Substitution of serine for alpha 1(I)-glycine 844 in a severe variant of osteogenesis imperfecta minimally destabilizes the triple helix of type I procollagen. The effects of glycine substitutions on thermal stability are either position of amino acid specific

Recent reports have demonstrated that a series of probands with severe osteogenesis imperfecta had single base mutations in one of the two structural genes for type I procollagen that substituted amino acids with bulkier side chains for glycine residues and decreased the melting temperature of the triple helix. Here we demonstrate that the type I procollagen synthesized by cultured fibroblasts from a proband with a severe form of osteogenesis imperfecta consisted of normal molecules and molecules over-modified by post-translational reactions. The thermal stability of the intact type I collagen was normal as assayed by protease digestion under conditions in which a decrease in thermal stability was previously observed with eight other substitutions for glycine in the alpha 1(I) chain. In contrast, the thermal stability of the one-quarter length B fragment generated by digestion with vertebrate collagenase was decreased by 2-3 degrees C under the same conditions. Nucleotide sequencing of cDNAs and genomic DNA established that the proband had a substitution of A for G in one allele of the pro alpha 1(I) gene that converted the codon for alpha 1-glycine 844 to a codon for serine. The results also established that the alpha 1-serine 844 was the only mutation that could account for the decrease in thermal stability of the collagenase B fragment. There are at least two possible explanations for the failure of the alpha 1-serine 844 substitution to decrease the thermal stability of the collagen molecule whereas eight similar mutations decreased the melting temperature. One possibility is that the effects of glycine substitutions are position specific because not all glycine residues make equivalent contributions to cooperative blocks of the triple helix that unfold in the predenaturation range of temperatures. A second possible explanation is that substitutions of glycine by serine have much less effect on the stability of protein than the substitutions by arginine, cysteine, and aspartate previously studied.     

A single base mutation that converts glycine 907 of the alpha 2(I) chain of type I procollagen to aspartate in a lethal variant of osteogenesis imperfecta. The single amino acid substitution near the carboxyl terminus destabilizes the whole triple helix

Type I procollagen was examined in cultured skin fibroblasts from a patient with a lethal variant of osteogenesis imperfecta. About half of the pro-alpha chains were post-translationally overmodified and had a decreased thermal stability. The vertebrate collagenase A fragment had a normal thermal stability, but the B fragment had a decreased thermal stability. Therefore, there was a change in primary structure in amino acids 776-1014 of either the alpha 1(I) or alpha 2(I) chain. Three of five cDNA clones for the alpha 2(I) chain contained a single-base substitution of an A for a G that converted the codon for glycine at amino acid position 907 to aspartate. Complete nucleotide sequencing of bases coding for amino acids 776 to 1014 of the alpha 2(I) chain was carried out in one cDNA clone that contained the mutation in the glycine codon and in one that did not. Also, nucleotide sequencing was performed of bases coding for amino acids 776-1014 of the alpha 1(I) chain in seven independent cDNA clones. No other mutations were found. Therefore, the single base substitution that converts glycine 907 in the alpha 2(I) chain to aspartate is solely responsible for the decreased thermal stability of the type I procollagen synthesized by the proband's fibroblasts. Also, glycine 907 of the alpha 2(I) chain is an important component of a cooperative block that determines the melting temperature of the whole molecule.     

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.     

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.     

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.     

Deletion of the pro-alpha 1(I) N-propeptide affects secretion of type I collagen in Chinese hamster lung cells but not in Mov-13 mouse cells.

We have introduced two mutations into a full-length human pro-alpha 1(I) cDNA that delete 114 amino acids or the entire 139 amino acids of the N-propeptide domain. Wild-type and mutated versions of the cDNA were introduced into cultured Chinese hamster lung (CHL) cells, which do not produce endogenous type I collagen, and into Mov-13 mouse cells, which produce endogenous pro-alpha 2(I) chains but not pro-alpha 1(I) chains. As judged by resistance to proteases, neither mutation impaired intracellular triple helical assembly of human alpha 1(I) homotrimers in CHL cells, or of chimeric type I collagen comprised of human alpha 1(I) and mouse alpha 2(I) chains in Mov-13 cells. Thus, the N-propeptide is not necessary for intracellular assembly of the main helical collagen domain of type I collagen. In CHL cells the rate of secretion of the mutant homotrimers was greatly reduced as compared to wild type homotrimers, and by immunofluorescence and immunoelectron microscopy, the mutant chains were shown to be accumulated in large vesicular expansions of the rough endoplasmic reticulum. When such cells were retransfected with cDNA encoding wild-type human alpha 2(I) chains, mutant alpha 1(I) chains were not rescued and heterotrimers containing the mutant chains were also retained in the intracellular vesicles. By contrast, deletion of the N-propeptide did not affect secretion of heterotrimers containing mutant chains from Mov-13 cells. Thus, an intact N-propeptide appears necessary for efficient secretion of type I collagen from some but not all cell types.     

