Evidence that Abnormal High Bone Mineralization in Growing Children with Osteogenesis Imperfecta is not Associated with Specific Collagen Mutations

Osteogenesis imperfecta type I (OI-I) represents the mildest form of OI. The collagen I mutations underlying the disorder can be classified as quantitative mutations that lead to formation of a decreased amount of normal collagen or qualitative mutations where structurally aberrant collagen chains are generated. However, the phenotypic consequences of a particular mutation are not well understood. Transiliac bone biopsies from 19 young OI-I patients (age range 2.0–14.1 years) and 19 age-matched controls were used to assess bone histomorphometric parameters and bone mineralization density distribution, measured by quantitative backscattered electron imaging. Thirteen of the OI-I patients were affected by quantitative and six patients by qualitative mutations. Compared to age-matched controls, iliac bone samples in the OI group were smaller and had thinner cortices and less trabecular bone. Resorption parameters were similar between groups, whereas surface-based parameters of bone formation were considerably higher in OI patients than in controls with the exception of bone formation rate per osteoblast surface, which was reduced in OI. Backscattered electron imaging revealed a higher mean mineralization density (+7%, P < 0.001) in OI-I patients than in age-matched controls, which was accompanied by a reduced heterogeneity of mineralization (−13%, P < 0.001). However, the increase of mean degree of mineralization in OI did not exceed the average level of normal adult bone. No differences were found between the two mutation types. In summary, the tissue- and material-level abnormalities found in OI-I (low bone mass and increased mineral content of the matrix) seem to be independent of the collagen mutations.     

Osteogenesis imperfecta: changes in noncollagenous proteins in bone

The noncollagenous proteins osteonectin, bone sialoprotein, osteocalcin, the small proteoglycan decorin (PG II), and alpha 2-HS glycoprotein (which is synthesized in the liver but highly concentrated in bone) were measured in extracts of cortical bone from 3 type I, 2 type II, 8 type III and 13 type IV patients with osteogenesis imperfecta (OI) and from 7 control subjects. Osteonectin was found to be reduced in the bone of all OI patients. The bone from severely affected type III OI patients contained the lowest levels of osteonectin. In contrast, bone sialoprotein was found to be elevated in the bones of OI patients. The highest levels were found in individuals classified as type IV patients. Osteocalcin and alpha 2-HS glycoprotein concentrations were increased in all OI patients. Decorin levels were not significantly altered in OI bones compared to controls. These changes in the concentrations of the noncollagenous proteins may contribute to the fragility of the OI bone by interfering with complete mineralization and/or normal tissue architecture.     

Identification of proteins secreted by human osteoblastic cells in culture.

To better understand the biochemistry of matrix-forming cells, we developed a simple and reproducible procedure for the isolation and identification by N-terminal sequencing of proteins secreted by cells into culture medium and applied this procedure to the analysis of the major Coomassie blue-staining proteins under 100 kD that are secreted from three different human osteoblastic cell cultures. The major proteins secreted by normal human osteoblasts from adult trabecular bone were identified by N-terminal sequencing to be gelatinase, osteonectin, the C-terminal propeptides of the alpha 1 and alpha 2 chains of type I collagen, tissue inhibitor of metalloproteinase 1 (TIMP-1), and beta 2-microglobulin. The amounts of each of these proteins secreted into medium over a 24 h interval did not change over the 7 consecutive days of culture under serum-free conditions, which indicates that this pattern of protein secretion is not significantly affected by the serum-free conditions needed for protein identification by this method. In addition, radioimmunoassay for bone gla protein (BGP), a marker for osteoblast phenotype, revealed that BGP secretion remained high over 7 days of culture under serum-free conditions and was comparable to the rate of BGP secretion in control cultures with 10% serum. The major proteins secreted by MG-63 cells were identified by N-terminal sequencing to be gelatinase, a novel 40 kD human bone protein we termed YKL-40, TIMP-1, the recently discovered TIMP-2, and beta 2-microglobulin. Further studies revealed that YKL-40 is the only protein detectable by Coomassie staining of SDS gels of MG-63 media proteins that is induced by extended time at confluence or by treatment with 1,25-(OH)2D3. The apparent absence of detectable Coomassie-stained bands corresponding to the C-terminal propeptides of collagen in the medium of MG-63 cells suggests that these transformed cells may not be a good model for bone matrix formation. The major proteins secreted by normal fetal osteoblastic cells were identified by N-terminal sequencing to be osteonectin and the C-terminal propeptides of the alpha 1 and alpha 2 chains of type I collagen. Gelatinase and TIMP could not be detected among the conditioned medium proteins by these methods. These observations indicate that fetal osteoblasts primarily express proteins that are matrix constituents and adult human osteoblasts secrete, in addition to these, proteins that could function in matrix turnover.     

