Biological Mechanisms of Tooth Movement. Группа авторов

Biological Mechanisms of Tooth Movement

force induces negative strain at the leading side, and positive strain at the trailing side. This results in strain of the periodontal fibroblasts. The integrins by which they are attached to the ECM can act as force transducers or “strain gauges” (Chiquet et al., 2003; Chiquet et al., 2007). Furthermore, fluid flow in the PDL, and also within the canalicular network in the alveolar bone, is induced. In addition, this fluid flow induces strain in the cell membranes, not only of the fibroblasts, but also of the osteoblasts and the osteocytes. The osteocytes within the canaliculi of the alveolar bone are important mechanosensors and transducers of applied mechanical strain. Together with osteoblasts and periodontal fibroblasts they contribute to the activation of cells by integrin‐mediated strain transmission to the cytoskeleton and the subsequent induction of the expression of a variety of growth factors and cytokines (Klein‐Nulend et al., 2013; Tresguerres et al., 2020). These factors, such as FGF, IGF‐1, IL‐1α, IL‐1β, IL‐6, and TNFα mediate the differentiation of precursors into osteoblasts and osteoclasts (Eriksen, 2010; Vansant et al., 2018).

For OTM, resorption of the alveolar bone by osteoclasts at the leading side of the tooth is essential. These cells are derived from myeloid precursors that have differentiated into monocytes and subsequently into osteoclast precursors through macrophage colony‐stimulating factor (M‐CSF). Their further differentiation is dependent on the ligand for the receptor activator of nuclear factor kappa‐B (RANKL) that is secreted by fibroblasts and osteoblasts. RANKL binds to RANK, expressed on the osteoclast precursors that subsequently become mononuclear osteoclasts, characterized by the expression of tartrate resistant acid phosphatase (TRAP). After fusion, these cells become multinuclear osteoclasts (Suda et al., 1999; Yamaguchi, 2009; Vansant et al., 2018). The differentiation of osteoclasts is counteracted by osteoprotegerin (OPG). This is a soluble decoy receptor for RANKL. This means that binding of OPG to RANKL inhibits the binding of RANKL to RANK on the osteoclast precursors and thus hampers both the further differentiation and the functioning of osteoclasts. Interestingly, strain affects both the secretion of RANKL and the secretion of OPG (Figure 3.13).

At the leading side of the tooth the negative strain stimulates the secretion of RANKL, but decreases the secretion of OPG, and thus the differentiation and functioning of osteoclasts are stimulated. On the other hand, in the areas with positive strain, the trailing side of the tooth, RANKL as well as OPG are upregulated, but OPG is more upregulated than RANKL, and thus osteoclast differentiation is prevented (Hadjidakis and Androulakis, 2006; Yamaguchi, 2009; Vansant et al., 2018).

For the functioning of osteoclasts, they should be attached to mineralized bone matrix through αVβ3 integrin. This is only possible when the osteoblasts, as well as the osteoid, the nonmineralized bone matrix covering the surface of the alveolar bone, are removed (Duong et al., 2000; Takahashi et al., 2007; Eriksen, 2010). The ECM of the osteoid is degraded through the action of MMPs, more specifically the collagenases MMP1, MMP8, MMP13, and MMP14 (Tokuhara et al., 2019). These enzymes are synthetized and secreted as pro‐enzymes by a variety of cell types, including lymphocytes and granulocytes, but in particular by activated macrophages. They are activated by proteolytic cleavage and regulated by a family of inhibitors called the tissue inhibitors of matrix metalloproteinases (TIMPs). The MMP activity is thus dependent on the balance between production and activation of MMPs and the local levels of TIMPs (Snoek‐van Beurden and Von den Hoff, 2005; Verstappen and Von den Hoff, 2006; Tokuhara et al., 2019). The osteoblasts disappear by apoptosis (programmed cell death), induced by binding of TNF‐α (that is secreted by activated macrophages, fibroblasts, and osteoblasts, in an autocrine way) to its receptors TNFR1 and TNFR2 on osteoblasts and the subsequent activation of the caspase pathway (Hill et al., 1997; Jilka et al., 1998; Hock et al., 2001).

