Differential expression of 92-kDa gelatinase in primary atherosclerotic versus restenotic coronary lesions.

Rupture of atherosclerotic plaque resulting in intravascular thrombosis and myocardial infarction (MI), while a common sequelae of de novo atherosclerotic lesions, is an uncommon consequence of restenosis. We hypothesize that the rarity of MI associated with restenotic lesions is a result of cellular and biochemical modifications induced by the local response to mechanical injury rendering the site resistant to rupture. Clinical and angiographic features of patients presenting with symptomatic primary (n = 24) or restenotic coronary lesions (n = 12) who underwent directional atherectomy were compared. Histologic analysis and immunostaining for 92-kDa gelatinase were performed on each atherectomy specimen. There was no significant difference between the 2 groups regarding age, gender, incidence of diabetes, smoking, hypertension, hypercholesterolemia, or previous MI. Lesion length, extent, and distribution of disease and percent stenosis were not significantly different between groups. However, 8% of primary lesions were hypercellular compared with 75% of restenotic specimens (p = 0.0001). Hypercellularity in restenotic specimens was shown by adjacent section staining to be composed of smooth muscle cells. Ninety-two kDa gelatinase was expressed in 79% of primary lesions versus 0% of restenotic specimens (p = 0.0001). Thrombus was identified in 54% of primary lesions versus 22% of restenotic lesions (p <0.05). These findings suggest that, independent of clinical or angiographic influences, balloon injury induces increased lesion cellularity and reduced expression of 92-kDa gelatinase, possibly resulting in a reduced propensity for plaque rupture and thrombosis.

Transcriptional regulation of the collagenase gene by basic fibroblast growth factor in osteoblastic MC3T3-E1 cells.

Recent studies have shown that Basic Fibroblast Growth Factor increases bone resorption and increases interstitial collagenase mRNA and protein in osteoblasts. We examined the effect of bFGF on a 1.8-kb fragment of the rabbit collagenase promoter linked to a chloramphenicol acetyl transferase CAT construct stably transfected into mouse osteoblastic MC3T3-E1 cells. Treatment with bFGF (10(-8)M) for 24 h caused a 3-fold increase in collagenase-CAT activity. CAT activity in a construct without the collagenase promoter was not regulated by 48 h treatment with bFGF (10(-8)M). Neither indomethacin nor staurosporine blocked the effect of bFGF on collagenase-CAT activity in these cells. However, the stimulatory effect of bFGF on collagenase-CAT activity was inhibited by genistein and herbimycin A, which are tyrosine kinase inhibitors. These data show for the first time that bFGF transcriptionally regulates collagenase gene expression in osteoblasts through a protein tyrosine kinase-dependent pathway.

Identification of 92-kD gelatinase in human coronary atherosclerotic lesions. Association of active enzyme synthesis with unstable angina.

BACKGROUND: Acute coronary ischemia is usually initiated by rupture of atherosclerotic plaque, leading to intracoronary thrombosis and clinical sequelae. The proximate cause of plaque rupture is unknown. Accordingly, we investigated the potential role of the 92-kD gelatinase member of the matrix metalloproteinase family in acute coronary ischemia. METHODS AND RESULTS: Coronary atherectomy specimens from patients with atherosclerosis and an acute ischemic syndrome consistent with recent plaque rupture (unstable angina) (n = 12) were immunostained for the presence of 92-kD gelatinase; the results were compared with those obtained by identical study of atherectomy specimens from patients with atherosclerosis and angina but without acute ischemia (stable angina) (n = 12). Positive immunostaining for 92-kD gelatinase was present in 83% of specimens from both unstable and stable angina patients. However, intracellular localization of enzyme (indicating active synthesis) was documented in 10 of 10 positively stained specimens from patients with unstable angina compared with 3 of 10 positively stained specimens from patients with stable angina. Macrophages and smooth muscle cells were the major sources of 92-kD gelatinase in all specimens examined by immunostaining of adjacent sections. CONCLUSIONS: 92-kD gelatinase is commonly expressed in coronary arterial atherosclerotic lesions. Active synthesis of 92-kD gelatinase by macrophages and smooth muscle cells in atherosclerotic lesions may play a pathogenic role in the development of acute coronary ischemia.

