Energy dispersive spectroscopy‐scanning transmission electron microscope observations of free radical production in human polymorphonuclear leukocytes phagocytosing non‐opsonized <i>Tannerella forsythia</i>

Moriguchi, Keiichi; Hasegawa, Yoshinori; Higuchi, Naoya; Murakami, Yukitaka; Yoshimura, Fuminobu; Nakata, Kazuhiko; Honda, Masaki

doi:10.1002/jemt.22819

Cited by 3 publications

(3 citation statements)

References 42 publications

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“…However, the genome of this pathogen encodes an oxidative stress response sensor protein (OxyR) homolog, that acts as a positive regulator for antioxidant gene expression. This can contribute to the resistance of the bacterial community to oxidative stress in the aerobic oral cavity and protect against oxidative burst in leukocytes, which is essential in the dental plaque biofilm formation ( Honma et al, 2009 ; Moriguchi et al, 2017 ).…”

Section: Pathogen-specific Effects On Neutrophil Functionsmentioning

confidence: 99%

Uncovering the Oral Dysbiotic Microbiota as Masters of Neutrophil Responses in the Pathobiology of Periodontitis

et al. 2021

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Numerous bacterial species participate in the shift of the oral microbiome from beneficial to dysbiotic. The biggest challenge lying ahead of microbiologists, immunologists and dentists is the fact that the bacterial species act differently, although usually synergistically, on the host immune cells, including neutrophils, and on the surrounding tissues, making the investigation of single factors challenging. As biofilm is a complex community, the members interact with each other, which can be a key issue in future studies designed to develop effective treatments. To understand how a patient gets to the stage of the late-onset (previously termed chronic) periodontitis or develops other, in some cases life-threatening, diseases, it is crucial to identify the microbial composition of the biofilm and the mechanisms behind its pathogenicity. The members of the red complex (Porphyromonas gingivalis, Treponema denticola, and Tannerella forsythia) have long been associated as the cause of periodontitis and stayed in the focus of research. However, novel techniques, such as 16S clonal analysis, demonstrated that the oral microbiome diversity is greater than ever expected and it opened a new era in periodontal research. This review aims to summarize the current knowledge concerning bacterial participation beyond P. gingivalis and the red complex in periodontal inflammation mediated by neutrophils and to spread awareness about the associated diseases and pathological conditions.

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Section: Pathogen-specific Effects On Neutrophil Functionsmentioning

confidence: 99%

Uncovering the Oral Dysbiotic Microbiota as Masters of Neutrophil Responses in the Pathobiology of Periodontitis

et al. 2021

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“…Like other effector functions, normal ROS generation by neutrophils is compromised in the context of periodontitis (Figure 1.4). When tested against individual periodontal bacteria in vitro, neutrophils can mount a ROS response of varying degrees against T. denticola , T. forsythia , F. nucleatum , A. actinomycetemcomitans , and P. gingivalis , although the extent of ROS production heavily depends on the strain used, multiplicity of infection, and type of opsonization (Hirschfeld et al., 2017; Katsuragi et al., 2003; Kurgan et al., 2017; Moriguchi et al., 2017; Shin et al., 2008; Yamazaki et al., 2006). Once generated, ROS do not discriminate between host and pathogen cells, and contribute heavily to disease progression.…”

Section: Neutrophil Effector Functions: Before and During The Dysbiotmentioning

confidence: 99%

Periodontal Pathogens’ strategies disarm neutrophils to promote dysregulated inflammation

Miralda

Uriarte

2020

Molecular Oral Microbiology

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Periodontal diseases affect the integrity of one or several tissues of the periodontium, which is comprised of the gingiva, periodontal ligament, cementum, and alveolar bone. Periodontitis is an irreversible, chronic inflammatory disease that causes the loss of connective tissue, alveolar bone, and eventually the loss of teeth (Pihlstrom et al., 2005). Preventative and treatment measures aim to control or

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“…Despite its importance, the specific interaction between T. forsythia and PMNs remains poorly investigated. A study demonstrated that PMNs can phagocytose non-opsonized T. forsythia , leading to ROS production ( 65 ). Additionally, T. forsythia has been shown to adhere to and invade dental follicle mesenchymal stem cells, resulting in diminished PMN chemotaxis, phagocytic activity, and NET formation induced by these cells ( 66 ).…”

Section: Cell-specific Responses To Tannerella Forsythiamentioning

confidence: 99%

The intriguing strategies of Tannerella forsythia's host interaction

Schäffer,

Andrukhov

2024

Front. Oral. Health

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Tannerella forsythia, a member of the “red complex” bacteria implicated in severe periodontitis, employs various survival strategies and virulence factors to interact with the host. It thrives as a late colonizer in the oral biofilm, relying on its unique adaptation mechanisms for persistence. Essential to its survival are the type 9 protein secretion system and O-glycosylation of proteins, crucial for host interaction and immune evasion. Virulence factors of T. forsythia, including sialidase and proteases, facilitate its pathogenicity by degrading host glycoproteins and proteins, respectively. Moreover, cell surface glycoproteins like the S-layer and BspA modulate host responses and bacterial adherence, influencing colonization and tissue invasion. Outer membrane vesicles and lipopolysaccharides further induce inflammatory responses, contributing to periodontal tissue destruction. Interactions with specific host cell types, including epithelial cells, polymorphonuclear leukocytes macrophages, and mesenchymal stromal cells, highlight the multifaceted nature of T. forsythia's pathogenicity. Notably, it can invade epithelial cells and impair PMN function, promoting dysregulated inflammation and bacterial survival. Comparative studies with periodontitis-associated Porphyromonas gingivalis reveal differences in protease activity and immune modulation, suggesting distinct roles in disease progression. T. forsythia's potential to influence oral antimicrobial defense through protease-mediated degradation and interactions with other bacteria underscores its significance in periodontal disease pathogenesis. However, understanding T. forsythia's precise role in host-microbiome interactions and its classification as a keystone pathogen requires further investigation. Challenges in translating research data stem from the complexity of the oral microbiome and biofilm dynamics, necessitating comprehensive studies to elucidate its clinical relevance and therapeutic implications in periodontitis management.

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Energy dispersive spectroscopy‐scanning transmission electron microscope observations of free radical production in human polymorphonuclear leukocytes phagocytosing non‐opsonized Tannerella forsythia

Cited by 3 publications

References 42 publications

Uncovering the Oral Dysbiotic Microbiota as Masters of Neutrophil Responses in the Pathobiology of Periodontitis

Uncovering the Oral Dysbiotic Microbiota as Masters of Neutrophil Responses in the Pathobiology of Periodontitis

Periodontal Pathogens’ strategies disarm neutrophils to promote dysregulated inflammation

The intriguing strategies of Tannerella forsythia's host interaction

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