Mutations that alter the primary structure of type I procollagen have long-range effects on its cleavage by procollagen N-proteinase

Type I/II procollagen N-proteinase was partially purified from chick embryos and used to examine the rate of cleavage of a series of purified type I procollagens synthesized by fibroblasts from probands with heritable disorders of connective tissue. The rate of cleavage was normal with procollagen from a proband with osteogenesis imperfecta that was overmodified by posttranslational enzymes. Therefore, posttranslational overmodification of the protein does not in itself alter the rate of cleavage under the conditions of the assay employed. Cleavage of the procollagen, however, was altered in several procollagens with known mutations in primary structure. Two of the procollagens had in-frame deletions of 18 amino acids encoded by exons 11 and 33 of the pro alpha 2(I) gene. In both procollagens, both the pro alpha 1(I) and the pro alpha 2(I) chains were totally resistant to cleavage. With a procollagen in which glycine-907 of the alpha 2(I) chain domain was substituted with aspartate, both pro alpha chains were cleaved but at a markedly decreased rate. The results, therefore, establish that mutations that alter the primary structure of the pro alpha chains of procollagen at sites far removed from the N-proteinase cleavage site can make the protein resistant to cleavage by the enzyme. The long-range effects of in-frame deletions or other changes in amino acid sequence are probably explained by their disruption of the hairpin structure that is formed by each of the three pro alpha chains in the region containing the cleavage site and that is essential for cleavage of the procollagen molecule by N-proteinase.     

Deletion of 24 amino acids from the pro-alpha 1(I) chain of type I procollagen in a patient with the Ehlers-Danlos syndrome type VII

A child with the type VII form of the Ehlers-Danlos syndrome was shown to have a structural defect in the amino terminus of the pro-alpha 1(I) chain of type I procollagen. Normal and mutant amino-terminal cyanogen bromide peptides (pN-alpha 1(I) CB0,1 peptides) were purified from the medium of the patient's cultured fibroblasts. Amino acid sequencing of tryptic peptides derived from the mutant pN-alpha 1(I) CB0,1 peptide showed that an expected sequence of 24 amino acids (positions 136-159 of the normal pN-alpha 1(I) CB0,1 peptide) was deleted. The segment deleted from the mutant pro-alpha 1(I) chain contains the small globular region of the NH2-propeptide, the procollagen N-proteinase cleavage site, the NH2-telopeptide, and first triplet of the helix of the alpha I(I) collagen chain (Chu, M.-L., de Wet, W., Bernard, M., Ding, J.F., Morabito, M., Myers, J., Williams, C., and Ramirez, F. (1984) Nature 310, 337-340). Loss of the procollagen N-proteinase cleavage site from the mutant pro-alpha 1(I) chain accounted for the persistence of its NH2-propeptide despite normal production of the N-proteinase by cultured mutant fibroblasts. Collagen production by mutant fibroblasts was doubled possibly due to reduced feedback inhibition by the NH2-propeptides. The child appeared to be heterozygous for the peptide deletion and, as the parents did not show any evidence of the deletion, it is likely that the child had a new mutation of one allele of the pro-alpha 1(I) gene. The deleted peptide corresponds precisely to the sequence coded by exon 46 of the normal pro-alpha 1(I) gene (Chu, M.-L., de Wet, W., Bernard, M., Ding, J.F., Morabito, M., Myers, J., Williams, C., and Ramirez, F. (1984) Nature 310, 337-340).     

Type I procollagen carboxyl-terminal proteinase from chick embryo tendons. Purification and characterization