The alpha 2 beta 1 integrin cell surface collagen receptor binds to the alpha 1 (I)-CB3 peptide of collagen

We have previously shown that platelets adhere to collagen substrates via a Mg2(+)-dependent mechanism mediated by the surface glycoprotein Ia-IIa (human leukocyte very late activation protein 2, alpha 2 beta 1 integrin) complex. The adhesion is specific for collagen and is supported by collagen types I, II, III, IV, and VI. Several other members of the integrin family of adhesive protein receptors recognize discrete linear amino acid sequences within their adhesive glycoprotein ligands. Experiments with both intact platelets and with liposomes containing the purified receptor complex indicated that the alpha 2 beta 1 receptor recognized denatured type I collagen in a Mg2(+)-dependent manner. To further localize the binding site, the alpha 1 and alpha 2 chains of type I collagen were purified by gel filtration and ion exchange chromatography and tested as adhesive substrates. Both the alpha 1(I) and alpha 2(I) chains effectively supported Mg2(+)-dependent platelet adhesion. The purified alpha 1(I) collagen chain was then subjected to cleavage with cyanogen bromide, and the resultant peptides were separated by chromatography on carboxymethylcellulose. Only the alpha 1(I)-CB3 fragment supported Mg2(+)-dependent platelet adhesion. The monoclonal antibody P1H5 which recognizes an epitope on the alpha 2 subunit of the integrin receptor and which inhibits the adhesion of both intact platelets and liposomes bearing the purified receptor to collagen also inhibited platelet adhesion to the alpha 1(I)-CB3 fragment. These results indicate that the alpha 2 beta 1 receptor recognizes a sequence of amino acids present in the alpha 1(I)-CB3 fragment of type I collagen. An identical or similar sequence likely mediates binding of the receptor to other collagen polypeptides.     

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.     

Altered triple helical structure of type I procollagen in lethal perinatal osteogenesis imperfecta

Cultured dermal fibroblasts from an infant with the lethal perinatal form of osteogenesis imperfecta (type II) synthesize normal and abnormal forms of type I procollagen. The abnormal type I procollagen molecules are excessively modified during their intracellular stay, have a lower than normal melting transition temperature, are secreted at a reduced rate, and form abnormally thin collagen fibrils in the extracellular matrix in vitro. Overmodification of the abnormal type I procollagen molecules was limited to the NH2-terminal three-fourths of the triple helical domain. Two-dimensional mapping of modified and unmodified alpha chains of type I collagen demonstrated neither charge alterations nor large insertions or deletions in the region of alpha 1(I) and alpha 2(I) in which overmodification begins. Both the structure and function of type I procollagen synthesized by cells from the parents of this infant were normal. The simplest interpretation of the results of this study is that the osteogenesis imperfecta phenotype arose from a new dominant mutation in one of the genes encoding the chains of type I procollagen. Given the requirement for glycine in every third position of the triple helical domain, the mutation may represent a single amino acid substitution for a glycine residue. These findings demonstrate further heterogeneity in the biochemical basis of osteogenesis imperfecta type II and suggest that the nature and location of mutations in type I procollagen may determine phenotypic variation.     

Structure of cDNA clones coding for the entire prepro alpha 1 (III) chain of human type III procollagen. Differences in protein structure from type I procollagen and conservation of codon preferences.

Two overlapping cDNA clones that cover the complete length of the mRNA for human type III procollagen were characterized. The data provided about 2500 base pairs of sequence not previously defined for human type III procollagen. Two tripeptide sequences of -Gly-Xaa-Yaa- were identified that were not detected previously by amino acid sequencing of human type III collagen. The two additional tripeptide units, together with three previously detected, establish that the alpha 1 (III) chain is 15 amino acids longer than either the alpha 1 (I) or alpha 2 (I) chains of type I collagen. The additional tripeptide units made hydropathy plots of the N-terminal and C-terminal regions of type III collagen distinctly different from those of type I collagen. The data also demonstrated that human type III procollagen has the same third base preference in codons for glycine, proline and alanine that was previously found with human and chick type I procollagen. In addition, comparison of two cDNA clones from the same individual revealed a variation in structure in that the codon for amino acid 880 of the alpha 1 (III) chain was -CTT- for leucine in one clone and -TTT- for phenylalanine in the other.     

Complete primary structure of rainbow trout type I collagen consisting of alpha1(I)alpha2(I)alpha3(I) heterotrimers.

