Osteoarthritic lesions: involvement of three different collagenases.

OBJECTIVE: To assess the presence of fibroblast collagenase (MMP-1), neutrophil collagenase (MMP-8), and collagenase 3 (MMP-13) in osteoarthritic (OA) cartilage, with particular emphasis on areas of macroscopic cartilage erosion. METHODS: Messenger RNA (mRNA) levels were assessed by reverse transcriptase-polymerase chain reaction (RT-PCR), in situ hybridization, and Northern blot analysis. RESULTS: MMP-1 and MMP-13 were expressed at higher levels by OA chondrocytes than by normal chondrocytes. In addition, mRNA for MMP-8 was present in OA cartilage but not normal cartilage by PCR and Northern blot analyses. Chondrocytes from areas surrounding the OA lesion expressed greater quantities of MMP-1 and MMP-13 compared with normal chondrocytes, suggesting local modulation by mechanical and inflammatory factors. Tumor necrosis factor alpha stimulated the expression of all 3 collagenases. Retinoic acid, an agent which induces autodigestion of cartilage in vitro, stimulated only the expression of MMP-13. CONCLUSION: These findings suggest a key role of MMP-13 and MMP-8, as well as MMP-1 in osteoarthritis.

Role of the conserved histidine and aspartic acid residues in activity and stabilization of human gelatinase B: an example of matrix metalloproteinases.

Gelatinase B (MMP-9), a member of the matrix metalloproteinase family, is a zinc- and calcium-dependent endopeptidase that is known to play a role in tumor cell invasion and in destruction of cartilage in arthritis. It contains a conserved sequence. 400His-(X)3-His-(X)28-Asp-Asp-(X)2-436Gly, the function of which is under investigation. The conserved Asp-432 and Asp-433 residues were individually replaced with Gly; these substitutions reduced the gelatinolytic activity of the enzyme to 23% and 0%, respectively. Replacing Asp-433 with Glu, however, decreased the gelatinolytic activity of the enzyme by 93% and proteolytic activity of the enzyme for the Mca-Pro-Leu-Gly-Leu-Dpa-Ala-Arg-NH2 substrate by 79%. The wild-type and D432G and D433E, mutant enzymes had similar Km values for the synthetic substrate and similar Ki values for the competitive inhibitor, GM6001. The kcat/Km values for D432G and D433E mutant enzymes, however, were reduced by a factor of approximately 4 and their KaCa values were increased by four- and sixfold, respectively. The significance of His-400 in the activity of the enzyme was assessed by replacing this residue with Ala and Phe. Both H400A and H400F mutants were inactive toward gelatin substrate. These data demonstrate that Asp-432, Asp-433, and His-400 residues are important for the activity of gelatinase B. His-400 may act as a zinc-binding ligand similar to the His-197 in interstitial collagenase (MMP-7) and Asp-432 and Asp-433 residues are probably involved in stabilization of the active site of the enzyme. The His-400 and Asp-433 residues are conserved in all members of the MMP family. Therefore, our results are relevant to this group as a whole.

Characteristics of 92 kDa type IV collagenase/gelatinase produced by granulocytic leukemia cells: structure, expression of cDNA in E. coli and enzymic properties.

Human neutrophils can be triggered to release the collagenolytic metalloenzymes, interstitial collagenase and 92 kDa type IV collagenase/gelatinase. We have isolated and sequenced a 2.3 kb cDNA from a chronic granulocytic leukemia cDNA library that encodes for human neutrophil type IV collagenase. With the exception of one amino-acid substitution at position 280 (Arg-->Gln), the deduced amino-acid sequences of neutrophil gelatinase are identical to the amino-acid sequences of the enzyme isolated from fibrosarcoma cells. Expression of the cDNA in E. coli yielded a 72 kDa protein having a gelatinolytic activity on zymogram gel. The recombinant enzyme was activated with APMA and trypsin. The activation was accompanied by a reduction in molecular weight of approximately 10 kDa; such a reduction is characteristic of matrix metalloproteinases. The recombinant gelatinase cleaved native type V and XI collagens. Native type I collagen was not a substrate for the enzyme. These data suggest that native and recombinant 92 kDa type IV collagenase produced in E. coli have similar biochemical properties. The successful expression of the collagenase in a prokaryotic system will greatly facilitate the structure-function characterization of the enzyme and allow a more precise analysis of its physiological and pathological roles.

