Nonenzymatic glycation of type I collagen. The effects of aging on preferential glycation sites.

The present study was designed to investigate the effects of aging on preferential sites of glucose adduct formation on type I collagen chains. Two CNBr peptides, one from each type of chain in the type I tropocollagen molecule, were investigated in detail: alpha 1(I)CB3 and alpha 2CB3-5. Together these peptides comprise approximately 25% of the total tropocollagen molecule. The CNBr peptides were purified from rat tail tendon, obtained from animals aged 6, 18, and 36 months, by ion exchange chromatography, gel filtration, and high-performance liquid chromatography (HPLC). Sugar adducts were radiolabeled by reduction with NaB3H4. Glycated tryptic peptides were prepared from tryptic digests of alpha 2CB3-5 and alpha 1(I)CB3 by boronate affinity chromatography and HPLC. Peptides were identified by sequencing and by compositional analysis. Preferential sites of glycation were observed in both CB3 and alpha 2CB3-5. Of the 5 lysine residues in CB3, Lys-434 was the favored glycation site. Of the 18 lysine residues and 1 hydroxylysine residue in alpha 2CB3-5, 3 residues (Lys-453, Lys-479, and Lys-924) contained more than 80% of the glucose adducts on the peptide. Preferential glycation sites were highly conserved with aging. In collagen that had been glycated in vitro, the relative distribution of glucose adducts in old animals differed from that of young animals. In vitro experiments suggest that primary structure is the major determinant of preferential glycation sites but that higher order structure may influence the relative distribution of glucose adducts among these preferred sites.     

Platelet-reactive sites in collagens type I and type III. Evidence for separate adhesion and aggregatory sites.

The adhesion of human and rabbit platelets to collagens and collagen-derived fragments immobilized on plastic was investigated. Adhesion appeared to be independent of collagen conformation, since similar attachment occurred to collagen (type I) in monomeric form, as fibres or in denatured state. The adhesion of human platelets was stimulated to a variable degree by Mg2+, but rabbit platelet adhesion showed little if any dependence on this cation. Collagens type I, III, V and VI were all able to support adhesion, although that to collagen type V (native) was lower than that to the other collagens. Adhesion to a series of peptides derived from collagens I and III was measured. Attachment did not require the presence of peptides in triple-helical configuration. The extent of adhesion ranged from relatively high, as good as to the intact parent collagen molecule, to little if any adhesive activity beyond the non-specific (background) level. The existence of very different degrees of activity suggests that platelet adhesion is associated with specific structural sites in the collagen molecule. Adhesion in many instances was essentially in accord with the known platelet-aggregatory activity of individual peptides. However, two peptides, alpha 1(I)CB3 and alpha 1(III)CB1,8,10,2, exhibited good adhesive activity although possessing little if any aggregatory activity. Of particular interest, despite its near-total lack of aggregatory activity, adhesion to peptide alpha 1(I)CB3 was as good as that to the structurally homologous peptide alpha 1(III)CB4, in which is located a highly reactive aggregatory site. This implies that platelet adhesion to collagen may involve sites in the collagen molecule distinct from those more directly associated with aggregation.     

Limited proteolysis of type I collagen at hyperreactive sites by class I and II Clostridium histolyticum collagenases: complementary digestion patterns

The initial proteolytic events in the hydrolysis of rat tendon type I collagen by the class I and II collagenases from Clostridium histolyticum have been investigated at 15 degrees C. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis has been used to detect the initial cleavage fragments of both the alpha 1(I) and alpha 2 chains, which migrate at different rates in the buffer system employed. Experiments with the class I collagenases indicate that the first cleavage occurs across all three chains of the triple helix close to the C-terminus to produce fragments whose alpha chains have molecular weights of approximately 88,000. The second cleavage occurs near the N-terminus to reduce the molecular weight of the alpha chains to 80,000. Initial proteolysis by the class II collagenases occurs across all three chains at a site in the interior of the collagen triple helix to give N- and C-terminal fragments with alpha-chain molecular weights of 35,000 and 62,000, respectively. The C-terminal fragment is subsequently cleaved to give fragments with alpha-chain molecular weights of 59,000. These results indicate that type I collagen is degraded at several hyperreactive sites by these enzymes. Thus, initial proteolysis by these bacterial collagenases occurs at specific sites, much like the mammalian collagenases. These results with the individual clostridial collagenases provide an explanation for earlier data which indicated that collagen is degraded sequentially from the ends by a crude clostridial collagenase preparation.     

