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.     

Abnormal type I collagen metabolism by cultured fibroblasts in lethal perinatal osteogenesis imperfecta.

Cultured skin fibroblasts from seven consecutive cases of lethal perinatal osteogenesis imperfecta (OI) expressed defects of type I collagen metabolism. The secretion of [14C]proline-labelled collagen by the OI cells was specifically reduced (51-79% of control), and collagen degradation was increased to twice that of control cells in five cases and increased by approx. 30% in the other two cases. Sodium dodecyl sulphate/polyacrylamide-gel electrophoresis revealed that four of the OI cell lines produced two forms of type I collagen consisting of both normally and slowly migrating forms of the alpha 1(I)- and alpha 2(I)-chains. In the other three OI cell lines only the 'slow' alpha (I)'- and alpha 2(I)'-chains were detected. In both groups inhibition of the post-translational modifications of proline and lysine resulted in the production of a single species of type I collagen with normal electrophoretic migration. Proline hydroxylation was normal, but the hydroxylysine contents of alpha 1(I)'- and alpha 2(I)'-chains purified by h.p.l.c. were greater than in control alpha-chains. The glucosylgalactosylhydroxylysine content was increased approx. 3-fold while the galactosylhydroxylysine content was only slightly increased in the alpha 1(I)'-chains relative to control alpha 1(I)-chains. Peptide mapping of the CNBr-cleavage peptides provided evidence that the increased post-translational modifications were distributed throughout the alpha 1(I)'- and alpha 2(I)'-chains. It is postulated that the greater modification of these chains was due to structural defects of the alpha-chains leading to delayed helix formation. The abnormal charge heterogeneity observed in the alpha 1 CB8 peptide of one patient may reflect such a structural defect in the type I collagen molecule.     

Physical activity in youth with osteogenesis imperfecta type I

Introduction:

Individuals with Osteogenesis Imperfecta (OI) type I often show muscular weakness. However, it is unclear whether muscular weakness is a consequence of physical inactivity or a result of the disease itself. The aim was to assess muscle function in youth with OI type I and evaluate physical activity (PA).

Methods:

Fourteen children with OI type I (mean age [SD]: 12.75 [4.62] years) were compared to 14 age- and gender-matched controls (mean age [SD]: 12.75 [4.59] years). Muscle force and power were determined through mechanography. PA and daily energy expenditure were measured with an accelerometer and a questionnaire.

Results:

Compared to controls, children with OI type I had lower muscle force and power. OI type I children were as active as their healthy counterparts.

Conclusions:

Children and adolescents with OI type I and their healthy counterparts did not reached daily recommendations of PA. Given their muscle function deficit, youth with OI type I would benefit to reach these recommendations to prevent precocious effect of aging on muscles.     

Analysis of cyanogen bromide peptides of type I collagen from a patient with lethal osteogenesis imperfecta.

The CNBr peptides of type I collagen from bone of a patient with lethal osteogenesis imperfecta and age-matched controls were isolated by molecular-sieve chromatography and their amino acid compositions were determined. No differences were found between the compositions of the peptides from the patient and those from the controls, except for an increase in the degree of hydroxylation of lysine in all peptides from the patient. Type I collagen CNBr peptides from chick-embryo skin [Barnes, Constable Morton & Kodicek (1971) Biochem. J. 125, 925--928] and guinea-pig scar tissue [Shuttleworth, Forrest & Jackson (1975) Biochim. Biophys. Acta 379, 207--216] also have an increased degree of hydroxylation of lysine with an otherwise normal amino acid composition, and it was believed that this could be an embryonic form of collagen. As a similar collagen was present in the bones of the patient studied, it seems possible that the same 'embryonic' collagen is synthesized during development, in repair process and also in genetic disorders of collagen metabolism.     

Altered processing of alpha (I) collagen in a case of lethal osteogenesis imperfecta

Cultured skin fibroblasts from a newborn with the lethal perinatal form of Osteogenesis imperfecta synthesized an over-hydroxylated form of pro alpha 1 (I) chain. The analysis of the CNBr peptides showed that over-hydroxylation occurred all along the molecule.     

