Collagenase of human skin basal cell epithelioma.

Collagenase of human basal cell epithelioma was purified by sequential ammonium sulfate precipitation, Sephadex gel filtration and affinity chromatography on collagen-polyacrylamide gel. The collagenase, when partially purified, was found to have an approximate molecular weight of 50,000. The purified enzyme contained no caseinolytic activity. On polyacrylamide gel electrophoresis, the purified enzyme gave a single protein band. The purified collagenase cleaved native acid-soluble guinea pig skin collagen at 37 degrees C with a pH optimum of 8. The enzyme was inhibited by EDTA, cysteine, and human serum but not by soybean trypsin inhibitor. Heparin did not stimulate the enzyme activity. Purified collagenase reduced the specific viscosity of native acid-soluble guinea pig skin collagen to 50 per cent of its original value at 27 degrees C. Polyacrylamide gel disc electrophoresis of the reaction products showed bands corresponding to alphaA, betaA, and alphaB fragments. Electron microscopic examination of SLS aggregates of the reaction products showed that the cleavage site by the enzyme was at a point 75 per cent from the "A" end (TCA75) and 25 per cent from the "B" end (TCB25) of the collagen molecule.     

Proteinases in human polymorphonuclear leukocytes. Purification and characterization of an enzyme which cleaves denatured collagen and a synthetic peptide with a Gly-Ile sequence

Polymorphonuclear leukocytes have been shown to contain proteolytic enzymes which are capable of degrading connective tissue proteins such as native collagen. In this study, proteolytic enzymes were extracted from human polymorphonuclear leukocytes and a neutral proteinase was extensively purified and characterized. The activity of this enzyme was monitored by degradation of denatured [ 3H ]proline-labeled type I collagen or by cleavage of a synthetic dinitrophenylated peptide with a Gly-Ile sequence. The enzyme was readily separated from leukocyte collagenase by concanavalin-A--Sepharose affinity chromatography and further purified by QAE-Sephadex ion-exchange chromatography and gel filtration on Sephacryl S-200. The purified enzyme had a molecular weight of approximately 105000, its pH optimum was about 7.8, and it was inhibited by Na2EDTA and dithiothreitol, but not by fetal calf serum. The enzyme degraded genetically distinct type I, II, III, IV and V collagens, when in a non-helical form, but not when in native triple-helical conformation. Dansyl-monitored end-group analyses, combined with digestion by carboxypeptidase A, indicated that the enzyme cleaved denaturated type I collagen at Gly-Xaa sequences, in which Xaa can be leucine, isoleucine, valine, phenylalanine, lysine, or methionine. Thus, the purified enzyme referred to here as Gly-Xaa proteinase, is a neutral proteinase, which may be of importance in inflammatory disease processes by degrading further collagen peptides which have been rendered non-helical as a result of collagenase cleavage.     

The characterization of type I and type III collagens from human peripheral nerve.

The normal chemical features of peripheral nerve collagens were determined on postmortem, histologically normal adult human femoral nerve. 1. Genetically distinct type I, [alpha1(I)2]alpha2, and type III, [alpha1(III)]3, were isolated by differential salt precipitation and the component subunit chains, alphal(I), alpha2 and alphal(III) were obtained by ion-exchange chromatography and gel filtration. 2. The molecular weight of alphal(I) and alpha2 of type I collagen was 95 000 and that for type III was 280 000. Reduction of type III with dithiothreitol yielded expected alpha1(III) chains of 95 000 molecular weight. 3. The amino acid composition of the three collagen chains, alpha1(I), alpha2, and alpha1(III), was the same as previously reported values for the corresponding chains from human skin except for slightly elevated hydroxylysine content. 4. Peripheral nerve collagen was found to contain 81% type I collagen and 19% type III. These results indicate that peripheral nerve collagen characteristics closely simulate that of human skin and differ from that of human aorta and other parenchymal organs. These data will permit a chemical analysis for possible abnormalities of peripheral nerve collagen in various neurogenic disorders.     