The gelatinolytic activity of human skin fibroblast collagenase

The gelatinolytic activity of human skin fibroblast collagenase was examined on denatured collagen types I-V. All denatured substrates were cleaved, including types IV and V, which are resistant to collagenase in native form. Interestingly, the earliest major cleavage in denatured collagen types I-III occurred at a 3/4-1/4 locus, resulting in products electrophoretically identical with TCA and TCB fragments of mammalian collagenase action on these native collagens. However, in the denatured substrates, multiple additional proteolytic cleavages followed. The propensity for cleavage at a 3/4-1/4 site in denatured collagen, where sequence is the major specifier of enzymatic action, would seem to indicate that the most favorable amino acid sequence of gamma chains for catalysis is located in this region. The peptide bond specificity of human fibroblast collagenase on gelatin was examined by amino acid sequencing of extensively cleaved denatured type I collagen. Analysis of the NH2-terminal amino acid residues from the resultant gelatin peptides showed sequences of "-H2N-Ile-Y-Gly" and "H2N-Leu-Y-Gly" only (where Y indicates that any amino acid can be found in that position), indicating that Gly-Ile and Gly-Leu bonds are the only sites of collagenase cleavage in this substrate. Whereas the gamma1 chains of denatured collagen types I-III were cleaved at similar rates, fibroblast collagenase was a much better gamma2-gelatinase than gamm1-gelatinase on denatured type 1 collagen. This preference for the cleavage of gamma2(I) was the result of both a higher kcat (750 versus 230 h-1) and lower Km (3.7 versus 7.0 microM) than for a gamma1(1), resulting in an overall selectivity (kcat/Km) of greater than 6-fold. Compared to such kinetic parameters on native collagen, these values indicate that gelatinolysis is somewhat slower than collagenolysis.     

Peptides of type II collagen can induce the cleavage of type II collagen and aggrecan in articular cartilage.

The objective of this study was to determine whether a fragment(s) of type II collagen can induce cartilage degradation. Fragments generated by cyanogen bromide (CB) cleavage of purified bovine type II collagen were separated by HPLC. These fragments together with selected overlapping synthetic peptides were first analysed for their capacity to induce cleavage of type II collagen by collagenases in chondrocyte and explant cultures of healthy adult bovine articular cartilage. Collagen cleavage was measured by immunoassay and degradation of proteoglycan (mainly aggrecan) was determined by analysis of cleavage products of core protein by Western blotting. Gene expression of matrix metalloproteinases MMP-13 and MMP-1 was measured using Real-time PCR. Induction of denaturation of type II collagen in situ in cartilage matrix with exposure of the CB domain was identified with a polyclonal and monoclonal antibodies that only react with this domain in denatured but not native type II collagen. As well as the mixture of CB fragments and peptide CB12, a single synthetic peptide CB12-II (residues 195-218), but not synthetic peptide CB12-IV (residues 231-254), potently and consistently induced in explant cultures at 10 microM and 25 microM, in a time, cell and dose dependent manner, collagenase-induced cleavage of type II collagen accompanied by upregulation of MMP-13 expression but not MMP-1. In isolated chondrocyte cultures CB12-II induced very limited upregulation of MMP-13 as well as MMP-1 expression. Although this was accompanied by concomitant induction of cleavage of type II collagen by collagenases, this was not associated by aggrecan cleavage. Peptide CB12-IV, which had no effect on collagen cleavage, clearly induced aggrecanase specific cleavage of the core protein of this proteoglycan. Thus these events involving matrix molecule cleavage can importantly occur independently of each other, contrary to popular belief. Denaturation of type II collagen with exposure of the CB12-II domain was also shown to be much increased in osteoarthritic human cartilage compared to non-arthritic cartilage. These observations reveal that peptides of type II collagen, to which there is increased exposure in osteoarthritic cartilage, can when present in sufficient concentration induce cleavage of type II collagen (CB12-II) and aggrecan (CB12-IV) accompanied by increased expression of collagenases. Such increased concentrations of denatured collagen are present in adult and osteoarthritic cartilages and the exposure of chondrocytes to the sequences they encode, either in soluble or more likely insoluble form, may therefore play a role in the excessive resorption of matrix molecules that is seen in arthritis and development.     

