Substitution of arginine for glycine at position 847 in the triple-helical domain of the alpha 1 (I) chain of type I collagen produces lethal osteogenesis imperfecta. Molecules that contain one or two abnormal chains differ in stability and secretion

Dermal fibroblasts from a fetus with perinatal lethal OI synthesized normal and abnormal type I procollagen molecules. The abnormal molecules contained one or two pro alpha 1 (I) chains in which glycine at position 847 in the triple helical region was substituted by arginine as the result of a de novo G-to-A transition in the first base of the glycine codon. The substitution resulted in increased posttranslational modification amino-terminal of the mutation site of all chains in molecules that contained one or more abnormal chains. Secretion of the overmodified molecules was impaired, and intracellular retention of molecules which contained two abnormal chains was greater than that of molecules which contained one abnormal chain. The thermal stability of molecules that contained two abnormal chains was markedly lower than that of molecules containing one abnormal chain. After cleavage of molecules with vertebrate collagenase, the thermal stability of the overmodified A fragments was greater than that of the normal molecules. Our findings indicate that the cell distinguishes three classes of molecules and suggest that these molecules differ depending on the number of abnormal chains in the trimer.     

Structure, stability and interactions of type I collagen with GLY349-CYS substitution in alpha 1(I) chain in a murine Osteogenesis Imperfecta model.

Here we report the structural and functional studies of collagen from the Brtl mouse, a heterozygous knock-in model for Osteogenesis Imperfecta, which has a G349C substitution introduced in one col1a1 allele. We observed that 25+/-5% of alpha 1(I) chains in different tissues and in different extracts from matrix deposited by cultured cells were S-S-linked mutant dimers. Apparently mutant and normal molecules are equally well incorporated into the matrix and they form mature covalent crosslinks with the same efficiency. We found different extents of post-translational overmodification of mutant molecules in different tissues, but we found no consistent differences between lethal and non-lethal animals. We did not detect any changes in the thermal stability or rate of thermal denaturation of mutant collagen. We also did not detect any changes in collagen-collagen recognition and interactions except for disruption of quasi-crystalline lateral packing of molecules in tendons from some, mostly prepubertal, mutant animals. In contrast, alpha 1(I)(3) collagen from the oim mouse--the only other non-lethal murine OI model studied by similar techniques--has altered stability, fibrillogenesis, collagen-collagen interactions and produces a more consistent and more pronounced disruption of tendon crystallinity. Nevertheless, while the G349C substitution causes moderate or lethal OI, heterozygous oim mice are much less affected. Overall, our results suggest that OI symptoms and phenotype variation in G349C animals are related to abnormal interactions of mutant collagen helices with other matrix molecules or abnormal function of osteoblasts rather than to abnormal structure, physical properties or interactions between mutant collagen helices.     

Mutations in type I collagen genes resulting in osteogenesis imperfecta in humans

Osteogenesis imperfecta (OI), commonly known as "brittle bone disease", is a dominant autosomal disorder characterized by bone fragility and abnormalities of connective tissue. Biochemical and molecular genetic studies have shown that the vast majority of affected individuals have mutations in either the COL1A1 or COL1A2 genes that encode the chains of type I procollagen. OI is associated with a wide spectrum of phenotypes varying from mild to severe and lethal conditions. The mild forms are usually caused by mutations which inactivate one allele of COL1A1 gene and result in a reduced amount of normal type I collagen, while the severe and lethal forms result from dominant negative mutations in COL1A1 or COL1A2 which produce structural defects in the collagen molecule. The most common mutations are substitutions of glycine residues, which are crucial to formation and function of the collagen triple helix, by larger amino acids. Although type I collagen is the major structural protein of both bone and skin, the mutations in type I collagen genes cause a bone disease. Some reports showed that the mutant collagen can be expressed differently in bone and in skin. Since most mutations identified in OI are dominant negative, the gene therapy requires a fundamentally different approach from that used for genetic-recessive disorders. The antisense therapy, by reducing the expression of mutant genes, is able to change a structural mutation into a null mutation, and thus convert severe forms of the disease into mild OI type I.     

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.     

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.     

Phenotypic heterogeneity in osteogenesis imperfecta: the mildly affected mother of a proband with a lethal variant has the same mutation substituting cysteine for alpha 1-glycine 904 in a type I procollagen gene (COL1A1).