Susceptibility of type I collagen containing mutated alpha 1(1) chains to cleavage by human neutrophil collagenase.

Two members of the matrix metalloproteinase family which can cleave native types I, II and III triple helical collagens are collagenases from fibroblasts and neutrophils. These enzymes are the products of different genes which share structural motifs but are only 57% identical. In this study, we determined the site of cleavage in the alpha 1(I) chains and showed that the neutrophil collagenase acted at the same site as the fibroblast collagenase. We also used collagens as substrates which were generated by site-directed mutagenesis of the murine Col1a1 gene and found that the pattern of susceptibility to cleavage by purified neutrophil collagenase was indistinguishable from that previously described for the fibroblast collagenase. Collagens containing substitutions of Pro for Ile-776 (P1) were not cleaved; whereas those containing substitutions of Met for Ile-776 were cleaved. Type I collagen which contained alpha 1(I) chains in which there were double substitutions of Pro for Gln-774 (P2) and Ala-777 (P2') were also not cleaved. These type I collagens contained wild type alpha 2(I) chains as well as mutant alpha 1(I) chains in the mixed helical trimers; the alpha 2(I) chain in the trimers containing the resistant alpha 1(I) chains were also not cleaved by the neutrophil collagenase.

Structure-function relationship of human neutrophil collagenase: identification of regions responsible for substrate specificity and general proteinase activity.

The family of matrix metalloproteinases is a family of closely related enzymes that play an important role in physiological and pathological processes of matrix degradation. The most distinctive characteristic of interstitial collagenases (fibroblast and neutrophil collagenases) is their ability to cleave interstitial collagens at a single peptide bond; however, the precise region of the enzyme responsible for this substrate specificity remains to be defined. To address this question, we generated truncated mutants of neutrophil collagenase with various deletions in the COOH-terminal domain and chimeric molecules between neutrophil collagenase and stromelysin and assayed the expressed enzymes against type I collagen and the general substrate, casein. Our data suggest that substrate specificity for interstitial collagen is determined by a 16-aa sequence in the COOH-terminal domain of neutrophil collagenase and is influenced by the integrity of a disulfide-defined loop at the COOH terminus for maximal activity. It was found that a relatively large region of 62-aa residues influenced the relative efficiency of collagenolytic activity. In addition to the region that conferred this specificity, a site at the COOH side of the presumptive zinc-binding locus was found to be necessary for general catalytic activity. Mutation of a critical aspartic residue at position 253 within this area resulted in complete loss of proteolytic activity, suggesting that Asp-253 might function as one of the ligands for divalent cations, which are essential for enzymatic activity.

Characterization of type V collagenase (gelatinase) in synovial fluid of patients with inflammatory arthritis.

Gelatin degrading matrix metalloproteinases in synovial fluid from 21 patients with inflammatory arthritis were shown to consist of two distinct gene products, 92 and 70 kDa gelatinases. The gelatinolytic activity of 92 kDa enzyme, which is released from stimulated neutrophils, was positively correlated to neutrophil count in the fluid. By contrast, 70 kDa molecule did not correlate with neutrophil cell count. Purification of these enzymes revealed they could degrade type XI collagen, a cartilage component resistant to interstitial collagenase. The elevated levels of 92 kDa gelatinase in rheumatoid arthritis samples compared to osteoarthritis suggest a role of this enzyme in cartilage destruction.

Differentiation of PC12 cells with nerve growth factor is associated with induction of transin synthesis and release.

We have identified and characterized a calcium-dependent metalloproteinase which is induced in rat pheochromocytoma cells (PC12 cells) during differentiation with nerve growth factor (NGF). Assays of proteolytic activity in media from differentiated PC12 cell cultures revealed a NGF-dependent increase in the activity of a proteinase which has a molecular weight of 62 kDa. Studies using serine, thiol, and metalloproteinase inhibitors demonstrated that the secreted enzyme is a metalloproteinase. Treatment of culture supernatants with aminophenylmercuric acid (APMA), a known activator of metalloproteinases, resulted in a decrease in the molecular weight of the proteinase. Western blot analysis of culture media from NGF-treated PC12 cells using an antibody directed against a synthetic peptide of rat transin identified this metalloproteinase as transin. Treatment of PC12 cells with acidic and basic fibroblast growth factor (FGF) resulted in distinct morphological changes as well as transin release. Incubation with epidermal growth factor (EGF) did not induce transin release. Dexamethasone inhibited the induction of transin release by NGF. 35S-methionine labeling and immunoprecipitation of newly synthesized proteins from culture supernatants confirmed that NGF induced the synthesis of this enzyme 8 hr after NGF treatment. The NGF-dependent induction of transin, a calcium-dependent metalloproteinase which degrades type IV collagen, laminin, and fibronectin suggests that transin may function to degrade the surrounding extracellular matrix during the invasive process of axonal elongation in neuronal development thereby allowing the movement of growth cones and axons toward specific targets.

