N.S. Ramamurthy

Some Characteristics of Collagenase Activity in Gingival Crevicular Fluid and Its Relationship to Gingival Diseases in Humans

Collagenase activity in human gingival fluid was measured using a radioactive collagen fibril assay. The activity was positively correlated with the severity of gingival disease. The fluid collagenase seemed to be controlled by α2-macroglobulin, based on its activation by NaSCN, and to be present solely in the extracellular fraction. Examination of the collagen breakdown products by acrylamide gel electrophoresis indicated that the fluid collagenase was of tissue rather than bacterial origin.

Matrix metalloproteinase inhibitor prevents acute lung injury after cardiopulmonary bypass.

BACKGROUND Acute lung injury (ALI) after cardiopulmonary bypass (CPB) results from sequential priming and activation of neutrophils. Activated neutrophils release neutral serine, elastase, and matrix metalloproteinases (MMPs) and oxygen radical species, which damage alveolar-capillary basement membranes and the extracellular matrix, resulting in an ALI clinically defined as adult respiratory distress syndrome (ARDS). We hypothesized that treatment with a potent MMP and elastase inhibitor, a chemically modified tetracycline (CMT-3), would prevent ALI in our sequential insult model of ALI after CPB. METHODS AND RESULTS Anesthetized Yorkshire pigs were randomized to 1 of 5 groups: control (n=3); CPB (n=5), femoral-femoral hypothermic bypass for 1 hour; LPS (n=7), sham bypass followed by infusion of low-dose Escherichia coli lipopolysaccharide (LPS; 1 microgram/kg); CPB+LPS (n=6), both insults; and CPB+LPS+CMT-3 (n=5), both insults plus intravenous CMT-3 dosed to obtain a 25-micromol/L blood concentration. CPB+LPS caused severe lung injury, as demonstrated by a significant fall in PaO(2) and an increase in intrapulmonary shunt compared with all groups (P<0.05). These changes were associated with significant pulmonary infiltration of neutrophils and an increase in elastase and MMP-9 activity. CONCLUSIONS All pathological changes typical of ALI after CPB were prevented by CMT-3. Prevention of lung dysfunction followed an attenuation of both elastase and MMP-2 activity. This study suggests that strategies to combat ARDS should target terminal neutrophil effectors.

Excessive matrix metalloproteinase activity in diabetes : Inhibition by tetracycline analogues with zinc reactivity

Diabetes mellitus in rats is characterized by excessive activity of several matrix metalloproteinases (MMPs), notably collagenase(s) and gelatinase(s), in skin, gingiva, and other tissues. A number of tetracyclines (TCs), both antimicrobial compounds as well as chemically modified non-antimicrobial TC analogues (CMTs) are known to possess potent inhibitory activity against these enzymes. Three conventional antimicrobial TCs and six CMTs were used in this study. In vitro, doxycycline was shown to possess higher inhibitory capacity (i.e. lower IC(max)) against diabetic rat skin collagenase than either minocycline or tetracycline HCl. Addition of excess zinc partially reversed the proteinase inhibition by TCs. In vivo, using rats made diabetic with streptozotocin (STZ), oral administration of various TCs led to decreased weight loss and substantial reductions in the activity of both skin collagenase and skin gelatinase (primarily MMP-9, 92 kDa) without affecting blood glucose. Using an in vitro spectrophotometric technique, the Zn(++) reactivity of several CMTs was assessed and found to be positively related to the potency of these compounds as MMP inhibitors. One particular CMT (CMT-5, pyrazole analogue), which is neither antimicrobial nor capable of binding metal cations, did not inhibit the MMPs. TCs have potential utility in management of diabetic complications mediated by excessive activity of MMPs.

The effect of experimental diabetes on the molecular characteristics of soluble rat-tail tendon collagen.

Acid soluble rat-tail tendon collagen was prepared from animals rendered diabetic by treatment with either streptozotocin or alloxan and from matched controls. In comparison to the normal, the diabetic collagens consistently demonstrated decreased solubility of reconstituted fibrils, marked increase in intrinsic viscosity and a decreased ratio of alpha to beta components. Electrophoresis in sodium dodecyl sulfate-polyacrylamide gels revealed a marked decrease in migration of alpha1, alpha2, and beta components from both types of diabetic collagen. These data indicate that diabetic collagens are larger than normal and are capable of higher degrees of polymerization due to increased intra- and inter-molecular interactions. These changes could explain, in part, the altered response of diabetic connective tissues to inflammation and trauma.