Collagen defect of bone in osteogenesis imperfecta (Type I). An electron microscopic study

Osteogenesis imperfecta (OI) is an inherited disorder of connective tissue metabolism characterized by fragility of the bones, resulting in multiple fractures. In this study electron microscopic examination of the osteoid region of iliac crest bone biopsy specimens from a 55-year-old man and his three sons (18, 21, and 25 years of age) affected with the common Type I (autosomal dominant) form of OI revealed collagen fibrils consistently smaller in diameter than those from normal age-matched control subjects, with the majority of OI fibrils measuring 0.04-0.06 micron, as opposed to 0.06-0.08 micron in the control subjects. This defect may be due to the biosynthesis of Type III collagen, not normally found in adult lamellar bone or, more likely, to a failure of maturation of Type I fibrils to their normal diameters, possibly owing to the increased levels of hydroxylysine previously reported in OI collagen, a factor known to be inversely related to fibril diameter.     

Type I collagen formation in rat type II alveolar cells immortalised by viral gene products.

BACKGROUND--Alveolar type II (T2) cells synthesise matrix proteins such as type IV collagen and fibronectin. In contrast, a fetal rat T2 cell line has been shown to synthesise type I and III collagen as well as type IV collagen. To study regulation of collagen production in T2 cells, neonatal T2 cells immortalised by adenoviral 12SE1A gene transfer were used. It was previously reported that this immortalised cell line (E1A-T2) retains epithelial features such as tight junctions and cytokeratins but also expresses mesenchymal features such as vimentin. METHODS--Collagen production was examined in E1A-T2 and primary neonatal T2 cells using polyacrylamide gel electrophoresis. Electron microscopy was used to examine collagen deposition in E1A-T2 cell culture. To define the mechanism by which alpha 1(I) type I collagen gene expression was activated in E1A-T2 cells, a deletional analysis of alpha 1(I) promoter constructs linked to the bacterial chloramphenicol acetyltransferase gene was performed. RESULTS--E1A-T2 cells produced large amounts of type I collagen with a predominance of alpha 1(I) homotrimers; alpha 2(I) peptides were detected only in the cell layer. In contrast, primary neonatal rat T2 cell cultures produced a trace amount of type I collagen. Production of alpha 1(I) peptide chains (per microgram DNA) in E1A-T2 cell cultures was 30 times higher than that observed in primary neonatal T2 cell cultures. Electron microscopy showed deposition of type I collagen fibrils in the extracellular matrix of E1A-T2 cell cultures. Transfection studies suggested at least two cis-acting elements which mediate increased alpha 1(I) gene expression in E1A-T2 cells. CONCLUSIONS--These studies indicate that the E1A-T2 cell line may be useful for studying type I collagen gene regulation in alveolar T2 cells. These findings also raise the possibility that viral activation of type I collagen genes in alveolar epithelium may be involved in certain forms of pulmonary fibrosis.     

Osteogenesis imperfecta type VI: a form of brittle bone disease with a mineralization defect.