Procollagen carboxyl-terminal proteinase, the enzyme which cleaves the carboxyl-terminal propeptides from type I procollagen, was extensively purified in a yield of 25% from pooled culture media of 17-day-old chick embryo tendons using a procedure which involved chromatography on Green A Dye matrix gel, concanavalin A-Sepharose and heparin-Sepharose, and filtration gels of Sephacryl S-300 and S-200. The purified enzyme is a neutral, Ca2+-dependent proteinase which is inhibited by metal chelators, but not by inhibitors for serine and cysteine proteinases. Calcium in a concentration of 5-10 mM is required for optimal activity. The molecular weight of the enzyme was determined to be 97,000-110,000 by gel filtration and by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. Other properties of the carboxyl-terminal proteinase are: 1) the Km for the type I procollagen is 96 nM at pH 7.5 and 35 degrees C; 2) the activation energy for the reaction with type I procollagen is 21,000 cal mol-1; 3) amino acid sequencing of the released carboxyl-terminal propeptide indicated the enzyme specifically cleaves an -Ala-Asp- bond in both the pro-alpha 1(I) and pro-alpha 2(I) chains; 4) the enzyme specifically cleaves the carboxyl-terminal propeptides of a homotrimer of pro-alpha 1(I) chains and type II and III procollagens, but it does not cleave type IV procollagen. The results suggest that the enzyme is involved in the processing of type I procollagen in vivo.     

A heterozygous defect for structurally altered pro-alpha 2 chain of type I procollagen in a mild variant of osteogenesis imperfecta. The altered structure decreases the thermal stability of procollagen and makes it resistant to procollagen N-proteinase

Cultured skin fibroblasts from a proband with an autosomal dominant variant of osteogenesis inperfecta were found to synthesize approximately equal amounts of normal pro-alpha 2(I) chains of type I procollagen and pro-alpha 2(I) chains which migrated more rapidly when examined by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. The structural alteration was present in alpha 2(I)-CB4, a cyanogen bromide fragment containing amino acid residues 7-327 of the alpha 2 chain, and it appeared to be a deletion of about 30 amino acids. The pro-alpha 2(I) chains with the apparent deletion associated with normal pro-alpha 1(I) chains synthesized by the same fibroblasts and formed triple-helical type I procollagen. The presence of the altered pro-alpha 2 chains in trimers of procollagen had two consequences in terms of the physical properties of the molecule. One was to decrease the thermal stability of the protein as judged by resistance to proteolysis at 37 degrees C and by the helix to coil transition as assayed by circular dichroism. The second consequence was to make type I procollagen containing the shortened pro-alpha 2(I) chains resistant to digestion by procollagen N-proteinase. The simplest explanation for the data is that the apparent deletion in half the pro-alpha 2(I) chains produced a partial unfolding of the N-terminal region of type I procollagen which prevented processing of the protein by procollagen N-proteinase.     

A monoclonal antibody specific for the amino terminal cleavage site of procollagen type I

A monoclonal mouse IgG1 antibody was produced against the aminopropeptide of dermatosparactic sheep procollagen type I by using the hybridoma technique. Radioimmunoassays demonstrated an apparent affinity constant of 10(8) l X mol-1. The antibody reacted with a 19-amino-acid-long sequence spanning the procollagen N-proteinase cleavage site with stronger binding to structures contributed by the aminopropeptide. The antibody showed strong cross-reactions with similar antigens of bovine, human or chick origin but failed to react with the aminopropeptide of procollagen type III. Incubation of chick or sheep procollagen type I with stoichiometric amounts of antibody blocked the release from procollagen molecules of the aminopropeptide by procollagen N-proteinase. Thus, this antibody seems useful for studying various biological problems encountered in the conversion of procollagen.     

Processing of type II procollagen amino propeptide by matrix metalloproteinases.

In many embryonic tissues, type IIA procollagen is synthesized and deposited into the extracellular matrix containing the NH(2)-propeptide, the cysteine-rich domain of which binds to bone morphogenic proteins. To investigate whether matrix metalloproteinases (MMPs) synthesized during development and disease can cleave the NH(2) terminus of type II procollagens, we tested eight types of enzymes. Recombinant trimeric type IIA collagen NH(2)-propeptide encoded by exons 1-8 fused to the lectin domain of rat surfactant protein D was used as a substrate. The latter allowed trimerization of the propeptide domain and permitted isolation by saccharide affinity chromatography. Although MMPs 1, 2, and 8 did not show cleavage, MMPs 3, 7, 9, 13, and 14 cleaved the recombinant protein both at the telopeptide region and at the procollagen N-proteinase cleavage site. MMPs 7 and 13 demonstrated other cleavage sites in the type II collagen-specific region of the N-propeptide; MMP-7 had another cleavage site close to the COOH terminus of the cysteine-rich domain. To prove that an MMP can cleave the native type IIA procollagen in situ, we demonstrated that MMP-7 removes the NH(2)-propeptide from collagen fibrils in the extracellular matrix of fetal cartilage and identified the cleavage products. Because the N-proteinase and telopeptidase cleavage sites are present in both type IIA and type IIB procollagens and the telopeptide cleavage site is retained in the mature collagen fibril, this processing could be important to type IIB procollagen and to mature collagen fibrils as well.     