Studies on type I collagen in skin fibroblasts cultured from twins with lethal osteogenesis imperfecta

Studies on type I procollagen produced by skin fibroblasts cultured from twins with lethal type II of osteogenesis imperfecta (OI) showed that biosynthesis of collagen (measured by L-[5-(3)H]proline incorporation into proteins susceptible to the action of bacterial collagenase) was slightly increased as compared to the control healthy infant. SDS/PAGE showed that the fibroblasts synthesized and secreted only normal type I procollagen. Electrophoretic analysis of collagen chains and CNBr peptides showed the same pattern of electrophoretic migration as in the controls. The lack of posttranslational overmodification of the collagen molecule suggested a molecular defect near the amino terminus of the collagen helix. Digestion of OI type I collagen with trypsin at 30 degrees C for 5 min generated a shorter than normal alpha2 chain which melted at 36 degrees C. Direct sequencing of an asymmetric PCR product revealed a heterozygous single nucleotide change C-->G causing a substitution of histidine by aspartic acid in the alpha2 chain at position 92. Pericellular processing of type I procollagen by the twin's fibroblasts yielded a later appearance of the intermediate pC-alpha1(I) form as compared with control cells.     

Type I procollagen in the severe non-lethal form of osteogenesis imperfecta

Summary We have screened type I procollagen synthesized in vitro by skin fibroblasts from several patients with the severe non-lethal form of osteogenesis imperfecta. Cells from one patient synthesized and secreted both normal and a larger amount of abnormal type I procollagen. The abnormal alpha chains are larger in size due to post-translational overmodifications involving the whole triple helical domain. Abnormal collagen heterotrimers had a melting temperature 2.5°–3°C lower than normal ones or from controls. Chemical analysis of collagen in the medium showed a greater degree of both lysyl hydroxylation and hydroxylysyl glycosylation, the major increase in molecular mass of overmodified alpha chains being due to the higher hydroxylysine-bound hexose content. The proband's cells modify proteoglycan metabolism and mineral proband's cells modify proteoglycan metabolism and mineral crystals form in the dermis, possibly a response to abnormal collagen-proteoglycan interactions. These findings can be explained by a small defect in the product of one allele for pro-1(I) chains: three-quarters of the synthesized type I procollagen molecules are composed of trimers containing one or two chains defective near the C-terminus of the triple helix or in the C-propeptide. The data obtained for this patient confirmed that the severity of clinical manifestations in osteogenesis imperfecta strongly depends on the location and nature of the mutations, and that the phenotype could be a consequence of a collagen defect(s) and its influence on collagen-collagen interactions and collagen interactions with other connective tissue components.     

Collagen defects in lethal perinatal osteogenesis imperfecta.

Quantitative and qualitative abnormalities of collagen were observed in tissues and fibroblast cultures from 17 consecutive cases of lethal perinatal osteogenesis imperfecta (OI). The content of type I collagen was reduced in OI dermis and bone and the content of type III collagen was also reduced in the dermis. Normal bone contained 99.3% type I and 0.7% type V collagen whereas OI bone contained a lower proportion of type I, a greater proportion of type V and a significant amount of type III collagen. The type III and V collagens appeared to be structurally normal. In contrast, abnormal type I collagen chains, which migrated slowly on electrophoresis, were observed in all babies with OI. Cultured fibroblasts from five babies produced a mixture of normal and abnormal type I collagens; the abnormal collagen was not secreted in two cases and was slowly secreted in the others. Fibroblasts from 12 babies produced only abnormal type I collagens and they were also secreted slowly. The slower electrophoretic migration of the abnormal chains was due to enzymic overmodification of the lysine residues. The distribution of the cyanogen bromide peptides containing the overmodified residues was used to localize the underlying structural abnormalities to three regions of the type I procollagen chains. These regions included the carboxy-propeptide of the pro alpha 1(I)-chain, the helical alpha 1(I) CB7 peptide and the helical alpha 1(I) CB8 and CB3 peptides. In one baby a basic charge mutation was observed in the alpha 1(I) CB7 peptide and in another baby a basic charge mutation was observed in the alpha 1(I) CB8 peptide. The primary defects in lethal perinatal OI appear to reside in the type I collagen chains. Type III and V collagens did not appear to compensate for the deficiency of type I collagen in the tissues.     

