P. gingivalis -mediated disruption of spiral artery remodeling is present by GD11. We previously demonstrated that by GD18, P. gingivalis infection disrupts the physiologic remodeling of uterine spiral arteries characterized by reduced arterial lumen size, increased retention of spiral VSMC, and decreased extravillous trophoblast in the placental bed [11]. The objective of this study was to determine if infection affected the “trophoblast-independent” phase of vascular remodeling. We chose GD11 as our study timepoint since the mesometrial triangle is decidualized at this time [18] but extravillous trophoblasts should not have invaded the mesometrium [19].
Immunofluorescent staining was used to confirm P. gingivalis infection of the uteroplacenta (Fig. 1). P. gingivalis antigen was not detected in control specimens. P. gingivalis was mainly detected in the decidua stroma near the maternal-fetal interface. In some specimens, bacteria were detected in the periphery of the placental bed surrounding spiral arteries.
The degree of spiral artery remodeling was assessed by dilation of the arterial lumen, loss of the vascular smooth muscle cell (VSMC) layer, and invasion of the uterine tissue by extravillous trophoblasts [20]. Analysis was performed on sections that included the center of the placental bed where vascular remodeling is most consistent (Fig. 2a) [21]. Spiral arterial lumen size was significantly reduced in the infected group compared to controls (Fig. 2b, P < 0.02). Infected animals also had a greater proportion of retained spiral arterial VSMC compared to controls (Fig. 3a and b, P < 0.003).
In contrast to a previous study [19], endovascular EVT were present in a subset of control and infected specimens. However, the proportion of infected specimens positive for endovascular EVT was significantly less than controls; 10 of 34 (29%) in the decidua of infected animals vs. 27 of 40 (68%) in the control group (P ≤ 0.002 by Fisher’s exact test). In specimens in which endovascular EVT reached the mesometrium: 1 of 34 (3%) in the infected group vs. 11 of 40 (28%) in the control group (P ≤ 0.004 by Fisher’s exact test).
Since endovascular EVT participate in the breakdown of the arterial wall and removal of spiral arterial VSMC [19,22], VSMC density in endovascular EVT positive arterial segments was reanalyzed. Despite the presence of endovascular EVT, the proportion of retained VSMC was greater in infected animals than in controls (Fig. 3b, P < 0.002). Interstitial EVT were not detected in any GD11 specimens (Fig. 3), which is consistent with previous reports [23].
Retained VSMC in control vs infected groups were also qualitatively different (Fig. 3c). In control specimens the spiral arterial wall in the decidua was mostly or completely obliterated with few to no VSMC present. Any remaining VSMC within the decidua were largely dedifferentiated (round shape with less smooth muscle actin). In the mesometrial triangle, the spiral arteries in control specimens showed partial disorganization of the arterial wall and VSMC showed varying degrees of rounding and decreased smooth muscle actin. In infected animals, decidual arterial segments were less disorganized and remaining VSMC retained contractile features (fusiform shape and increased smooth muscle actin). In the mesometrial triangle, the spiral arteries in infected specimens retained their structure and VSMC contractile features. Thus, despite the presence of endovascular EVT at GD11, spiral arterial remodeling was significantly reduced in P. gingivalis infected specimens.
Vascular necrosis with thrombosis was more prevalent in P. gingivalis-infected specimens. Hematoxylin and eosin stained GD11 specimens were examined for coagulative necrosis and perivascular necrosis with or without thrombosis since these lesions have been observed in GD18 placental bed tissues [10,11]. Coagulative necrosis with or without hemorrhage was present at the decidual-placental junction in 6 of 34 (18%) control specimens and 2 of 40 (5%) infected specimens (P = 0.1322 by Fisher’s exact test, representative images available in supplement file Fig S1a). In contrast, decidual vascular necrosis with thrombosis of affected vessels was 8 of 40 (20%) infected specimens whereas only 1 of 34 (3%) of controls had this lesion (Fig S1b, P ≤ 0.0332 by Fisher’s exact test).