Cytokine regulation of gelatinase production by head and neck squamous cell carcinoma: the role of tumor necrosis factor-alpha.

Gelatinases (GLs) belong to a family of enzymes known as matrix metalloproteinases (MMPs), which are produced by both normal and neoplastic cells. These enzymes have been implicated in tumor invasion and metastasis, although the mechanism of regulation of tumor MMP production is unknown. Since our previous studies have shown that numerous cytokines are present in the tumor microenvironment, our goal was to establish the effect of selected cytokines on GL production by both established tumor cell lines and primary cultures of head and neck squamous cell carcinoma (HNSCC). Supernatants of HNSCC cell lines SCC-25 and FADU stimulated with interleukin (IL)-1 alpha and IL-1 beta demonstrated modest induction of 92 kd GL production by zymogram analysis when compared with controls; IL-2, IL-6, and interferon-gamma had no consistent effect on MMP production. Stimulation of cell lines with tumor necrosis factor (TNF)-alpha (10(4) to 10 U/mL), however, dramatically enhanced production of 92 kd GL by both cell lines in a dose-dependent fashion, although tissue inhibitor of metalloproteinase (TIMP) expression was unaffected. Northern blot analysis showed that this enhancement of 92 kd GL occurred at the messenger RNA level. Stimulation of short-term primary tumor cultures with TNF-alpha resulted in significant enhancement of 92 kd GL expression in one of four cultures and enhancement of 72 kd GL expression in all cultures. The observed increase in GL expression by TNF-alpha suggests a role for this cytokine in the regulation of GL expression by tumor cells during invasion and metastasis.

Retroviral gene transfer of epidermal growth factor receptor into HL60 cells results in a partial block of retinoic acid-induced granulocytic differentiation.

HL60 cells are devoid of endogenous epidermal growth factor receptor (EGFR). They respond to retinoic acid and undergo terminal granulocytic differentiation. EGFR complementary DNA was introduced into HL60 cells by retroviral gene transfer. Scatchard plot showed that the binding characteristics are identical to those of A431 cells. HL60-EGFR cells were estimated to express 34,000 EGFR/cell (Kd = 5 nM). The tyrosine phosphorylation upon ligand binding is the first step of signal transduction. The dominant phosphotyrosyl proteins in epidermal growth factor-stimulated HL60-EGFR cells include a 170 kDa protein (EGFR itself), and 125 and 53 kDa proteins. The EGFR signal results in the induction of 92 kDa gelatinase/matrix metalloproteinase in HL60-EGFR cells, thereby providing evidence of the function of the exogenous EGFR and a semiquantitative measure of the EGFR signal. These HL60-EGFR cells offer a unique opportunity to examine the potentially important role of EGFR (c-erbB) in maintaining homeostasis between self-renewal and differentiation. c-erbB has been shown to play a physiological role in the self-renewal of the very early avian stem cells which do express EGFR. The v-erbB (double truncated EGFR) has been shown to cause avian erythroblastosis. We found that these HL60-EGFR cells responded to retinoic acid differently from the HL60-control cells. A partial block of only 45% granulocytic differentiation and concomitant proliferation was noted, consistent with a shift of balance between self-renewal and differentiation toward the former.

Altered epidermal growth factor signal transduction in activated Ha-ras-transformed human keratinocytes.

