Defective pro alpha 2(I) collagen synthesis in a recessive mutation in mice: a model of human osteogenesis imperfecta.

Osteogenesis imperfecta (OI) is a heritable disorder of connective tissue associated with fractures, osteopenia, and short stature. OI results from mutations affecting the pro alpha 1 or pro alpha 2 gene of type I collagen. We describe a strain of mice with a nonlethal recessively inherited mutation (oim) that results in phenotypic and biochemical features that simulate moderate to severe human OI. The phenotype of homozygous oim mice includes skeletal fractures, limb deformities, generalized osteopenia, and small body size. Their femurs are smaller and demonstrate marked cortical thinning and fewer medullary trabeculae than those of wild-type mice. Breeding studies show the mutation is inherited in most crosses as a single recessive gene on chromosome 6, near the murine Cola-2 gene. Biochemical analysis of skin and bone, as well as isolated dermal fibroblast cultures, demonstrate that alpha 1(I) homotrimeric collagen accumulates in these tissues and is secreted by fibroblasts. Short labeling studies in fibroblasts demonstrate an absence of pro alpha 2(I) collagen chains. Nucleotide sequencing of the cDNA encoding the COOH-propeptide reveals a G deletion at pro alpha 2(I) nucleotide 3983; this results in an alteration of the sequence of the last 48 amino acids. The oim mouse will facilitate the study of type I collagen-related skeletal disease.

Expression of mutant alpha (I)-procollagen in osteoblast and fibroblast cultures from a proband with osteogenesis imperfecta type IV.

This study compares the synthesis of mutant type I collagen in cultured dermal fibroblasts and trabecular osteoblasts that were isolated from a patient with moderately severe osteogenesis imperfecta (type IV). Previous study of this patient's dermal fibroblasts revealed a 2000 dalton deletion located in cyanogen bromide peptide 4 of alpha 2(I)-collagen. The phenotype of the bone cell cultures was defined by a 3-4 day logarithmic phase doubling time, predominantly type I collagen production over type III and alkaline phosphatase activity 13.5 times dermal fibroblast levels. The current study revealed that both fibroblasts and osteoblasts synthesized a normal and a shortened alpha 2(I) chain, each as the product of separate alleles. Following pepsin treatment of the procollagens, a shortened alpha 1(I) chain was also seen in both cell types. Cyanogen bromide peptide mapping of osteoblast alpha-chains demonstrated the same deletions in the cyanogen bromide peptide 4 as observed in the fibroblast cyanogen bromide maps. PAGE analysis of oligonucleotide-specific cDNA that was reverse transcribed from RNA isolated from fibroblasts and osteoblasts also demonstrated the presence of two bands, one the normal size of alpha 2(I) cDNA and a second species that was smaller by 54 base pairs. Sequencing of polymerase chain reaction-amplified cDNA fragments revealed an in-frame deletion of exon 12. This finding was confirmed by the RNase protection method. Genomic DNA sequencing detected a T----G point mutation in the second position of the 5' splice donor site of intron 12. Therefore, in this patient with osteogenesis imperfecta there was no qualitative alteration in the osteoblast-specific expression of this mutant alpha 2(I)-collagen allele compared to dermal fibroblasts.

Identification of estrogen receptor mRNA and the estrogen modulation of parathyroid hormone-stimulated cyclic AMP accumulation in opossum kidney cells.

