Negative regulation of human parathyroid hormone gene promoter by vitamin D3 through nuclear factor Y.

The negative regulation of the human parathyroid hormone (PTH) gene by biologically active vitamin D3 (1,25-dihydroxyvitamin D3; 1,25(OH)2D3) was studied in rat pituitary GH4C1 cells, which express factors needed for the negative regulation. We report here that NF-Y binds to sequences downstream of the site previously reported to bind the vitamin D receptor (VDR). Additional binding sites for NF-Y reside in the near vicinity and were shown to be important for full activity of the PTH gene promoter. VDR and NF-Y were shown to exhibit mutually exclusive binding to the VDRE region. According to our results, sequestration of binding partners for NF-Y by VDR also affects transcription through a NF-Y consensus binding element in GH4C1 but not in ROS17/2.8 cells. These results indicate that 1,25(OH)2D3 may affect transcription of the human PTH gene both by competitive binding of VDR and NF-Y, and by modulating transcriptional activity of NF-Y.

Homotypic interactions of soluble and immobilized osteopontin.

Osteopontin (OPN) is an extracellular matrix protein found in bones and teeth, where it accumulates at matrix-matrix interfaces. We postulate that OPN interacts homotypically and heterotypically in the adhesion of apposing matrices. Using suspensions of OPN-coupled aldehyde/sulfate latex spheres, we measured the strength of homotypic OPN-OPN binding in vitro. Doublets formed through shear-induced collisions in a cone and plate rheoscope were subjected to shear stresses >0.6 Nm(-2) and the fraction broken up determined over 60 s. Rapid initial breakup of 35% of doublets was followed by very slow breakup of the remaining 65%. Monte Carlo simulation of the breakup kinetics pointed to the existence of low and high bond strength populations of doublets. Dynamic light scattering spectroscopy of soluble OPN showed that 27% by mass existed as dimers. We postulate that OPN dimers binding to monomers account for the low strength bonds since a strong bond has already formed between the molecules of the dimer. In contrast, OPN-OPN monomer bonds had higher tensile strength than bonds between the high-affinity interaction of IgG and protein G, previously studied. Antibody blocking studies showed that the self-binding region of OPN resides in the C-terminus. These data suggest that homotypic OPN-OPN bonds have physiologically significant strength, supporting the hypothesis that OPN-OPN binding and self-assembly participate in adhesion within mineralized tissues.

Vitamin D(3) analogs (MC 1288, KH 1060, EB 1089, GS 1558, and CB 1093): studies on their mechanism of action.

Selected 20-epi and 20-normal vitamin D(3) analogs were studied. First, point mutations were introduced into human vitamin D receptor (VDR) to identify residues important for ligand binding. In helices three, four and five, His229, Asp232, Ser237 and Arg274 seem to have an important role in the binding of calcitriol. Surprisingly, the 20-epi analog MC 1288 did not bind to Ser237. Second, the effects of analogs on VDR degradation were studied. The transcriptionally active 20-epi analogs protected VDR against degradation more efficiently than the 20-normal analogs and calcitriol. With proteasome inhibitor MG-132 formation of Sug-1-RXRbeta-VDR-VDRE complex was detected. The 20-epi analogs effectively prevented its formation. Thus, the 20-epi analogs induce a VDR conformation, which prevents binding of factors mediating VDR degradation. Third, the analogs were found to be powerful regulators of cell cycle progression in MG-63 cells. They arrested cell cycle in the G0/G1 phase at lower concentrations and earlier time points than calcitriol. This was accompanied by hypophosphorylation of Rb followed by strong inhibition of Cdk2 activity. This correlated with increased levels of p27. Cdk2 and cyclin E levels were downregulated but those of p21 and cyclin D1 were not affected. Thus, a similar sequence of events with calcitriol and the analogs in inhibiting MG-63 cell growth was detected but the analogs had much longer lasting and stronger effects than calcitriol. A unifying scheme for the varying effects of vitamin D(3) analogs is presented.

The protective effect of hormone-replacement therapy on fracture risk is modulated by estrogen receptor alpha genotype in early postmenopausal women.