Human neutrophil collagenase. A distinct gene product with homology to other matrix metalloproteinases.

We have identified and sequenced a cDNA encoding human neutrophil collagenase from a lambda gt11 cDNA library constructed from mRNA extracted from the peripheral leukocytes of a patient with chronic granulocytic leukemia. The library was screened with an oligonucleotide probe constructed from the putative zinc-binding region of fibroblast collagenase. Eleven positive clones were identified, of which the one bearing the largest insert (2.2 kilobases (kb)) was sequenced. From the nucleotide sequence of the 2.2-kb cDNA clone we have deduced a 467-amino acid sequence representing the entire coding sequence of the enzyme. The deduced protein was confirmed as neutrophil collagenase by conformity with the amino-terminal sequence analyses of three tryptic peptides of purified neutrophil collagenase. The cDNA clone hybridizes to a 3.3-kb mRNA present in RNA extracted from human bone marrow but did not hybridize with RNA isolated from U937 cells induced to differentiate with phorbol myristate acetate. Neutrophil collagenase was found to possess 57% identity with the deduced protein sequence for fibroblast collagenase with 72% chemical similarity. Certain regions of the molecule, including the putative zinc-binding region, are highly conserved. When compared with the published sequence for fibroblast collagenase, neutrophil collagenase contains four additional sites for glycosylation. Medium from COS-7 cells transfected with a pcDNA1 eucaryotic expression vector containing cDNA for neutrophil collagenase degraded type I collagen into the three-quarter, one-quarter fragments characteristic of mammalian interstitial collagenase activity. Thus, definitive evidence based on the cDNA sequence confirms the neutrophil collagenase is a distinct gene product and a member of the family of matrix metalloproteinases.

Secretion and glycosylation of rabbit macrophage type V collagenase.

Cultures of freshly isolated rabbit alveolar macrophages were used to study the synthesis, secretion, and glycosylation of type V collagenase. Cells were pulse-labeled with [35S-]methionine for 15 minutes followed by a chase with cold methionine for various time periods. Type V collagenase was identified in the culture supernatants and cell lysates by immunoprecipitation with a specific antiserum. Within 10 minutes of chase, an 82-kDa protein was found in the cell lysates. This protein was subsequently processed to a 92-kDa protein without identifiable intermediate forms. By 60 minutes of chase, intracellular radioactivity was no longer detectable. The larger protein could be detected within 20 minutes in the culture supernatants and accumulated in the medium for 60 minutes of chase time. Only the 92-kDa form was seen in the supernatants and the proteinase was secreted without intracellular storage or membrane association. Treatment of the 92-kDa proteinase with an enzyme which specifically removes N-linked carbohydrates resulted in an apparent reduction in molecular mass of approximately 10 kDa. Deglycosylation of the proteinase did not result in an apparent loss of activity. Thus, it was concluded that macrophage type V collagenase is synthesized as an 82-kDa polypeptide which is glycosylated by N-linkage and secreted.

Biochemical mechanisms of articular destruction.

The destruction of articular structures in inflammatory arthritis is a complex process. Both proteolytic degradation of the individual structural proteins that make up the tissues of the joint as well as nonproteolytic processes, such as bone demineralization are involved. Proteinases that can degrade collagen and proteoglycans are present in the various cells that comprise the rheumatoid lesion. Neutrophils contain collagenolytic metalloproteinases (collagenase and gelatinase) as well as potent serine proteinases (elastase and cathepsin G). Synovial cells and chondrocytes secrete metalloproteinases, which are also capable of degrading the extracellular matrix. Evidence would support the concept that the regulatory and counter-regulatory factors that govern the activity of these enzymes are abnormal in inflammatory arthritis, resulting in articular destruction.

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.

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.

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.

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.