Enhanced Collagenase Activity in Diabetic Rat Gingiva: In Vitro and In Vivo Evidence

Gingiva from alloxan and streptozotocin-diabetic rats exhibited markedly enhanced collagenolytic activity in tissue culture. This effect was eliminated by puromycin or by repeated freeze-thawing of the tissue prior to incubation. Soluble extracts of the diabetic gingiva in situ were found to contain breakdown products of collagen similar in size to the reaction products generated by tissue collagenase. These fragments were not detected in the control tissue. This study indicates that experimental diabetes stimulates the synthesis of gingival collagenase in culture and that a similar effect occurs in vivo.

Response of rat connective tissues to streptozotocin-diabetes. Tissue-specific effects on collagen metabolism.

Abstract We assessed the effect of streptozotocin-diabetes on in vivo collagen metabolism in skin, aorta and intestine by injecting [ 3 H]proline into rats, 20 days after administering the diabetogen, streptozotocin. One day after [ 3 H]proline injection, diabetic and control animals were killed, their tissues analyzed for both 3 H-labeled and unlabeled hydroxyproline and results expressed per entire tissue. Thereby, the effect of diabetes on net collagen synthesis and tissue collagen mass, respectively, was evaluated. Diabetes resulted in a lower content of [ 3 H]collagen in skin and aorta, suggesting decreased net collagen synthesis. This decrease in net synthesis was accompanied by a decrease of collagen mass in skin, whereas aortic collagen mass was unaffected. Consequently, an acceleration of collagen degradation in skin is postulated to have accompanied the expected depression of collagen synthesis; alterations of the physiochemical properties of skin from diabetic rats support this interpretation. For intestine, both net collagen synthesis and mass increased in diabetic rats, reflecting increased collagen synthesis—possibly associated with polyphagy. In conclusion, with regard to collagen metabolism, representative connective tissues respond differently to experimental diabetes, and we suggest that this insight will be useful in future studies aimed at understanding the pathophysiology of connective tissues affected by diabetes.

Extensive Degradation of Recently Synthesized Collagen in Gingiva of Normal and Streptozotocin-induced Diabetic Rats

The degradation of recently synthesized collagen (probably procollagen) in rat incisor gingiva was three times greater than that in skin. Concomitantly, the formation of undegraded (intact) collagen molecules in gingiva was slower than that in skin. This high basal rate of degradation in gingiva was just slightly increased in streptozotocin-induced diabetic rats, whereas the low basal rate in skin was dramatically increased by the diabetic state. The degradation of recently synthesized collagen was measured by the relative amounts(%) of [3H]hydroxyproline-containing material in the TCA-soluble fraction of a tissue, compared with the total amount (TCA-soluble + TCA-insoluble) of [3H]hydroxyproline-containing material. Separation of the TCA fractions allowed the formation of collagen degradation products (TCA-soluble) to be viewed separately from the formation of undegraded collagen molecules (TCA-insoluble). The [3H]hydroxyproline-containing material in the TCA-soluble fraction was greatest in amount and in specific activity, 30 min after [ 3H] proline injection, supporting the origin of this material as being procollagen. At this time period, the relative amounts of TCA-soluble [ 3H] hydroxyproline-containing material were 40.3% (gingiva) and 12.7% (skin). For diabetic rats, the values were 55% and 48.8%, respectively. For the [3H] hydroxyproline-containing material in the TCA-insoluble fraction, at 30 min, the specific activity of [3H] hydroxyproline was 4.3 for gingiva and 7.4 for skin. At all other time periods, the values were also greater for skin than for gingiva, making it unlikely that the formation of intact collagen molecules occurred faster in gingiva than in skin. Overall, the prevailing concept of rapid collagen turnover in oral tissues seems applicable to procollagen, but not to collagen of rat incisor gingiva.

Tetracyclines inhibit intracellular muscle proteolysis in vitro

Tetracycline antibiotics (TETs) have a recently discovered novel action: inhibition of extracellular metalloproteinase activity, especially that of collagenase and gelatinase. This property, now confirmed in 8 different laboratories using > 40 tissue sources, includes natural and semi-synthetic TETs as well as a chemically modified TET (CMT) devoid of antimicrobial activity. We have used 14C-Tyr biosynthetically labelled intracellular proteins in L-6 myoblast culture as a test system to assess intracellular proteolysis. Starvation accelerates proteolysis, which can be suppressed by agents such as insulin or serum. Minocycline, doxycycline, and CMT all retarded the rate of intracellular protein degradation in a dose dependent manner. These agents also demonstrated marked synergism with insulin. A CMT derivative (pyrazole) stripped of one of its metal chelation sites and lacking anti-collagenase activity, also lost its antiproteolytic effect. CMT at physiologic concentrations (< or = 5 micrograms/ml) had no effect on protein synthesis, but at 15 micrograms/ml (pharmacologic), a suppressive effect was noted. These findings demonstrate that TETs can inhibit protein degradation as well as synthesis in a mammalian muscle-derived cell line.