Osteogenesis imperfecta (OI) is a heritable disease of bone in which the hallmark is bone fragility. Usually, the disorder is divided into four groups on clinical grounds. We previously described a group of patients initially classified with OI type IV who had a discrete phenotype including hyperplastic callus formation without evidence of mutations in type I collagen. We called that disease entity OI type V. In this study, we describe another group of 8 patients initially diagnosed with OI type IV who share unique, common characteristics. We propose to name this disorder "OI type VI." Fractures were first documented between 4 and 18 months of age. Patients with OI type VI sustained more frequent fractures than patients with OI type IV. Sclerae were white or faintly blue and dentinogenesis imperfecta was uniformly absent. All patients had vertebral compression fractures. No patients showed radiological signs of rickets. Lumbar spine areal bone mineral density (aBMD) was low and similar to age-matched patients with OI type IV. Serum alkaline phosphatase levels were elevated compared with age-matched patients with type IV OI (409 +/- 145 U/liter vs. 295 +/- 95 U/liter; p < 0.03 by t-test). Other biochemical parameters of bone and mineral metabolism were within the reference range. Mutation screening of the coding regions and exon/intron boundaries of both collagen type I genes did not reveal any mutations, and type I collagen protein analyses were normal. Qualitative histology of iliac crest bone biopsy specimens showed an absence of the birefringent pattern of normal lamellar bone under polarized light, often with a "fish-scale" pattern. Quantitative histomorphometry revealed thin cortices, hyperosteoidosis, and a prolonged mineralization lag time in the presence of a decreased mineral apposition rate. We conclude that type VI OI is a moderate to severe form of brittle bone disease with accumulation of osteoid due to a mineralization defect, in the absence of a disturbance of mineral metabolism. The underlying genetic defect remains to be elucidated.     

Bone cell culture in a three-dimensional polymer bead stabilizes the differentiated phenotype and provides evidence that osteoblastic cells synthesize type III collagen and fibronectin.

We report a novel method to culture chick embryo osteoblasts in vitro. Primary cells were grown from explants of calvaria and then cultured within alginate polymer beads. Enriched cultures of primary osteoblasts were obtained because these cells grow readily within alginate beads but other cell types present in the initial outgrowth from calvarial fragments, such as fibroblasts, do not. A reproducible bone cell phenotype was observed in calvarial cells cultured in the alginate polymer for as long as 8 months. Alginate is a uronic acid monomer that reversibly polymerizes based on the presence or absence of divalent cations. Osteoblasts derived from the alginate beads elaborated and mineralized an extracellular matrix in vitro that contained fibronectin, type III collagen, and type I collagen. The synthesis and deposition of these matrix molecules was also demonstrated in the chick embryo calvaria in vivo. Together, these in vitro and in vivo observations provide the first evidence that type III collagen and fibronectin colocalize with type I collagen during the development of avian membranous bone. They also indicate that the phenotype of chick embryo osteoblasts can be expanded to include the synthesis of fibronectin and type III collagen.     

Unique micro- and nano-scale mineralization pattern of human osteogenesis imperfecta type VI bone

Osteogenesis imperfecta (OI) is a heterogeneous group of inheritable connective tissue disorders characterized by mutation in genes involved in collagen synthesis and leading to increased bone fragility, low bone mass, impaired bone material properties and abnormally high bone matrix mineralization. Recessive OI type VI is caused by mutation in SERPINF1 leading to a loss-of-function of pigment epithelium-derived factor (PEDF) a collagen-binding protein with potent antiangiogenic activity. Affected patients develop a severe OI phenotype with a striking histological characteristic, rare in other OI types, of an excess of osteoid tissue and prolonged mineralization lag time.To get insights into matrix mineralization, we evaluated biopsies from 9 affected children by quantitative and by high-resolution backscattered electron imaging and assessed bone mineralization density distribution. Thickness, shape and arrangement of mineral particles were measured in a subset of 4 patients by synchrotron small angle X-ray scattering.Typical calcium content in the bone matrix was found to be increased compared to controls, even exceeding values found previously in OI patients with collagen-gene mutations. A main characteristic however, is the coexistence of this highly mineralized bone matrix with seams showing abnormally low mineral content. Atypical collagen fibril organization was found in the perilacunar region of young osteocytes, suggesting a disturbance in the early steps of mineralization. These observations are consistent with the presence of a heterogeneous population of mineral particles with unusual size, shape and arrangement, especially in the region with lower mineral content. The majority of the particles in the highly mineralized bone areas were less disorganized, but smaller and more densely packed than in controls and in previously measured OI patients.These data suggest that the lack of PEDF impairs a proper osteoblast–osteocyte transition and consequently affects the early steps of mineralization, downstream collagen assembly making OI type VI different from “classical” OI with mutations in collagen-type I encoding genes, despite the typical hypermineralization of the bone matrix.     

