Evidence for genetic control of changes in f-actin polymerization caused by pathogenic microorganisms: in vitro assessment using gingival fibroblasts from human twins

Treponema denticola-Induced RASA4 Upregulation Mediates Cytoskeletal Dysfunction and MMP-2 Activity in Periodontal Fibroblasts

The periodontal complex consists of the periodontal ligament (PDL), alveolar bone, and cementum, which work together to turn mechanical load into biological responses that are responsible for maintaining a homeostatic environment. However oral microbes, under conditions of dysbiosis, may challenge the actin dynamic properties of the PDL in the context of periodontal disease. To study this process, we examined host-microbial interactions in the context of the periodontium via molecular and functional cell assays and showed that human PDL cell interactions with Treponema denticola induce actin depolymerization through a novel actin reorganization signaling mechanism. This actin reorganization mechanism and loss of cell adhesion is a pathological response characterized by an initial upregulation of RASA4 mRNA expression resulting in an increase in matrix metalloproteinase-2 activity. This mechanism is specific to the T. denticola effector protein, dentilisin, thereby uncovering a novel effect for Treponema denticola-mediated RASA4 transcriptional activation and actin depolymerization in primary human PDL cells.

Alterations of neutrophil f-actin kinetics by tobacco smoke: implications for periodontal diseases

Tobacco smoking is a major risk factor in the incidence and severity of periodontal diseases. Alterations of neutrophil function by short-term high levels of smoke during the act of smoking (acute smoke exposure) as well as long-term exposure to lower levels of tobacco substances in the bloodstream (chronic smoke exposure) may play a role in the pathogenesis of periodontal diseases in smokers. The polymerization and depolymerization of f-actin in response to infectious agents or inflammatory mediators is a critical process in a variety of neutrophil functions. In this study, we examined the effects of in vitro smoke exposure on neutrophils from smokers and non-smokers (which may be comparable to in vivo acute smoke exposure) and neutrophils from smokers not exposed to further in vitro smoke (which may be comparable to chronic smoke exposure) on f-actin kinetics. Peripheral neutrophils were isolated from seven healthy smoking subjects and seven healthy age-matched non-smoking subjects and exposed to 1-5 min of acute smoke in a smoke box system or not exposed to further smoke (baseline controls). Selected aliquots of neutrophils from control and 5-min exposures of acute smoke were then stimulated with the chemotactic peptide F-met-leu-phe at 10(-7) M for an additional 30-360 s. Cells were fixed and permeabilized, stained for f-actin with NBD phallacidin, and analyzed by flow cytometry. From baseline to 5 min of in vitro smoke exposure, there was a 38% decline in f-actin stain in non-smokers and a 30% decline in f-actin stain in smokers (p > 0.05) with f-actin values slightly higher in smokers than-non-smokers (p > 0.05). With F-met-leu-phe stimulation, both smokers and-non-smokers demonstrated a characteristic rise in f-actin stain from 0 to 120 s with a subsequent decline to baseline at 360 s and no significant differences in f-actin levels at any time of stimulation between groups. After preincubation with 5 min of in vitro smoke, the magnitude of rise in f-actin was less in both smokers and non-smokers when compared to cells not incubated with 5 min of smoke (p < 0.05 at 120 s for both smokers and non-smokers). F-actin values in smokers were higher than-non-smokers from 30 to 360 s of F-met-leu-phe exposure (p > 0.05). These results demonstrate that in vitro smoke exposure may impair normal f-actin kinetics. These alterations in f-actin kinetics may in turn affect other neutrophil functions which may impact on the pathogenesis of periodontal diseases in smokers.

Perturbation and exploitation of host cell cytoskeleton by periodontal pathogens

Some periodontal pathogens disrupt epithelial barriers and cellular adhesion to the extracellular matrix, which affects the cytoskeleton. Porphyromonas gingivalis and Actinobacillus actinomycetemcomitans exploit the cytoskeleton during their uptake by epithelial cells. Treponema denticola perturbs actin and actin-regulating pathways in host cells. Cytoskeletal dysfunction due to pathogenic bacteria may impair physiologic remodeling and wound repair in the periodontium.