A base substitution at a splice site in the COL3A1 gene causes exon skipping and generates abnormal type III procollagen in a patient with Ehlers-Danlos syndrome type IV

The dermis of a child with Ehlers-Danlos syndrome type IV (EDS-IV) contained about 11% of the normal amount of type III collagen and cultured dermal fibroblasts produced a reduced amount of type III procollagen which was secreted poorly. Type III collagen produced by these cells contained normal and abnormal alpha-chains and cyanogen bromide peptides. The site of the structural defect in the abnormal alpha 1 (III) chains was localized to the region of Met797, which is at the junction of the two carboxyl-terminal CB5 and CB9 cyanogen bromide peptides. Chemical cleavage of heteroduplexes formed between EDS-IV mRNA and a normal cDNA clone covering the CB5 and CB9 region showed that about 100 nucleotides were mismatched. Sequencing of amplified and cloned cDNA spanning the mutant region revealed a 108 nucleotide deletion corresponding to amino acid residues Gly775 to Lys810. The deleted nucleotide sequence corresponded to sequences that, by analogy to the organization of the type I collagen genes, should be precisely encoded by exon 41 of the COL3A1 gene. Sequencing of amplified genomic DNA, prepared using disimilar amounts of primers specific for exons 41 and 42, displayed a base substitution (G-to-A) in the highly conserved GT dinucleotide of the 5' splice site of intron 41. Normal sequences were also obtained from the normal allele. It is likely that the GT-to-AT transition at the splice donor site of intron 41 generated an abnormally spliced mRNA in which sequences of exon 40 and 42 were joined together with maintenance of the reading frame. The corresponding peptide deletion included the cyanogen bromide cleavage site Met797-Pro798 and the mammalian collagenase cleavage site at Gly781-Ile782. These losses account for the resistance of EDS-IV collagen to cyanogen bromide and mammalian collagenase digestion. Cultured fibroblasts produced normal homotrimer, mutant homotrimer, and mixed heterotrimer type III collagen molecules. The mutant homotrimer molecules were the major pepsin-resistant species and about 69% of the alpha 1(III) mRNA was in the mutant form.     

Ehlers-Danlos syndrome type VIIB. Deletion of 18 amino acids comprising the N-telopeptide region of a pro-alpha 2(I) chain