Collagen synthesis is not altered in women with stress urinary incontinence

AIMS: The objective of this study was to demonstrate that weakened pelvic floor support of the lower genitourinary tract in women with stress urinary incontinence (SUI) is due, in part, to decreased collagen synthesis and secretion and/or an altered ratio of collagen III/I synthesis by the fibroblasts of the endopelvic fascia and skin compared to that of women without evidence of pelvic floor weakening. METHODS: Endopelvic fascia and skin biopsies were obtained from women with SUI (n = 14) and women without evidence of SUI or genital prolapse (n = 12). Fibroblast cultures established from the biopsies were incubated with 3H-proline in medium containing ascorbic acid for 3 hr. Conditioned medium was collected and cells were harvested. The radiolabeled collagens were precipitated and digested with collagenase. The collagen synthesized (as a percent of total protein) was determined. Collagen alpha1(III) was separated from collagen alpha1(I) and alpha2(I) by interrupted SDS-PAGE and the amount of (3)H-proline in each band was determined. RESULTS: Collagen synthesis, expressed as percent of total protein synthesis, was not significantly different between fibroblasts obtained from women with or without SUI. The mean of collagen III/I synthesized in fibroblasts was not significantly different between fibroblasts obtained from women with or without SUI. CONCLUSIONS: These data suggest that the lower collagen content in the endopelvic fascia and skin of women with SUI is not due to reduced collagen synthesis or selective reduction in synthesis of either collagen I or collagen III, compared to women without pelvic floor weakening.     

Three isolation techniques for primary culture of human osteoblast-like cells: A comparison

The culture of osteoblast-like cells of human origin has become an important experimental model in bone biology. We report here a comparison and evaluation of three of the most widely used systems available today: bone marrow stroma cell cultures (BMSC), human osteoblast explant cultures (hOB) and osteoblast explant cultures from collagenase-treated bone (hOB^col). Cultures from 16 bone specimens obtained from various donors were established and their expression of the osteoblast phenotype were then compared in secondary cultures by use of biochemical markers. BMSC had the highest basal and 1,25-dihy-droxyvitaminD₃ (1,25(OH)₂D.))-induced alkaline phosphatase activities in all cell isolations, with levels approximately twice those in explant cultures. Basal osteocalcin secretion was low-to-undetectable in all cell cultures but was detected in 1,25(OH)₂D₃-stimulated cultures. BMSC produced half of the amount of osteocalcin synthesized in explant cultures. The BMSC cultures also synthesized the lowest amounts of type I collagen, whereas collagen type III synthesis did not differ significantly among the various cultures. When secondary cultures were treated with 100 nM dexam-ethasone in the presence of ascorbic acid (50 u.g/mL) and B-glycerophosphate (10 mM), cultures deposited calcium mineral into the cell layer within 2-4 weeks. PTH-induced cAMP formation was detected in only 5 of 15 isolations and no consistent isolation-dependent response pattern was seen. We conclude that BMSC cultures differ significantly from explant cultures obtained from the same bone specimen. However, all cultures represent cells which can differentiate further and induce mineralization of the extracellular matrix in response to osteoinductive drugs.     

