Chronic periodontitis is clinically characterized by loss of gingival tissue attachment to the tooth, deepening of the gingival crevice (designated ‘periodontal pocket’ in periodontitis), degradation of the periodontal ligament and loss of alveolar bone 1. This destructive process is associated with the presence of subgingival microbial communities and a dense immuno-inflammatory infiltrate in the periodontium that may lead to tooth loss if not appropriately treated. In gingivitis, a reversible form of periodontal disease that does not result in bone loss, the inflammatory process is restricted to the gingival epithelium and the connective tissue without affecting the deeper compartments of the periodontium 1. However, it should be noted that gingivitis is a major risk factor and a necessary pre-requisite for periodontitis and, moreover, can increase the serum levels of inflammatory biomarkers such as C-reactive protein
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pathogenesis-of-periodontal.pdf
1.
2. Pathogenesis of Periodontal Disease
Assistant lecture of Oral Medicine,
Periodontology, Diagnosis and Dental
Radiology (Al-Azhar Univerisity)
3. Content:
Introduction
Periodontal pathogenesis
The role of specific bacteria in the initial pathogenesis of
periodontitis
Periodontal histopathology
Immune responses in the pathogenesis of periodontal disease
Targets for host-modulation therapy
4. The periodontium includes four tissues located
near the teeth: (1) the alveolar bone (AB), (2) root
cementum (CR), (3) periodontal ligament (PL), and (4)
gingiva (G).
5. The main function of the periodontium is to join the
tooth to the bone tissue and maintain integrity on the
surface of the masticatory mucosa of the oral cavity.
6. Figure 1. Periodontal tissues.
(a) Tissues that support the tooth include the
alveolar bone (AB), root cementum (RC),
periodontal ligament (PL), and gingiva (G).
(b) Forms of cementum: acellular afibrillar
cementum (AAC), acellular extrinsic fibers
cementum (AEFC), cellular mixed stratified
cementum (CMSC), and cellular intrinsic fibers
cementum (CIFC).
(c) Bundles of collagen fibers: crestal alveolar
fibers (CAF), horizontal fibers (HF), oblique
fibers (OF), and apical fibers (AF).
(d) Parts of the gingiva: free gingiva (FG),
interdental gingiva (IG), and attached gingiva
(AG
7. Periodontitis is a globally widespread pathology of the
human oral cavity.
Approximately 10% of the global adult population is
highly vulnerable to severe periodontitis, and 10–15%
appears to be completely resistant to it, while the
remainder varies between these two situations .
8. Periodontitis is a major public health problem due to its
high prevalence, as well as because it may lead to tooth
loss and disability, negatively affect chewing function and
aesthetics, be a source of social inequality, and impair the
quality of life.
9. Periodontitis accounts for a substantial proportion
of edentulism and masticatory dysfunction, results in
significant dental care costs, and has a plausible
negative impact on general health .
10. Periodontitis is a chronic multifactorial disease
characterized by an inflammation of the periodontal tissue
mediated by the host,
which is associated with dysbiotic plaque biofilms,
resulting in the progressive destruction of the
toothsupporting apparatus and loss of periodontal
attachment [1, 10].
11.
12.
13.
14.
15. FIGURE 1 Periodontal disease pathogenesis.
Periodontal health is maintained by homeostatic immunity and is associated with a symbiotic
microbiota.
Periodontitis is associated with a dysbiotic polymicrobial community, in which different
members have distinct and synergistic roles that promote destructive inflammation.
Keystone pathogens — which are aided by accessory pathogens in terms of nutritional and/or
colonization support — initially subvert host immunity leading to the emergence of dysbiotic
microbiota, in which commensal-turned pathobionts overactivate the inflammatory response
and cause tissue destruction.
Inflammation, in turn, can exacerbate dysbiosis through provision of nutrients for the bacteria
(derived from tissue breakdown products; eg, collagen peptides and hemecontaining
compounds).
Therefore, inflammation and dysbiosis are reciprocally reinforced and generate a positive-
feedback loop.This self-sustaining loop may underlie the chronicity of periodontitis, the
development of which requires a susceptible host.