The combined osteoblast apoptosis and ECM degradation leads to areas of exposure of mineralized bone matrix, which can serve as landing sites for osteoclasts. The osteoclasts move to the landing sites by chemotaxis, and attach to the bone by αVβ3 integrins, connecting the osteoclast to RGD peptides in the bone matrix (Takahashi et al., 2007; Lerner et al., 2019). Upon adhesion to bone, osteoclasts polarize and reorganize their cytoskeleton to generate a ring‐like F‐actin‐rich structure, the sealing zone, that isolates the Howship’s lacuna from the surroundings. Inside the sealing zone, the ruffled border is formed. The isolated area becomes acidic through an H⁺‐ATPase‐mediated proton pump. This favors the dissolution of bone minerals. In addition, the lysosomal enzyme cathepsin K, a cysteine proteinase with a pH optimum of 4.5, and matrix metalloproteinases, especially MMP‐9 (pH optimum = 7.4) are secreted into Howship’s lacunae to degrade the organic bone matrix (Teitelbaum, 2000) (Figure 3.14).

Schematic illustration of the RANK or RANKL or OPG system. The RANKL that is secreted by fibroblasts and osteoblasts binds to RANK, expressed on the osteoclast precursors. The latter subsequently become mononuclear osteoclasts. After fusion, these cells become multinuclear osteoclasts. However, fibroblasts and osteoblasts also can secrete osteoprotegerin (OPG), a soluble factor that also binds to RANKL, thereby hampering the differentiation of osteoclasts.

Figure 3.13 The RANK/RANKL/OPG system. The RANKL that is secreted by fibroblasts and osteoblasts binds to RANK, expressed on the osteoclast precursors. The latter subsequently become mononuclear osteoclasts. After fusion, these cells become multinuclear osteoclasts. However, fibroblasts and osteoblasts also can secrete osteoprotegerin (OPG), a soluble factor that also binds to RANKL, thereby hampering the differentiation of osteoclasts.

(Source: Jaap Maltha.)

Schematic illustration of an active osteoclast.

Figure 3.14 An active osteoclast.

(Source: Jaap Maltha.)

At the trailing side of the moving tooth, the PDL is widened, accompanied with a positive strain in the ECM and an acute inflammatory reaction (Figure 3.15). This results in an increase in IL‐1β, IL‐10, PGE2, and TGF‐β expression (Tsuge et al., 2016; Li et al., 2018), and subsequently in an increase in OPG and a decrease in RANKL secretion by the osteoblasts and periodontal fibroblast (Li et al., 2018).

Schematic illustration su millimeter ary of the remodeling processes at the trailing side. Fibroblasts under tensile strain secrete IL-1 and IL-6 (1), which in turn stimulate millimeter Ps and inhibit TIMPs (2). Fibroblasts also secrete VEGF that stimulates angiogenesis (3). These actions result together in anabolic activities of fibroblasts (4) and osteoblasts (5).

Figure 3.15 Summary of the remodeling processes at the trailing side. Fibroblasts under tensile strain secrete IL‐1 and IL‐6 (1), which in turn stimulate MMPs and inhibit TIMPs (2). Fibroblasts also secrete VEGF that stimulates angiogenesis (3). These actions result together in anabolic activities of fibroblasts (4) and osteoblasts (5).

(Source Meikle, 2006. Reproduced with permission of Oxford University Press.)

Furthermore, the number of fibroblasts increases, and the secretion of collagen type I and collagen type III, as well as the formation of new Sharpey’s fibers, is stimulated. Simultaneously with the deposition of the Sharpey’s fibers, osteoblasts deposit new bone matrix on the adjacent alveolar bone socket wall, anchoring the Sharpey’s fibers in the bone matrix (Garant and Cho, 1979; Militi et al., 2019). On the other hand, the expression of MMPs is downregulated and the expression of TIMPs is upregulated, and thus ECM breakdown is inhibited.

Finally,

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