Three isolation techniques for primary culture of human osteoblast-like cells: a comparison

The culture of osteoblast-like cells of human origin has become an important experimental model in bone biology. We report here a comparison and evaluation of three of the most widely used systems available today: bone marrow stroma cell cultures (BMSC), human osteoblast explant cultures (hOB) and osteoblast explant cultures from collagenase-treated bone (hOBcol). Cultures from 16 bone specimens obtained from various donors were established and their expression of the osteoblast phenotype were then compared in secondary cultures by use of biochemical markers. BMSC had the highest basal and 1,25-dihydroxyvitaminD3 (1,25(OH)2D3)-induced alkaline phosphatase activities in all cell isolations, with levels approximately twice those in explant cultures. Basal osteocalcin secretion was low-to-undetectable in all cell cultures but was detected in 1,25(OH)2D3-stimulated cultures. BMSC produced half of the amount of osteocalcin synthesized in explant cultures. The BMSC cultures also synthesized the lowest amounts of type I collagen, whereas collagen type III synthesis did not differ significantly among the various cultures. When secondary cultures were treated with 100 nM dexamethasone in the presence of ascorbic acid (50 microg/mL) and beta-glycerophosphate (10 mM), cultures deposited calcium mineral into the cell layer within 2-4 weeks. PTH-induced cAMP formation was detected in only 5 of 15 isolations and no consistent isolation-dependent response pattern was seen. We conclude that BMSC cultures differ significantly from explant cultures obtained from the same bone specimen. However, all cultures represent cells which can differentiate further and induce mineralization of the extracellular matrix in response to osteoinductive drugs.     

Bone turnover markers in patients with osteogenesis imperfecta

Osteogenesis imperfecta (OI) is a heterologous group of rare inherited bone disorders resulting from defect in collagen synthesis or function. In previous studies, bone turnover has been found either increased or low-normal. These contradictory results might result from the study population made of children with prior recent fractures. We measured serum total and bone alkaline phosphatase (total and bone AP) serum osteocalcin (sOC), serum type I collagen C-telopeptide breakdown products (sCTX), urinary free-deoxypyridinoline (ufDPD), and urinary cross-linked N-telopeptides of type I collagen (uNTX) in 39 male and 38 premenopausal patients with different types of OI aged between 18 and 51 years who had not experienced new clinical fracture during 12 months preceding the laboratory assessment. The study also includes a control group of 29 men and 26 women matched for age and gender.

Most bone markers were 50–200% higher in patients than in controls. Only sCTX was comparable to that found in controls. From a sub-analysis of the data, a trend for higher bone resorption markers was observed for any OI type, but patients with OI type III and IV had significantly higher values in ufDPD and uNTX than patients with type I OI, and their sOC levels were not significantly higher than in controls. These results provide a strong rational for the use of anti-resorbing agent in OI.     

Gene therapy for meniscal injury: enhanced synthesis of proteoglycan and collagen by meniscal cells transduced with a TGFbeta(1)gene

Objective To determine whether meniscal cells can express a TGFbeta(1)transgene delivered by a retroviral vector, and respond to the gene product by increasing matrix synthesis.Methods Monolayer cultures of human and canine meniscal cells were infected with retroviruses carrying either a human TGFbeta(1)cDNA or marker genes. Conditioned media were assayed for the presence of TGFbeta(1). Biosynthesis assays using radiolabeled precursors were employed to determine the effects of the transgenes on the synthesis of proteoglycan, collagen and noncollagenous proteins. Collagen phenotyping was performed by SDS-PAGE.Results Media conditioned by canine and human meniscal cells transduced with the TGFbeta(1)gene, accumulated several nanograms/10(6)cells of TGFbeta(1)during a 48 h incubation. Media conditioned by control cells contained very little TGFbeta(1). Transduction with the TGFbeta(1)gene, but not marker genes, increased the synthesis of collagen and proteoglycan by 8-15-fold. The synthesis of noncollagenous proteins was enhanced more modestly. Monolayers of meniscal cells synthesized types I, III, V and VI collagen. The TGFbeta(1)gene increased the synthesis of all types of collagen without altering the ratios between them. Conclusions Meniscal cells are readily transduced by retroviral vectors and respond to the transfer of a TGFbeta(1)cDNA by greatly increasing matrix synthesis. These findings encourage the further development of genetic approaches to the healing of meniscal lesions.     