Genetic factors regulate bone mineral density (BMD) and possibly development of osteoporosis. It has been suggested that estrogen receptor alpha (ERalpha) genotype is associated with BMD, but the association between ERalpha genotype, fracture risk, and postmenopausal hormone replacement therapy (HRT) has not been studied. Therefore, we evaluated whether ERalpha polymorphism is associated with fracture risk in a 5-year trial with HRT in a population-based, randomized group of 331 early postmenopausal women. The participants consisted of two treatment groups: the HRT group (n = 151) received a sequential combination of 2 mg of estradiol valerate (E2Val) and 1 mg of cyproterone acetate with or without vitamin D3, 100-300 IU + 93 mg calcium as lactate per day; and the non-HRT group (n = 180) received 93 mg of calcium alone or in combination with vitamin D3, 100-300 IU/day. All new symptomatic, radiographically defined fractures were recorded. Pvu II restriction fragment length polymorphism of the ERalpha was determined using polymerase chain reaction (PCR). In all, 28 women sustained 33 fractures during the approximately 5.1-year follow-up. In the HRT group, the ERalpha genotype (PP, Pp, and pp) was not significantly associated with fracture risk (p = 0.138; Cox proportional hazards model). When the genotype was dichotomized (PP + Pp vs. pp), the incidence of new fractures in the HRT group was significantly reduced in women with the P allele (p = 0.046) with the relative risk (HR) of 0.25 (95% CI, 0.07-0.98), in comparison with the non-P allele group. After adjustment for time since menopause and previous fracture, the association between the dichotomous genotype and fracture risk persisted with HR of 0.24 (95% CI, 0.06-0.95;p = 0.042). In the non-HRT group, the ERalpha genotype was not significantly associated with fracture risk. During HRT, women with the pp genotype have a greater fracture risk than those with the P allele. The results suggest that the pp genotype is a relatively hormone-insensitive genotype, and it appears that women with the P allele may benefit more from the protective effect of HRT on fracture risk than women with the pp genotype.

Early postmenopausal bone loss is associated with PvuII estrogen receptor gene polymorphism in Finnish women: effect of hormone replacement therapy.

Genetic factors regulate bone mineral density (BMD) and possibly the development of osteoporosis. An association between estrogen receptor (ER) polymorphism, BMD, and postmenopausal hormone replacement therapy (HRT) has not been established. Therefore, we studied the influence of the ER genotype on BMD before and after a 5-year HRT in a placebo-controlled, population-based, randomized group of 322 early postmenopausal women. The participants were randomized into two treatment groups: the HRT group (n = 145) received a sequential combination of 2 mg estradiol valerate and 1 mg CPA with or without vitamin D3, 100-300 IU + 500 mg calcium lactate/day (equal to 93 mg Ca2+), and the non-HRT group (n = 177) received calcium lactate, 500 mg alone or in combination with vitamin D3, 100-300 IU/day. PvuII restriction fragment length polymorphism (RFLP) of the ERalpha was determined using polymerase chain reaction (PCR). BMDs of the lumbar spine (L2-4) and proximal femur were measured by using dual-energy X-ray absorptiometry (DXA). At the baseline, there were no significant differences in the lumbar or femoral neck BMDs between the three ER PvuII genotype groups (PP, Pp, pp). After 5 years, the BMD of the femoral neck remained unaltered and that of the lumbar spine increased by 1.7% in the HRT group, whereas both BMDs were decreased by 4-5% in the non-HRT group. The ER genotype did not modulate the femoral neck BMD change during the follow-up. In contrast, in the non-HRT-group the lumbar spine BMD decreased more in subjects with the ER genotypes PP (6.4%) and Pp (5.2%) than in subjects with the pp genotype (2.9%) (p = 0.002). In the HRT group, the relative changes of the lumbar spine BMD were similar in all three ER genotype groups. Thus without HRT, the pp genotype was associated with a smaller decrease in the lumbar spine BMD than the Pp and PP genotypes. Long-term HRT seemed to eliminate the ER genotype-related differences in the BMD. We conclude that subjects with the ER PvuII genotypes PP and Pp may have a greater risk of relatively fast bone loss after menopause than those with the pp genotype and that they may preferentially derive benefit from HRT.