Dental findings in osteogenesis imperfecta: I. Occurrence and expression of type I dentinogenesis imperfecta

Sixty-eight patients with osteogenesis imperfecta (OI) classified according to Sillence were evaluated for dentinogenesis imperfecta (DI). Orthopantomograms of 51 of the 68 were examined. Type I DI was recognized in 22 patients from 16 families. DI was observed in 4/45 patients with type I OI, in one of two patients with type III, and in 13/16 patients with type IV OI. Four of the five patients with an unidentified type of OI had DI. The expression of type I DI was variable. Discoloration and pulpal obliteration were the major manifestations. Teeth from 14 patients from 12 families were studied histologically. Eight of the 14 patients were from six families who had clinical and/or radiographic evidence of DI. Irregularity of the dentin matrix and tubular pattern in the circumpulpal dentin and normal mantle dentin were observed. Interfamilial variability was greater than intrafamilial variability. The expression of DI was mild in one family with type I OI. There was no further relation between the type of OI and the severity of DI.     

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.     

Transgenic mice that express a mini-gene version of the human gene for type I procollagen (COL1A1) develop a phenotype resembling a lethal form of osteogenesis imperfecta.

A mini-gene version of the human gene for a pro-alpha 1(I) chain of type I procollagen (COL1A1) was prepared that contained -2.5 kilobases of the promoter region and the 5'- and 3'-ends of the gene but lacked a large central region containing 41 exons. The construct was modeled after a sporadic in-frame deletion of the human gene that produced a lethal variant of osteogenesis imperfecta, because it caused synthesis of shortened pro-alpha 1(I) chains that associated with normal pro-alpha 1(I) and pro-alpha 2(I) chains and caused degradation of both the shortened and normal pro-alpha chains through a process called procollagen suicide. The mini-gene was used to prepare transgenic mice. Eight of 15 transgenic mice expressed varying levels of the gene. All except one of the Fo founders were phenotypically normal, but several of the founders were apparently mosaic since they produced F1 progeny that died shortly after birth with a distinctive phenotype. The phenotype included extensive fractures of ribs and long bones similar to the fractures seen in lethal variants of osteogenesis imperfecta. Mice with the lethal phenotype expressed much higher levels of the mini-gene than transgenic mice without the lethal phenotype. Experiments with cultured skin fibroblasts from the transgenic mice demonstrated that shortened pro-alpha 1(I) chains synthesized from the mini-gene became disulfide-linked to pro-alpha 1(I) chains synthesized from the endogenous mouse gene. The results demonstrate that a mutated type I procollagen gene based on the model of procollagen suicide can be used to produce a severe phenotype of osteogenesis imperfecta that is genetically transmitted.     

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.     

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.     

Defective C-propeptides of the proalpha2(I) chain of type I procollagen impede molecular assembly and result in osteogenesis imperfecta

Type I procollagen is a heterotrimer composed of two proalpha1(I) chains and one proalpha2(I) chain, encoded by the COL1A1 and COL1A2 genes, respectively. Mutations in these genes usually lead to dominantly inherited forms of osteogenesis imperfecta (OI) by altering the triple helical domains, but a few affect sequences in the proalpha1(I) C-terminal propeptide (C-propeptide), and one, which has a phenotype only in homozygotes, alters the proalpha2(I) C-propeptide. Here we describe four dominant mutations in the COL1A2 gene that alter sequences of the proalpha2(I) C-propeptide in individuals with clinical features of a milder form of the disease, OI type IV. Three of the four appear to interfere with disulfide bonds that stabilize the C-propeptide conformation and its interaction with other chains in the trimer. Cultured cells synthesized proalpha2(I) chains that were slow to assemble with proalpha1(I) chains to form heterotrimers and that were retained intracellularly. Some alterations led to the uncharacteristic formation of proalpha1(I) homotrimers. These findings show that the C-propeptide of proalpha2(I), like that of the proalpha1(I) C-propeptide, is essential for efficient assembly of type I procollagen heterotrimers. The milder OI phenotypes likely reflect a diminished amount of normal type I procollagen, small populations of overmodified heterotrimers, and proalpha1(I) homotrimers that are compatible with normal skeletal growth.     