The opossum kidney (OK) cell was used as a model to test the hypothesis that estrogen directly affects proximal renal tubular epithelial cells. To demonstrate the expression of estrogen receptor in OK cells, we developed an approach using reverse transcription and the polymerase chain reaction. Analysis of the DNA amplified with nested primers revealed the predicted size fragment and restriction enzyme digestion products. To demonstrate the functional effects of estrogen, OK cells at confluence were preincubated in serum-free medium for 7-10 days with or without 17 beta-estradiol. Bovine PTH(1-34) (bPTH(1-34)) then stimulated a dose-dependent intracellular accumulation of cAMP that was maximal after 1 min and then gradually declined. Cyclic AMP in the medium slowly increased over 60 min. Preincubation with 17 beta-estradiol did not affect cell proliferation as measured by total protein content but caused an inhibition of bPTH(1-34)-stimulated intracellular cAMP accumulation that was maximal at 10(-11) M 17 beta-estradiol (71 +/- 3% control, p less than .001). bPTH(1-34) also increased cAMP release into the medium, an effect maximal using 10(-10) M 17 beta-estradiol (118 +/- 3% control, p less than .001). Preincubation with the inactive isomer 17 alpha-estradiol caused no changes in cAMP accumulation or release. Coincubation with the antiestrogen tamoxifen blocked the effects of 17 beta-estradiol. Sodium-dependent phosphate transport was: (1) inhibited by 2-h incubations with 10(-8) or 10(-10) M bPTH(1-34) and not affected by preincubation with 17 beta-estradiol, and (2) not inhibited by a 20-min incubation with 10(-8) M bPTH(1-34) unless cells were preincubated with 10(-8) M 17 beta-estradiol, suggesting that any possible effects of estrogen on phosphate transport are not directly mediated by changes in cAMP. These studies demonstrate the presence of estrogen receptor mRNA in OK cells as well as direct and specific effects of physiologic concentrations of estrogen on cAMP accumulation in these cells. This system may be a good model for further study of estrogen and PTH effects on the kidney.

An osteopenic nonfracture syndrome with features of mild osteogenesis imperfecta associated with the substitution of a cysteine for glycine at triple helix position 43 in the pro alpha 1(I) chain of type I collagen.

Mutations affecting the pro alpha 1(I) or pro alpha 2(I) collagen genes have been identified in each of the major clinical types of osteogenesis imperfecta. This study reports the presence of a heritable connective tissue disorder in a family with an osteopenic syndrome which has features of mild osteogenesis imperfecta but was considered idiopathic osteoporosis in the proband. At age 38, while still premenopausal, she was found to have osteopenia, short stature, hypermobile joints, mild hyperelastic skin, mild scoliosis, and blue sclerae. There was no history of vertebral or appendicular fracture. Hip and vertebral bone mineral density measurements were consistent with marked fracture risk. Delayed reduction SDS-PAGE of pepsin-digested collagens from dermal fibroblast cultures demonstrated an anomalous band migrating between alpha 1(I) and alpha 1(III). This band merged with the normal alpha-chains upon prereduction, indicating an unexpected cysteine residue. Cyanogen bromide peptide mapping suggested that the mutation was in the smaller NH2-terminal peptides. cDNA was reverse transcribed from mRNA and amplified by the polymerase chain reaction. A basepair mismatch between proband and control alpha 1(I) cDNA hybrids was detected by chemical cleavage with hydroxylamine:piperidine. The cysteine substitution was thus localized to alpha 1(I) exon 9 within the cyanogen bromide 4 peptide. Nucleotide sequence analysis localized a G----T point mutation in the first position of helical codon 43, replacing the expected glycine (GGT) residue with a cysteine (TGT). The prevalence of similar NH2-terminal mutations in subjects with this phenotype which clinically overlaps idiopathic osteoporosis remains to be determined.

Osteoporosis and familial idiopathic scoliosis: association with an abnormal alpha 2(I) collagen.

A positive family history is considered a risk factor for osteoporosis (OP) although the genetic or biochemical basis for this relationship remains undefined. Various mutations affecting normal synthesis of type I collagen have been reported in osteogenesis imperfecta (OI), a heritable disorder of connective tissue. Family A, in which the proband and a daughter are afflicted with OP and idiopathic scoliosis was examined for defects in collagen metabolism. Dermal fibroblast cultures were established to investigate de novo collagen synthesis. SDS-PAGE revealed an abnormally migrating alpha 2(I) chain and procollagen in two generations. Examination of the kinetics of type I collagen pC & N-propeptide processing demonstrated a rate 2x control in the proband. The phenotype family A is not OI. It shares features with families B & C, having familial clustering of OP. However, collagen synthesis was not abnormal in family B & C. These data suggest that in family A the alpha 2(I) structural defect may be related to defective skeletal matrix formation.

Pulmonary hypoplasia and osteogenesis imperfecta type II with defective synthesis of alpha I(1) procollagen.