Mechanism of action of superactive vitamin D analogs through regulated receptor degradation.

We and others have previously shown that selected vitamin D analogs potentiate the vitamin D receptor (VDR) mediated transcription much more efficiently than the natural hormone itself. Here we show that the transcriptionally active 20-epi analogs, namely KH 1060 and MC 1288, protect VDR against degradation more efficiently than calcitriol at 10(-10) M concentration (VDR t(1/2) > 48 h, 17 h, and 10 h, respectively). The conformationally epi-like analog EB 1089 did not significantly alter the half-life of VDR (10.3 h), but retained the VDR levels over longer periods of time than calcitriol. The transcriptionally weak analog GS 1558, on the other hand, enhanced VDR degradation even more than what was observed with the unliganded receptor (t(1/2) 4.5 h and 5 h, respectively). Inhibition of proteasome activity by the inhibitor MG-132 resulted in a marked increase in the VDR levels in cells treated with the vehicle or GS 1558 (2.5-fold and 2.7-fold, respectively), more than twice the levels observed in the presence of calcitriol or EB 1089 (1.2-fold and 1.1-fold, respectively). MG-132 treatment did not increase the VDR levels in cells treated with KH 1060 or MC 1288. The electrophoretic mobility shift assay (EMSA) with nuclear extracts from MG-132-treated cells revealed formation of a high-molecular-weight RXRbeta-VDR-VDRE complex, which also contained Sug1. In the presence of calcitriol, 34% of total VDR in its DNA binding state was present in this complex. The 20-epi analogs effectively prevented the formation of this complex, since, in this case, only 16% of total VDR was found in this complex. These results suggest that KH 1060 and MC 1288 induce a VDR conformation, which prevents binding of proteins mediating receptor degradation. As a result, the regulation of VDR degradation differs from that found with the calcitriol-VDR complex resulting in superactive transcriptional action of the analogs.

The importance of the putative helices 4 and 5 of human vitamin D(3) receptor for conformation and ligand binding.

The 3-D structure of the human vitamin D(3) receptor has not been solved to date. To study the conformation of the ligand binding pocket and the amino acid residues important for binding of calcitriol and its synthetic 20-epi analog MC1288, we have introduced several point mutations into putative helices 4 and 5 of human vitamin D(3) receptor by site-directed mutagenesis. The amino acid residues Ser256, Glu257, Asp258, Gln259, Lys264, Ser265, Ser266, Glu269, Arg274, Ser278, and Phe279 were substituted by alanine. Our results suggest that Arg274 is important for the binding of calcitriol and probably also for the binding of the synthetic vitamin D analog MC1288, whereas Asp258, Gln259, Glu269, and Phe279 may have an important role in stabilizing the conformation of hVDR after ligand binding.

Structure-function studies of new C-20 epimer pairs of vitamin D3 analogs.

A growing number of calcitriol (1alpha,25-dihydroxyvitamin D3) analogs have become available in recent years. Many of these analogs exhibit lower calcemic effects than calcitriol and inhibit cell proliferation and enhance cell differentation more efficiently than calcitriol. We have compared structure-function relationships of a series of new C-20 epimer (20-epi) vitamin D3 analogs with their natural C-20 counterparts. In human MG-63 osteosarcoma cells, quantification of cellular osteocalcin mRNA levels by Northern blot analysis and osteocalcin biosynthesis by radioimmunoassay indicated that most studied analogs at a concentration of 10 nm induced osteocalcin gene expression more efficiently than the parent compound, calcitriol. Interestingly, when the biological responses were compared with the binding affinities of the analogs to in-vitro translated human vitamin D receptor and with their ability to protect the receptor against partial proteolytic digestion, significant correlations were not observed. Further, molecular modelling of the compounds by energy minimization did not reveal marked differences in the three-dimensional structures of the analogs. These results suggest that higher than normal ligand binding affinity or 'natural' conformation of the ligand-receptor complex are not necessarily required for the 'superagonist' transactivation activity. The mechanism of action of the efficient analogs may involve stabilization and/or differential binding of transcriptional coactivators or transcription intermediary factors to the hVDR during transactivation.