A patient with Ehlers-Danlos syndrome Type VIIB was found to have an interstitial deletion of 18 amino acids in approximately half of the pro-alpha 2(I) chains of Type I procollagen. Analysis of pepsin-solubilized tissue and fibroblast collagen revealed an abnormal additional chain, alpha 2(I)', which migrated in sodium dodecyl sulfate-5% polyacrylamide gel electrophoresis between the normal alpha 1(I) and alpha 2(I) chains. The apparent ratio of normal alpha 1(I):mutant alpha 2(I)':normal alpha 2(I) was 4:1:1. Procollagen studies and enzyme digestion studies of native mutant collagen suggested defective removal of the amino propeptide. Sieve chromatography of CNBr peptides from purified alpha 2(I)' chains revealed the absence of the normal amino telopeptide fragment CB 1 and the appearance of a larger new peptide of approximately 60 residues (CB X). Compositional and sequencing studies of this peptide identified normal amino propeptide sequences. However, the most carboxyl-terminal tryptic peptide of CB X differed substantially in composition and sequence from the expected and was found to have an interstitial deletion of 18 amino acids corresponding to the N-telopeptide of the pro-alpha 2(I) chain. This deletion removes the normal sites of cleavage of the N-proteinase and also removes a critical cross-linking lysine residue. The 18 amino acids deleted correspond exactly to the residues encoded by exon 6 of the pro-alpha 2(I) collagen gene (COL 1 A2), and, therefore, the protein defect may be due to a genomic deletion, or alternatively, an RNA splicing defect.     

Interaction of fibronectin and its gelatin-binding domains with fluorescent-labeled chains of type I collagen

Fluorescent probes have been used to obtain dissociation constants for the fluid-phase interaction of human plasma fibronectin and several of its gelatin-binding fragments with purified alpha chains of type I rat tail collagen, as well as with a cyanogen bromide fragment (CB7) of the alpha 1 chain in 0.02 M Tris buffer containing 0.15 M NaCl at pH 7.4. Addition of fibronectin to fluorescein-labeled collagen chains caused a dose-dependent increase in the fluorescence anisotropy which continued over several logs of titrant concentration. Scatchard-type plots of the anisotropy response were biphasic indicating the presence of one or more weak sites (Kd greater than microM) along the collagen chain in addition to a strong site characterized by Kd = 1.3 X 10(-8) M at 25 degrees C. Gelatin-binding fragments with Mr = 42,000, 60,000, and 72,000 also produced a biphasic response with Kd values for the high affinity site being 10- to 20-fold greater than for intact fibronectin. Binding of fibronectin and its fragments to fluorescent-labeled CB7 was essentially the same as to the whole alpha 1 chain. In all cases, the anisotropy response could be reversed or prevented by addition of excess unlabeled gelatin or CB7, but not by synthetic peptides spanning the collagenase cleavage site of alpha 1 (I). Studies of the temperature dependence of Kd for binding of fibronectin to the high affinity site on alpha 1 produced a value of +16 kcal/mol for the enthalpy of dissociation below 30 degrees C. Above this temperature, fibronectin appeared to undergo a subtle conformational transition characterization by a reduced affinity for collagen. This transition occurred in whole fibronectin but not in the gelatin-binding fragments and may involve disruption of intramolecular interactions between different domains.     

Covalent structure of collagen: amino acid sequence of three cyanogen bromide-derived peptides from human alpha 1(V) collagen chain

Type V collagen was prepared from human amnionic/chorionic membranes and separated into alpha 1(V) and alpha 2(V) polypeptide chains. The alpha 1(V) chain was digested with cyanogen bromide and nine peptides were obtained and purified. Three of the peptides, alpha 1(V)CB1, CB4, and CB7 having molecular weights of 5000, 8000, and 6000, respectively, were further analyzed by amino acid sequence analysis and thermolytic or tryptic digestions. CB1 contained 54 amino acids and identification of its complete sequence was aided by thermolysin digestion and isolation of two peptides, Th1 and Th2. CB4 contained 81 amino acids and sequence analysis of intact CB4 and five tryptic peptides provided us with its complete amino acid sequence. The peptide CB7 contained 67 amino acids and was cleaved into four tryptic peptides that were used for complete sequence analysis. The above results represent the first available covalent structure information on the alpha 1(V) collagen chain. These data enabled us to establish the location of these peptides within the helical structure of other collagen chains. CB4 was homologous to residues 66-145 in the collagen chain while CB1 represented residues 146-200 and CB7 was homologous with residues 201-269. This alignment was facilitated by identification of a helical collagen crossing site consisting of Hyl-Gly-His-Arg located at positions 87-90 in all collagen chains of this size thus far identified. Seventy-one percent homology (excluding Gly residues) was found between amino acids in this region of the alpha 1(XI) and of alpha 1(V) collagen chains while only 21 and 19% identity was calculated for the same region of alpha 2(V) and alpha 1(I) collagen chains, respectively.     