Type I procollagen N-proteinase from whole chick embryos. Cleavage of a homotrimer of pro-alpha 1(I) chains and the requirement for procollagen with a triple-helical conformation

Procollagen N-proteinase, the enzyme which cleaves the NH2-terminal propeptides from type I procollagen, was purified over 15,000-fold from extracts of chick embryos by chromatography on columns of DEAE-cellulose, concanavalin A-agarose, heparin-agarose, pN-collagen-agarose, and a filtration gel. The purified enzyme had an apparent molecular weight of 320,000 as estimated by gel filtration and a pH optimum for activity of 7.4 to 9.0. The enzyme was inhibited by metal chelators and the thiol reagent dithiothreitol. Addition of calcium was required for maximal activity under the standard assay conditions, and the presence of calcium decreased thermal inactivation at 37 degrees C. The purified enzyme cleaved a homotrimer of pro-alpha 1(I) chains, an observation which indicated that the presence of pro-alpha 2(I) chain is not essential for the enzymic cleavage of NH2-terminal propeptides. Previous observations suggesting that the enzyme requires a substrate with a native conformation were explored further by reacting the enzyme with type I procollagen at different temperatures. Type I procollagen from chick embryo fibroblasts became resistant to cleavage at about 43 degrees C. Type I procollagen from human skin fibroblasts, which was previously shown to have a slightly lower thermal stability than chick embryo type I procollagen, became resistant to cleavage at temperatures that were about 2 degrees C lower. The results suggested that the enzyme is a sensitive probe for the three-dimensional structure of the NH2-terminal region of the procollagen molecule and that it requires the protein substrate to be triple helical.     

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.     

A base substitution at the splice acceptor site of intron 5 of the COL1A2 gene activates a cryptic splice site within exon 6 and generates abnormal type I procollagen in a patient with Ehlers-Danlos syndrome type VII.

The dermal type I collagen of a patient with Ehlers-Danlos type VIIB (EDS-VIIB) contained normal alpha 2(I) chains and mutant pN-alpha 2(I)' chains in which the amino-terminal propeptide (N-propeptide) remained attached to the alpha 2(I) chain. Similar alpha 2(I) chains were produced by cultured dermal fibroblasts. Amino acid sequencing of tryptic peptides, prepared from the mutant amino-terminal pN-alpha 2(I) CB1' peptide, indicated that five amino acids, including the N-proteinase (the specific proteinase that cleaves the procollagen N-propeptide) cleavage site, had been deleted from the junction of the N-propeptide and the N-telopeptide (the nonhelical domain at the amino-terminus of the alpha chains of fully processed type I polypeptide chains) of the mutant pro-alpha 2(I)' chain. The corresponding 15 nucleotides, which were deleted from approximately half of the alpha 2(I) cDNA polymerase chain reaction products, of the alpha 2(I) cDNA polymerase chain reaction products, were encoded by the +1 to +15 nucleotides of exon 6 of the normal alpha 2(I) gene (COL1A2). These 15 nucleotides were deleted in the splicing of alpha 2(I) pre-mRNA to mRNA as a result of inactivation of the 3' splice site of intron 5 by an AG to AC mutation and the activation of a cryptic AG splice acceptor site corresponding to positions +14 and +15 of exon 6. Loss of the N-proteinase cleavage site explained the persistence of the pN-alpha 2(I)' chains in the dermis and in fibroblast cultures. Collagen production by cultured dermal fibroblasts was doubled, possibly due to reduced feedback inhibition by the N-propeptides. In contrast to previously reported cases of EDS-VIIB, Lys5 of the N-telopeptide was not deleted and appeared to take part in the formation of intramolecular cross-linkages. However, increased collagen solubility and abnormal extraction profiles of the mutant type I collagen molecules indicated that collagen cross-linking was abnormal in the dermis. The proband and her son were heterozygous for the mutation. It is likely that the heterozygous loss of the N-proteinase cleavage site, with persistence of a shortened N-propeptide, was the major factor responsible for the EDS-VIIB phenotype.     