Risk factors include (but are not limited to) the presence of bacteria that subvert the host
response, systemic disease, smoking, aging, a high-fat diet, and immune deficiencies. These
factors could promote dysbiosis by acting individually or, more effectively, in combination. Syst,
systemi
16. This leads to the activation of several key molecular
pathways, which ultimately activate host-derived
proteinases that enable loss of marginal periodontal
ligament fibers, apical migration of the junctional
epithelium, and allows apical spread of the bacterial
biofilm along the root surface [1].
17. Therefore, the primary features of periodontitis
include the loss of periodontal tissue support,
manifested through clinical attachment loss and
radiographically assessed alveolar bone loss,
presence of periodontal pocketing, and gingival
bleeding.
18.
19. The homeostasis of periodontal tissue, pathogenesis of chronic periodontitis and roles of the
involved cytokines.
In a healthy state, local challenge and a mild host immune response are balanced.
Both the commensal microbiota and mechanical stimulation caused by mastication
participate in the training of local mucosal immunity.
In this state, there is an appropriate number of infiltrating neutrophils in the gingival sulcus, as
well as some resident immune cells in the gingival tissue, including Th17 cells and innate
lymphoid cells.
However, if the immune pathogenicity of the local microbiota is elevated by the colonization
of keystone pathogens, which over-activate the host immune response, tissue destruction is
initiated.
The interaction between the microbiota and all host cells leads to the first wave of cytokine
secretion (1), which mainly participates in the amplification of the pro-inflammatory cytokine
cascade and the recruitment, activation and differentiation of specific immune cells. In
addition, a group of cytokines (2) closely related to the differentiation of a specific subset of
lymphocytes are secreted by MNPs and APCs after stimulation by the microbiome. Each of these
cell subsets secretes a certain pattern of cytokines, which might act as the positive-feedback
factor or direct effector (3), eventually leading to tissue destruction
20. The role of specific bacteria
in the initial pathogenesis of
periodontitis
21.
22. FIGURE 1 (a)
Conventional
paradigm of
polymicrobial
synergy and
dysbiosis model as
a hypothesis for
the pathogenesis
of periodontitis.
(b) Inverted
paradigm
hypothesis for the
pathogenesis of
periodontitis
whereby
inflammation
drives and
exacerbated
periodontal
infection
24. The development of gingivitis and periodontitis can
be divided into a series of stages: initial, early,
established, and advanced lesions
25. The initial lesion begins 2–4 days after the accumulation
of the microbial plaque.
During the initial lesion, an acute exudative vasculitis in
the plexus of the venules lateral to the junctional
epithelium, migration of polymorphonuclear (PMN) cells
through the junctional epithelium into the gingival sulcus,
co-exudation of fluid from the sulcus, and the loss of
perivascular collagen were observed.
26. The early injury develops within 4–10 days.
This lesion is characterized by a dense infiltrate of T
lymphocytes and other mononuclear cells, as well as by
the pathological alteration of the fibroblasts.
27. The established lesion develops within 2–3 weeks.
This lesion is dominated by activated B cells (plasma cells)
and accompanied by further loss of the marginal gingival
connective tissue matrix, but no bone loss is yet detectable.
Several PMN continue to migrate through the junctional
epithelium, and the gingival pocket is gradually established.
28. Finally, in the advanced lesion, plasma cells continue to
predominate as the architecture of the gingival tissue is
disturbed, together with the destruction of the alveolar
bone and periodontal ligament.
29. It is characterized by a conversion of junctional
epithelium to the pocket epithelium, formation of denser
inflammatory infiltrate composed of plasma cells and
macrophages, loss of collagen attachment to the root
surface, and resorption of the alveolar bone.