Infection and gestational stage effects on maternal serum cytokine/chemokine concentrations. In our previous study, we found that P. gingivalis infection did not alter circulating cytokines and chemokines in GD18 dams [11]. This contradicted previous studies that reported experimental infection with P. gingivalis induced TNF and/or IL-1 expression in pregnant animals [24,25]. To determine if maternal systemic inflammation was increased at GD11, cytokines and chemokines in maternal serum were profiled using the same methodology for GD18 dams [11]. To be able to compare GD11 to GD18 sera, both groups were analyzed within the same assay. GM-CSF was not detected in any of the specimens. Overall, infection did not alter maternal cytokine/chemokine profiles at GD11 (Fig S2a, supplement file). To determine if gestational stage had any effect on circulating maternal cytokine/chemokine concentrations, GD11 groups were compared to GD18. There were no differences in maternal serum cytokine/chemokine concentrations between control GD11 and GD18 groups (Fig S2b, supplement file). Among infected groups, GD11 dams had higher circulating IL-17A (P < 0.02), MIP-2 (P < 0.02) and IL-12p70 (P < 0.03) compared to GD18 dams, (Fig S2c, supplement file).
lymphocyte populations are altered in P. gingivalis infected dams. Placental bed leukocytes, particularly uterine NK cells (uNK) and macrophages (MΦ), play important roles in spiral artery remodeling [13,26,27]. Therefore, flow cytometry was used to measure placental bed uNK cell (CD45+/CD161a+/CD3−/CD68−), MΦ (CD45+/CD68+/CD3−) populations in both GD11 and GD18 specimens. T cells were identified as (CD45+/CD3+/CD68−) since they also express CD161a. Gating strategy is available in supplement file, Fig S3a.
Processed datasets from all treatment groups and gestational ages were combined and analyzed by t-distributed stochastic neighbor embedding (tSNE), which generated unbiased population cluster maps (Fig. 4a). Unbiased clustering identified a subset of CD161a + mesometrial MΦs in all groups. However, neither infection nor gestational age significantly altered this subpopulation of MΦ. P. gingivalis-infected specimens were found to have significantly more uNK cells at GD11 than control tissue (Fig. 4b, and S3b in supplement file), with controls having 3.9% uNKs and the P. gingivalis group having 14.9% uNKs (P ≤ 0.022) out of total leukocytes. Population means of MΦs and T cells were not significantly different between groups (Fig S3b in supplement file). Production of TNFα by leukocyte populations was also assessed. At GD11, there was no significant difference in the number of TNFα + cells between control and infected groups (Fig S3c in supplement file). At GD18, there was no significant difference in the number of TNFα + MΦ and uNK cells between control and infected groups (Fig S3c, supplement file). However, TNFα + T cells were reduced in infected specimens (1.01% in P. gingivalis vs 12.56% in controls, (P ≤ value 0.048).
Immunostaining was used to determine the location of uterine MΦ, uNK cells, and T cells in GD11 and/or GD18 uteroplacental specimens. MΦs were double stained for CD161 + and CD68 since CD68+/CD161a + MΦ had not been previously reported. CD68 + cells were detected around spiral arteries. CD161+/CD68 + cells were scant and found to be randomly scattered through the myometrial stroma of all groups (Fig S4 in supplement file). None were detected in the decidua.
UNK cell populations were identified by double staining using the NK marker, a-natural killer cell activation structures (ANK61) combined with TNF or granzyme B (Fig. 5 and Fig S5 in supplement file). In both GD11 and GD18, uNK cells were concentrated around spiral arteries of control and infected specimens. At GD11, 8 of 14 (57%) of infected specimens had a heavy concentration of uNK cells surrounding decidual spiral arterial segments compared to 2 of 13 (15%) controls (P < 0.05 by Fisher’s exact test). Six of 14 (43%) infected specimens versus 11 of 13 (85%) controls had scant numbers of uNK cells surrounding decidual spiral arterioles. In GD18 specimens, Ank61+/TNF + cells were primarily located in the outer periphery of the mesometrial triangle (Fig S5a, supplement file).