Performance of COLIA1 Polymorphism and Bone Turnover Markers to Identify Postmenopausal Women with Prevalent Vertebral Fractures

Some studies have suggested that bone turnover markers (BTM) and collagen type I alpha 1 gene (COLIA1) may be useful in the prediction of rates of future bone loss, and may therefore provide information about fracture risk. Our study aimed to examine the association of the COLIA1 genotype with the risk of vertebral fracture and to investigate the predictive value of this genetic factor in comparison with bone mineral density (BMD) and BTM, in ambulatory postmenopausal Spanish women. We determined the COLIA1 polymorphism by polymerase chain reaction, BMD by dual-energy X-ray absorptiometry and BTM in 43 postmenopausal women with prevalent vertebral fracture and a control group of 101 postmenopausal women without fracture. There was a significant overrepresentation of the ‘T’ allele in fractured women (p= 0.029). BTM exhibited no differences between women with or without fractures or COLIA1 genotype groups. After adjusting for all other variables, the osteoporosis densitometric criteria variable was the most strongly associated with fracture (OR = 5 [1.8–13.3]) followed by COLIA1 (OR = 2.1 [1–4.3] per copy of the ‘T’ allele). Our study shows that COLIA1 is associated with prevalent vertebral fracture independently of bone mass, and the performance of this genetic factor to assess prevalent vertebral fracture is better than bone turnover markers. Received: 29 June 2001 / Accepted: 11 December 2001     

Primary culture of rat growth plate chondrocytes: an in vitro model of growth plate histotype, matrix vesicle biogenesis and mineralization

During endochondral ossification (EO), cartilage is replaced by bone. Chondrocytes of growth plate undergo proliferation, maturation, hypertrophy, matrix vesicle (MV) biogenesis and programmed cell death (PCD, apoptosis). The in vitro system presented here provides a potential experimental model for studying in vitro differentiation and MV biogenesis in chondrocyte cultures. Chondrocytes were obtained from collagenase-digested tibial and femoral growth plate cartilage of 7-week-old rachitic rats. The isolated chondrocytes were plated as monolayers at a density of 0.5 × 10⁶ cells per 35-mm plate and grown for 17 days in BGJ_b medium supplemented with 10% fetal bovine serum, 50 μg/ml ascorbic acid. Light microscopy revealed Sirius red-positive, apparent bone matrix in layers at the surfaces of cartilaginous nodules that developed in the cultures. The central matrix was largely alcian blue staining thus resembling cartilage matrix. Electron microscopy revealed superficial areas of bone like matrix with large banded collagen fibrils, consistent with type I collagen. Most of the central matrix was cartilaginous, with small fibrils, randomly arranged consistent with type II collagen. The presence of peripheral type I and central type II and type X collagen was confirmed by immunohistochemical staining. Immunohistochemistry with anti-Bone morphogenetic proteins 2, 4 and 6 showed that BMP expression is associated with maturing hypertrophic central chondrocytes, many of which were TUNEL positive and undergoing cell death with plasma membrane breaks, hydropic swelling and cell fragmentation. During early mineralization, small radial clusters of hydroxyapatite-like mineral were associated with matrix vesicles. Collagenase digestion-released MVs from the cultures showed a high specific activity for alkaline phosphatase and demonstrated a pattern of AMP-stimulated nonradioactive ⁴⁰Calcium deposition comparable to that observed with native MVs. These studies confirm that primary cultures of rat growth plate chondrocytes are a reasonable in vitro model of growth plate histotype, MV biogenesis and programmed cell death.     

Three-dimensional cultures of normal human osteoblasts: proliferation and differentiation potential in vitro and upon ectopic implantation in nude mice

