adaptation to the GDM reproductive tract, including a putative glycosyltransferase (yfhO), and altered host responses. GDM disruption of immunity included reduced uterine natural killer cell activation, impaired recruitment to placentae, and altered vaginal cytokines. Lastly, we observed distinct vaginal microbial taxa associated with GDM status and GBS invasive disease status. Our translational model of GBS perinatal transmission in GDM hosts recapitulates several clinical aspects and enables discovery of host and bacterial drivers of GBS perinatal disease.

Project description:The aim of the study was to assess the cellular composition and transcriptional changes at single-cell resolution of the female reproductive tract across the four stages of estrus cycle in young adult mice (ovary, oviduct, uterus, cervix and vagina, with spleen as a comparison) and compared this with similar analyses of decidualization (uterus) and ageing (ovary, oviduct, uterus, cervix, vagina and spleen). Vaginal smears were used to stage the estrus cycle in young mice. To collect the decidualized uteri mice were mated and uterine tissue was collected from pregnant mice at day 5.5 after mating. Tissues of aged mice were collected at the age of 18 months. All tissues were collected and digested using a collagenase and trypsin protocol to obtain single cell suspension. Libraries were prepared using the 10x scRNA-seq protocol.

Project description:Gene expression in the neonatal uterus and vagina from transformation related protein 63 (Trp63) conditional heterozygous and null mice was analyzed in order to identify upstream and downstream of Trp63 in the developing vagina. Differential gene expression between vaginal (Trp63 positive) and uterine (Trp63 negative) tissues should reflect both the upstream and downstream of Trp63 expression, whereas the comparison between conditional knockout and heterozygous vaginae should identify what is downstream of Trp63. Thus, the three-way comparison should identify what is upstream of Trp63.

Project description:GBS RNASeq during vaginal colonization

Project description:GBS TnSeq during vaginal colonization

Project description:Gene expression in the neonatal uterus and vagina from transformation related protein 63 (Trp63) conditional heterozygous and null mice was analyzed in order to identify upstream and downstream of Trp63 in the developing vagina. Differential gene expression between vaginal (Trp63 positive) and uterine (Trp63 negative) tissues should reflect both the upstream and downstream of Trp63 expression, whereas the comparison between conditional knockout and heterozygous vaginae should identify what is downstream of Trp63. Thus, the three-way comparison should identify what is upstream of Trp63. Total RNA was extracted from the Trp63 conditional heterozygous (Trp63 flox/wt ; Pax2-cre) uteri and vaginae, and Trp63 conditional knockout (Trp63 flox/floxt ; Pax2-cre) vaginae. Total 12 samples (3 different genotype/tissue groups x 4 independent samples each).

Project description:Multiple levels of interkingdom signaling have been implicated in maintaining the ecological balance between Candida albicans and commensal streptococci to assure a state of oral health. To better understand the molecular mechanisms involved in the initial streptococcal response to the presence of C. albicans that can initiate oral surface colonization and biofilm formation, hypha-forming cells were incubated with Streptococcus gordonii cells for 30 minutes to assess the streptococcal transcriptome response. A genome wide microarray analysis and quantitative PCR validation of S. gordonii transcripts identified a number of genes, the majority of which were involved in metabolic functions, that were differentially expressed in the presence of hyphae. The fruR, fruB and fruA genes encoding the transcriptional regulator, fructose-1-phosphate kinase, and fructose-specific permease, respectively, of the phosphoenolpyruvate-dependent fructose phosphotransferase system, were consistently up-regulated. An S. gordonii mutant in which these genes were deleted by allelic replacement, formed an architecturally-distinct, less robust biofilm with C. albicans than did parental strain cells. Complementing the mutant with plasmid borne fruR, fruB and fruA genes caused phenotype reversion, indicating that the genes in this operon played a role in dual species biofilm formation. This genome wide analysis of the S. gordonii transcriptional response to C. albicans has identified several genes that have potential roles in interkingdom signaling and responses.