Degradation of monomeric and fibrillar type III collagens by human skin collagenase. Kinetic constants using different animal substrates

Human skin collagenase activity was examined against type III collagens, in both soluble and fibrillar form, from different animal species. In either form, human, dog, and cat type III were degraded 10- to 30-fold faster than was that from guinea pig and nearly 100-fold more readily than chick type III. These differences in susceptibility were mirrored by essentially identical differences in the rate of trypsin cleavage of the same substrates. Human, dog, and cat type III were cleaved most rapidly by trypsin, guinea pig III more slowly, and chick III was completely resistant to the serine protease. Arrhenius plots, relating enzyme activity to temperature, revealed differences in the various type III substrates consistent with their collagenase and trypsin susceptibilities. Human, dog, and cat type III collagens yielded nonlinear plots, with accompanying activation energies which decreased at temperatures above 26 degrees C; guinea pig type III displayed a plot which deviated only slightly from linearity while the plot for chick type III was completely linear. These data strongly suggest that type III collagens display substantial variability in the stability of the helix at or near the collagenase cleavage site. The susceptibility of these type III substrates as reconstituted fibrils was also examined. The relative rates of degradation of these substrates by collagenase, and by trypsin, were the same as those observed in solution. The absolute rates of degradation of collagen in fibrillar form, however, were massively lower than predicted by extrapolation from solution values. This reduction in rate is even greater for type III than for type I collagens. Thus, whereas in solution type III substrates are cleaved much faster than type I collagens, in fibrillar form these differences are less than 2-fold. These data, together with values for activation energies and deuterium isotope effects on type III fibrillar substrates, reinforce the concept that helical integrity near the collagenase cleavage site is a major specifier of the rate of collagenase activity. Furthermore, the data suggest that the exclusion of water accompanying the tight packing of monomers into fibrils presents a major energy barrier to collagenase activity, which is particularly large for type III collagen.     

Quantitation of types I and III collagens in human tissue samples and cell culture by cyanogen bromide peptide analysis

A procedure for the quantitation of types I and III collagens by cyanogen bromide peptide analysis was developed with the aim of eliminating certain problems associated with this method. Ion-exchange chromatography reduced high background levels on gel scans used to quantitate the peptides; reduction with beta-mercaptoethanol substantially increased the efficiency of the cyanogen bromide cleavage; use of a concave gradient in acrylamide from 8 to 20% improved the resolution of cyanogen bromide peptides separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis; and a normalization procedure eliminated variations due to differences in the amount of material loaded on the gel system. This method of quantitation was applied to human aorta samples and to collagen secreted by human skin fibroblasts. Metachromasy of type I and type III collagen cyanogen bromide peptides stained with Coomassie blue R-250 was established and this was used as an index of the purity of the cyanogen bromide peptide preparations. Type I and III collagens were prepared from human placental tissue, and these purified collagens were used to construct calibration curves to determine the relationship between the quantity of diagnostic cyanogen bromide peptides present and the composition of the sample in terms of types I and III collagens.     

Covalent structure of collagen: amino acid sequence of alpha 1 (III)-CB5 from type III collagen of human liver

Type III collagen was prepared from human liver by limited pepsin digestion, differential salt precipitation, and carboxymethylcellulose chromatography. Ten distinct peptides were obtained by cyanogen bromide digestion. The peptide alpha 1 (III)-CB5 was further purified by carboxymethylcellulose chromatography, and its amino acid sequence was determined. Automatic Edman degradation of intact alpha 1 (III)-CB5, tryptic and thermolytic peptides, and hydroxylamine-derived fragments was used to establish the total sequence. The mammalian collagenase site contained in the alpha 1 (III)-CB5 sequence was ascertained by digestion of native type III collagen with purified rheumatoid synovial collagenase. Collagenase cleavage occurred at a single Gly--Ile bond, one triplet before the corresponding specific cleavage site of type I collagen. The present work brings the known sequence of human liver type III collagen to include alpha 1 (III)-CB3-7-6-1-8-10-2-4-5. These correspond to the homologous region of alpha 1 (I)-CB0-1-2-4-5-8-3-7 residues 11--804.     