In vitro phosphorylation of type I collagen by cyclic AMP-dependent protein kinase

Both the triple-helical and denatured forms of nonfibrillar bovine dermal type I collagen were tested as substrates for the catalytic subunit of cAMP-dependent protein kinase in an in vitro reaction. Native, triple-helical collagen was not phosphorylated, but collagen that had been thermally denatured into individual alpha chains was a substrate for the protein kinase. Catalytic subunit of cAMP-dependent protein kinase phosphorylated denatured collagen to between 3 to 4 mol of phosphate/mol of (alpha 1(I)2 alpha 2(I). Pepsin-solubilized and intact collagens were phosphorylated similarly, as long as each was in a nonhelical conformation. The first 2 mol of phosphate incorporated into type I collagen by the protein kinase were present in the alpha 2(I) chain. The alpha 1(I) chain was only phosphorylated during long incubations in which the stoichiometry exceeded 2 mol of phosphate/mol of (alpha 1(I)2 alpha 2(I). Phosphoserine was the only phosphoamino acid identified in collagen that had been phosphorylated to any degree by the protein kinase. The 2 mol of phosphate incorporated into the alpha 2(I) chain were localized to the alpha 2(I)CB4 cyanogen bromide fragment. The catalytic subunit of cAMP-dependent protein kinase phosphorylated denatured pepsin-solubilized collagen with a Km of 8 microM and a Vmax of approximately 0.1 mumol/min/mg of enzyme. Denatured, but not triple-helical, type I collagen was also phosphorylated by cGMP-dependent protein kinase, although it was a poorer substrate for this enzyme than for the cAMP-dependent protein kinase. Collagen was not a substrate for phospholipid-sensitive Ca2+-dependent protein kinase. These results suggest the potential for nascent alpha chains of type I collagen to be susceptible to phosphorylation by cAMP-dependent protein kinase in vivo prior to triple-helix formation. Such a phosphorylation of collagen could be relevant to the action of cAMP to increase the intracellular degradation of newly synthesized collagen.     

Cleavage specificity of type IV collagenase (gelatinase) from human skin. Use of synthetic peptides as model substrates

Type IV collagenase (gelatinase) has a marked substrate specificity for denatured collagen (gelatin). Cleavage site specificity of type IV collagenase from human skin was determined using small collagenous peptides with varied sequences around Gly-Leu or Gly-Ile. Type IV collagenase showed essentially the same order of preference for the peptide substrates as did interstitial collagenase. Both required a peptide with a minimum of six amino acid residues to demonstrate significant gelatinolytic activity and were able to cleave uncharged molecules more rapidly than charged molecules. the repeating Gly-X-Y-Gly sequence of collagen is not an absolute requirement for either enzyme since both digested AcPro-Leu-Gly-Ile-Leu-Ala-Ala-OC2H5 at 70% of the rate of the best substrate peptide, AcPro-Leu-Gly-Leu-Leu-Gly-OC2H5. Km and kcat (Vmax) values were determined for several of the peptides and for the native substrate. Turnover numbers with type IV collagenase were similar to those with interstitial collagenase (Weingarten, H., Martin, R., and Feder, J. (1985) Biochemistry 24, 6730-6734). However, the Km for all peptides investigated was approximately 10-fold lower for type IV collagenase than for interstitial collagenase. Because type IV collagenase does not cleave helical interstitial collagens, the data support the conclusion that secondary structure determines whether the peptide bond can be hydrolyzed at any potential cleavage site.     