Type I procollagens containing substitutions of aspartate, arginine, and cysteine for glycine in the pro alpha 1 (I) chain are cleaved slowly by N-proteinase, but only the cysteine substitution introduces a kink in the molecule.

Type I procollagen was purified from the medium of dermal fibroblasts cultured from four individuals with osteogenesis imperfecta (OI) type II who had mutations in the COL1A1 gene of type I procollagen. The procollagens were mixtures of normal molecules and molecules that contained substitutions of aspartate for glycine 97, arginine for glycine 550, cysteine for glycine 718, and aspartate for glycine 883 in one or both of the alpha 1 (I) chains of the molecule. The procollagens were cleaved more slowly than control type I procollagen by procollagen N-proteinase. Double-reciprocal plots of initial relative velocities and initial substrate concentrations indicated that the OI procollagens were all cleaved slowly by N-proteinase because of decreased Vmax, rather than increased Km. This suggested that slow cleavage of the OI procollagens by N-proteinase was the result of slow conversion of the N-proteinase-procollagen complex. Further experiments showed that the vertebrate collagenase A fragment of the aspartate for glycine alpha 1(I) 883 OI procollagen that contained the N-proteinase cleavage site but not the site of the substitution was also cleaved more slowly by N-proteinase than the normal vertebrate collagenase A fragments in the samples. These data show, for the first time, that an altered triple-helical structure is propagated from the site of a substitution of a bulky residue for glycine to the amino-terminal end of the procollagen molecule and disrupts the conformation of the N-proteinase cleavage site. Rotary shadowing electron microscopy of molecules in the preparation of cysteine for glycine alpha 1(I)-718 showed the presence of a kink in approximately 5% of a population of molecules in which 60% were abnormal and 20% contained a disulfide bond. In contrast, procollagens containing aspartate and arginine for glycine were indistinguishable by rotary shadowing electron microscopy from those in control samples. The results here confirm previous suggestions that substitution of cysteine for glycine in the alpha 1(I) chain of type I collagen can introduce a kink near the site of the substitution. However, the presence of a kink is not a prerequisite for delayed cleavage of abnormal procollagens by N-proteinase.     

Isolation and characterization of a cDNA clone for the amino-terminal portion of the pro-alpha 1(II) chain of cartilage collagen

We have isolated a cDNA clone (pRcol 2) which is complementary to the 5'-terminal portion of the rat pro-alpha 1(II) chain mRNA. A synthetic oligonucleotide was used both as a primer for cDNA synthesis and as a probe for screening a cDNA library. The probe was a mixture of sixteen 14-mers deduced from an amino acid sequence present in the amino-terminal telopeptide of the rat cartilage alpha 1(II) chain. This primer was chosen so that the resulting cDNA would contain the sequence of the 5' end of the mRNA. The nucleotide sequences of the cDNA were determined and compared with that of three other interstitial procollagen chain mRNAs (pro-alpha 1(I), pro-alpha 2(I), and pro-alpha 1(III) chain mRNA). pRcol 2 contains a 521-base pair (bp) insert, including 153 bp of the 5' untranslated region plus 368 bp coding for the signal peptide, the amino-terminal propeptide, and a part of the telopeptide. The signal peptide of the type II collagen chain is composed of about 20 amino acids. There is little homology between the amino acid sequence of the signal peptide in the pro-alpha 1(II) chain and that of three other interstitial procollagen chains. The NH2-terminal propeptide is deduced to contain short nonhelical sequences at its amino and carboxyl ends and an internal helical collagenous domain comprising 25 repeats of Gly-X-Y with one interruption. There is a strong conservation of the amino acid sequence of the carboxyl-terminal part of the NH2-terminal propeptide in the pro-alpha 1(II), pro-alpha 1(I), and pro-alpha 2(I) chains. Type II collagen mRNA does not contain a sequence corresponding to a uniquely conserved nucleotide sequence around the translation initiation site which occurs in mRNA for other procollagen chains.     

