Figure 1.
Heat map of bacterial sequence reads clustered using Dirichlet Multinomial Mixtures model.
Classification and clustering of bacterial sequence reads from 220 women resulted in four clusters. Transformed frequencies of sequence reads are shown in the legend with darker colors representing more abundant sequence reads. The abundance of bacterial morphotypes, assessed by Gram stain, are reflected as numbers ranging from 0 to 4 with higher numbers indicating increased abundance. Nugent scores used for diagnosis of BV are presented as follows: BV negative (0-3), Intermediate score (4-6) and BV positive (7-10). White bars denote that data are not available. The model was not informed of bacterial morphotype data. Taxa are ordered based on contribution to variance between clusters, and then are grouped by genus-level classifications. The heat map includes taxa whose total abundance across samples exceeds the 80th quantile. Note absence of Mobiluncus species in the list of taxa presented due to low abundance of sequence reads.
Figure 2.
Association of bacterial sequence reads with Gram stain bacterial morphotypes.
Based on a priori hypothesis and abundance of taxa represented in DMM clustering, bacterial sequence reads (asinh-transformed) obtained using broad-range PCR and pyrosequencing (Y-axis) were correlated with abundance of Gram stain morphotypes (X-axis). The inverse hyperbolic sin (asinh) is a log-like transformation with better (linear) behavior near zero. This makes it applicable to count data with many zeros, as is found in our data. Data are grouped as <=2 (0, 1+, 2+) and >2 (3+, 4+) (X-axis) which indicate average number of bacterial morphotypes observed under oil-immersion per high-powered field. 0, no morphotypes present; 1+, <1 morphotype present; 2+, 1 to 4 morphotypes present; 3+, 5 to 30 morphotypes present; 4+, 30 or more morphotypes present. Open blue circles denote abundance of sequence reads from a single woman; closed black circles indicate median values. Numbers below box plots denote numbers of samples in each group.
Figure 3.
Curved Gram negative rods are more likely to be BVAB1 rather than Mobiluncus species.
Comparison of rank abundance plots in women with Nugent scores of 7-8 (A) and 9-10 (B) show percentage of sequence reads in each group. Women with Nugent scores 9-10 are dominated with BVAB1. Quantitative PCR targeting BVAB1 and Mobiluncus (C) was performed for vaginal samples obtained from women with BV demonstrating higher concentrations of BVAB1 compared to Mobiluncus in each group.
Figure 4.
FISH reveals higher quantities of BVAB1 cells than Mobiluncus cells in vaginal fluid.
Vaginal fluid smears from all women with Nugent 10 were assessed for relative quantities of BVAB1 and Mobiluncus cells. The lines in the box plot represent the mean and whiskers denote 95% confidence intervals.
Figure 5.
Fluorescence micrographs and Gram stain images of vaginal fluid smears.
Vaginal fluid smears from two representative study participants are shown. 4+ curved rods were documented by Gram stain (A & C) for both participants who had BV (Nugent score 10). Panels A (Gram stain) and B (FISH) are vaginal fluid smears from a representative participant with low concentrations of Mobiluncus DNA (2·5×105 copies 16S-rRNA gene/swab) and high concentrations of BVAB1 DNA (2·4×109 16S rRNA gene copies/swab). Panel B shows a field of bacteria hybridizing with probes for BVAB1 (green) while no hybridization was observed with Mobiluncus probe (red). Mean quantity of BVAB1 cells was 661 versus <1 Mobiluncus cell. Panels C (Gram stain) and D (FISH) are vaginal fluid smears from a representative participant with high concentrations of Mobiluncus DNA (1·3×107 16S-rRNA gene copies/swab) and BVAB1 DNA (5·1×108 16S-rRNA gene copies/swab). Panel D shows a field of bacteria hybridizing with both Mobiluncus (red) and BVAB1 (green) DNA. Mean quantity of BVAB1 cells was 908 versus 145 Mobiluncus cells.