The role of the Wnt signaling pathway in bone metabolism is well-established (47). The Wnt/β-catenin pathway is associated with differentiation of mesenchymal stem cells (MSCs) toward the osteoblastic lineage while inhibiting adipogenesis and chondrogenesis (30, 47–49). Hyperactivation of the Wnt/β-catenin pathway leads to an increase in bone volume, while its inhibition correlates with a decrease in bone volume, sometimes with root resorption due to disorganization of PDL collagen fibrils and the absence of cementum (50–52). On the other hand, the non-canonical Wnt pathway might promote osteoclastogenesis (53), although the role of Wnt5a on bone metabolism has not been fully elucidated (54).

The role of the Wnt/β-catenin pathway in cementum homeostasis might depend on the level of activation and the cell type (55–59). Negative modulation of the Wnt/β-catenin pathway in cells from the PDL might positively modulate the regeneration of cementum (60, 61). However, there is increased deposition of cementum in cell lines with higher levels of Wnt/β-catenin activity (62). Mechanistically, the Wnt/β-catenin pathway induces the expression of Osterix (Osx), leading to DKK1 expression, which dampens Wnt/β-catenin signaling (50, 63). Therefore, proper fine-tuning of the Wnt/β-catenin pathway might be necessary to promote cementum formation.

Epithelial rests cells from the periodontium, which are sensitive to Wnt/β-catenin stimulation, might also be involved in the deposition of cementum during early development (61). In animal models, it has been observed that Malassez epithelial cells express higher levels of Wnt3a, relative to other cell types from the periodontium (64). In addition, Wnt/β-catenin-sensitive stem cells and epithelial cells from the periodontium can differentiate toward a cementogenic lineage to repair root resorption in rats (63).

Altogether, these findings encourage further research regarding the signaling pathways and mechanisms involved in cementum formation and suggest a crucial role for the Wnt/β-catenin signaling pathway in this process.

A study employing the murine model of continuous eruption of the incisors described the existence of a gradient of Wnt/β-catenin activity across the PDL, with higher activity in the interface between the cementum and the PDL, correlating with higher cell proliferation. In contrast, lower Wnt/β-catenin activity is observed in the interface between the PDL and the alveolar bone, matching higher differentiation toward the osteogenic lineage (51, 65). This suggests that spatially fine-tuning of the Wnt/β-catenin pathway is necessary for both proliferation and differentiation in the PDL. Later studies using transgenic mice corroborated these findings and demonstrated that excessive activity of the Wnt/β-catenin pathway leads to a reduction of the space occupied by the PDL and disorganization of collagen fibers, together with a decrease in bone resorption and alveolar bone accumulation (50, 51).

It has also been suggested that human fibroblasts present in the PDL can differentiate toward distinct cell lineages, promoting the nodular formation of mineralized deposits, collagen matrices, and/or reparative fibrous structures in response to periodontal wounds (66). Cells present in the PDL are sensitive to cues that activate the Wnt/β-catenin pathway (67), and this pathway might increase PDL mineralization (68). On the other hand, PDL cells cultured in vitro express the mRNAs of WNT5A, ROR2, FZD2, FZD4, and FZD5, and these cells are sensitive to Wnt5a (69). The stimulation of PDL cells with Wnt5a abrogates the expression of osteogenic markers and increases the abundance of POSTN (periostin), FBN1 (fibrillin), and COL1A1. The authors linked these effects to a possible role of Wnt5a in the remodeling of the PDL. Later studies in a cell line derived from immortalized human fibroblasts from the PDL demonstrated that JNK and the non-canonical co-receptor ROR2 are required to mediate Wnt5a signaling (70) (Figure 1D).

Secreted Wnt modulators might also play a role during PDL development and maintenance. Fibroblasts from the PDL express sFRP1, and the inhibition of this protein increased CTNNB1 (the gene encoding for β-catenin), levels and the expression of osteogenic markers (60). R-spondin proteins are secreted by cells from the healthy PDL in rats and by primary cultures of PDL cells, fulfilling an essential role in regulating the osteoblastic differentiation of immature human PDL cells through the Wnt/β-catenin pathway (71). Also, TGF-β can activate β-catenin to modulate the differentiation of PDL cells (72). Finally, an inflammatory context might modulate the Wnt pathway through secreted molecules. For instance, IL-6 and TNF-α might inhibit the osteogenic and cementogenic differentiation in cells from the PDL by activating the non-canonical Wnt pathway (73) (Figure 1D).

In summary, the cellular components of the periodontium express ligands, inhibitors, and receptors of the Wnt pathway and are sensitive to cues that activate or inhibit this pathway (Figure 2A). Moreover, the evidence obtained from in vitro studies shows that each branch of the Wnt pathway might have different roles: while the Wnt/β-catenin pathway has been correlated with the osteogenic differentiation, the non-canonical Wnt pathway might inhibit this differentiation program. Consequently, the study of possible alterations in the Wnt pathway in periodontitis is attractive from a clinical perspective.

Establishing a precise diagnosis for periodontal disease depends on laborious measurements, likely to be influenced by the expertise of the treating physician (74). Therefore, the identification of molecular markers is highly valuable, and several reports have searched for changes in the levels of specific proteins in patients.