Cleavage of native type III collagen in the collagenase susceptible region by thermolysin.

Viscometric assays were used to demonstrate the activity of thermolysin (EC 3.4.24.4) on native type III collagen in solution. Analysis of the reaction products by sodium dodecyl sulphate-polyacrylamide gel electrophoresis and electron microscopic visualisation of segment long spacing aggregates demonstrated localised cleavage of the collagen in the collagenase susceptible region.     

Collagen synthesis by bovine aortic endothelial cells in culture.

Endothelial cells isolated from bovine aorta synthesize and secrete type III procollagen in culture. The procollagen, which represents the major collagenous protein in culture medium, was specifically precipitated by antibodies to bovine type III procollagen and was purified by diethyl-aminoethylcellulose chromatography. Unequivocal identification of the pepsin-treated collagen was made by direct comparison with type III collagen isolated by pepsin digestion of bovine skin, utilizing peptide cleavage patterns generated by vertebrate collagenase, CNBr, and mast cell protease. The type III collagen was hydroxylated to a high degree, having a hydroxyproline/proline ratio of 1.5:1.0. Pulse-chase studies indicated that the procollagen was not processed to procollagen intermediates or to collagen. Pepsin treatment of cell layers, followed by salt fractionation at acidic and neutral pH, produced several components which were sensitive to bacterial collagenase and which comigrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with alpha A, alpha B, and type IV collagen chains purified from human placenta by similar techniques. Bovine aortic endothelial cells also secreted fibronectin and a bacterial collagenase-insensitive glycoprotein which, after reduction, had a molecular weight of 135,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (using procollagen molecular weight standards) and which was not precipitable by antibodies to cold-insoluble globulin or to alpha 2-macroglobulin. Collagen biosynthesis by these cells provides an interesting model system for studying the polarity of protein secretion and the attachment of cells to an extracellular matrix. The presence of type III collagen in the subendothelium and the specific interaction of this protein with fibronectin and platelets suggest the involvement of this collagen in thrombus formation following endothelial cell injury.     

Studies on the activation energy and deuterium isotope effect of human skin collagenase on homologous collagen substrates

The activation energy (EA) and solvent-deuterium kinetic isotope effect (kH/kD) of human skin fibroblast collagenase were studied on the homologous human type I, II, and III collagens in both native and denatured states. Values for EA on human type I and II collagens in solution were 47,000 and 61,000 cal, respectively. The Arrhenius plot for type III collagen, unlike that for the other types, was characterized by a break in EA at approximately 26 degrees C. At temperatures below this point, EA was 42,500 cal; at higher temperatures, EA fell to 29,500 cal. This latter value, intermediate between type I collagen monomers and denatured random gelatin alpha chains, appears to result from a further opening in the already loosened helix of the type III collagen molecule in the region of the 3/4:1/4 collagenase cleavage site. The EA of trypsin on native human type III collagen was also measured and found to be 70,000 cal. This high value calls into question the role of serine proteases in the physiologic degradation of this substrate; a much higher energy expenditure was required for trypsin to cleave type III collagen than for the fibroblast collagenase. Reaction velocity on human collagen types I-III in solution was slowed 15-35% (kH/kD = 1.2-1.5) by the substitution of deuterium for hydrogen in the solvent buffer. This value was far lower than that observed following the aggregation of solution monomers into insoluble fibrils (kH/kD = 9). Denaturation of triple helical monomers into random gelatin alpha chains eliminated any slowing by deuterium, and kH/kD was 1.0 in all cases. Since the same peptide bond hydrolysis accompanies the cleavage of all these forms of the collagen substrate, it would appear that the role of water at the rate-limiting step of collagen degradation may not reside in the hydrolysis of a peptide bond per se, but rather may reflect the difficulty in transporting water molecules to the site of such catalysis, especially following fibril aggregation.     

Comparison of extracellular matrix-degrading activities between 64-kDa and 90-kDa gelatinases purified in inhibitor-free forms from human schwannoma cells.