The subunit compositions of skin and muscle type I collagens from rainbow trout were found to be alpha1(I)alpha2(I)alpha3(I) and [alpha1(I)](2)alpha2(I), respectively. The occurrence of alpha3(I) has been observed only for bonyfish. The skin collagen exhibited more susceptibility to both heat denaturation and MMP-13 digestion than the muscle counterpart; the former had a lower denaturation temperature by about 0.5 degrees C than the latter. The lower stability of skin collagen, however, is not due to the low levels of imino acids because the contents of Pro and Hyp were almost constant in both collagens. On the other hand, some cDNAs coding for the N-terminal and/or a part of triple-helical domains of proalpha(I) chains were cloned from the cDNA library of rainbow trout fibroblasts. These cDNAs together with the previously cloned collagen cDNAs gave information about the complete primary structure of type I procollagen. The main triple-helical domain of each proalpha(I) chain had 338 uninterrupted Gly-X-Y triplets consisting of 1014 amino acids and was unique in its high content of Gly-Gly doublets. In particular, the bonyfish-specific alpha(I) chain, proalpha3(I) was characterized by the small number of Gly-Pro-Pro triplets, 19, and the large number of Gly-Gly doublets, 38, in the triple-helical domain, compared to 23 and 22, respectively, for proalpha1(I). The small number of Gly-Pro-Pro and the large number of Gly-Gly in proalpha3(I) was assumed to partially loosen the triple-helical structure of skin collagen, leading to the lower stability of skin collagen mentioned above. Finally, phylogenetic analyses revealed that proalpha3(I) had diverged from proalpha1(I). This study is the first report of the complete primary structure of fish type I procollagen.     

A critical crosslink region in human-bone-derived collagen type I. Specific cleavage site at residue Leu95

Collagen was extracted from human adult bone by limited pepsin digestion and collagen types were purified by consecutive salt precipitation first under neutral and then under acid conditions. In SDS/PAGE, all collagen type I preparations showed a protein band [alpha 1s(I)] migrating between alpha 1(I) and alpha 2(I) as well as a band [alpha 2s(I)] migrating in front of alpha 2(I). The collagenous nature of the pepsin-stable alpha 1s(I) protein was clearly demonstrated by digestion with human-leucocyte-derived collagenase, immunoblotting with antibodies against collagen type I and amino acid analysis. Partial amino acid sequencing of alpha 1(I) and alpha 1s(I) identified alpha 1s(I) as a shortened alpha 1(I) chain due to a specific cleavage site between residues Leu95 and Asp96 which is in close vicinity to the hydroxylysine-derived crosslink at position 87. In circular dichroism, the proportion of thermally labile collagen molecules was proportional to the amount of shortened alpha 1(I) and alpha 2(I) chains, respectively. The melting temperature was found to be 36 +/- 0.5 degrees C as judged from circular dichroism and susceptibility to proteolysis. Our data provide clear evidence that a shortened alpha 1-derived collagen chain can be extracted from human adult bone whereas it is hardly found in human skin. The unique cleavage site might provide important information about the collagen I molecule embedded in the calcified matrix of human bone.     

A heterozygous collagen defect in a variant of the Ehlers-Danlos syndrome type VII. Evidence for a deleted amino-telopeptide domain in the pro-alpha 2(I) chain

A structural defect in the alpha 2(I) chain of type I collagen was characterized in a new case of the Ehlers-Danlos syndrome type VII. The patient's skin, fascia, and bone collagens all showed an abnormal additional chain, pN-alpha 2(I)s, running slower than the alpha 2(I) chain on electrophoresis. The extension was shown to be on the amino-terminal fragment of pN-alpha (I)s by cleavage with human collagenase, but pepsin was unable to convert pN-alpha 2(I)s to alpha 2(I). Skin collagen was 4-fold more extractable and contained fewer beta-dimers and a lower concentration of cross-linking amino acids than control skin collagen. Electron micrographs of both dermis and bone showed markedly irregular ragged outlines of the collagen fibrils in cross-section, although the patient had no clinical signs of bone disease. Procollagen secreted by her skin fibroblasts in culture showed equal amounts of the normal and abnormal alpha 2(I) chains on pepsin digestion. Before pepsin, the pN-alpha 2(I) component ran as a doublet on electrophoresis; pepsin removed only the normal slower chain. The suspected deletion in pN-alpha 2(I)s was traced by CNBr peptide analysis to the N-propeptide fragment, which behaved on electrophoresis about 15-20 residues smaller than that from the normal pN-alpha 2(I) chain. The simplest genetic explanation is a spontaneous heterozygote in which one normal and one abnormal allele for the pro-alpha 2(I) gene are expressed, the protein defect being a deletion of the junction domain that spans the N-propeptidase cleavage site and the N-telopeptide cross-linking sequence.     

Isolation and characterization of pepsin-treated type III collagen from calf skin.