Glucocorticoids decrease the synthesis of type I procollagen mRNAs

Glucocorticoids selectively decrease procollagen synthesis in animal and human skin fibroblasts. beta-Actin content and beta-actin mRNA are not affected by glucocorticoid treatment of chick skin fibroblasts. The inhibitory effect of glucocorticoids on procollagen synthesis is associated with a decrease in total cellular type I procollagen mRNAs in chick skin fibroblasts. These effects of dexamethasone are receptor mediated as determined by pretreatment with the glucocorticoid antagonists progesterone and RU-486 and with the agonist beta-dihydrocortisol. Dexamethasone has a small but significant inhibitory effect on cell growth of chick skin fibroblasts. The ability of this corticosteroid to decrease the steady-state levels of type I procollagen mRNAs in nuclei, cytoplasm, and polysomes varies. The largest decrease of type I procollagen mRNAs is observed in the nuclear and cytoplasmic subcellular fractions 24 h after dexamethasone treatment. Type I procollagen hnRNAs are also decreased as determined by Northern blot analysis of total nuclear RNA. The synthesis of total cellular type I procollagen mRNAs is reversibly decreased by dexamethasone treatment. In addition the synthesis of total nuclear type I procollagen mRNA sequences is decreased at 2, 4, and 24 h following the addition of radioactive nucleoside and dexamethasone to cell cultures. Although the synthesis of pro alpha 1(I) and pro alpha 2(I) mRNAs is decreased in dexamethasone-treated chick skin fibroblasts, the degradation of the total cellular procollagen mRNAs is not altered while the degradation of total cellular RNA is stabilized. These data indicate that the dexamethasone-mediated decrease of procollagen synthesis in embryonic chick skin fibroblasts results from the regulation of procollagen gene expression.     

RNA sequence analysis of a perinatal lethal osteogenesis imperfecta mutation

The perinatal lethal form of osteogenesis imperfecta often results from mutations which disrupt stable assembly, delay secretion, and cause excessive posttranslational modification of type I procollagen molecules. One such mutation was efficiently characterized by an indirect method of RNA sequence analysis. The mutation initially was localized in procollagen by mapping the distribution of abnormal posttranslational modification within the triple helical domain of mutant molecules. Total RNA was isolated from osteogenesis imperfecta cells in culture, cDNA was synthesized using alpha 1(I) and alpha 2(I) specific primers, and fragments of cDNA suspected to harbor the mutation were amplified by the polymerase chain reaction technique and then cloned in M13 vectors. Sequence analysis of the amplified cDNA revealed a new, heterozygous Gly----Val substitution at residue 256 of the triple helical domain of alpha 1(I) chains produced by the perinatal lethal osteogenesis imperfecta cells. The nature and location of the mutation were confirmed by sequence analysis of amplified genomic DNA. A Gly----Val substitution has not previously been associated with the lethal form of osteogenesis imperfecta, and this mutation has the most amino-terminal location within the alpha 1(I) chain triple helical domain reported to date.     

Incorporation of type I collagen molecules that contain a mutant alpha 2(I) chain (Gly580-->Asp) into bone matrix in a lethal case of osteogenesis imperfecta.