Intermolecular cross-linking and stereospecific molecular packing in type I collagen fibrils of the periodontal ligament

A trypsin digest of denatured NaB3H4-reduced native bovine periodontal ligament was prepared and fractionated by gel filtration and cellulose ion-exchange column chromatography. Prior to trypsin digestion, a complete acid hydrolysate was subjected to analyses for nonreducible stable and reducible intermolecular cross-links. Minute amounts of the former and significant amounts of the reduced cross-links dihydroxylysinonorleucine (1.1 mol/mol of collagen), hydroxylysinonorleucine (0.9 mol/mol of collagen), and histidinohydroxymerodesmosine (0.6 mol/mol of collagen) were found. The covalent intermolecular cross-linked two-chained peptides that were isolated were subjected to amino acid and sequence analyses. The structures for the different two-chained linked peptides were alpha 1CB4-5(76-90)[Hyl-87] X alpha 1CB6-(993-22c)[Lysald-16c], alpha 1CB4-5(76-90)[Hyl-87] X alpha 1CB6(993-22c)[Hylald-16c], alpha 2CB4(76-90)[Hyl-87] X alpha 1CB6(993-22c)[Lysald-16c], and alpha 2CB4(76-90)[Hyl-87] X alpha 1CB6(993-22c)[Hylald-16c]. The cross-link in each peptide was glycosylated. This is the first characterization by sequence analysis of a cross-link involving Hyl-87 in an alpha 2 chain in collagen. A stoichiometric conversion of residue 16c aldehyde to an intermolecular cross-link in each of the COOH-terminal nonhelical peptide regions of both alpha 1 chains in a molecule of type I collagen was found. The ratio of alpha 1 to alpha 2 intermolecularly cross-linked chains involved was 3.3:1, indicating a stereospecific three-dimensional molecular packing of type I collagen molecules in bovine periodontal ligament.     

Lethal perinatal osteogenesis imperfecta due to the substitution of arginine for glycine at residue 391 of the alpha 1(I) chain of type I collagen

A baby with the lethal perinatal form of osteogenesis imperfecta was shown to have a structural defect in the alpha 1(I) chain of type I procollagen. Normal and mutant alpha 1(I) CB8 cyanogen bromide peptides, from the helical part of the alpha 1(I) chains, were purified from bone. Amino acid sequencing of tryptic peptides derived from the mutant alpha 1(I) CB8 peptide showed that the glycine residue at position 391 of the alpha 1(I) chain had been replaced by an arginine residue. This substitution accounted for the more basic charged form of this peptide that was observed on two-dimensional electrophoresis of the collagen peptides obtained from the tissues. The substitution was associated with increased enzymatic hydroxylation of lysine residues in the alpha 1(I) CB8 and the adjoining CB3 peptides but not in the carboxyl-terminal CB6 and CB7 peptides. This finding suggested that the sequence abnormality had interfered with the propagation of the triple helix across the mutant region. The abnormal collagen was not incorporated into the more insoluble fraction of bone collagen. The baby appeared to be heterozygous for the sequence abnormality and as the parents did not show any evidence of the defect it is likely that the baby had a new mutation of one allele of the pro-alpha 1(I) gene. The amino acid substitution could result from a single nucleotide mutation in the codon GGC (glycine) to produce the codon CGC (arginine).     

Isolation and purification of biopolymers using an affinity chromatography method. X. A biospecific approach to preparing collagen-like peptides containing segments binding fibronectin

A biospecific method for one-stage isolation of collagen peptides containing the fibronectin binding site is proposed. alpha 1CB7-peptide of the type I collagen cyanogen bromide cleavage was isolated by means of affinity chromatography on adsorbents containing an immobilized gelatin-binding domain (45 kDa) of fibronectin. The method allows one to obtain, in a short time, highly purified preparation of alpha 1CB7-peptide necessary for biochemical studies.     

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.     

