Copolymerization of normal type I collagen with three mutated type I collagens containing substitutions of cysteine at different glycine positions in the alpha 1 (I) chain.

Previous observations with type I collagen from a proband with lethal osteogenesis imperfecta demonstrated that type I collagen containing a substitution of cysteine for glycine alpha 1-748 copolymerized with normal type I collagen (Kadler, K. E., Torre-Blanco, A., Adachi, E., Vogel, B. E., Hojima, Y., and Prockop, D. J. (1991) Biochemistry 30, 5081-5088). Here, three preparations containing normal type I procollagen and type I procollagen with a substitution of cysteine for glycine alpha 1-175, glycine alpha 1-691, or glycine alpha 1-988 were purified from cultured skin fibroblasts from probands with osteogenesis imperfecta. The procollagens were then used as substrates in a system for assaying the self-assembly of type I collagen into fibrils. The cysteine-substituted collagens in all three preparations were incorporated into fibrils. The cysteine alpha 1-175 and cysteine alpha 1-691 collagens were shown to increase the lag time and decrease the propagation rate constant for fibril assembly. All three preparations containing cysteine-substituted collagens formed fibrils with diameters that were two to four times the diameter of fibrils formed under the same conditions by normal type I collagen. Also, the three preparations containing cysteine substituted collagens had higher solubilities than normal type I collagen. The results, therefore, demonstrated that the three cysteine-substituted collagens copolymerized with normal type I collagen. The effects of the mutated collagens on fibril assembly can be understood in terms of a recently proposed model of fibril growth from symmetrical tips by assuming that the mutated monomers partially inhibit tip growth but not lateral growth of the fibrils. Of special interest was the observation that the Cys alpha 1-175 collagen from a proband with a non-lethal variant of osteogenesis imperfecta had quantitatively less effect on several parameters of fibril assembly at 37 degrees C than cysteine-substituted collagens from three probands with lethal variants of the disease.     

Studies of type I collagen (COL1A1) alpha1 chain in patients with osteogenesis imperfecta

Nucleotide sequences of exon 51, adjacent intron areas, and regulatory region of the alpha1 chain of type I collagen (COL1A1) gene were analyzed in 41 patients with osteogenesis imperfecta (OI) from 33 families and their 68 relatives residing at Bashkortostan Republic (BR). Six mutations (four nonsense mutations c.967G > T (p.Gly323X), c.1081C > T (p.Arg361X), c.1243C > T (p.Arg415X), and c.2869C > T (p.Gln957X)) in patients of the Russian origin and two mutations with open reading frame shift c.579delT (p.Gly194ValfsX71), and c.2444delG (p.Gly815AlafsX293)) in patients with OI of Tatar ethnicity as well as 14 single nucleotide polymorphisms in the COL1A1 gene were revealed. Mutations c.967G > T (p.Gly323X) and three alterations in the nucleotide sequence c.544-24C > T, c.643-36delT, and c.957 + 10insA were described for the first time.     

Identification of collagen alpha1(I) trimer and normal type I collagen in a polyoma virus-induced mouse tumor.

A bone- and cartilage-forming mouse tumor, induced by transforming salivary epithelial cells with polyoma virus, contained large quantities of collagen. Two types of collagen molecules were isolated which had different solubilities in salt. One was type I collagen with a chain composition [α1(I)]₂ α2 and the other was an unusual form of type I collagen with a chain composition [α1(I)]₃. This would appear to be the first in vivo demonstration of α1 type I 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.     

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 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 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.     

Substitution of cysteine for glycine within the carboxyl-terminal telopeptide of the alpha 1 chain of type I collagen produces mild osteogenesis imperfecta

We have characterized a mutation that produces mild, dominantly inherited osteogenesis imperfecta. Half of the alpha 1 (I) chains of type I collagen synthesized by cells from an affected individual contain a cysteine residue in the 196-residue carboxyl-terminal cyanogen bromide peptide of the triple-helical domain (Steinmann, B., Nicholls, A., and Pope, F. M. (1986) J. Biol. Chem. 261, 8958-8964). Unexpectedly, sequence determined from a proteolytic fragment of the alpha 1 (I) chain derived from procollagen molecules synthesized in the presence of both [3H]proline and [35S]cysteine indicated that the cysteine is located at the third residue carboxyl-terminal to the triple-helical domain, normally a glycine. The nucleotide sequence of a fragment amplified from genomic DNA confirmed the location of the cysteine residue and showed that the mutation was a single nucleotide change in one COL1A1 allele. This represents a new class of mutations, point mutations outside the triple-helical domain of the chains of type I collagen, that produce the osteogenesis imperfecta phenotype.     

A novel Gly to Arg substitution at position 388 of the alpha1 chain of type I collagen in lethal form of osteogenesis imperfecta

Cultured skin fibroblasts from a proband with a lethal form of osteogenesis imperfecta produce two forms of type I collagen chains, with normal and delayed electrophoretic migration; collagen of the proband's mother was normal. Peptide mapping experiments localized the structural defect in the proband to alpha1(I) CB8 peptide in which residues 123 to 402 are spaned. Direct sequencing of amplified cDNA covering this region revealed a G to A single base change in one allele of the alpha1(I) chain, that converted glycine 388 to arginine. Restriction enzyme digestion of the RT-PCR product was consistent with a heterozygous COL1A1 mutation. The novel mutation conforms to the linear gradient of clinical severity for the alpha1(I) chain and results in reduced thermal stability by 3 degrees C and intracellular retention of abnormal molecules.     