To understand more directly the tissue defect in osteogenesis imperfecta (OI), bone matrix was analyzed from an infant with lethal OI (type II) of defined mutation (collagen alpha 2(I)Gly580-->Asp). Pepsin-solubilized alpha 1(I) and alpha 2(I) chains and derived CNBr-peptides migrated more slowly on sodium dodecyl sulfate-polyacrylamide gel electrophoresis compared with normal human controls. The peptide alpha 2(I)CB3,5, predicted to contain the mutation site, ran as a retarded doublet band and was purified by high performance liquid chromatography and digested with V8 protease. Two peptides with amino-terminal sequences beginning at residue 576 of the alpha 2(I) chain were isolated. One had the normal sequence. The other differed in that aspartic acid replaced glycine at residue 580 as predicted from cDNA analysis, and in having an unhydroxylated proline at residue 579. From yields on microsequencing and the relative intensities of the two forms of alpha 2(I)CB3,5 on SDS-polyacrylamide gel electrophoresis, the ratio of mutant to normal alpha 2(I) chains in the infant's bone matrix was 0.7/1. Although the effects of an efficient incorporation of mutant chains on the properties of the bone matrix are unknown, it may be that in this OI case the tissue abnormalities result more from the presence of mutant protein than from an underexpression of matrix.     

Mutation characteristics in type I collagen genes in Chinese patients with osteogenesis imperfecta

Osteogenesis imperfecta is normally caused by an autosomal dominant mutation in the type I collagen genes COL1A1 and COL1A2. The severity of osteogenesis imperfecta varies, ranging from perinatal lethality to a very mild phenotype. Although there have been many reports of COL1A1 and COL1A2 mutations, few cases have been reported in Chinese people. We report on five unrelated families and three sporadic cases. The mutations were detected by PCR and direct sequencing. Four mutations in COL1A1 and one in COL1A2 were found, among which three mutations were previously unreported. The mutation rates of G>C at base 128 in intron 31 of the COL1A1 gene and G>A at base 162 in intron 30 of the COL1A2 gene were higher than normal. The patients' clinical characteristics with the same mutation were variable even in the same family. We conclude that mutations in COL1A1 and COL1A2 also have an important role in osteogenesis imperfecta in the Chinese population. As the Han Chinese people account for a quarter of the world's population, these new data contribute to the type I collagen mutation map.     

The molecular defect in a nonlethal variant of osteogenesis imperfecta. Synthesis of pro-alpha 2(I) chains which are not incorporated into trimers of type I procollagen

Cultured fibroblasts were examined from a patient with a nonlethal form of osteogenesis imperfecta. As reported previously (Nicholls, A. C., Pope, F. M., and Schloon, H. (1979) Lancet 1, 1193), the cells synthesized and secreted a type I procollagen which lacked pro-alpha 2(I) chains and consisted of a trimer of pro-alpha 1(I) chains. No pro-alpha 2(I) chains were recovered from the medium under conditions in which nonhelical pro-alpha 1(I) and pro-alpha 2(I) chains were readily detected in the medium of normal fibroblasts incubated with the hydroxylase inhibitor, alpha, alpha'-dipyridyl. Examination of cellular proteins demonstrated that the fibroblasts synthesized both pro-alpha 1(I) and pro-alpha 2(I) chains. The cellular pro-alpha 2(I) chains did not, however, become disulfide-linked into dimers or trimers of pro-alpha chains. Since the association of pro-alpha chains during the biosynthesis of type I procollagen is directed by the conformation of the COOH-terminal propeptides, the data suggest that the pro-alpha 2(I) chains synthesized by the fibroblasts have a mutated structure in the COOH-terminal propeptides which markedly reduces their affinity for pro-alpha 1(I) chains. A further observation was that the ratio of newly synthesized pro-alpha (I):pro-alpha 2(I) chains in the patient's fibroblasts was 7.18 +/- 0.58 S.E. instead of the value of 2.25 +/- 0.16 S.E. seen in control fibroblasts. One possible explanation for the high ratio is that the proband is homozygous for a mutation altering the structure of the pro-alpha 2(I) chain and that a secondary effect of the structural mutation is a decreased rate of synthesis of pro-alpha 2(I) chains.