Tetracyclines have long been considered useful adjuncts in peridontal therapy based on their antimicrobial efficacy against putative periodontopathogens. However, recently these drugs were found to inhibit mammalian collagenases and several other matrix metalloproteinases (MMPs) by a mechanism independent of their antimicrobial activity. Evidence is presented that this property may be therapeutically useful in retarding pathologic connective tissue breakdown, including bone resorption. The experiments leading to this discovery are described and possible mechanisms are addressed, including the specificity of tetracyclines' anti-collagenase activity, the role of the drugs' metal ion (Zn2+, Ca2+)-binding capacity, and the site on the tetracycline molecule responsible for this nonantimicrobial property. Of extreme interest, the tetracycline molecule has been chemically modified in multiple ways, generating a new family of compounds called CMTs (chemically modified tetracyclines) that lack antimicrobial but still retain anti-collagenase activity. The first of these CMTs, 4-de-di-methylaminotetracycline, was found not to produce a major side-effect of antimicrobial tetracycline therapy--its administration to experimental animals did not result in the emergence of tetracycline-resistant microorganisms in the oral flora and gut. Numerous examples of the clinical potential of this non-antimicrobial property of tetracyclines in the treatment of periodontal and several medical diseases (e.g., sterile corneal ulcers, rheumatoid arthritis, skin bullous lesions, tumor-induced angiogenesis and metastasis) are discussed.
Ryanodine receptors (RyRs) reside in microsomal membranes where they gate Ca2" release in response to changes in the cytosolic Ca2" concentration. In the osteoclast, a divalent cation sensor, the Ca2" receptor (CaR) Ca2" elevations induced by Ni2". In contrast, the responses to Ni2" were strongly potentiated by an antiserum Ab"2 raised to an epitope located within the channel-forming domain of the type II RyR. The antiserum also stained the surface of intact, unfixed, trypan blue-negative osteoclasts. Serial confocal sections and immunogold scanning electron microscopy confirmed a plasma membrane localization of this staining. Antiserum AbM directed to a putatively intracellular RyR epitope expectedly did not stain live osteoclasts nor did it potentiate CaR activation. It did, however, stain fixed, permeabilized cells in a distinctive cytoplasmic pattern. We conclude that an RyR-like molecule resides within the osteoclast plasma membrane and plays an important role in extracellular Ca2" sensing. (J. Clin. Invest. 1995.
Since both conventional (antimicrobial) and non-antimicrobial tetracyclines inhibited periodontal bone resorption induced by endotoxin injection, MMP-mediated bone loss in this model can be prevented by inhibition of MMPs.
Tetracyclines (TCs) have wide therapeutic usage as antimicrobial agents; these drugs (e.g., minocycline, doxycycline) remain useful as adjuncts in periodontal therapy. However, TCs also have non-antimicrobial properties which appear to modulate host response. In that regard, TCs and their chemically-modified analogs (CMTs) have been shown to inhibit the activity of the matrix metalloproteinase (MMP), collagenase. The activity of this enzyme appears crucial in the destruction of the major structural protein of connective tissues, collagen. Such pathologic collagenolysis may be a common denominator in tissue destructive diseases such as rheumatoid and osteoarthritis, diabetes mellitus, bullous dermatologic diseases, corneal ulcers, and periodontitis. The mechanisms by which TCs affect and, possibly, diminish bone resorption (a key event in the pathogenesis of periodontal and other diseases) are not yet understood. However, a number of possibilities remain open for investigation including the following: TCs may 1) directly inhibit the activity of extracellular collagenase and other MMPs such as gelatinase; 2) prevent the activation of its proenzyme by scavenging reactive oxygen species generated by other cell types (e.g. PMNs, osteoclasts); 3) inhibit the secretion of other collagenolytic enzymes (i.e. lysosomal cathepsins); and 4) directly affect other aspects of osteoclast structure and function. Several recent studies have also addressed the therapeutic potential of TCs and CMTs in periodontal disease. These drugs reduced excessive gingival collagenase activity and severity of periodontal breakdown in rats infected with Porphyromonas gingivalis and in diabetic rats. Furthermore, the latter drug (CMT) was not associated with the emergence of TC-resistant microorganisms.(ABSTRACT TRUNCATED AT 250 WORDS)
Combination of a CMT and a bisphosphonate may be a useful treatment to optimally suppress periodontal destruction and tooth loss and in other tissue-destructive inflammatory diseases such as arthritis.
The molecular mechanisms of jaw cyst expansion probably involve interactions of matrix metalloproteinases (MMPs) and the tissue inhibitors of MMPs (TIMPs). In this study, molecular species of gelatinases present in neutral salt extracts of cyst walls and cyst fluids were characterized by functional activity measurements (type I gelatin and alpha-casein zymography) and immunologically (Western-blotting). The effects of various protein thiol-group or cysteine-switch reactants involved in the activation of collagenases were studied on cyst gelatinases and a gelatinases purified from human gingival fibroblasts (72 kD MMP-2), gingival keratinocytes (92 kD MMP-9) and polymorphonuclear neutrophilic leukocytes (92 kD MMP-9). Western-blotting revealed the presence of both 92 kD (MMP-9) and 72 kD (MMP-2) gelatinases in cyst wall extracts and cyst fluids. Western-blot studies further suggested that jaw cyst gelatinases were only in part complexed with and thus inhibited by TIMP-1 or TIMP-2, suggesting that both MMP-9 and MMP-2 may participate in cyst expansion. MMP-2 was also partially fragmented to a 68 kD form and additional lower molecular weight proteinases (< 60 kD) were detected by alpha-casein zymography and by Western-blotting, suggesting proteolytic fragmentation. MMP-9 was at least partially activated by all protein-thiol group reactants and rather resistant to oxidative inhibition by hypochlorite (NaOCl); in contrast, MMP-2 was activated by APMA but not at all by gold thioglucose (GTG) and was clearly inactivated by hypochlorite (NaOCl).(ABSTRACT TRUNCATED AT 250 WORDS)
1. Acute exacerbation of gingivitis can lead to destructive periodontitis. 2. Such periods of acute inflammation may be associated with epithelial ulceration. 3. Bone loss in periodontal disease may occur in bursts of osteoclastic activity triggered by cells or factors generated during an acute phase. 4. Partial repair can follow an acute episode and a "stable lesion" may become re-established.
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