Calf skin collagen was solubilized by incubating acid-extracted calf skin with pepsin at pH 2.0 and 25 degrees C, conditions that did not cause degradation of the triple helical region of collagen. Type III collagen was separated from type I collagen by differential salt precipitation at pH 7.5. The isolated type III collagen contained mainly gamma and higher molecular weight components cross-linked by reducible and/or non-reducible bonds. The isolated alpha1 (III) chains had an amino acid composition characteristic of type III collagen. Denatured but unreduced type III collagen, chromatographed on carboxymethyl-cellulose, eluted in the alpha 2 region, while after reduction and alkylation the alpha1 (III) chains eluted between the positions of alpha1 (I) and alpha2. The mid-point melting temperature temperature (tm) of type III collagen (35.1 degrees C) in a citrate buffer at pH 3.7 was somewhat lower than that of type I collagen (35.9 degrees C). Renaturation experiments at 25 degrees C showed that denatured type III collagen molecules with intact intramolecular disulfide bridges (gamma components) reform the triple helical structure of collagen much faster than reduced and carboxymethylated alpha1 (III) chains.     

A novel mutation causes a perinatal lethal form of osteogenesis imperfecta. An insertion in one alpha 1(I) collagen allele (COL1A1)

We have identified an infant with the perinatal lethal form of osteogenesis imperfecta (type II) whose cells synthesize in equal amounts two different pro alpha 1(I) chains of type I procollagen: one chain is normal in length, the other contains an insertion of approximately 50-70 amino acid residues within the triple helical domain defined by amino acids 123-220. The structure of the insertion is consistent with duplication of an approximately 600-base pair segment in one allele of the alpha 1(I) gene (COL1A1). These cells synthesize normal type I procollagen molecules as well as molecules that contain one or two mutant chains. Unlike type I procollagen molecules synthesized by cells from most other infants with osteogenesis imperfecta type II which contain increased lysyl hydroxylation and hydroxylysyl glycosylation along the triple helical domain, the abnormal molecules synthesized by these cells are not overmodified. The lethal effect of this mutation may result from secretion of about one-quarter the normal amount of normal type I procollagen and secretion of a large amount of a molecule which has a lowered melting temperature, is extended asymmetrically, and which has altered structure in domains important for cross-link formation and bone mineralization.     

Fibronectin binding site in type I collagen regulates fibronectin fibril formation

Mov13 fibroblasts, which do not express endogenous alpha 1(I) collagen chains due to a retroviral insertion, were used to study the role of type I collagen in the process of fibronectin fibrillogenesis. While Mov13 cells produced a sparse matrix containing short fibronectin fibrils, transfection with a wild type pro alpha 1(I) collagen gene resulted in the production of an extensive matrix containing fibronectin fibrils of normal length. To study the amino acids involved in the fibronectin-collagen interaction, mutations were introduced into the known fibronectin binding region of the pro alpha 1(I) collagen gene. Substitution of Gln and Ala at positions 774 and 777 of the alpha 1(I) chain for Pro resulted in the formation of short fibronectin fibrils similar to what was observed in untransfected Mov13 cells. Type I collagen carrying these substitutions bound weakly to fibronectin- sepharose and could be eluted off with 1 M urea. The effect of this mutation on fibronectin fibrillogenesis could be rescued by adding either type I collagen or a peptide fragment (CB.7) which contained the wild type fibronectin binding region of the alpha 1(I) chain to the cell culture. These results suggest that fibronectin fibrillogenesis in tissue culture is dependent on type I collagen synthesis, and define an important role for the fibronectin binding site in this process.     

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.     

Discrete reduction of type I collagen thermal stability upon oxidation

The oxidation of acid-soluble calf skin collagen type I caused by metal-dependent free radical generating systems, Fe(II)/H2O2 and Cu(II)/H2O2, was found to bring down in a specific, discrete way the collagen thermal stability, as determined by microcalorimetry and scanning densitometry. Initial oxidation results in splitting of the collagen denaturational transition into two components. Along with the endotherm at 41 degrees C typical for non-oxidized collagen, a second, similarly cooperative endotherm appears at 35 degrees C and increases in enthalpy with the oxidant concentration and exposure time, while the first peak correspondingly decreases. The two transitions at 35 and 41 degrees C were registered by densitometry as stepwise increases of the collagen-specific volume. Further oxidation results in massive collagen destruction manifested as abolishment of both denaturational transitions. The two oxidative systems used produce identical effects on the collagen stability but at higher concentrations of Cu(II) in comparison to Fe(II). The discrete reduction of the protein thermal stability is accompanied by a decrease of the free amino groups, suggestive of an oxidation attack of the side chains of lysine residues. Since the denaturation temperature of collagen shifts from above to below body temperature (41 degrees C-35 degrees C) upon oxidation, it appears important to account for this effect in a context of the possible physiological implications of collagen oxidation.