Epidermal growth factor (EGF) can stimulate proliferation and 92 kDa gelatinase/matrix metalloproteinase (MMP-9) expression. The induction of MMP-9 is not only pathologically significant for invasion and metastasis, but also serves as a semiquantitative measure of EGF signal transduction. In order to examine the role of mutated ras p21 in EGF signal transduction, an activated Ha-ras-transformed human keratinocyte cell line was developed and characterized. Overexpression of the mutated Ha-ras p21 in these cells was demonstrated. Our results showed that EGF induced 92 kDa MMP-9 secretion was doubled in the ras-transformed keratinocytes in comparison to the parent cells. The karyotype, the expression of EGF receptor (EGFR) and transforming growth factor (TGF) alpha at the mRNA level remained unchanged. These results suggest that the presence of high levels of mutated ras p21 may be responsible for the aberrant EGF signal transduction and contributes to transformation. In addition, a reduction of TGF beta expression at mRNA level by 70% was found in the activated Ha-ras-transformed keratinocytes when compared to the parent cells.

Production of both 92- and 72-kDa gelatinases by bone cells.

We investigated the ability of murine bone organ cultures and osteoblast-like bone cells to produce 72- and 92-kDa gelatinase. 4-6 day newborn mouse calvaria cultures were found to release gelatinase activity into their conditioned medium (CM). This activity was increased by four stimulators of resorption, tumor necrosis factor alpha (TNF), interleukin-1 alpha (IL-1), parathyroid hormone (PTH) and the active phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA). Both the 72- and 92-kDa forms of gelatinase were produced by murine bone cultures. In unstimulated bones 72-kDa gelatinase activity was approximately equal to that of the 92-kDa enzyme. IL-1, TNF, PTH and TPA all increased 92-kDa gelatinase activity in the CM of the bone cultures by about 2- to 2.5-fold. In addition TPA and IL-1 also increased 72-kDa gelatinase activity. In unstimulated osteoblast-like MC3T3-E1 cell cultures 72-kDa gelatinase enzyme activity was much greater than 92-kDa activity and was not substantially regulated (less than 40% change) by IL-1, TNF or PTH. In contrast, these agents stimulated 92-kDa gelatinase activity by 2- to 5-fold. As with the MC3T3-E1 cells, primary cells constitutively produced both 72-kDa and 92-kDa gelatinase. This was true for cells with both the most differentiated osteoblast-like phenotype (populations 3 and 4) and the least osteoblast-like phenotype (populations 1 and 2). In unstimulated cultures of all 4-primary populations, 92-kDa gelatinase production was less than 72-kDa and IL-1, TNF and PTH had only small effects on 72-kDa production in any of the populations (less than 60% change).(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of 92 kDa phagocyte gelatinase by inflammatory and connective tissue cells.

It is now apparent that multiple proteinases cooperate in the degradation of the collagenous matrix. Among these proteinases are two biochemically related proteinases which were originally identified by their ability to degrade denatured collagens. The higher molecular weight proteinase (M(r) = 92,000) is predominantly expressed by inflammatory cells while the lower molecular weight proteinase (M(r) = 72,000) is secreted constitutively by fibroblasts. To explore the expression of the 92 kDa proteinase, the gelatinase from human neutrophils was purified and characterized and specific immunologic probes developed for its study in other cell types. Studies of leukemic cell lines (U937s and HL60s) which can be differentiated to a monocyte/macrophage phenotype revealed that after differentiation with phorbol myristic acetate the 92 kDa proteinase was the major proteinase produced. Additional studies of human alveolar macrophages and monocytes differentiated in vitro suggest that these cells secrete a proteinase immunologically and biochemically similar to human neutrophil gelatinase. Although the major gelatinase secreted by the fibroblasts is the 72 kDa proteinase, they also produce the 92 kDa proteinase in a regulated manner. These studies suggest that the regulation of these similar gelatinolytic proteinases varies dependent on cell type. Further studies of their regulation will be important to define the roles of these proteinases in physiologic and pathological processes.

Constitutive expression of a 92-kD gelatinase (type V collagenase) by rheumatoid synovial fibroblasts and its induction in normal human fibroblasts by inflammatory cytokines.