Two kinds of gelatinases (or type IV collagenases), 90-kDa and 64-kDa gelatinases, were purified in a tissue inhibitor of metalloproteinases (TIMP)- or TIMP-2-free form from the serum-free conditioned medium of human schwannoma YST-3 cells, and their activities on extracellular matrix proteins were compared. Sequential chromatographies on a gelatin-Sepharose column, an LCA-agarose column, and a gel filtration column in the presence of 5 M urea yielded 600 micrograms of the 64-kDa enzyme and 45 micrograms of the 90-kDa enzyme from 2.8 liters of the conditioned medium. The purified enzymes showed high gelatinolytic activities without activation by p-aminophenyl mercuric acetate (APMA), indicating that 5 M urea used in the final chromatography not only dissociated the inhibitors from the progelatinases but also activated the proenzymes. The inhibitor-free gelatinases showed a much higher activity than the APMA-activated inhibitor-bound enzymes. The specific activity of the 90-kDa enzyme was nearly 25 times higher than that of the 64-kDa enzyme. The 90-kDa gelatinase hydrolyzed type I collagen as well as native and pepsin-treated type IV collagens at 30 degrees C, while at 37 degrees C it potently hydrolyzed types I, III, and IV collagens but not fibronectin or laminin. The 64-kDa gelatinase showed a similar substrate specificity to that of the 90-kDa enzyme, except that it did not hydrolyze type I collagen and native type IV collagen at 30 degrees C.     

Fibroblast behavior on gels of type I, III, and IV human placental collagens

Various collagens were extracted and purified from human placenta after partial pepsin digestion. We prepared type III + I (57:43), enriched type I, type III, and type IV collagens on an industrial level, and studied their biological properties with MRC5 fibroblast cells. Using the process of contraction of a hydrated collagen lattice described by Bell, we found tha the contraction rate was dependent on collagen type composition. The contraction was faster and more pronounced with pepsinized type I collagen than with pepsinized type III + I (57:43) collagen; the lowest rate was obtained with the pepsinized type III collagen. Using a new technique of collagen cross-linking, a gel was made with type IV collagen. This cross-linking procedure, based on partial oxidation of sugar residues and hydroxylysine by periodic acid, followed by neutralization, resulted in an increased number of natural cross-link bridges between oxidized and nonoxidized collagen molecules, without internal toxic residues. The fibroblasts were unable to contract type IV/IVox collagen gels. The type IV/IVox collagen gel was transparent and its amorphous ultrastructure lacked any visible striated fibrils. Fibroblast cells exhibited atypical behavior in these type IV/IVox collagen gels as evidenced by optical and electron microscopy. The penetration of fibroblasts could be measured. Fibroblasts penetrated faster in type IV/IVox collagen gels than in untreated type III + I collagen gels. The lowest rate of penetration was obtained with cross-linked type III + I gels. Fibroblast proliferation was similar on untreated or cross-linked type III + I collagen gels and slightly increased on type IV/IVox collagen gels, suggesting that this cross-linking procedure was not toxic.     

Cleavage of type VII collagen by interstitial collagenase and type IV collagenase (gelatinase) derived from human skin

Type VII collagen is the major structural protein of anchoring fibrils, which are believed to be critical for epidermal-dermal adhesion in the basement membrane zone of the skin. To elucidate possible mechanisms for the turnover of this protein, we examined the capacities of two proteases, human skin collagenase, which degrades interstitial collagens, and a protease with gelatinolytic and type IV collagenase activities, to cleave type VII collagen. At temperatures below the denaturation temperature, pepsin cleaves type VII collagen into products of approximately 95 and approximately 75 kDa. Human skin collagenase cleaved type VII collagen into two stable fragments of approximately 83 and approximately 80 kDa, and the type IV collagenase (gelatinase) produced a broad band of approximately 80 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Cleavage of type VII collagen was linear with time and enzyme concentration for both enzymes. Although the Km values were similar for both enzymes, the catalytic rate of cleavage by type IV collagenase is much faster than by interstitial collagenase, and shows a greater rate of increase with increasing temperature. Sequence analysis of the cleavage products from both enzymes showed typical collagenous sequences, indicating a relaxation in the helical part of the type VII collagen molecule at physiological temperature which makes it susceptible to gelatinolytic degradation. Interstitial collagenase from both normal skin cells and cells from patients with recessive dystrophic epidermolysis bullosa, a severe hereditary blistering disease in which both an anchoring fibril defect and excessive production of collagenase can be observed, produced identical cleavage products from type VII collagen. These data suggest a pathophysiological link between increased enzyme levels and the observed decrease or absence of anchoring fibrils.     

