Tuula Ingman

Human Neutrophil Gelatinase and Associated Lipocalin in Adult and Localized Juvenile Periodontitis

In search of direct in vivo evidence of matrix metalloproteinases (MMPs) in periodontal tissue destruction, we studied the presence and localization of MMP-9 and neutrophil gelatinase-associated lipocalin (NGAL) in adult periodontitis (AP) and localized juvenile periodontitis (LJP) gingival tissue specimens by immunohistochemistry, and the activities of gelatinases by Western blot, enzymography, and activity measurements, using radioactive gelatin as substrate in gingival crevicular fluid (GCF) and saliva. In gingival tissue obtained from AP and LJP patients, polymorphonuclear leukocyte (PMN) 92-kDa MMP-9 and NGAL were seen in the connective tissue, but both the sulcular and the oral epithelia were consistently negative. Whereas PMNs located in the gingival blood vessels showed strictly cytoplasmic MMP-9 and NGAL immunoreactivities, in the case of PMN extravasation the staining reactions extended extracellularly. Gelatinase activities consisting mainly of 92-kDa gelatinase were increased in AP GCF relative to LJP GCF and periodontally healthy control GCF. Western blot with specific anti-NGAL antibodies revealed the presence of 25-kDa NGAL and its high-molecular-weight forms in AP and LJP GCF and saliva and in culture medium of oral keratinocytes, but not in gingival fibroblast culture medium. We conclude that extravasated degranulating PMNs are the major source of MMP-9 and NGAL in periodontitis gingiva, GCF, and saliva.

Human Neutrophil Collagenase MMP-8 in Peri-implant Sulcus Fluid and its Inhibition by Clodronate

The exact molecular mechanisms of the loosening of a dental implant are not well-known. The characteristics of implant sulci are similar to those of periodontal sulci regarding gingival crevicular fluid (GCF) and peri-implant sulcular fluid (PISF). Proteolytic enzymes, matrix metalloproteinases (MMPs), participate in peri-implant tissue remodeling. Clodronate is a well-tolerated bisphosphonate-group drug currently used in bone-resorption-related diseases in humans. The mechanisms of bisphosphonate action are not clarified. Collagenase activity in diseased PISF was significantly higher than in the clinically healthy group. Immunoblotting disclosed that diseased PISF contained increased immunoreactives MMP-8 compared with the healthy PISF. The residual latent collagenase activity in the diseased PISF was activated by gold thioglucose and inhibited completely by 100 pM of doxycycline closely resembling pure neutrophil collagenase (MMP-8). The presence of MMP-8 in diseased but not in clinically healthy PISF may prove to be a useful biochemical indicator to monitor peri-implant health and disease. Pure human neutrophil collagenase (MMP-8) and the MMP-8 present in PISF and in the GCF of both loosening implants and periodontitis-affected teeth were efficiently inhibited in vitro by clodronate (50% inhibition [IC50] was achieved by 150 uM of clodronate), an osteoactive, antiresorptive bisphosphonate. Furthermore, the new finding suggests an extended and hitherto-undescribed potential for clodronate in preventing the loosening of both implants and teeth, based on a dual beneficial effect: prevention of both bone resorption/osteolysis and of soft tissue/dental ligament destruction. Potential new therapeutic indications based on the collagenase-inhibiting effect of clodronate provide potential new therapeutic indications for a variety of diseases involving connective tissue breakdown, such as periodontal disease, arthritides, and tumor invasion.

Inhibition of Matrix Metalloproteinase-1 by Dichloromethylene Bisphosphonate (Clodronate)

Abstract. Interstitial collagenase present in human jaw cyst extract and purified human fibroblast-type collagenase (MMP-1) were both efficiently inhibited in vitro by clodronate, an osteoactive, antiresorptive bisphosphonate. The IC50 of clodronate to inhibit MMP-1 is 150 μM. These findings suggest an extended and hitherto undescribed properties for clodronate/biphosphonates in prevention and treatment of tissue degradation in both bone and soft tissue destructive diseases.

The in vivo levels of matrix metalloproteinase-1 and -8 in gingival crevicular fluid during initial orthodontic tooth movement.

Orthodontic force induces biochemical responses in the periodontal ligament (PDL), but the matrix metalloproteinase (MMP)-dependent molecular mechanisms in orthodontically induced periodontal remodeling have remained unclear. Previous studies indicate that mechanical stress induces MMP-1 production in human PDL cells in vitro. We tested the hypothesis whether the in vivo levels, molecular forms, and degree of activation of MMP-1 and MMP-8 in gingival crevicular fluid (GCF) reflect an early stage of orthodontic tooth movement. Molecular forms of MMP-1 and MMP-8 were analyzed by Western blot, and MMP-8 levels by quantitative immunofluoro-metric assay (IFMA). The results showed that GCF MMP-8 levels for orthodontically treated teeth were significantly higher at 4-8 hrs after force application than before activation, and when compared with the control teeth (p < 0.05). Analysis of our data indicates that the cells within the periodontium are up-regulated to produce MMP-8, and the increased expression and activation of GCF MMP-8 reflect enhanced periodontal remodeling induced by orthodontic force.

Presence, activities, and molecular forms of cathepsin G, elastase,α1-antitrypsin, andα1-antichymotrypsin in bronchiectasis

The presence, activities, and molecular forms of the serine proteinases, elastase, and cathepsin G, and their endogenous inhibitors,α1-antitrypsin andα1-antichymotrypsin, were investigated in bronchoalveolar lavage (BAL) fluid of bronchiectasis patients divided into mild, moderate, and severe disease subgroups and compared to BAL fluid from healthy controls. Immunochemical characterization and quantitation were performed by Western immunoblot. The activities of elastase and cathepsin G were recorded spectrophotometrically using synthetic substrates. The results showed a significant difference in elastase and cathepsin G activities in BAL fluid of the three subgroups, revealing the following data—mild subgroup, 0.21±0.09 mU/g and 57.35±20.9 U/g; moderate subgroup, 1.87±1.12 mU/g and 89.24±31.4 U/g; and severe subgroup, 2.64±1.63 mU/g and 139.18±58.3 U/g, respectively—compared to those of the healthy control group, 0.09±0.03 mU/g and 50.96±16.5 U/g. Evidently, the protective shield of plasma-derived antiproteinases was sufficient in healthy subjects and, also, in mild cases of bronchiectasis, but not in cases of severe and moderate forms of bronchiectasis, in which free and catalytically active elastase and cathepsin G were detected. The serine proteinases inhibitors (serpins),α1-antitrypsin andα1-antichymotrypsin, have evidently been oxidized and/or proteolytically cleaved in the cases of moderate and severe bronchiectasis. The results indicate that insufficient endogenous downregulation of catalytically active elastase and cathepsin G in BALF leads to tissue injury, resulting in alterative and deformative processes in the bronchiectasis lung.