Bleomycin treatment of chick fibroblasts causes an increase of polysomal type I procollagen mRNAs. Reversal of the bleomycin effect by dexamethasone

Bleomycin treatment of primary chick skin fibroblasts and chick lung fibroblasts resulted in a selective dose-dependent increase of cell layer procollagen synthesis. Solid support hybridization of total cellular RNA to 32P-labeled pro-alpha 1(I) and pro-alpha 2(I) cDNAs did not indicate an increase of total cellular procollagen type I mRNAs in bleomycin-treated cells. However, bleomycin treatment of chick skin fibroblasts causes a redistribution of procollagen type I mRNAs within the nuclear, cytoplasmic, and polysomal subcellular fractions. Both the nuclear and cytoplasmic procollagen type I mRNAs are significantly decreased in concentration after bleomycin administration. In contrast, the polysomal procollagen type I mRNAs are significantly increased in both chick skin and lung fibroblasts treated with bleomycin. Administration of dexamethasone to bleomycin-treated fibroblasts resulted in a reversal of the bleomycin-induced increase in cell layer procollagen synthesis. The increased amounts of polysomal procollagen type I mRNAs in bleomycin-treated cells were also reduced by subsequent administration of dexamethasone. These data indicate that bleomycin treatment of chick skin and chick lung fibroblasts results in a specific increase in procollagen synthesis in the cell layer which is mediated by elevated levels of polysomal type I procollagen mRNAs via a repartitioning of these mRNAs within the fibroblast. Furthermore, dexamethasone reverses the bleomycin-induced elevations of both cell layer procollagen synthesis and polysomal type I procollagen mRNAs.     

Synthesis and processing of a type I procollagen containing shortened pro-alpha 1(I) chains by fibroblasts from a patient with osteogenesis imperfecta

Skin fibroblasts from a patient with a lethal form of osteogenesis imprefecta were found to synthesize equal amounts of normal pro-alpha 1(I) chains and pro-alpha 1(I) chains which are about 10% shorter because of a deletion of about 100 amino acids in the middle of the alpha chain domain. The pro-alpha 1(I) chains were incorporated into three different kinds of trimers: a normal type I trimer with normal length pro-alpha 1(I) chains; a type Is trimer with one shortened pro-alpha 1(I) chain and two normal length chains; and a type Iss trimer containing two shortened pro-alpha 1(I) chains and one normal length pro-alpha 2(I) chain. As judged by resistance to digestion by chymotrypsin and trypsin, the type Is and Iss trimers denatured at a temperature at least 3 degrees C lower than normal type I procollagen. Procollagen containing the shortened pro-alpha 1(I) chains was slowly secreted by the cells but was degraded by extracellular proteinases within 6 h of chase into the medium. The results indicated that the presence of the shortened pro-alpha 1(I) chains in procollagen trimers produces a delay in rate of helix formation, overmodification of the polypeptides by post-translational enzymes, a decrease in the thermal stability of the trimers, and increased susceptibility of the protein to endogenous proteinases. Additionally, the fibroblasts of this patient synthesized and secreted a type III-like species of procollagen with unusual chromatographic properties.     

Molecular mechanism of alpha 1(I)-osteogenesis imperfecta/Ehlers-Danlos syndrome: unfolding of an N-anchor domain at the N-terminal end of the type I collagen triple helix

We demonstrate that 85 N-terminal amino acids of the alpha1(I) chain participate in a highly stable folding domain, acting as the stabilizing anchor for the amino end of the type I collagen triple helix. This anchor region is bordered by a microunfolding region, 15 amino acids in each chain, which include no proline or hydroxyproline residues and contain a chymotrypsin cleavage site. Glycine substitutions and amino acid deletions within the N-anchor domain induce its reversible unfolding above 34 degrees C. The overall triple helix denaturation temperature is reduced by 5-6 degrees C, similar to complete N-anchor removal. N-propeptide partially restores the stability of mutant procollagen but not sufficiently to prevent N-anchor unfolding and a conformational change at the N-propeptide cleavage site. The ensuing failure of N-proteinase to cleave at the misfolded site leads to incorporation of pN-collagen into fibrils. Similar, but weaker, effects are caused by G88E substitution in the adjacent triplet, which appears to alter N-anchor structure as well. As in Ehlers-Danlos syndrome (EDS) VIIA/B, fibrils containing pN-collagen are thinner and weaker causing EDS-like laxity of large and small joints and paraspinal ligaments. However, distinct structural consequences of N-anchor destabilization result in a distinct alpha1(I)-osteogenesis imperfecta (OI)/EDS phenotype.     