One report measured Wnt5a levels in serum, failing to observe differences between subjects with and without periodontitis; however, there was higher expression of sFRP5 in patients without periodontitis, relative to patients with periodontitis followed by tooth loss, leading to changes in the sFRP5/Wnt5a ratio (75). In contrast, two independent studies (44, 76) correlated an increased expression of WNT5A with a higher degree of periodontal destruction and observed lower expression of this ligand in healthy subjects. Also, one study reported higher SOST protein levels in tissue samples from patients with moderate to severe periodontitis, while a similar trend, albeit not statistically significant, was seen for Wnt5a (77). When using a more permissive classification of periodontitis, the difference between disease and control tissues was not observed in samples from gingival crevicular fluid, suggesting that changes in the expression of Wnt5a might be highly restricted to the damaged site in severe periodontitis, thus explaining the absence of significant differences in serum samples (75).

In human stem cells from the periodontal ligament cultured on osteogenic medium and stimulated with LPS from E. coli and DKK1, LPS promoted, while DKK1 impaired, osteogenic differentiation (78). Also, proteolysis by gingipains might induce partial degradation of GSK-3β, thus increasing the nuclear fraction of β-catenin (46).

The inflammatory context can also modulate the Wnt pathway. For instance, the treatment of PDL cells with cytokines such as IL-6 and TNF-α inhibits cell proliferation, the relative activity of ALP, the expression of genes and proteins related with osteogenic and cementogenic differentiation and the activation of the Wnt/β-catenin pathway (73). More significantly, the same treatments induced an increase in the levels of WNT5A, FZD6, and DKK1, suggesting that the inflammatory context might shift the balance from a Wnt/β-catenin to a non-canonical profile, dampening the osteogenic and cementogenic differentiation. In agreement with this notion, blocking the non-canonical Wnt pathway stimulated cementogenesis in these cells, even in the presence of IL-6 or TNF-α (73).

In addition, the exposure of human gingival cells to LPS from P. gingivalis differentially modulates the expression of WNT5A and SFRP5. While WNT5A levels were increased in subjects with periodontitis and in cells treated with LPS, the levels of SFRP5 were increased in healthy subjects; however, the exposure to LPS induced a reduction in SFRP5 levels (79). LPS from P. gingivalis also increases WNT5A levels in the cell line THP-1 (44).

Collectively, these observations indicate that the diseased environment shifts the balance between Wnt pathways, favoring Wnt5a-mediated signaling (Figure 2B). Wnt5a has a role in cell migration and invasion, due to its ability to promote both the turnover of focal adhesions (80) and the expression of proteins such as Laminin-γ2 (81). Interestingly, the exposure of PDL cells to periodontopathogens and Wnt5a significantly increases proliferation and migration, together with a significant upregulation in the expression of genes such as POSTN, COL1A1, and FBN1 (70). Therefore, the pathogenic challenge in the PDL might lead to changes in the differentiation of progenitor cells and the remodeling of the extracellular matrix through Wnt5a.

MCP-1 might be important during the local inflammatory response by initiating the recruitment of monocytes as a host defense mechanism (82, 83). As noted above, Wnt5a induces MCP-1 expression (25–27). Macrophage infection with P. gingivalis increases Wnt5a levels, while the reduction of Wnt5a decreases the production of MCP-1 and other pro-inflammatory mediators such as IL-1β and MMP2 (84). In this same study, Wnt5a was shown to be elevated in the gingival tissues of peri-implantitis patients (84).

This evidence suggests a strong link between the non-canonical Wnt pathway and inflammation in periodontitis. However, the Wnt/β-catenin pathway might also modulate the inflammatory response. A recent report showed that P. gingivalis increases JAK3 phosphorylation in several cell types, including monocytes and innate immune cells; in turn, JAK3 signaling stabilizes Wnt3a, leading to a reduction in pro-inflammatory cytokines, and restricting the severity of periodontitis, since abrogating JAK3 signaling in a mice model of P. gingivalis-induced oral infection leads to enhanced bone loss (85). Thus, both Wnt pathways play a role in mediating different aspects of the inflammatory response, further suggesting that proper balance between Wnt modalities might help restoring tissue homeostasis.

In a murine model of ligature-induced periodontitis (86), local treatment with sFRP5 inhibited inflammation and bone loss, which correlated with a lower number of osteoclasts. Periodontitis was associated with a high expression of Wnt5a and lower expression of sFRP5, a profile that was reversed after sFRP5 treatment (79). Meanwhile, a report employing a rat model of occlusal pressure removal by extraction of opposite teeth showed that Wnt5a levels were decreased in the PDL tissue in sites where the occlusal pressure had been eliminated, relative to controls (69). Therefore, Wnt5a expression is dynamic and can be regulated by either the inflammatory or mechanical context.

On the other hand, in a study using a model of bone-periodontal defect by fenestration in rats, the activation of the Wnt/β-catenin pathway resulted in the significant deposition of cellular cementum and formation of well-organized PDL fibers (68), while another report showed that the constitutive deletion of Dkk1 in osteocytes, in the model of ligature-induced periodontitis, abolished alveolar bone loss (87). By histological analysis, the study reported a lower number of inflammatory infiltrates, a reduction in the expression of TNF-α and IL-1 in gingival tissue, and a lower number of osteoclasts, together with an improvement in bone formation.