Normally, uNK cells express granzyme B [28] and form immature activating synapses that are not cytolytic [29]. UNK cells were dual stained with Ank61 and granzyme B to determine if these cells were associated with perivascular necrosis detected in infected GD11 specimens. There was no difference in the proportion of Ank61+/granzyme B + uNK cells among control and infected groups (79 ± 12% in controls vs. 71 ± 13% in infected, N = 8/group, P = 0.2932 by unpaired t test). Granzyme B positive uNK cells with immature activating synapses were present in both control and infected specimens, but degranulation by these cells was not detected in either group (Fig S5b in supplement file).
To assess the relationship between T cells and spiral arteries, GD18 specimens were dual stained for CD3 and smooth muscle actin (ACTA), (Fig. 6). CD3 + cells were localized to the outer periphery of the spiral arteries within the outer myometrium in both control and infected specimens.
In summary, P. gingivalis infection resulted in an increased number of uNK cells surrounding the spiral arteries during mid-gestation (GD11). By GD18, infected dams had a significant reduction in mesometrial TNFα + T cells found in the deeper myometrium surrounding the spiral arterial segments.
P. gingivalis alters expression of interleukin 18 and high temperature requirement A1 in GD11 placental bed. To assess if infection altered the uterine microenvironment, placental bed specimens were analyzed for the expression of genes implicated in spiral artery remodeling by regulating decidualization, inflammation and oxidative stress, uNK cell dynamics, VSMC dedifferentiation, or angiogenesis [26,30–35]. Placental specimens from GD11 and GD18 groups were examined for the expression of interleukin 1β (Il1b), Il6, Il10, Il12b, Il15, Il18, tumor necrosis factor (Tnf), C-C Motif Chemokine Ligand 11(Ccl11), transforming growth factor beta 1(Tgfb1), activin subunits: inhibin subunit beta A (Inhba) and inhibin A (Inha), activin antagonist follistatin-like 3 (fstl3), oxidative stress marker high temperature requirement A1 (Htra1), and vascular endothelial growth factor A (Vegfa). Gene expression was measured by RT-qPCR with beta-actin (Actb) used as the reference gene [36].
At GD11, P. gingivalis infected specimens had a reduction in Il18 expression coupled with an increase in Htra1 expression (Fig. 7a, P < 0.05). However, by GD18 both Il18 and Htra1 expression levels were equivalent between control and infected groups (Fig. 7b). All other gene expression levels were equivalent between gestational age matched control and infected groups.
Immunofluorescent staining of GD11 placental bed specimens was used to assess changes IL-18 and HTRA1 at the protein level. For IL-18 analysis, tissues were dual stained with MΦ marker CD68 or uNK marker Ank61 (Fig. 8a). IL-18 staining was strongest in myometrial MΦs in both control and infected groups. The proportion of IL-18 positive MΦs was equivalent in both control and infected groups (P = 0.0859, Fig. 8b). However, the proportion of IL-18 positive uNK cells was reduced in infected specimens (P < 0.001, Fig. 8c).
Immunostaining for HTRA1 was done in conjunction with trophoblast marker, cytokeratin 7 (CYTO7), or smooth muscle cell marker, ACTA (Fig. 3c). CYTO7 was chosen because trophoblasts are known to express HTRA1 [37]. ACTA was selected since HTRA1 is essential for VSMC differentiation into the contractile phenotype [38,39]. Overall, the distribution of HTRA1 staining was different between control and infected specimens. Stromal cells in both groups were positive for HTRA1, but staining was more intense and widespread in infected specimens (Fig. 3c). Endovascular EVT were positive for HTRA1, but staining was more intense in controls than in infected tissues (Supplement file, Fig. S3). There was no observable difference between HTRA1 expression in spiral VSMC from control and infected groups. Collectively, infection-induced changes in placental bed IL-18 and Htra1 involved cells that participate in spiral artery remodeling (i.e uNK cells and endovascular EVT).