A proband with a lethal variant of osteogenesis imperfecta (OI) has been shown to have, in one allele in a gene for type I procollagen (COL1A1), a single base mutation that converted the codon for alpha 1-glycine 904 to a codon for cysteine. The mutation caused the synthesis of type I procollagen that was posttranslationally overmodified, secreted at a decreased rate, and had a decreased thermal stability. The results here demonstrate that the proband's mother had the same single base mutation as the proband. The mother had no fractures and no signs of OI except for short stature, slightly blue sclerae, and mild frontal bossing. As a child, however, she had the triangular facies frequently seen in many patients with OI. On repeated subculturing, the proband's fibroblasts grew more slowly than the mother's, but they continued to synthesize large amounts of the mutated procollagen in passages 7-14. In contrast, the mother's fibroblasts synthesized decreasing amounts of the mutated procollagen after passage 11. Also, the relative amount of the mutated allele in the mother's fibroblasts decreased with passage number. In addition, the ratio of the mutated allele to the normal allele in leukocyte DNA from the mother was half the value in fibroblast DNA from the proband. The simplest interpretation of the data is that the mother was mildly affected because she was a mosaic for the mutation that produced a lethal phenotype in one of her three children.     

Clinical variability of osteogenesis imperfecta reflecting molecular heterogeneity: cysteine substitutions in the alpha 1(I) collagen chain producing lethal and mild forms

We have examined the collagenous proteins extracted from skin and produced by skin fibroblast cultures from the members of a family with mild dominant osteogenesis imperfecta (OI type I). The two affected patients, mother and son, produce two populations of alpha 1(I) chains of type I collagen, one chain being normal, the other containing a cysteine within the triple-helical domain. Both forms can be incorporated into triple-helical molecules with an alpha 2(I) chain. When two mutant alpha (I) chains are incorporated into the same molecule, a disulfide bonded dimer is produced. We have characterized these chains by sodium dodecyl sulfate-gel electrophoresis and CNBr-peptide mapping and by measuring a number of biosynthetic and physical variables. The cysteine was localized to the COOH-terminal peptide alpha (I) CB6. Molecules containing the mutant chains are stable, have a normal denaturation temperature, are secreted normally, and have normal levels of post-translational modification of lysyl residues and intracellular degradation. We have compared and contrasted these observations with those made in a patient with lethal osteogenesis imperfecta in which there was a cysteine substitution in alpha 1(I) CB6 (Steinmann, B., Rao, V. H., Vogel, A., Bruckner, P., Gitzelmann, R., and Byers, P. H. (1984) J. Biol. Chem 259, 11129-11138) and have concluded that the mutation in the present family occurs in the X or Y position of a Gly-X-Y repeating unit of collagen and not in the glycine position shown for the previous patient (Cohn, D. H., Byers, P. H., Steinmann, B, and Gelinas, R. E. (1986) Proc. Natl. Acad. Sci. U. S. A., in press.     

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.     

Defects of type I procollagen metabolism correlated with decrease of prolidase activity in a case of lethal osteogenesis imperfecta.

We have studied the structure and metabolism of type I procollagen in a case of perinatal lethal osteogenesis imperfecta (OI) type II. Cultured skin fibroblasts from the proband synthesized both normal and abnormal forms of type I procollagen. Some abnormal, overmodified molecules were secreted by OI cells, although less efficiently than normal molecules from control cells. The OI fibroblasts accumulated large amounts of abnormal proalpha1(I) and proalpha2(I) chains intracellularly. The extracellular collagenolytic activity was decreased compared to control cells. Furthermore, OI cells produced less type I procollagen and demonstrated lower capacity to synthesize DNA than control cells. We have found that in contrast to prolinase activity, the activity of prolidase (an enzyme essential for collagen synthesis and cell growth) is also significantly reduced in OI cells. No differences were found in the amount of the enzyme protein recovered from both the OI and control cells. However, we found that expressions of beta1 integrin and insulin-like growth factor-I receptor (receptors known to play an important role in up regulation of prolidase activity) were decreased in OI cells compared to control cells. The decrease in prolidase activity may provide an important mechanism of altered cell growth and collagen metabolism involved in producing the perinatal lethal form of the OI phenotype.     