We report the establishment in vitro of three-dimensional (3D) cultures of human osteoblasts (hOB) derived from normal adults and supported uniquely by the extracellular matrix (ECM) they deposit. Osteoblasts were cultured in 3D cultures in vitro for up to 120 days. The 3D cultures, examined at 25, 31, and 48 days, expressed protein markers of osteoblastic cells, namely osteonectin, collagen type I, fibronectin, osteopontin, bone sialoprotein, biglycan, and decorin. Sequentially, alkaline phosphatase (AP) and then Ca incorporation, mineralization of matrix (monitored by histochemistry and transmission electron microscopy), and finally osteocalcin expression, were detected in the 3D cultures. Ultrastructurally, morphology progressed from early to mature osteoblast and to osteocyte-like. Cells were embedded in a matrix with organized collagen type I fibers containing, increasingly with time of culture, needle-shaped crystals, often associated with matrix vesicles, characteristic of those in bone. During the culture (up to 120 days) there was an outgrowth of proliferating osteogenic cells from the 3D structure. Subcutaneous implantation in nude mice for 20 days of osteoblasts cultured in 3D culture for different lengths of time in vitro, showed progression of mineralization from the inner region of the implant outward, with peripheral cells being embedded in nonmineralized, collagen-rich matrix. The 3D implants were invaded by vessels derived from the host.     

Effects of bone associated growth factors on DNA, collagen and osteocalcin synthesis in cultured fetal rat calvariae

Studies in bone and bone cell cultures have shown that osteocalcin synthesis is dependent on the maturity of the osteoblast and the presence of 1,25-dihydroxyvitamin D3 (1,25(OH)2D3. The bone matrix is a rich source of growth factors that play a role in bone formation, but their effects on osteocalcin synthesis and their interactions with 1,25(OH)2D3 have not been examined. Insulin-like growth factor I (IGF I), basic and acidic fibroblast growth factor (bFGF and aFGF), platelet-derived growth factor (PDGF) and transforming growth factor beta (TGF beta), are growth factors associated with the bone matrix. These factors were shown to stimulate [3H]thymidine incorporation into DNA in 24 h cultures of fetal rat calvariae, and their effect was not modified by 1,25(OH)2D3. IGF I and TGF beta stimulated [3H]proline incorporation into calvarial collagen while the other growth factors studied did not; 1,25(OH)2D3 inhibited collagen synthesis in control as well as in IGF I and TGF beta treated calvariae. IGF I, bFGF and aFGF stimulated osteocalcin synthesis 1.5 to 2.5 fold but only IGF I was synergistic with the stimulatory effect of 1,25(OH)2D3. PDGF and TGF beta had no effect on osteocalcin synthesis. In conclusion, bone matrix-associated factors have important mitogenic effects in bone cultures, but only IGF I and FGFs stimulate osteocalcin synthesis, an effect that is of small magnitude when compared to that of 1,25(OH)2D3.     

Hyaluronan and rat renal fibroblasts: in vitro studies

Hyaluronic acid (HA) is a ubiquitous component of extracellular matrix. After tissue injury, HA appears in greater abundance during the inflammatory response and the phase of clearance of cell and matrix debris, before collagen production and matrix degradation. The aim of this study was to examine whether normal rat renal fibroblasts were capable of HA synthesis and to determine the effect of HA on in vitro collagen production in a series of normal rat cortical fibroblast cultures. Fibroblast cultures from both renal cortex and medulla were established from adult Sprague-Dawley rats. HA synthesis was measured by radioimmunoassay, and incorporation of (3)H-proline into collagen was used to determine collagen synthesis. Fibroblasts were defined on the basis of morphology and alpha smooth muscle actin immunohistochemistry. HA synthesis was measured in both renal cortical and medullary fibroblasts at passage 3 for both 24 and 48 h in 5 animals and expressed as a fraction of protein content. HA was synthesized by both cortical and medullary fibroblasts; however, cortical fibroblasts produced less HA than medullary fibroblasts at both 24 h (p = 0.05) and 48 h (p = 0.02). In normal cortical fibroblasts, exogenous HA suppressed overall total (cell and media) collagen production after a 22-hour labelling period (p = 0.002 compared to controls). Decreased collagen production was also found individually in cell (p = 0.02) and media fractions (p = 0.01). Both cortical and medullary fibroblasts are capable of synthesizing HA in vitro. Furthermore, the findings in this study suggest that HA may be an important mediator in reducing renal cortical fibroblast collagen production and may play an important role in limiting renal interstitial scarring.