Synovial fibroblasts freshly isolated from the rheumatoid joint are characterized by their marked connective tissue degradative ability. This phenotype includes the ability to secrete large amounts of the matrix-degrading metalloproteinases, collagenase, and stromelysin. We have found that another aspect of this phenotype is the constitutive expression at both protein and mRNA levels of a 92-kD gelatinolytic metalloproteinase, which is not secreted by normal dermal or lung fibroblasts and is immunologically cross-reactive with a type V collagenase expressed by activated macrophages and neutrophils. Expression of this 92-kD metalloproteinase confers upon the fibroblasts the capacity to degrade collagenase- and stromelysin-resistant interstitial elements, such as collagen types IV, V and XI. In contrast to the 92-kD metalloproteinase, a 68-kD gelatinase (type IV collagenase) was expressed by all fibroblast types studied, indicating that its regulation is distinct from that of the 92-kD gelatinase. To identify what cytokines may be important in the induction of the rheumatoid synovial phenotype, including expression of the 92-kD gelatinase, we exposed normal dermal fibroblasts to a number of cytokines including many known or considered likely to be present in rheumatoid synovial fluid and tissue. Although IL-1 beta, tumor necrosis factor-alpha, lymphotoxin, platelet-derived growth factor, and basic fibroblast growth factor were capable of stimulating fibroblasts to secrete collagenase, only tumor necrosis factor-alpha, lymphotoxin, and IL-1 beta were able to induce expression of the 92-kD gelatinase, demonstrating discordant regulation of the two metalloproteinases. Expression of the 68-kD gelatinase was independent of that of the 92-kD gelatinase, as demonstrated at the protein and mRNA levels. Late passage rheumatoid synovial fibroblasts, which no longer constitutively expressed the 92-kD gelatinase, displayed an accentuated response to IL-1 beta when compared to normal dermal fibroblasts. Thus, in addition to IL-1 beta, tumor necrosis factor-alpha or lymphotoxin may contribute to the expression of a specific rheumatoid synovial phenotype in vivo that is associated with progressive matrix destruction.

Human neutrophil gelatinase is a component of specific granules.

Previous investigators have proposed that gelatinase, a metalloproteinase found in neutrophils, is stored in a novel secretory compartment distinct from the two major granule populations, azurophilic and specific. To locate this proteinase in human neutrophils we reacted the cells for peroxidase and then applied monospecific polyclonal antibodies to human neutrophil gelatinase to immunolabel ultrathin frozen sections using an immunogold technique. Gelatinase was localized in a population of peroxidase-negative granules. Double-labeling experiments using antibodies against lactoferrin, a marker for specific granules, and gelatinase demonstrated colocalization of the two antigens in 80% of the specific granules. However, some granules immunostained with only the lactoferrin or gelatinase antibody. Similar techniques were used to examine precursor cells from bone marrow. In myelocytes both gelatinase and lactoferrin were present in large developing specific granules; however, some mature specific granules contained only lactoferrin. Thus, it is possible that lactoferrin synthesis begins earlier than gelatinase synthesis and that overlapping synthesis and segregation occurs during the myelocyte stage. These findings suggest that the main storage compartment of gelatinase is within the peroxidase-negative specific granules.

Expression of a metalloproteinase that degrades native type V collagen and denatured collagens by cultured human alveolar macrophages.

Human pulmonary alveolar macrophages obtained by bronchoalveolar lavage from both normal controls and smokers secreted in vitro a neutral proteinase that degraded denatured collagens. Optimal expression of the proteinase was detected after 3-5 d of culture. The proteinase could not be detected in the media of cultures that had been treated with 0.5 micrograms/ml of cycloheximide. The gelatinase had an Mr of 90,000 and was immunologically cross-reactive with human neutrophil gelatinase. When newly synthesized 35S-methionine-labeled proteins were analyzed, the proteinase appeared to be a major secretion product of alveolar macrophages. Chromatography on gelatin-Sepharose gave a single peak of activity that was predominantly composed of the 90,000-mol-wt proteinase. The proteolytic activity in the gelatin-Sepharose-purified material was inhibited by EDTA and 1,10-phenanthroline, but not by N-ethylmaleimide or phenylmethanesulfonyl fluoride, indicating that the proteinase was a metalloproteinase. The partially purified material was also capable of degrading native type V collagen and this degradation was inhibited in the presence of an antibody to neutrophil gelatinase. The data suggest that human alveolar macrophages in culture elaborate a metalloproteinase that degrades both native type V collagen and denatured collagens.