Cross-linking of osteopontin by tissue transglutaminase increases its collagen binding properties.

Osteopontin, a major noncollagenous bone protein, is an in vitro and in vivo substrate of tissue transglutaminase, which catalyzes formation of cross-linked protein aggregates. The roles of the enzyme and the polymeric osteopontin are presently not fully understood. In this study we provide evidence that transglutaminase treatment significantly increases the binding of osteopontin to collagen. This was tested with an enzyme-linked immunosorbent assay. The results also show that this increased interaction is clearly calcium-dependent and specific to osteopontin. In dot blot overlay assay 1 microgram of collagen type I was able to bind 420 ng of in vitro prepared and purified polymeric osteopontin and only 83 ng of monomeric osteopontin, indicating that the transglutaminase treatment introduces a 5-fold amount of osteopontin onto collagen. Assays using a reversed situation showed that the collagen binding of the polymeric form of osteopontin appears to be dependent on its conformation in solution. Circular dichroism analysis of monomeric and polymeric osteopontin indicated that transglutaminase treatment induces a conformational change in osteopontin, probably exposing motives relevant to its interactions with other extracellular molecules. This altered collagen binding property of osteopontin may have relevance to its biological functions in tissue repair, bone remodeling, and collagen fibrillogenesis.

Putative helices 3 and 5 of the human vitamin D3 receptor are important for the binding of calcitriol.

We have introduced eleven point mutations into the human vitamin D receptor by site-directed mutagenesis in order to identify some of the amino acid residues that are important for ligand binding. The amino acid residues Ser225, His229, Asp232, Val234, Ser235, Tyr236, Ser237, Lys240, Ile242, Lys246 (helix 3), and Ser275 (helix 5) of the human vitamin D receptor were substituted by alanine. We report here that His229, Asp232, and Ser237 have an important role in the binding of calcitriol. In addition, the amino acid residues Tyr236 and Ser275 also seem to participate in the ligand binding process.

Inhibition of proliferation and induction of differentiation of osteoblastic cells by a novel 1,25-dihydroxyvitamin D3 analog with an extensively modified side chain (CB1093).

1,25-Dihydroxyvitamin D3 (1,25D) is involved in the regulation of proliferation and differentiation of a variety of cell types including cancer cells. In recent years, numerous new vitamin D3 analogs have been developed in order to obtain favorable therapeutic properties. The effects of a new 20-epi analog, CB1093 (20-epi-22-ethoxy-23-yne-24a,26a,27a-trihomo+ ++-1alpha,25(OH)2D3), on the proliferation and differentiation of human MG-63 osteosarcoma cell line were compared here with those of the parent compound 1,25D. Proliferation of the MG-63 cells was inhibited similarly by 22%, 50% and 59% after treatment with 0.1 microM 1,25D or CB1093 for 48 h, 96 h, and 144 h, respectively. In transfection experiments, the compounds were equipotent in stimulating reporter gene activity under the control of human osteocalcin gene promoter. In cell culture experiments, however, CB1093 was more potent than 1,25D at low concentrations and more effective for a longer period of time in activating the osteocalcin gene expression at mRNA and protein levels. Also, a 6-h pretreatment and subsequent culture for up to 120 h without 1,25D or CB1093 yielded higher osteocalcin mRNA and protein levels with analog-treated cells than with 1,25D-treated cells. The electrophoretic mobility shift assay (EMSA) revealed stronger VDR-VDRE binding with analog-treated MG-63 cells than with 1,25D-treated cells. The differences in the DNA binding of 1,25D-bound vs. analog-bound VDR, however, largely disappeared when the binding reactions were performed with recombinant hVDR and hRXRbeta proteins. These results demonstrate that the new analog CB1093 was equally or even more effective than 1,25D in regulating all human osteosarcoma cell functions ranging from growth inhibition to marker gene expression and that the differences in effectivity most probably resulted from interactions of the hVDR:hRXRbeta-complex with additional nuclear proteins.

Type I procollagen synthesis is regulated by steroids and related hormones in human osteosarcoma cells.