Degradation of native type IV procollagen by human neutrophil elastase. Implications for leukocyte-mediated degradation of basement membranes

Leukocyte-derived proteases may contribute to the destruction of basement membranes during inflammation. We have, therefore, examined the degradation of human type IV procollagen (PC) by purified human neutrophil elastase (HLE). Native [14C]proline-labeled type IV PC was isolated from cultures of human HT-1080 cells and incubated with HLE for various times at 25 or 37 degrees C. Cleavage products were resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and identified by CNBr peptide mapping. Incubation of type IV PC with HLE (less than 1:10 HLE:type IV weight ratio) resulted in cleavage of the pro alpha 1 (IV) and pro alpha 2 chains (Mr 180,000 and 175,000) to discrete components of Mr greater than 140,000. Peptide mapping indicated that the carboxy-terminal collagenase-resistant domains of both chains were rapidly and preferentially degraded. Longer incubations or incubations at higher enzyme:substrate ratios resulted in extensive and asymmetric internal cleavage with the generation of fragments similar in size distribution to the major pepsin-resistant fragments of type IV collagen. Our findings indicate that soluble, native human type IV PC is a substrate for HLE and is preferentially cleaved within the globular carboxy-terminal domains of the pro alpha 1 and pro alpha 2 chains. We suggest that even limited cleavage of type IV PC by HLE may disrupt intermolecular carboxy-terminal interactions believed to be important for basement membrane assembly and for maintaining basement membrane structure in vivo.     

Partial purification and characterization of latent human leukocyte collagenase

Latent and active collagenase were extracted from human polymorphonuclear leukocytes. Separation of the two forms of the enzyme was performed by gel filtration on Sepharose 6 B. The latent form of the enzyme was detected from chromatographic fractions after a brief treatment with trypsin or exposure of the fractions to the sulfhydryl reagent phenylmercuric chloride. Latent enzyme eluted before active enzyme from the column, indicating a higher apparent molecular weight. Partially purified latent enzyme exhibited an apparent molecular size of 70-75 kDa as estimated by gel filtration. A value of 50-55 kDa was obtained for active enzyme. Without activation the latent enzyme did not degrade soluble collagen substrate. This was demonstrated by a quantitative viscometric assay and also by sodium dodecyl sulfate polyacrylamide gel electrophoresis, when no typical cleavage products of collagen could be seen. Latent enzyme could not be obtained unless serine protease inhibitors were present during the extraction and purification procedures. The effects of the activators trypsin, phenylmercuric chloride, phenylmethyl sulfonyltrypsin, and N-ethylmaleimide on the latent human polymorphonuclear leukocyte collagenase were studied. Contrary to the suggestion that inactive proteases activate latent human polymorphonuclear leukocyte collagenase, the inactive phenylmethyl sulfonyl-trypsin could not activate latent collagenase.     

