2.2.4 Treponema denticolaT. dentico

2.2.4 Treponema denticola
T. denticola is but one member of the oral treponemes. These rapidly motile, obligatory anaerobic gram-negative bacteria have been estimated to account for approximately 50% of the total bacteria present in a periodontal lesion. T. denticola increases to large numbers in adult periodontitis but is almost undetectable in oral health (Holt and Ebersole 2005; Sakamoto et al. 2005). Treponemes, as a group, often localize at the forefront of periodontal infections, in chronic periodontitis and necrotizing ulcerative gingivitis (NUG), in both invasive disease and when confined to the pocket (Ellen and Galimanas 2005).
Socransky and coworkers’ studies have emphasized the cohabitation of oral bacterial species and have demonstrated a pattern of bacterial fl ora succession, emphasizing a relationship of the various clusters with periodontal disease progression and severity.
The cluster composed of highly proteolytic species P. gingivalis, T. forsythia, and T. denticola, the socalled “red” cluster, has the strongest relationship to advanced and progressive periodontitis (Ellen and Galimanas 2005).
Tissue invasion is a hallmark of spirochetal infections, and many oral treponemes have the capacity to penetrate the gingiva as individual species in experimental models or as cohabitants of natural mixed infections.
The known virulence factors that determine their invasiveness are the various proteins involved in the synthesis and energetics of flagellar motility, chemotaxis proteins, and the chymotrypsin-like protease, dentilisin (Ellen and Galimanas 2005). T. denticola possesses several peptidases associated with its outer sheath. One of these, a prolyl-phenylalanine specific protease, also called chymotrypsin-like protease, appears to be important in T. denticola virulence. Isolated in its native form, it appears to exist as a complex protein with a molecular mass of approximately 100 kDa. When denatured, the 100 kDa native protein was separated into three peptides, with molecular masses of 72, 43, and 38 kDa.
The 72 kDa protein has been named dentilisin (Holt and Ebersole 2005).
Periodontal pathogens in the proteolytic complex have the ability to degrade human matrix components, which would enhance their tissue penetration and those of neighboring species.T. denticola binds extracellular matrix proteins and proteoglycans, elaborates an
enzyme that degrades hyaluronic acid and chondroitin sulfate, while its subtilisin family serine protease, dentilisin, has a wide range of protein substrates including fibronectin, laminin, and fibrinogen (Ellen and Galimanas 2005).
T. denticola also synthesizes two low-iron induced outer membrane proteins, HbpA and HbpB that bind hemin. These proteins appear to be necessary for effi cient iron utilization, although this microorganism has the ability to replace the function of these proteins by
accessing a variety of sources of host iron for nutrition (Ellen and Galimanas 2005).
Elevated levels of T. denticola were identifi ed along with nearly a dozen other species in sulfi de-positive compared with sulfide-negative sites. The results suggested that the sulfide levels in the pockets reflected the proportion of bacteria, whose metabolism resulted
in the production of sulfide as an end-product (Ellen and Galimanas 2005).