Change in the synthesis of type I collagen, the major extracellular matrix component of skin and bone, are associated with normal growth, tissue repair processes, and several pathological conditions. Expression of the COL 1A1 gene is regulated by transcriptional and post-transcriptional mechanisms. However, the hormonal regulation of type I collagen synthesis in human bone has not been well characterized. We have studied the influence of calcitriol, dexamethasone, retinoic acid, and estradiol on the COL 1A1 gene expression by determining the secretion of the C-terminal propeptide (PICP) and the levels of alpha 1(I) procollagen mRNA in cultured human MG-63 and SaOs-2 osteoblast-like osteosarcoma cells. Similar experiments were also performed with respect to expression of the nuclear proto-oncogenes, c-fos and c-jun, in MG-63 cells. In MG-63 cells, calcitriol stimulated the synthesis and secretion of PICP. The alpha 1(I) procollagen mRNA level was elevated with no effect on message stability, indicating a transcriptional mechanism of regulation. In contrast, dexamethasone treatment was accompanied by an accelerated rate of alpha 1(I) procollagen mRNA turnover, observed as decreased amounts of the message and the secreted PICP, implying a posttranscriptional regulation. Retinoic acid, in turn, decreased the levels of alpha 1(I) procollagen mRNA and secreted PICP by slowing down transcription of the COL1A1 gene without any effect on message stability. The ability of these hormones to regulate the alpha 1(I) transcripts was sensitive to puromycin treatment, suggesting an involvement of an induced mediator protein in the action of the hormones on the COL1A1 gene. Both dexamethasone and calcitriol rapidly but transiently increased the expression of the c-fos and c-jun proto-oncogenes. Neither proto-oncogene responded to retinoic acid treatment with significant changes in mRNA levels. Estradiol treatment was found to have no influence on type I procollagen synthesis. In SaOs-2 cells, which are not as well differentiated as the MG-63 cells, calcitriol and dexamethasone did not influence type I procollagen synthesis. Retinoic acid as well as estradiol reduced collagen gene expression in these cells. These findings suggest that hormonal effects on type I procollagen synthesis may depend on the maturational state of the osteoblastic cells that express different regulatory factors and receptors, resulting in, in each case, a finely adjusted rate of gene expression.

Transglutaminase-catalyzed cross-linking of osteopontin is inhibited by osteocalcin.

Osteocalcin, the most abundant noncollagenous protein of bone matrix, has been demonstrated to inhibit bone growth by gene knockout experiments (Ducy, P., Desbois, C., Boyce, B., Pinero, G., Story, B., Dunstan, C., Smith, E., Bonadio, J., Goldstein, S., Gundberg, C., Bradley, A., and Karsenty, G. (1996) Nature 382, 448-452). Its specific functional mechanism in bone metabolism is, however, largely unknown. In this study, we provide evidence that osteocalcin has an inhibitory effect on tissue transglutaminase activity, as measured by cross-linking of osteopontin, another bone matrix protein. Using a set of synthetic peptides, we found that the inhibitory activity resided within the first 13 N-terminal amino acid residues of osteocalcin. An N-terminal peptide also inhibited cross-linking of another tissue transglutaminase substrate, beta-casein. The inhibitory peptide was shown to have affinity for the substrates of transglutaminase rather than for the enzyme. Since the N terminus of osteocalcin exhibits homology to the substrate recognition site sequences of two transglutaminases, we conclude that the inhibitory effect is most likely due to competition with the enzyme for the transglutaminase-binding region of the substrates, osteopontin and beta-casein, which prevents access of the enzyme to them to perform its function. The interference of osteocalcin with osteopontin cross-linking gives osteocalcin a new potential function as the first protein inhibitor of tissue transglutaminase. This suggests a specific role and a plausible mechanism for it as a modulator of maturation, stabilization, and calcification of bone matrix.

State of methylation of the human osteocalcin gene in bone-derived and other types of cells.