32. The inflammatory response consists of four main
components:
(1) endogenous or exogenous factors, such as molecular
patterns associated with pathogens (PAMP) and damage
(DAMP), which are derived from bacteria, viruses, fungi,
parasites, and cell damage, as well as toxic cellular
components or any other harmful condition;
33. (2) cellular receptors that recognize these molecular
patterns (PRR), for example, Toll-like receptors (TLR); (3)
proinflammatory mediators, such as cytokines,
chemokines, the complement system, etc.; and
(4) target cells and tissues, where these proinflammatory
mediators act.
34. The inflammatory response is mainly characterized
by four successive phases:
(1) silent phase, where the cells synthesize and
release the first proinflammatory mediators;
(2) vascular phase, characterized by an increase in
vascular permeability and dilatation;
35. 3) cellular phase, characterized by the infiltration of
inflammatory cells at the site of injury; and
(4) the resolution of the inflammatory response
36. The junctional epithelium is the first periodontal
structure to face the bacterial challenge [23].
Bacteria are capable to cross the junctional epithelium
and pass to the gingival conjunctive tissue, where they
stimulate the gingival epithelial cells and fibroblasts to
trigger the initial inflammatory responses.
37. These resident periodontal cells detect bacterial PAMP,
such as lipopolysaccharide (LPS) [25], which binds to the
Toll-like receptors (TLR4/2), triggering the recruitment of
several protein kinases in the cytoplasmic end of the
receptors,
38. ultimately causing the activation of proinflammatory
transcription factors, such as nuclear factor kappa B (NFκB)
and activator protein 1 (AP-1) , which induces the synthesis
and release of mediators to trigger the inflammatory
response.
39. The gingival fibroblasts and the periodontal ligament are
responsible for the destruction and disorganization of the
fibrous component of the extracellular matrix of the
periodontal tissue by increasing the local production and
the activity of the matrix metalloproteinases (MMPs)
40.
41. it was shown that activated neutrophils express
membrane-bound receptor activator of nuclear factor
kappa Β ligand (RANKL), a key osteoclastogenic cytokine
and, thereby able of inducing osteoclastic bone
resorption.
42. These recent concepts suggest that neutrophils could
contribute to periodontitis not only by initiating the
lesion but also by participating in its progression, by
recruiting T-helper 17 cells or promoting the
accumulation of B cells and plasma cells in the
established and advanced lesions.
43. Macrophages are an important source of
proinflammatory and potentially destructive molecules for
tissues, such as interleukin-1 (IL-1), tumor necrosis factor
alpha (TNF-α), MMP, and prostaglandin, which play an
important role and are elevated in the gingival tissue and in
the gingival crevicular fluid of patients with chronic
periodontitis.
44. Therefore, studies have shown a direct correlation of
macrophage infiltration with the severity of periodontal
disease [31], contributing greatly to the intensification of
the degradation of the collagen matrix in the connective
periodontal tissue [32, 33].
45. These macrophages may undergo a classical (M1) or
alternative (M2) activation.
M1 macrophages are induced by microbial agents (e.g.,
LPS) or by Th1 cytokines and show high phagocytic
capacity and an increased expression of proinflammatory
cytokines, costimulatory, and antimicrobial molecules.
46. In contrast, M2 macrophages are induced by Th2
cytokines and secrete high levels of IL-10 and
transforming growth factor beta 1 (TGF-β1).
47. In gingivitis, the predominant APCs are CD14+
and CD83+ dendritic cells.
While in the periodontitis, the predominant APCs
are CD19+ and CD83+ B lymphocytes .
48. Therefore, the activation of adaptive immunity has a
great influence on the bone loss in periodontitis,
associated with B and T lymphocytes, since several
studies have shown that these cells are the main
cellular sources of activator of the κB ligand receptor of
the nuclear factor (RANKL) during periodontal
inflammation
49. Activated T and B cells produce both the membrane-bound
and soluble RANKL forms.
Soluble RANKL can induce osteoclastogenesis
independently of direct contact between infiltrating
lymphocytes and osteoclast precursors on the bone surface.
However, 17 T-helper cells expressing RANKL, but not T-
helper 1 cells, activate osteoclasts also by direct cell-cell
contact.
50. In the alveolar bone, the RANKL/OPG/RANK system
controls the balance of the bone metabolism.