The complete primary structure of the alpha 2 chain of human type IV collagen and comparison with the alpha 1(IV) chain

The complete primary structure of the human type IV collagen alpha 2(IV) chain has been determined by nucleotide sequencing of cDNA clones. The overlapping cDNA clones cover 6,257 base pairs with a 5'-untranslated region of 283 base pairs, the 5,136-base pair open reading frame, and the 3'-untranslated region of 838 base pairs. The predicted amino acid sequence demonstrates that the complete translation product consists of 1,712 residues corresponding in molecular weight to 167,560. The translated polypeptide has a signal peptide of 36 amino acids, an amino-terminal noncollagenous part of 21 residues, a 1,428-residue collagenous domain with 23 interruptions, and a carboxyl-terminal noncollagenous (NC) domain of 227 residues. The calculated molecular mass of the mature human alpha 2(IV) chain is 163,774 Da.     

Human basement membrane collagen (type IV). The amino acid sequence of the alpha 2(IV) chain and its comparison with the alpha 1(IV) chain reveals deletions in the alpha 1(IV) chain

The cDNA and protein sequences of the N-terminal 60% of the alpha 2(IV) chain of human basement membrane collagen have been determined. By repeated primer extension with synthetic oligodeoxynucleotides and mRNA from either HT1080 cells or human placenta overlapping clones were obtained which cover 3414 bp. The derived protein sequence allows for the first time a comparison and alignment of both alpha chains of type IV collagen from the N terminus. This alignment reveals an additional 43 amino acid residues in the alpha 2(IV) chain as compared to the alpha 1(IV) chain. 21 of these additional residues form a disulfide-bridged loop within the triple helix which is unique among all known collagens.     

Immunity to type XI collagen in mice. Evidence that the alpha 3(XI) chain of type XI collagen and the alpha 1(II) chain of type II collagen share arthritogenic determinants and induce arthritis in DBA/1 mice.

To determine whether native bovine type XI collagen (BXI) is arthritogenic, five strains of inbred mice were immunized with BXI/CFA. Arthritis was not observed in any of these strains, though it was prevalent in DBA/1 and B10.RIII controls immunized with bovine type II collagen (BII). Antisera from BXI-immunized mice reacted with mouse type XI collagen (MsXI), weakly with the alpha-chains of BXI, and minimally with mouse type II collagen (MsII). However, antisera to BII reacted with MsII and MsXI, indicating antibodies to conformation-independent epitopes shared by alpha 1(II) and alpha 3(XI). Mice immunized with BXI containing a small amount of BII developed arthritis much like those immunized with BII; sera from these mice reacted with MsXI and MsII. Delayed-type hypersensitivity responses differed from IgG responses, i.e., BXI elicited responses to alpha 1(XI), alpha 2(XI), alpha 3(XI), and alpha 1(II); BII, to alpha 3(XI) and alpha 1(II) exclusively. To determine whether alpha 1(XI), alpha 2(XI), alpha 3(XI), and alpha 1(II) are arthritogenic, DBA/1J mice were immunized with each alpha-chain. Arthritis was seen in mice injected with alpha 3(XI) or alpha 1(II). Sera to both alpha-chains reacted similarly with MsII and peptide fragment alpha 1(II)-CB11. Epitope mapping using polyclonal and mAb to type II collagen revealed that all polyclonal and 11 of 14 mAb reacted with alpha 3(XI) and alpha 1(II), whereas three mAb reacted only with alpha 1(II). In conclusion, BXI is immunogenic but not arthritogenic in five strains of mice, whereas alpha 3(XI) and alpha 1(II) are arthritogenic and immunogenic in DBA/1 mice and share greater than or equal to 11 epitopes recognized by autoantibody.     

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.     

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.     

An amino acid substitution (Gly853-->Glu) in the collagen alpha 1(II) chain produces hypochondrogenesis.

The spondyloepiphyseal dysplasia subclassification of bone dysplasias includes achondrogenesis, hypochondrogenesis, and spondyloepiphyseal dysplasia congenita. The phenotypic expression of these disorders ranges from mild to perinatal lethal forms. We report the detection and partial characterization of a defect in type II collagen in a perinatal lethal form of hypochondrogenesis. Electrophoresis in sodium dodecyl sulfate-polyacrylamide of CB peptides (where CB represents cyanogen bromide) from type II collagen of the diseased cartilage showed a doublet band for peptide alpha 1(II)CB10 and evidence for post-translational overmodification of the major peptides (CB8, CB10, and CB11) seen as a retarded electrophoretic mobility. Peptide CB10 was digested by endoproteinase Asp-N; and on reverse-phase high pressure liquid chromatography, fragments of abnormal mobility were noted. Sequence analysis of a unique peptide D12 revealed a single amino acid substitution (Gly-->Glu) at position 853 of the triple helical domain. This was confirmed by sequence analysis of amplified COL2A1 cDNA, which revealed a single nucleotide substitution (GGA-->GAA) in 5 of 10 clones. Electron micrographs of the diseased cartilage showed a sparse extracellular matrix and chondrocytes containing dilated rough endoplasmic reticulum, which suggested impaired assembly and secretion of the mutant protein. This case further documents the molecular basis of the spondyloepiphyseal dysplasia spectrum of chondrodysplasias as mutations in COL2A1.     

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.     

Identification of the cartilage alpha 1(XI) chain in type V collagen from bovine bone

Type V collagen prepared from bovine bone was resolved into three distinct alpha-chains by high performance liquid chromatography and gel electrophoresis. Peptide mapping established two chains as alpha 1(V) and alpha 2(V) as expected and the third as the cartilage alpha 1(XI) chain (previously thought to be unique to cartilage). In adult bone, the type V collagen fraction was richer in alpha 1(XI) chains than in fetal bone (about 1/3 of the chains in the adult). How these polypeptides are organized into native molecules is not yet clear, though the stoichiometry suggests cross-type heterotrimers between the type V and XI chains.