DNA methylation is a general mechanism of controlling tissue-specific gene expression. Osteocalcin is a bone matrix protein whose expression is limited almost entirely to osteoblasts. We were interested in determining whether the state of methylation of the osteocalcin gene plays a role in its expression by studying human bone-derived (MG-63, U2-Os, SaOs-2) and other types (normal lymphocytes, A-498, Hep G2) of cells. Reverse transcription-polymerase chain reaction (RT-PCR) analysis revealed that osteocalcin mRNA production is stimulated by 1,25(OH)2D3 in MG-63 and induced in SaOs-2 but not in U2-Os osteoblast-like osteosarcoma cells. Genomic analysis of the human osteocalcin gene showed that the local surroundings of this single-copy gene are identical in all cell lines studied. Using an isoschizomeric pair of restriction enzymes and Southern analysis, we found that the osteocalcin gene is identically methylated in all three osteosarcoma cell lines. The same sites are also methylated in human normal lymphocytes and A-498 kidney cells, whereas the degree of methylation is higher in Hep G2 human hepatocellular carcinoma cells. Furthermore, the osteocalcin gene was identically protected against enzymatic digestion at the chromatin level in normal lymphocytes and in all cell lines studied. Induction of hypomethylation of DNA by 5-azacytidine treatment did not cause an induction of osteocalcin synthesis in these cell lines. On the contrary, it attenuated the induction by 1,25(OH)2D3 in MG-63 cells. In gel mobility shift assays, human vitamin D receptor and the AP-1 transcription factor bound to an unmethylated response element oligonucleotide of the osteocalcin gene with greater affinity than to an in vitro methylated response element. These results indicate that the in vivo methylation state of the osteocalcin gene at sites determined in this study does not correlate with the inducibility of this gene. Nevertheless, the in vitro results clearly indicated that hypomethylation of critical regions of the osteocalcin gene promoter is a potential mechanism influencing effective binding of specific nuclear factors and, consequently, gene expression.

Conformational studies of human vitamin-D receptor by antipeptide antibodies, partial proteolytic digestion and ligand binding.

We have studied conformational changes of human vitamin-D receptor by using antipeptide antibodies, partial proteolytic digestion and binding of the natural ligand calcitriol or its synthetic analogs. Before exposing either [35S]methionine-labelled in vitro translated human vitamin-D receptor or a recombinant human vitamin-D receptor produced either in Escherichia coli or in Sf9 insect cells to limited proteolysis by trypsin or chymotrypsin, the proteins were treated with calcitriol or its synthetic analogs. The digestion products were analyzed by SDS/PAGE, immunoblotting with polyclonal antipeptide antibodies targeted against different domains of the receptor, and Edman N-terminal sequencing. After limited proteolysis with trypsin, two fragments of Mr 21,000 and Mr 34,000 could be localized into N-terminus and C-terminus of the receptor, respectively, by antipeptide antibodies. We found that treatment with calcitriol or its synthetic analogs leads to differential resistance of the ligand-binding domain of the recombinant receptor to partial proteolysis in vitro. We suggest that this is due to distinct conformational changes in the domain induced by the different ligands. The short N-terminal region and the Zn-finger domain form, however, a protease-resistant structure which is independent on the presence or absence of the ligand. When the C-terminal fragment of Mr 34,000 was further analyzed by Edman N-terminal sequencing, the major cleavage site in the receptor between amino acids Arg173 and His174 was revealed.

Active nuclear transport of chicken lipovitellin-2.

Chicken lipovitellin-2 is a small, approximately 30 kDa yolk protein, derived from the intracellular breakdown of the precursor protein vitellogenin. In principle, lipovitellin-2 is small enough to directly diffuse into the nucleus. Our results, however, demonstrate that its nuclear transport is an active process which can be inhibited by wheat germ agglutinin, chilling, and energy depletion. The N-terminal sequence analysis identifies chicken lipovitellin-2 beginning at Ala1544 in the C-terminal region of vitellogenin yielding of protein of 30,982 Da.

EB 1089, a novel vitamin D analog with strong antiproliferative and differentiation-inducing effects on target cells.