Degradation of intact basement membranes by human and murine tumor enzymes

Homogenates from malignant tumors, obtained from surgery specimens or from transplants of Walker 256 carcinosarcoma in rats, contained an enzyme activity capable of degrading intact 3H-acetylated basement membranes from bovine lens. The enzyme activity from murine tumor was purified about 7500-fold by (NH4)2SO4 fractionation, ion exchange and gel chromatography. The apparent molecular weight of the purified enzyme was approximately 50,000. The rate of degradation of 3H-labelled basement membrane by the murine tumor enzyme was reduced by addition of excess type IV collagen, but not of excess type I, type III or type V collagen. These results suggested specificity of this enzyme for type IV collagen. Inhibitors of serine proteinases, thiol proteinases and soybean trypsin inhibitor were without effect on the enzyme activity. Chelators such as 1,10-phenanthroline or EDTA reduced the activity to control levels, indicating that the enzyme activity was due to a metalloproteinase. Chromatographic and electrophoretic separation of the enzymatic products from 3H-labelled basement membrane and type IV collagen indicated that the enzyme activity was due to a type IV collagenase. The use of basement membrane in the native physiological state as a substrate for the study of basement membrane-degrading activity by homogenates of solid malignant tumors offers an in vitro model for the investigation of the metastatic potential of these tumors.     

Characterization of a novel collagen chain in human placenta and its relation to AB collagen.

A novel collagen chain, termed alpha C, has been isolated from human placenta by limited pepsin digestion. The collagen containing the alpha C chain copurifies with placental AB collagen during selective salt precipitation but is virtually absent from fetal birth membranes, which contain relatively larger amounts of AB. Both native AB and alpha C-containing collagens are resistant to human skin collagenase under conditions that support cleavage of type I by greater than 90%. The alpha C chain was separated from alpha B by phosphocellulose chromatography and subsequently from alpha P by chromatography on CM-cellulose. Its amino acid composition is distinct from alpha A and alha B although all three chains posses compositional features in common; the carbohydrate content of the alpha C chain was intermediate between those of alpha A and alpha B. Analysis by NaDodSO4-polyacrylamide gel electrophoresis of peptides produced by CNBr cleavage and by limited digestion with the enzyme mast cell protease indicated different and unique products for the alpha A, alpha B, and alpha C chains. The data support the existence of another collagen chain which is related to the alpha A and alpha B chains but which is structurally unique. The proteins containing these chains may in turn comprise a subfamily of collagen isotypes which represents a divergence from and/or specialization of the type IV basement membrane collagens.     

Collagen composition of normal and myxomatous human mitral heart valves.

The collagens were studied in 13 normal and 19 myxomatous human mitral valves. The collagens of the valve were completely solubilized by using a method consisting of guanidinium chloride extraction, limited pepsin digestions and CNBr cleavage of the residue. The normal valves contained 74% type I, 24% type III and 2% type V collagen. The type I and type III collagens had similar solubility patterns, although only type I collagen was detected in the guanidinium chloride extract. Type V collagen was only detected in the first pepsin extract. The type I and III collagens had higher contents of hydroxylysine than did the same collagens from age-matched dermis. The two-dimensional electrophoretic 'maps' of CNBr-cleavage peptides showed low recoveries of the C-terminal alpha 1(I) CB6 and alpha 1(III) CB9 peptides, which are involved in forming intermolecular cross-linkages. Most of the reducible cross-linkages were present in large-Mr peptide complexes, and these complexes were shown by labelling with 125I to include the tyrosine-containing alpha 1(I) CB6 peptide. The myxomatous valves contained 67% type I, 31% type III and 2% type V collagens. There was a significant increase in the concentration of each type of collagen, which consisted of a 9% increase of type I collagen, a 53% increase of type III collagen and a 25% increase of type V collagen. The contents of hydroxylysine in type I and III collagens and the electrophoretic 'maps' of the CNBr-cleavage peptides involved in cross-linkages did not differ significantly from the results obtained from the normal valves. The biochemical findings suggest that there is an increased production of collagen, in particular type III collagen, and glycosaminoglycan as well as a proliferation of cells as part of a repair process in the myxomatous valves.     