A point mutation in a type I procollagen gene converts glycine 748 of the alpha 1 chain to cysteine and destabilizes the triple helix in a lethal variant of osteogenesis imperfecta

Synthesis of type I procollagen was examined in fibroblasts from a proband with a lethal perinatal variant of osteogenesis imperfecta. After trypsin digestion of the type I procollagen, a portion of the alpha 1 (I) chains was recovered as disulfide-linked dimers. Digestion of the protein with vertebrate collagenase and mapping of cyanogen bromide peptides suggested that a new cysteine residue was present between residues 551 and 775 of the alpha 1 (I) chain. Sequencing of cloned cDNAs prepared using mRNA from the proband's fibroblasts demonstrated that some of the clones contained a single base mutation that converted the glycine codon in amino acid position 748 of the alpha 1 (I) chain to a cysteine codon. About 80% of the type I procollagen synthesized by the proband's fibroblasts had a decreased thermal stability. The results, therefore, were consistent with the conclusion that normal pro-alpha 1 (I) chains and pro-alpha 1 (I) chains containing a cysteine residue in the alpha chain domain were synthesized in about equal amounts and incorporated randomly into type I procollagen. However, only about 10% of the alpha 1 (I) chains generated by trypsin digestion were disulfide-linked. Further studies demonstrated a decreased rate of secretion of type I procollagen containing the new cysteine residue and decreased processing of the protein by procollagen N-proteinase in cultures of postconfluent fibroblasts. Both parents were phenotypically normal and their fibroblasts synthesized only normal type I procollagen. Therefore, the mutation in the proband was a sporadic one and is very likely to have caused the connective tissue fragility that produced the lethal phenotype.     

A substitution of cysteine for glycine 748 of the alpha 1 chain produces a kink at this site in the procollagen I molecule and an altered N-proteinase cleavage site over 225 nm away

In previous work (Vogel, B. E., Minor, R. R., Freund, M., and Prockop, D. J. (1987) J. Biol. Chem. 262, 14737-14744), we identified a single-base mutation that converted the glycine at position 748 of the alpha 1 chain of type I procollagen to a cysteine in a proband with a lethal variant of osteogenesis imperfecta. In addition to posttranslational overmodification, the abnormal molecules displayed decreased thermal stability and a decreased rate of secretion. An unexplained finding was that procollagen was poorly processed to pCcollagen in postconfluent cultures of skin fibroblasts. Here, we show that the procollagen synthesized by the proband's cells is resistant to cleavage by procollagen N-proteinase, a conformation-sensitive enzyme. Since the only detectable defect in the molecule was the cysteine for glycine substitution, we assembled several space-filling models to try to explain how the structure of the N-proteinase cleavage site can be affected by an amino acid substitution over 700 amino acid residues or 225 nm away. The models incorporated a phase shift of a tripeptide unit in one or both of the alpha 1 chains. The most satisfactory models produced a flexible kink of 30 degrees or 60 degrees at the site of the cysteine substitution. Therefore, we examined the procollagen by electron microscopy. About 25% of the molecules had a kink not seen in control samples, and the kink was at the site of the cysteine substitution.     

A tripeptide deletion in the triple-helical domain of the pro alpha 1(I) chain of type I procollagen in a patient with lethal osteogenesis imperfecta does not alter cleavage of the molecule by N-proteinase.