RANKL is the osteoclasts activator and the molecular
signal directly responsible for the bone resorption, which
interacts with its associated receptor RANK on the
surface of osteoclast and osteoclast precursors, which
triggers its recruitment on the bone surface and cell fusion
and activation.
51. Osteoprotegerin (OPG) is a soluble protein that
has the ability to block the biological functions of
RANKL by competitive inhibition.
52. In periodontitis, theTh1 lymphocytes have a
fundamental role in the establishment and
progression of periodontitis, through the increase of
IFN-γ levels.
53. Studies have shown that mice IFN-γ-deficient
showed low levels of inflammatory cytokines and
chemokines, as well as macrophages infiltrated in
periodontal tissue, developing a less severe
phenotype of alveolar bone destruction.
54. Th2 lymphocytes are the main cellular source of IL-4,
which promotes the change of class to the secretion of
IgE in B cells and favors the alternative activation of
macrophages in an IFN-γindependent pathway.
55. Finally, RANKL can also be secreted by Th17
lymphocytes, which in cooperation with inflammatory
cytokines derived from Th1 lymphocytes are capable to
tilt bone metabolism favoring bone resorption.
56.
57. Fig. 2
The cytokine network in the pathogenesis of periodontitis. In this figure, the
effects of cytokines in the host immune response are shown at the level of
intercellular interactions.
Briefly, well-established pro-inflammatory cytokines from IL-1, IL-6 and TNF
families are secreted by host periodontal cells and immunocytes after stimulation by
pathobionts, which activates and recruits specific immune cell subsets and causes
direct tissue damage.
Then, naive T cells and B cells differentiate into mature T cells or plasma cells
under the action of specific cytokines and further activate or promote other effector
cells, such as osteoclasts and neutrophils, which exert pro-inflammatory or anti-
inflammatory effects by secreting cell-specific cytokine clusters. Among these cell
subsets, Th1 and Treg cells mainly act as protectors,
while Th2/B and Th17 cells exert complex effects that may lead to tissue
destruction or protection under certain circumstances (full lines: the effect of
cytokines on cells and the interactions between cells; dashed lines: the secretion of
cytokines)
58.
59. Pro-inflammatory cytokines, related receptor complexes and downstream
signalling pathways
. Most IL-1 (represented by IL-1, IL-18 and IL-33), IL-6 and TNF family members
have pleiotropic effects on lymphocyte promotion and tissue destruction and act as
pro-inflammatory cytokines.
By binding to their corresponding receptor, IL-1 family members mainly activate
transcription factors related to T cell activation and pro-inflammatory cytokine
secretion, and IL-6 mainly mediates B cell activation.
Depending on the state of key transduction proteins, the binding between TNF
family members and their related receptors can lead to very different cell fates
that include death (apoptosis and necroptosis) or life (secretion of pro-
inflammatory and osteoclastogenic factors) and both lead to the destruction of
periodontal tissue
60.
61. Cytokines that are closely related to certain groups of T lymphocytes.
Most of the remaining cytokines are closely related to the differentiation
and/or effects of specific immune cell subsets.
Under stimulation by certain inflammatory cytokines, naive CD4+ T cells
differentiate towards multiple directions, including Th1 (IL-12) and Treg (IL-2
and TGF-β) cells, which mainly have protective effects, and Th17 (IL-23) and
Th2 (IL-4) cells, which mainly have pleiotropic effects.
The signalling pathways downstream of IL-17 (secreted by Th17 cells) and
IL10 (secreted by Treg cells) are specific and of special significance to the
periodontal host immune response, as shown i
62.
63. FIGURE 1
Panel (A) shows how immune fitness of the host determines the host
response to the dental biofilm, which can either be symbiosis and
homeostasis, or an aberrant host response leading to an imbalance
resulting in inflammationdriven destruction of periodontal tissues, ie,
periodontitis.
Panel (B) summarizes the complexity of periodontitis
64.
65.