Perinatal lethal osteogenesis imperfecta (OI type II), a heritable disorder of connective tissue occurs approximately once in 60,000 live births. Phenotypic characteristics include defective cranial ossification and severe skeletal deformity due to intrauterine rib and long bone fractures. Lethal OI may be associated with intracranial hemorrhage or severe respiratory insufficiency. Pulmonary hypoplasia has been previously observed in OI type II, but has not been defined clinically. The infant described herein was born with OI type II and pulmonary hypoplasia. Pathological examination of airway branching patterns indicated that lung development had progressed to only the 10 week stage with immature acinar development. Investigation type I collagen synthesis by cultured dermal fibroblasts revealed the presence of electrophoretically abnormal alpha 1(I) polypeptides. These findings suggest that biochemically regulated processes, as well as mechanical factors, may impeded pulmonary development in similar cases of OI type II.

Collagen expression, ultrastructural assembly, and mineralization in cultures of chicken embryo osteoblasts.

A newly defined chick calvariae osteoblast culture system that undergoes a temporal sequence of differentiation of the osteoblast phenotype with subsequent mineralization (Gerstenfeld, L. C., S. Chipman, J. Glowacki, and J. B. Lian. 1987. Dev. Biol. 122:49-60) has been examined for the regulation of collagen synthesis, ultrastructural organization of collagen fibrils, and extracellular matrix mineralization. Collagen gene expression, protein synthesis, processing, and accumulation were studied in this system over a 30-d period. Steady state mRNA levels for pro alpha 1(I) and pro alpha 2 collagen and total collagen synthesis increased 1.2- and 1.8-fold, respectively, between days 3 and 12. Thereafter, total collagen synthesis decreased 10-fold while mRNA levels decreased 2.5-fold. In contrast to the decreasing protein synthesis after day 12, total accumulated collagen in the cell layers increased sixfold from day 12 to 30. Examination of the kinetics of procollagen processing demonstrated that there was a sixfold increase in the rate of procollagen conversion to alpha chains from days 3 to 30 and the newly synthesized collagen was more efficiently incorporated into the extracellular matrix at later culture times. The macrostructural assembly of collagen and its relationship to culture mineralization were also examined. High voltage electron microscopy demonstrated that culture cell layers were three to four cells thick. Each cell layer was associated with a layer of well developed collagen fibrils orthogonally arranged with respect to adjacent layers. Fibrils had distinct 64-70-nm periodicity typical of type I collagen. Electron opaque areas found principally associated with the deepest layers of the fibrils consisted of calcium and phosphorus determined by electron probe microanalysis and were identified by electron diffraction as a very poorly crystalline hydroxyapatite mineral phase. These data demonstrate for the first time that cultured osteoblasts are capable of assembling their collagen fibrils into a bone-specific macrostructure which mineralizes in a manner similar to that characterized in vivo. Further, this matrix maturation may influence the processing kinetics of the collagen molecule.

Expression of differentiated function by mineralizing cultures of chicken osteoblasts.

This report documents osteoblast differentiation in vitro, as demonstrated by the 50-100X increase of proteins which are known markers of the osteoblast phenotype. Collagen type I and osteocalcin synthesis and accumulation, alkaline phosphatase activity, and matrix calcification show similar temporal relationships that are analogous to those seen during in vivo bone development. Chicken embryonic osteoblast progenitor cells were selected by initial growth at low densities in minimal medium. Upon subcultivation into nutrient-enriched medium at higher cell densities, near homogeneous populations of osteoblasts were obtained as demonstrated by the greater than 80% enrichment of cells positive for alkaline phosphatase activity. A comparison was made between cells grown in the presence or absence of 10 mM beta-glycerolphosphate (beta-GPO4), a chemical stimulant of matrix calcification, as a function of time. Cultures treated with beta-GPO4 showed visible calcification at Day 12 when culture monolayers became confluent. By Day 30, numerous large foci of calcification were visible and a 20-fold increase in calcium (Ca) content was observed. In contrast, untreated cultures had only a 3-fold increase in Ca content with many smaller diffuse areas of calcification. DNA, RNA, and total protein levels were nearly identical between the two cultures, indicating that beta-GPO4 had no marked effect on either cell proliferation or transcriptional activity. The major collagen type produced by either culture was type I, with no detectable type III as determined by CNBr peptide mapping and delayed reduction analysis. Alkaline phosphatase activity showed a rapid approximately 50-fold induction by Day 18 and remained elevated in control cultures. However, cultures treated with beta-GPO4 demonstrated a rapid 80% decline of enzyme activity after 18 days. In contrast, total osteocalcin levels showed a 100-fold induction by Day 18 and remained elevated in both control and beta-GPO4-treated cultures throughout the time period examined. While the overall levels of osteocalcin were the same in beta-GPO4-treated and untreated cultures, 2- to 5-fold more osteocalcin was associated with the more mineralized matrices of the beta-GPO4-treated cultures. In order to confirm the association of osteocalcin with areas of mineralization, co-localization of mineral to osteocalcin and collagen was carried out by combining vital labeling with tetracycline and immunofluorescent staining with anti-osteocalcin and anti-collagen antibodies. Both collagen and osteocalcin showed strong localization with areas of mineralization.(ABSTRACT TRUNCATED AT 400 WORDS)