The physiologically active form of vitamin D, 1alpha,25-dihydroxyvitamin D3, plays an important role not only in the establishment and maintenance of calcium metabolism, but also in regulating cell growth and differentiation. As the clinical usefulness of 1alpha,25-dihydroxyvitamin D3 is limited by its tendency to cause hypercalcemia, new analogs with a better therapeutic profile have been synthesized. One of these new synthetic vitamin D analogs is EB 1089, which is characterized by an altered side chain structure featuring 26,27-dimethyl groups and two double bonds. This analog has been shown to be more potent than 1,25-dihydroxyvitamin D3 in inhibiting proliferation, stimulating differentiation, and inducing apoptosis in a number of different cell types, including cancer cells. Despite being more potent than 1alpha,25-dihydroxyvitamin D3 with respect to its cell regulatory effects, EB 1089 displays weaker calcemic side-effects. These characteristics make EB 1089 a potentially useful compound for the treatment of a diversity of clinical disorders, including cancer and metabolic bone diseases. A promising phase I study with EB 1089 in patients with advanced breast and colon cancer has already been carried out, and more clinical trials evaluating the clinical effectiveness of EB 1089 in other types of cancer are in progress.

Synthetic 20-epi analogs of calcitriol are potent inducers of target-gene activation in osteoblastic cells.

We have compared the actions of calcitriol and its three synthetic analogs, 20-epi-22-oxa-24a,26a,27a-trihomo-1 alpha,25-dihydroxyvitamin D3 (KH 1060), 1 alpha,24S-(OH)2-22-ene-26,27-cyclopropyl vitamin D3 (MC 903) and 20-epi-1 alpha,25-dihydroxyvitamin D3 (MC 1288), on the expression of two marker genes of differentiated osteoblasts, namely alkaline phosphatase and osteocalcin, using human MG-63 osteosarcoma cells. Calcitriol and the analogs had qualitatively similar stimulatory effects on target-gene activation. Quantitatively, MC 903 behaved in most experiments essentially as the parent compound calcitriol. In vitamin D receptor/DNA complex formation MC 903, however, was more potent than calcitriol. In contrast, the 20-epi analogs, KH 1060 and MC 1288, were much more potent even at lower concentrations, than calcitriol and MC 903 in stimulating alkaline phosphatase activity, osteocalcin mRNA synthesis and osteocalcin secretion. The stimulation occurred to a greater degree and for a longer period than with calcitriol. This effect was apparently mediated by stronger and longer lasting binding of the vitamin D receptor to the osteocalcin vitamin D responsive element by the 20-epi analogs. After a 6-h treatment and during subsequent culture without hormone, the effects of the 20-epi analogs were also stronger and lasted longer than those with calcitriol or MC 903. Collectively, at comparable and lower concentrations, the 20-epi analogs, KH 1060 and MC 1288, mediate much stronger and longer lasting stimulatory effects than calcitriol or its analog MC 903 on target-gene expression associated with the differentiated phenotype of the MG-63 human osteosarcoma cells.

A novel vitamin D analog with two double bonds in its side chain. A potent inducer of osteoblastic cell differentiation.

EB 1089 (1 alpha,25-dihydroxy-22,24-diene-24,26,27-trihomovitamin D3) is a novel, synthetic analog of calcitriol, characterized by two extra double bonds in its side chain. It is less potent than calcitriol in its calcemic action, but is an order of magnitude more potent in its antiproliferative action. The aim of this study was to determine the ability of EB 1089 to induce the well-known biological effects of calcitriol in MG-63 human osteosarcoma cells (i.e. by inhibiting cell proliferation and by induction of differentiation). Both calcitriol and EB 1089 significantly decreased cell growth after 2 days in culture. At 5 days, however, Eb 1089 was more potent than the natural hormone in inhibiting the proliferation of MG-63 cells. Potent effects of EB 1089 on cell differentiation were also seen in the stimulation of alkaline phosphatase activity, cellular vitamin D receptor mRNA levels, and medium osteocalcin synthesis. EB 1089 was clearly more effective than calcitriol in stimulating alkaline phosphatase activity and osteocalcin synthesis. In gel shift assays, the binding of vitamin D receptor to the composite AP-1 plus vitamin-D responsive promoter region of the human osteocalcin gene after EB 1089 treatment was stronger and longer-lasting than after calcitriol treatment.