Homozygosity by descent for a COL1A2 mutation in two sibs with severe osteogenesis imperfecta and mild clinical expression in the heterozygotes

We report two sibs with severe, progressively deforming osteogenesis imperfecta (OI) and homozygosity by descent for a glycine 751 to serine substitution in the α2(I) collagen chain due to a G to A transition in the COL1A2 gene. The parents, who were first cousins, and two elder sibs were heterozygous for the mutation and presented mild clinical manifestations of OI. Collagen studies on cultured fibroblasts from one of the probands and from the father showed that cells from the homozygote produced only mutant, unstable collagen I, whereas cells from the heterozygote produced both normal and mutant collagen I. This family represents an exceptional example of autosomal recessive OI, caused by homozygosity for a missense mutation in collagen I. Received: 22 July 1996     

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.     

Two novelCOL1A1 mutations in patients with osteogenesis imperfecta (OI) affect the stability of the collagen type I triple-helix

Osteogenesis imperfecta (OI) is a bone dysplasia caused by mutations in theCOL1A1 andCOL1A2 genes. Although the condition has been intensely studied for over 25 years and recently over 800 novel mutations have been published, the relation between the location of mutations and clinical manifestation is poorly understood. Here we report missense mutations inCOL1A1 of several OI patients. Two novel mutations were found in the D1 period. One caused a substitution of glycine 200 by valine at the N-terminus of D1 in OI type I/IV, lowering collagen stability by 50% at 34°C. The other one was a substitution of valine 349 by phenylalanine at the C-terminus of D1 in OI type I, lowering collagen stability at 37.5°C. Two other mutations, reported before, changed amino residues in D4. One was a lethal substitution changing glycine 866 to serine in genetically identical twins with OI type II. That mutated amino acid was near the border of D3 and D4. The second mutation changed glycine 1040 to serine located at the border of D4 and D0.4, in a proband manifesting OI type III, and lowered collagen stability at 39°C (2°C lower than normal). Our results confirm the hypothesis on a critical role of the D1 and D4 regions in stabilization of the collagen triple-helix. The defect in D1 seemed to produce a milder clinical type of OI, whereas the defect in the C-terminal end of collagen type caused the more severe or lethal types of OI.     

A frameshift mutation results in a truncated nonfunctional carboxyl-terminal pro alpha 1(I) propeptide of type I collagen in osteogenesis imperfecta

A codon frameshift mutation caused by a single base (U) insertion after base pair 4088 of prepro alpha 1(I) mRNA of type I procollagen was identified in a baby with lethal perinatal osteogenesis imperfecta. The mutation was identified in fibroblast RNA by a new method that allows the direct detection of mismatched bases by chemical modification and cleavage in heteroduplexes formed between mRNA and control cDNA probes. The region of mismatches was specifically amplified by the polymerase chain reaction and sequenced. The heterozygous mutation in the amplified cDNA most likely resulted from a T insertion in exon 49 of COL1A1. The frameshift resulted in a truncated pro alpha 1(I) carboxyl-terminal propeptide in which the amino acid sequence was abnormal from Val1146 to the carboxyl terminus. The propeptide lacked Asn1187, which normally carries an N-linked oligosaccharide unit, and was more basic than the normal propeptide. The distribution of cysteines was altered and the mutant propeptide was unable to form normal interchain disulfide bonds. Some of the mutant pro alpha 1(I)' chains were incorporated into type I procollagen molecules but resulted in abnormal helix formation with over-hydroxylation of lysine residues, increased degradation, and poor secretion. Only normal type I collagen was incorporated into the extracellular matrix in vivo resulting in a tissue type I collagen content approximately 20% of that of control (Bateman, J. F., Chan, D., Mascara, T., Rogers, J. G., and Cole, W. G. (1986) Biochem. J. 240, 699-708).     

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.     

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

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

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.     