The collagen substrate specificity of human neutrophil collagenase.

The substrate specificity of human neutrophil collagenase was examined using both monomeric and fibrillar collagens. The neutrophil enzyme cleaved types I, II, and III collagens, but failed to attack types IV or V. Against monomeric collagen substrates at 25 degrees C, the neutrophil enzyme displayed values for the Michaelis constant (Km) of 0.6-1.8 X 10(-6) M, essentially indistinguishable from the substrate affinities that characterize human fibroblast collagenase. Catalytic rates, however, varied considerably; type I collagen was cleaved with a specificity (kappa cat/Km) some 20-fold greater than type III. Type II collagen was degraded with intermediate selectivity, approximately equal to 25% of the type I rate, but 450% that of type III. This specificity contrasted markedly with that of human fibroblast collagenase, which cleaved human type III collagen 15-fold faster than type I and greater than 500-fold more rapidly than type II. Interestingly, the 20-fold selectivity for type I over type III exhibited by neutrophil collagenase against monomeric collagens was largely abolished following the reconstitution of these substrates into insoluble fibrils, falling to a value of just 1.5-fold. The distinctive and opposite preference by the human fibroblast enzyme for monomeric type III collagen over type I (15-fold) was similarly reduced to less than 2-fold upon substrate aggregation. The transition from native soluble collagen monomers into insoluble fibrils appeared to be handled by both the human neutrophil and fibroblast collagenases with similar facility on type I substrates. By comparison, however, the neutrophil enzyme degraded type III collagen fibrils faster than would have been predicted from solution rates, while the fibroblast enzyme cleaved such fibrils much slower than expected from solution values. In exploring this phenomenon further, solvent deuterium isotope effects were measured. The deuterium studies suggest that neutrophil collagenase, acting on type III fibrils (kappa H2O/kappa D2O = 5.0), is less sensitive to factors which govern the availability of water at the relatively hydrophobic site of peptide bond hydrolysis in the collagen molecule than is fibroblast collagenase (kappa H2O/kappa D2O = 15.0).

The immunologic relationship of human neutrophil and skin collagenases.

An understanding of the immunologic relationships between collagenases of various cellular origins is necessary to define the roles of various cell types in the pathologic tissue destruction seen in chronic inflammatory diseases, such as rheumatoid arthritis. We compared the immunologic cross-reactivity of human neutrophil and skin fibroblast collagenases, utilizing polyclonal antisera prepared to purified enzymes. Polyclonal antisera from rabbits immunized with neutrophil collagenase recognized fibroblast collagenase, as well as the neutrophil enzyme, when analyzed by immunoblot techniques. The cross-reactive epitopes constituted a major proportion of the antibody population, as shown by competitive inhibition enzyme-linked immunosorbent assay; 50% of the antibody to neutrophil collagenase was inhibited by skin collagenase. Paradoxically, antisera to fibroblast collagenase failed to recognize the neutrophil enzyme, either by immunoblot techniques or competitive inhibition enzyme-linked immunosorbent assay, an observation which supports the notion that there are unique immunodominant epitopes. The cross-reactivity with skin fibroblast collagenase shown by the neutrophil antibody suggests a conservation of epitopes between collagenases of different cellular origins. The presence of epitopes unique for each enzyme, however, could lead to a feasible approach for investigating the differential contribution of various cell types to collagenolytic activity in inflamed tissues.

Collagen degradation by inflammatory phagocytes.