Partial covalent structure of the human alpha 2 type V collagen chain

Human cDNA libraries were screened with a cDNA fragment presumably encoding the 3' terminus of a procollagen carboxyl propeptide not identifiable as types I, II, III, or IV by protein sequence or Northern blot hybridization. One clone contained a 1350-base pair insert coding in part for 55 uninterrupted Gly-X-Y triplets. Comparison with the amino acid composition of the COOH-terminal cyanogen bromide (CB) peptides of the alpha 1 and alpha 2 type V collagen chains showed similarity only to the alpha 2(V)CB fragment. To identify the NH2 terminus of the peptide designated by methionine, an additional isolate was sequenced and found to contain a Gly-Met-Pro triplet. Thirty-one amino acids from the NH2 terminus of the alpha 2(V)CB9 fragment were then determined by Edman degradation and found to be identical to those derived from the cDNA clone. The DNA sequence encoding part of the triple helical region establishes for the first time the partial structure of a type V collagen chain. Although comparison of residues 796-1020 of the alpha 2(V) collagenous region with alpha 1 (III), alpha 1(I), and alpha 2(I) shows strong conservation of charged positions, the latter three chains appear considerably more similar to each other than to alpha 2(V). A striking feature of the alpha 2(V) sequence between 918-944 is the absence of proline residues. In the analogous region of alpha 1(I) where this amino acid is also lacking, a flexible site in the rigid triple helical structure of type I collagen has been observed (Hofmann, H., Voss, T., Kuhn, K. and Engel, J. (1984) J. Mol. Biol. 172, 325-343).     

Cleavage of type I and type II procollagens by type I/II procollagen N-proteinase. Correlation of kinetic constants with the predicted conformations of procollagen substrates

The kinetic constants were examined for the cleavage of several types of procollagen by type I/II procollagen N-proteinase. The Km values were essentially the same (0.2 microM) for chick type I procollagen, human type I procollagen, and chick type II procollagen. However, the Vmax values differed over a 14-fold range. As reported previously, the enzyme did not cleave denatured type I or II procollagen. Also, it did not cleave human type III procollagen which contains the same scissle -Pro-Gln- bond as the pro-alpha 1(I) chain of type I procollagen. To explain the observations, Chou-Fasman rules were used to compare the secondary structures of the cleavage sites in the procollagens. The results supported a previous suggestion (Helseth, D. L., Jr., Lechner, J. L., and Veis, A. (1979) Biopolymers 18, 3005-3014) that the region carboxyl-terminal to cleavage site in the pro-alpha 1(I) chain of type I procollagen was in a hairpin conformation consisting of a beta-sheet, beta-turn, and beta-sheet. In both chick and human type I procollagen, the hairpin loop in the pro-alpha 1(I) chain consisted of about 18 amino acids. The cleavage site itself was in a short alpha-helical structure of four or five amino acids. The pro-alpha 2(I) chains had a similar hairpin loop of about 14 amino acids and alpha-helix of four or five amino acids containing the cleavage site. Chick type II procollagen, which had the highest Vmax value, had a longer hairpin structure of 22 amino acids, and the cleavage site was in a longer alpha-helical domain of 10 amino acids. In contrast, type III procollagen had a random-coil conformation in the same region. The results help to explain the unusual substrate requirements of type I/II N-proteinase. They also help explain why mutations that produce in-frame deletions of amino acids 84 or more residues carboxyl-terminal to the cleavage site make the protein resistant to the enzyme.     