Dermal fibroblasts from a fetus with perinatal lethal osteogenesis imperfecta synthesized normal and abnormal type I procollagen molecules. The abnormal molecules contained one or two pro alpha 1(I) chains in which glycine, alanine, and hydroxyproline at positions 874, 875, and 876 in the triple-helical region were deleted as the result of a 9-base pair genomic deletion. Molecules that contained abnormal chains were overmodified from the site of the deletion toward the amino-terminal region of the molecule. Secretion of the overmodified molecules was impaired. The thermal stability of molecules containing abnormal chains was lower than that of normally modified molecules. After cleavage of molecules with vertebrate collagenase, the temperature of thermal denaturation of the overmodified A fragments was greater than that of the fragments from the normal molecules. The rates of cleavage of the normal and the abnormal molecules by N-proteinase were indistinguishable. Our findings suggest that the tripeptide deletion introduces a shift in the phase of the chains in the triple helix. This structural change is propagated from the site of the deletion toward the amino terminus of the molecule, but the subsequent alteration in the structure of the N-proteinase cleavage site is not sufficient to cause a decrease in the rate of cleavage by the enzyme.     

The molecular defect in an autosomal dominant form of osteogenesis imperfecta. Synthesis of type I procollagen containing cysteine in the triple-helical domain of pro-alpha 1(I) chains

Synthesis of procollagen was examined in skin fibroblasts from a patient with a moderately severe autosomal dominant form of osteogenesis imperfecta. Proteolytic removal of the propeptide regions of newly synthesized procollagen, followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing conditions, revealed the presence of type I collagen in which two alpha 1(I) chains were linked through interchain disulfide bonds. Fragmentation of the disulfide-bonded alpha 1(I) dimers with vertebrate collagenase and cyanogen bromide demonstrated the presence of a cysteine residue in alpha 1(I)CB8, a fragment containing amino acid residues 124-402 of the alpha 1(I) collagen chain. Cysteine residues are not normally found in the triple-helical domain of type I collagen chains. The heterozygous nature of the molecular defect resulted in the formation of three kinds of type I trimers: a normal type with normal pro-alpha(I) chains, a type I trimer with one mutant pro-alpha 1(I) chain and two normal chains, and a type I trimer containing two mutant pro-alpha 1(I) chains and one normal pro-alpha 2(I) chain. The presence of one or two mutant pro-alpha 1(I) chains in trimers of type I procollagen was found to reduce the thermal stability of the protein by 2.5 and 1 degree C, respectively. In addition to post-translational overmodification, procollagen containing one mutant pro-alpha 1(I) chain was also cleared more slowly from cultured fibroblasts. The most likely explanation for these disruptive changes in the physical stability and secretion of the mutant procollagen is that a cysteine residue is substituted for a glycine in half of the pro-alpha 1(I) chains synthesized by the patient's fibroblasts.     

Type I procollagen N-proteinase from chick embryo tendons. Purification of a new 500-kDa form of the enzyme and identification of the catalytically active polypeptides

Procollagen N-proteinase (EC 3.4.24.14), the enzyme that cleaves the NH2-terminal propeptides from type I procollagen, was purified over 20,000-fold with a yield of 12% from extracts of 17-day-old chick embryo tendons. The procedure involved precipitation with ammonium sulfate, adsorption on concanavalin A-Sepharose, and five additional column chromatographic steps. The purified enzyme was a neutral, Ca2+-dependent proteinase (5-10 mM) that was inhibited by metal chelators. It had a molecular mass of 500 kDa as determined by gel filtration. The enzyme contained unreduced polypeptides of 61, 120, 135, and 161 kDa that were separated by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. The 135- and 161-kDa polypeptides were catalytically active after elution from the polyacrylamide gel. Other properties of 500-kDa enzyme are: 1) the Km for type I procollagen is 54 nM at pH 7.5 and 35 degrees C, and the kappa cat is 350 h-1; 2) the activation energy for reaction with type I procollagen is 7,100 cal mol-1; 3) the isoelectric point is 3.6; and 4) the enzyme specifically cleaves the NH2-terminal propeptides of type I and II procollagen, but not of type III procollagen. A minor form of N-proteinase with a 300-kDa mass was also purified and was found to contain a 90-kDa polypeptide as the major active polypeptide. The enzyme appeared to be a degraded form of the 500-kDa N-proteinase. The properties of the 300-kDa enzyme were similar to those observed for the 500-kDa enzyme.