66. Characteristics of the three main periodontal complex traits used to identify loci
associated with periodontal disease susceptibility
67. Immunohistochemical detection of IFI16 and AIM2 in human gingival tissues. Images
of tissue sections from a healthy individual (A through F) and an individual with
periodontal disease (G through L) according to the American Academy of
Periodontology classification,26 stained with antibodies recognizing the indicated
proteins. A, D, G, J represent original magnification× 10 (scale bar = 200 mm); B, C, E, F,
E, H, K, I, L represent original magnification × 40 (scale bar = 50 mm) of the square
inserts located in the figures with original magnification × 10 in the epithelial and
connective tissue layer. Green arrowheads = epithelial cells; black arrowheads =
fibroblasts; yellow arrowheads = leukocytes; red arrowheads = endothelial cells
68. Proinflammatory and anti-inflammatory functions of AIM2 and IFI16. IFI16 and AIM2 form
inflammasome complexes that respond to microbial DNA to promote production of mature IL-1β
IFI16 also inhibits AIM2 and NLRP3 inflammasome activity to limit production of mature IL-1β. The
priming step that induces expression of the inflammasome genes and IL1B is not shown. [Credit:
Heather McDonald, BioSerendipity, LLC, Elkridge, MD]
71. FIGURE 2 Targets for host-modulation interventions in periodontitis.
Periodontitis arises from the disruption of host-microbe homeostasis in
susceptible individuals, leading to dysbiosis and destructive inflammation that
not only activates osteoclastogenesis and bone loss but also provides nutrients
(tissue breakdown products) that enable the dysbiotic microbiota to grow and
persist
. Shown are important therapeutic targets and potential interventions, most of
which are currently at an experimental stage.
C, complement; Del-1, development endothelial locus-1; IL, interleukin;
MMPs, matrix metalloproteinases; NSAIDs, nonsteroidal antiinflammatory
drugs; OPG-Fc, osteoprotegerin (tumor necrosis factor receptor superfamily
member 11B) fused to the Fc part of IgG; PGE2, prostaglandin E2; RANKL,
receptor activator of nuclear factor-kappaB ligand (tumor necrosis factor ligand
superfamily member 11);
SPM, specialized pro-resolving mediators; TLR, toll-like receptor; TNF, tumor
necrosis factor; Treg, regulatory T-cel
72.
73. FIGURE 3 Proinflammatory functions of interleukin-17 with potential for periodontal
tissue destruction.
Synergistic complement and toll-like receptor signaling in antigen-presenting cells
enhance interleukin-17 production by adaptive immune cells (eg, T-helper cell 17).
Interleukin-17, in turn, acts predominantly on innate immune and stromal cells to
promote inflammatory responses.
By upregulating granulocyte colony-stimulating factor, interleukin-17 can orchestrate the
production of neutrophils in the bone marrow and their mobilization to the circulation.
By inducing CXC chemokines, interleukin-17 can induce the chemotactic recruitment of
neutrophils to the periodontium
74. Additionally, interleukin-17 facilitates neutrophil recruitment by inhibiting negative
regulators of the leukocyte adhesion cascade.
Specifically, interleukin-17 can inhibit endothelial cell production of
development endothelial locus-1, a homeostatic protein that suppresses
neutrophil adhesion and extravasation by blocking the interaction between the
lymphocyte function-associated antigen 1 integrin on neutrophils and the intercellular
adhesion molecule-1 on endothelial cells.
Moreover, interleukin-17 activates macrophages and may promote the degradation of
both connective tissue and the underlying bone by inducing the production of matrix
metalloproteinases and RANKL from stromal cell types.
Del-1, development endothelial locus-1; ICAM-1, intercellular adhesion molecule 1; G-
CSF, granulocyte colony-stimulating factor; IL, interleukin; LFA-1, lymphocyte function-
associated antigen 1; MMPs, matrix metalloproteinases; PGE2, prostaglandin E2; RANKL,
receptor activator of nuclear factor-kappaB ligand (tumor necrosis factor ligand
superfamily member 11); ROS, reactive oxygen species; T; Th17, T-helper 17 cell; TNF,
tumor necrosis factor.