The gelatinolytic activity of rat uterus collagenase

The collagenase produced by rat uterine cells in culture has been examined for its ability to degrade denatured collagen. Acting as a gelatinase, rat uterus collagenase was able to successfully degrade the denatured chains of collagen types I through V. In addition, the enzyme produced multiple cleavages in these chains and displayed values for Km of 4-5 microM, compared to values of 1-2 microM when native collagen was used as substrate. Furthermore, rat uterus collagenase degraded the alpha 2 chain of denatured type I collagen at a significantly faster rate than the alpha 1 chain, as previously observed for human skin fibroblast collagenase. In contrast to the action of human skin collagenase, however, the rat uterus enzyme was found to be a markedly better gelatinase than a collagenase, degrading the alpha chains of denatured type I guinea pig skin collagen at rates some 7-15-fold greater than native collagen. Human skin collagenase degrades the same denatured chains at rates ranging from 13-44% of its rate on native collagen. Rat uterus collagenase, then, is approximately 50 times better a gelatinase than is human skin collagenase. In addition to its ability to cleave denatured collagen chains at greater rates than native collagen, the rat uterus collagenase also attacked a wider spectrum of peptide bonds in gelatin than does human skin collagenase. In addition to cleaving the Gly-Leu and Gly-Ile bonds characteristic of its action on native collagen, rat uterus collagenase readily catalyzed the cleavage of Gly-Phe bonds in gelatin. The rat enzyme was also capable of cleaving Gly-Ala and Gly-Val bonds, although these bonds were somewhat less preferred by the enzyme. The cleavage of peptide bonds other than Gly-Leu and Gly-Ile appears to be a property of the collagenase itself and not a contaminating protease. Thus, it appears that the collagenase responsible for the degradation of collagen during the massive involution of the uterus might also act as a gelatinase to further degrade the initial products of collagenolysis to small peptides suitable for further metabolism.     

Changes in thermal stability and microunfolding pattern of collagen helix resulting from the loss of alpha2(I) chain in osteogenesis imperfecta murine

Homozygous mutations resulting in formation of alpha1(I)(3) homotrimers instead of normal type I collagen cause mild to severe osteogenesis imperfecta (OI) in humans and mice. Limited studies of changes in thermal stability of type I homotrimers were reported previously, but the results were not fully consistent. We revisited this question in more detail using purified tendon collagen from wild-type (alpha1(I)(2)alpha2(I) heterotrimers) and oim (alpha1(I)(3)) mice as well as artificial alpha1(I)(3) homotrimers obtained by refolding of rat-tail-tendon collagen. We found that at the same heating rate oim homotrimers completely denature at approximately 2.5deg.C higher temperature than wild-type heterotrimers, as determined by differential scanning calorimetry. At the same, constant temperature, homotrimers denature approximately 100 times slower than heterotrimers, as determined by circular dichroism. Detailed analysis of proteolytic cleavage at different temperatures revealed that microunfolding of oim homotrimers and wild-type heterotrimers occurs at similar rate but within a number of different sites. In particular, the weakest spot on the oim triple helix is located approximately 100 amino acid residues from the C-terminal end within the cyanogen bromide peptide CB6. The same microunfolding site is also present in wild-type collagen, but the weakest spot of the latter is located close to the N-terminal end of CB8. Amino acid analysis and differential gel electrophoresis showed virtually no posttranslational overmodification of oim mouse tendon collagen. Moreover, thermal stability and microunfolding of artificial rat-tail-tendon homotrimers were similar to oim homotrimers. Thus, the observed changes are associated with difference in the amino acid composition of alpha1(I) and alpha2(I) chains rather than posttranslational overmodification.     

Identification of cyanogen bromide peptides involved in intermolecular cross-linking of bovine type III collagen.

Cyanogn bromide peptides derived from bovine type III collagen and containing reducible cross-links were isolated and identified. Two peptides, alpha 1 (III)CB7 and alpha 1 (III)CB9B, from within the helical portion of the molecule were shown to contain the 'amino donor' residues cross-linked to non-helical 'aldehyde donor' residues in the formation of cross-links. This information, in conjunction with previously published data for the order of the cyanogen bromide peptides [Fietzek, Allman, Rauterberg & Wachter (1977) Proc. Natl. Acad. Sci. U.S.A. 74, 84-86], suggests that in type III collagen intermolecular cross-links are located in the end-overlap regions, so as to stabilize a quarter-stagger arrangement of molecules within the fibre in a similar manner to that proposed for type I and type II collagens.