Osteogenesis imperfecta type IV. Detection of a point mutation in one alpha 1(I) collagen allele (COL1A1) by RNA/RNA hybrid analysis

We have identified a point mutation in one alpha 1(I) collagen allele (COL1A1) of a child with the type IV osteogenesis imperfecta phenotype. When compared to parental and control samples, skin fibroblasts of the proband synthesized two populations of type I collagen molecules. One population was normal; the other was delayed in secretion and electrophoretic migration due to post-translational overmodification. Two-dimensional gel electrophoresis of the CNBr peptides demonstrated a gradient of overmodification beginning near the carboxyl-terminal CB peptides. This predicts that the mutation delaying helix formation is near the carboxyl-terminal end of one of the component chains of type I collagen. The mRNA of the patient was probed with overlapping antisense riboprobes to type I collagen cDNA. Cleavage of a mismatch in RNA/RNA hybrids of RNase A allowed the location of the mutation to a 225-base pair region of alpha 1(I) cDNA. The mismatch was not present in RNA/RNA hybrids from either parent. This region of both alpha 1(I) alleles of the patient was isolated by screening a lambda ZAP cDNA library. Sequence determination of both alleles demonstrated a single nucleotide change, G----A, resulting in the substitution of a serine for a glycine at amino acid residue 832. This point mutation occurs in the coding region for alpha 1(I) CB6 and is concordant with the protein data. The finding of a glycine substitution in an alpha 1(I) chain of a patient with the milder type IV osteogenesis imperfecta phenotype requires modification of current molecular models for types II and IV osteogenesis imperfecta.     

Cysteine in the triple-helical domain of one allelic product of the alpha 1(I) gene of type I collagen produces a lethal form of osteogenesis imperfecta

We studied tissue and cultured skin fibroblasts from a newborn with the lethal perinatal form of osteogenesis imperfecta born to a mother with the Marfan syndrome and her unrelated husband. Dermis from the infant was thinner and fibril diameter smaller than control; dermal fibroblastic cells had dilated endoplasmic reticulum. His fibroblasts in culture synthesized two different species of pro alpha 1(I) chains in about equal quantity. One chain was normal, the other contained cysteine within the triple-helical portion of the COOH-terminal cyanogen bromide peptide alpha 1(I)CB6. Molecules which contained two copies of the mutant chain formed alpha 1(I)-dimers linked through interchain disulfide bonds. Molecules which contained either one or two mutant chains were delayed in secretion and underwent excessive lysyl hydroxylation and hydroxylysyl glycosylation of all chains in the molecule, probably as a result of delayed triple-helix formation. Molecules containing either one or two copies of the mutant chain melted at 38 degrees C instead of 41 degrees C. The most likely explanation for these findings is that a cysteine is substituted for a glycine in the triple-helical domain of the products of one of the alpha 1(I) alleles. Such a substitution would interfere with triple-helix formation and stability and thus explain 1) the decreased melting temperature, 2) the increased post-translational modification, 3) the altered rate of secretion and accumulation of intracellular material, 4) the increased intracellular degradation of newly synthesized collagen, and 5) the decreased collagen production. Since neither parental cell strain produced the same mutant chain, the findings are best explained by a new mutation in one of the alpha 1(I) genes. The role of the uncharacterized "Marfan" gene in modifying the phenotype in this patient is unclear.     

A structural mutation of the collagen alpha 1(I)CB7 peptide in lethal perinatal osteogenesis imperfecta

Structurally abnormal type I collagen was identified in the dermis, bone, and cultured fibroblasts obtained from a baby with lethal perinatal osteogenesis imperfecta. Two-dimensional gel electrophoresis of the CNBr peptides demonstrated that the alpha 1(I)CB7 peptide from the alpha 1(I)-chain of type I collagen existed in a normal form and a mutant form with a more basic charge distribution. This heterozygous peptide defect was not detected in the collagens from either parent. The defect was localized to a 224-residue region at the NH2 terminus of the alpha 1(I)CB7 peptide by mammalian collagenase digestion. Analysis of unhydroxylated collagens produced in cell culture indicated that the mutant alpha 1(I)CB7 migrated faster on electrophoresis suggesting that the abnormality may be a small deletion or a mutation that alters sodium dodecyl sulfate binding. The post-translational hydroxylation of lysine residues was increased in the CB7 peptide and also in peptides CB3 and CB8 which are toward the NH2 terminus of the alpha 1(I)-chain. The COOH-terminal CB6 peptide was normally hydroxylated. These findings support the proposal that the lysine overhydroxylation resulted from a perturbation of helix propagation from the COOH to NH2 terminus of the collagen trimer caused by the structural defect in alpha 1(I)CB7.