Incorporation of sulphate into type III procollagen by cultured human fibroblasts. Identification of tyrosine O-sulphate

Confluent cultures of normal human skin fibroblasts were labelled overnight with [35S]sulphate, and the incorporation of the isotope into type III procollagen, secreted into the medium, was verified by radioimmunoassay and immunoprecipitation after removing the heavily sulphated proteoglycans by anion-exchange chromatography. Type III procollagen and its pro and pN alpha chains were visualized in fluorographs of the immunoprecipitates. The labelled procollagen could be isolated by a combination of ion-exchange chromatography and gel filtration and was found to contain tyrosine O-sulphate, which was identified by thin-layer electrophoresis after Ba(OH)2 hydrolysis. The regions sulphated in the type III procollagen molecule were susceptible to pepsin digestion. Digestion with purified bacterial collagenase at +37 degrees C produced a labelled fragment that was recognized by antibodies against the aminoterminal propeptide of type III procollagen, indicating that the sulphated tyrosine residues are located either in this propeptide or in the non-helical telopeptide region of the type III collagen molecule proper. Sulphation of tyrosine residues is a new post-translational modification in procollagen, which could be involved in the regulation of the processing of type III procollagen into collagen and thus affect the formation of collagen fibres.     

Accurate, quantitative assays for the hydrolysis of soluble type I, II, and III 3H-acetylated collagens by bacterial and tissue collagenases

Accurate and quantitative assays for the hydrolysis of soluble 3H-acetylated rat tendon type I, bovine cartilage type II, and human amnion type III collagens by both bacterial and tissue collagenases have been developed. The assays are carried out at any temperature in the 1-30 degrees C range in a single reaction tube and the progress of the reaction is monitored by withdrawing aliquots as a function of time, quenching with 1,10-phenanthroline, and quantitation of the concentration of hydrolysis fragments. The latter is achieved by selective denaturation of these fragments by incubation under conditions described in the previous paper of this issue. The assays give percentages of hydrolysis of all three collagen types by neutrophil collagenase that agree well with the results of gel electrophoresis experiments. The initial rates of hydrolysis of all three collagens are proportional to the concentration of both neutrophil or Clostridial collagenases over a 10-fold range of enzyme concentrations. All three assays can be carried out at collagen concentrations. that range from 0.06 to 2 mg/ml and give linear double reciprocal plots for both tissue and bacterial collagenases that can be used to evaluate the kinetic parameters Km and kcat or Vmax. The assay developed for the hydrolysis of rat type I collagen by neutrophil collagenase is shown to be more sensitive by at least one order of magnitude than comparable assays that use rat type I collagen fibrils or gels as substrate.     

Matrix metalloproteinase-1 cleavage site recognition and binding in full-length human type III collagen

Matrix metalloproteinases (MMPs) are essential for normal collagen turnover, recovery from fibrosis, and vascular permeability. In fibrillar collagens, MMP-1, MMP-8, and MMP-13 cleave a specific glycine–isoleucine or glycine–leucine bond, despite the presence of this sequence in other parts of the protein. This cut site specificity has been hypothesized to arise from a unique, relaxed super-secondary structure in this area due to local hydroxyproline poor character. In this study we examined the mechanism of interaction and cleavage of human type III collagen by fibroblast MMP-1 by using a panel of recombinant human type III collagens (rhCIIIs) containing engineered sequences in the vicinity of the cleavage site. Native and recombinant type III collagens had similar biochemical and structural characteristics, as indicated by transmission electron microscopy, circular dichroism spectropolarimetry, melting temperature and hydroxyproline analysis. A single amino acid change at the I785 cleavage site to proline resulted in partial MMP-1 resistance, but cuts were found in novel sites in the original cleavage region. However, the replacement of five Y-position residues by proline in this region, regardless of I785 variation, conferred complete resistance to MMP-1, MMP-8, MMP-13, trypsin, and elastase. MMP-1 had a decreased specific activity towards and reduced cleavage rate of rhCIII I785P but a K_m similar to wild-type. Despite the reductions in protease sensitivity, MMP-1 bound to all of the engineered rhCIIIs with comparable affinity, indicating that MMP-1 binding is not sufficient for cleavage. The relaxed tertiary structure in the MMP cleavage region may permit local collagen unwinding by MMP-1 that enables site-specific proteolysis.