Inflammatory phagocytes are frequently found in the osteoarthritic joint. Current models of the pathogenesis of osteoarthritis (OA) would indicate that proteolytic modification of the cartilage extracellular matrix is important in the development of irreversible joint destruction. Neutrophils and macrophages contain collagenolytic proteinases with different substrate specificity and which are capable of degrading native collagens which are present in articular cartilage. The biochemical nature of these proteinases is discussed. Inflammatory phagocytes may contribute to the process of joint destruction in OA.

Stimulation of interstitial collagenase in co-cultures of rat hepatocytes and sinusoidal cells.

Although the fibrosis observed during chronic liver injury is the result of a complex process, the striking accumulation of collagen in end stage liver disease has provoked interest in the mechanisms that regulate both collagen production and degradation in the diseased liver. The present studies have examined the cell interactions that may be important in the regulation of collagen degradation. Although minimal amounts of interstitial collagenase activity were noted in cultures of normal hepatocytes and sinusoidal cells, the co-cultures of these cells in the presence of lipopolysaccharide showed a substantial increase in collagenase activity. When the hepatocytes were obtained from rats that had been treated with carbon tetrachloride in vivo, the enhanced activity seen in the co-cultures did not require the addition of lipopolysaccharide. Further characterization of this interaction suggested that the increase in collagenolytic activity was partially due to the elaboration of soluble factors by the hepatocyte, which stimulated collagenase production by the sinusoidal cell population. Elaboration of collagenase activity by the sinusoidal cells was inhibited by cycloheximide, suggesting that protein synthesis was required. The proteolytic activity was abrogated by inhibitors of metalloproteinases but not by serine or thiol proteinase inhibitors. The degradation products of type I collagen were typical of the expected products seen with vertebrate collagenases. Thus, it appears that the increased collagenolytic activity detected in this co-culture system is attributable to the production of interstitial collagenase by the sinusoidal cell population. Such cell-cell interactions may play an important role in the maintenance of normal connective tissue structure of the liver during disease processes.

Secreted forms of human neutrophil collagenase.

Collagenase in human neutrophils is found within intracellular granules which can be stimulated to be secreted with phorbol myristic acetate. This extracellular secreted form of neutrophil collagenase was isolated by immunoaffinity chromatography using a monoclonal antibody previously shown to specifically recognize neutrophil collagenase. The enzyme efficiently bound to this column and was eluted with NaSCN as three major species of 75, 57, and 22 kDa, respectively. These proteins were closely related immunologically since, after radiolabeling and separation by gel filtration, each of the three proteins was precipitated by the monoclonal antibody. Also, the 75- and 57-kDa proteins exhibited collagenase activity after elution from polyacrylamide gels run under nondenaturing conditions. Further, the 57-kDa protein autodegraded into a 22-kDa protein with time. Polyclonal antibody, prepared to the 57-kDa enzyme, also recognized the 75- and 22-kDa proteins using an immunoblot technique. When crude neutrophil supernatants containing latent collagenase were immunoblotted, both the 75- and the 57-kDa enzymes were present. Our immunoaffinity purified active enzymes, although activated during the course of purification, resemble the latent enzymes in crude neutrophil supernatants. The multiple forms of secreted collagenase from degranulated leukocytes may resemble more closely that seen in inflammation.

Establishment of basal cell carcinoma in culture: evidence for a basal cell carcinoma-derived factor(s) which stimulates fibroblasts to proliferate and release collagenase.

The connective tissue adjacent to basal cell carcinomas (BCC) is frequently abnormal and contains increased numbers of fibroblasts and increased extractable collagenase. To determine whether BCC could produce these alterations by releasing mediators that regulated fibroblast function, we established BCC in culture and tested the ability of their culture supernatants to alter fibroblast proliferation and production of collagenase. Using tissue culture plates coated with type IV collagen and containing x-irradiated 3T3 feeder cells, we established epithelial colonies from 47% of the BCC cultured. The BCC-derived colonies differed from normal epidermal cell colonies in their morphology, growth rate, and keratin production. Culture supernatants from 4 out of 5 confluent BCC-derived colonies contained factors that stimulated fibroblasts to proliferate and release collagenase. These findings show that BCC-derived epidermal cell colonies release mediators which alter fibroblast functions and suggest that some of the connective tissue changes associated with BCC in vivo are the result of BCC-fibroblast interactions.