Processing of soluble elastin in cultured neonatal rat smooth muscle cells.

The synthesis and extracellular deposition of elastin by cultured neonatal rat aorta smooth muscle cells has been followed. The addition of beta-aminopropionitrile to the culture medium promotes accumulation of soluble precursors of elastin. Under such conditions, a protein possessing characteristics of a soluble elastin precursor with an apparent molecular weight of 77,000 was detected and partially purified. Pulse-chase studies suggested that this 77-kDa protein undergoes an extracellular, enzymatically catalyzed process to a 71-kDa protein. This 71-kDa protein is strikingly similar to tropoelastins isolated from other tissue systems, in which no evidence for higher molecular weight soluble precursors is at present available. Data presented in this communication suggest that the 77-kDa protein, which we have designated protropoelastin, represents a precursor to the tropoelastin moiety produced in the neonatal rat smooth muscle cell culture.

Alteration of the extracellular matrix of smooth muscle cells by ascorbate treatment.

The protein composition in the extracellular matrix of cultured neonatal rat aortic smooth muscle cells has been monitored over time in culture. The influence of ascorbate on insoluble elastin and collagen has been described. In the absence of ascorbate, the cells accumulate an insoluble elastin component which can account for as much as 50% of the total protein in the extracellular matrix. In the presence of ascorbate, the amount of insoluble collagen increases, while the insoluble elastin content is significantly less. When ascorbate conditions are varied at different times during the culture, the extracellular matrices are altered with respect to collagen and elastin ratios. The decrease in elastin accumulation in the presence of ascorbate may be explained by an overhydroxylation of tropoelastin. Approximately 1/3 of the prolyl residues in the soluble elastin fractions isolated from cultures grown in the presence of ascorbate are hydroxylated. Since the insoluble elastin accumulated in these cultures contain the unique lysine-derived cross-links in amounts comparable to aortic tissue, this culture system proves ideal for studying the influence of extracellular matrix elastin on cell growth and metabolism.

The serum growth and survival requirements of SV40-transformed 3T3 cells.

Simian virus 40-transformed 3T3 cells are dependent on serum for survival and growth. This growth activity can be separated on a pH 2 Sephadex G100 column into two fractions: a high molecular weight activity and a low molecular weight substance that has recently been characterized as containing as its major agent, biotin. To replace the remainder of the serum requirement, hormones and other growth factors were tested. Both insulin at high, nonphysiological concentrations (200 to 500 ng/ml) and transferrin (5 X 10(-8) M) stimulate the growth rate in low serum medium (0.3% v/v bovine calf serum DME) individually and, when added together, are nearly as growth enhancing as 10% serum. The need for the residual serum in this medium can be eliminated by the use of crystalline trypsin during trypsinization. Under these serum-free conditions, biotin and transferrin supplementation provide for moderately good growth (20 to 30 hr population doubling time, 1 X 10(6) cells/3.2-cm dish final cell density). Insulin addition further stimulate the growth rate (16 to 20 hr) and the final density (1.5 X 10(6) cells). Although the protein growth factors, EGF (0.5 to 1.0 ng/ml) and FGF (4 to 10 ng/ml), also appear to enhance growth individually and additively, their effects are slight and very variable. Nevertheless, the complete serum-free medium (DME supplemented with biotin, transferrin, insulin, EGF, and FGF) yields growth comparable but still inferior to 10% serum supplementation (14-versus 12-hr population doubling time, 1 to 2 X 10(6) versus 2 to 3 X 10(6) cells final cell density).