The role of neutrophils in the development of cadmium chloride-induced emphysema in lathyrogen-fed hamsters.

This study was designed to evaluate the role of neutrophils (PMNs) in the pathogenesis of emphysema. After administration of CdCl2 intratracheally to hamsters fed a lathyrogen, beta-amino propionitrile fumarate (BAPN), the classic lesions of emphysema developed. Administration of specific antineutrophil serum markedly reduced the PMN influx into the lungs which followed CdCl2 exposure and produced a substantial decrease in elastase and collagenase content of bronchoalveolar lavage fluid (BAL). The degree of emphysema in PMN-depleted hamsters given BAPN and CdCl2 was not different from that in hamsters given BAPN and CdCl2. Furthermore, the degree of acute lung injury following CdCl2, as determined by hydroxyproline content of BAL and by lung lipid peroxidation, was the same in PMN-depleted and non-depleted groups. Thus, PMNs were not necessary for the induction of emphysema in BAPN-CdCl2-treated hamsters. The results suggest that PMNs may not be obligate mediators of emphysema.

Biochemical and immunological characterization of the secreted forms of human neutrophil gelatinase.

Human neutrophils contain a neutral metalloproteinase which degrades denatured collagens and potentiates the action of interstitial collagenase. This gelatinase is rapidly secreted from neutrophils stimulated with phorbol myristate acetate. The secreted enzyme has been purified by a combination of chromatography on DEAE-cellulose and gelatin-Sepharose. The purified enzyme was latent and had a specific activity of 24,000 units. Estimated molecular weight obtained by gel filtration was 150,000-180,000. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the purified enzyme showed three bands with relative molecular weights of 225,000, 130,000, and 92,000. Electrophoresis in the presence of a reducing agent revealed a single band of Mr = 92,000. All the proteins seen on the unreduced gel were found to contain proteolytic activity against gelatin and native type V collagen. Polyclonal antibodies were prepared against the Mr = 130,000 and 92,000 proteins. When analyzed by immunoblotting, both antibodies recognized all three proteins. Furthermore, the identical three proteins were identified by the antibodies when crude culture medium was immunoblotted. The purified enzyme was inhibited by EDTA and 1,10-phenanthroline but not by serine or thiol proteinase inhibitors, suggesting that the enzyme is a metalloendoproteinase. The enzyme had little or no activity against common protein substrates such as bovine serum albumin or casein. Native type I collagen was not cleaved under conditions where native type V collagen was extensively degraded.

Secretion of collagenolytic enzymes by human polymorphonuclear leukocytes.

The polymorphonuclear leukocyte contains three proteinases capable of degrading the collagenous components of the connective tissue matrix. These proteinases, gelatinase, interstitial collagenase and elastase, were found to be rapidly secreted by the neutrophil in response to soluble stimuli with maximal accumulation of the gelatinase and interstitial collagenase occurring during a 20 minute incubation. When neutrophils were stimulated with the chemotactic peptide, formyl-met-leu-phe, gelatinase was the predominant collagenolytic enzyme detected. Stimulation of neutrophils with increasing doses of the Ca++ ionophore A23187 lead to a sequential release of collagenolytic proteinases. Gelatinase release was detected at Ca++ ionophore concentrations of .05-.1 microM, while significant release of interstitial collagenase required 0.5-1 microM A23187. Elastolytic activity was detected only at high concentrations of A23187 (5-10 microM). No release of lactic acid dehydrogenase was detected indicating that the enzyme release was not due to cell death. These studies suggest that the neutrophil may modulate its collagenolytic potential by selective release of collagenolytic proteinases.