Direct inhibition of osteoclast formation and activity by the vitamin E isomer gamma-tocotrienol.

Vitamin E homologues, specifically tocotrienols, have been shown to have favorable effects on bone. They possess properties that are indicative of anti-resorptive activity, suggesting the potential for vitamin E in preventing bone loss. To investigate the anti-resorptive activity of the various vitamin E homologues, we cultured human osteoclasts from blood-derived CD14+ cells on collagen, dentin, and calcium phosphate substrates, with some samples supplemented with vitamin E homologues in their cell culture medium. These were compared to the clinically used bisphosphonate, pamidronate. Compounds were either added at the start of culture to study effects on osteoclast formation, or at the start of osteoclastic resorption to determine their effects on activity. The alpha- and gamma-tocotrienol isomers inhibited osteoclast formation without consequent reduction in total cell number. Only gamma-tocotrienol inhibited osteoclast activity without toxicity. Gamma-tocotrienol was the most potent inhibitor of both osteoclast formation and activity and requires further investigation into its anti-resorptive effects on bone.

The role of electrosprayed apatite nanocrystals in guiding osteoblast behaviour.

Apatite nanocrystals, which mimic the dimensions of natural bone mineral, were electrosprayed on glass substrates, as a suitable synthetic biomedical material for osteoblast outgrowth was explored. A variety of topographic patterns were deposited and the influence of these designs on osteoblast alignment and cell differentiation was investigated. Patterned cell growth and enhanced cell differentiation were seen. Osteoblasts were also cultured on apatite nanocrystals chemically modified with either carbonate or silicon ions. Enhanced cell proliferation and early formation of mineral nodules were observed on apatite nanocrystals with silicon addition. This work highlights the importance of the combined effects of surface topography and surface chemistry in the guidance of cell behaviour.

Characterization of osteocrin expression in human bone.

Osteocrin (Ostn), a bone-active molecule, has been shown in animals to be highly expressed in cells of the osteoblast lineage. We have characterized this protein in human cultured primary human osteoblasts, in developing human neonatal bone, and in iliac crest bone biopsies from adult women. In vivo, Ostn expression was localized in developing human neonatal rib bone, with intense immunoreactivity in osteoblasts on bone-forming surfaces, in newly incorporated osteocytes, and in some late hypertrophic chondrocytes. In adult bone, Ostn expression was specifically localized to osteoblasts and young osteocytes at bone-forming sites. In vitro, Ostn expression decreased time dependently (p<0.02) in osteoblasts cultured for 2, 3, and 6 days. Expression was further decreased in cultures containing 200 nM hydrocortisone by 1.5-, 2.3-, and 3.1-fold (p<0.05) at the same time points. In contrast, alkaline phosphatase expression increased with osteoblast differentiation (p<0.05). Low-dose estradiol decreased Ostn expression time dependently (p<0.05), whereas Ostn expression in cultures treated with high-dose estradiol was not significantly changed. These results demonstrate that Ostn is expressed in human skeletal tissue, particularly in osteoblasts in developing bone and at sites of bone remodeling, suggesting a role in bone formation. Thus, Ostn provides a marker of osteoblast lineage cells and appears to correlate with osteoblast activity.

Vacuolar H+-ATPase d2 subunit: molecular characterization, developmental regulation, and localization to specialized proton pumps in kidney and bone.

The ubiquitous multisubunit vacuolar-type proton pump (H+- or V-ATPase) is essential for acidification of diverse intracellular compartments. It is also present in specialized forms at the plasma membrane of intercalated cells in the distal nephron, where it is required for urine acidification, and in osteoclasts, playing an important role in bone resorption by acid secretion across the ruffled border membrane. It was reported previously that, in human, several of the renal pump's constituent subunits are encoded by genes that are different from those that are ubiquitously expressed. These paralogous proteins may be important in differential functions, targeting or regulation of H+-ATPases. They include the d subunit, where d1 is ubiquitous whereas d2 has a limited tissue expression. This article reports on an investigation of d2. It was first confirmed that in mouse, as in human, kidney and bone are two of the main sites of d2 mRNA expression. d2 mRNA and protein appear later during nephrogenesis than does the ubiquitously expressed E1 subunit. Mouse nephron-segment reverse transcription-PCR revealed detectable mRNA in all segments except thin limb of Henle's loop and distal convoluted tubule. However, with the use of a novel d2-specific antibody, high-intensity d2 staining was observed only in intercalated cells of the collecting duct in fresh-frozen human kidney, where it co-localized with the a4 subunit in the characteristic plasma membrane-enhanced pattern. In human bone, d2 co-localized with the a3 subunit in osteoclasts. This different subunit association in different tissues emphasizes the possibility of the H+-ATPase as a future therapeutic target.

Estrogen stimulates differentiation of megakaryocytes and modulates their expression of estrogen receptors alpha and beta.

Estrogen has multifunctional effects influencing growth, differentiation, and function in many tissues. High-dose estrogen has been shown to produce anabolic skeletal effects in the skeleton of postmenopausal women with increased megakaryocyte (MK) population in the bone marrow, suggesting a possible role for these cells in bone remodelling. To investigate if estrogen stimulates megakaryocytopoiesis and affects on estrogen receptor (ER) expression, CD34(+) cells were cultured for 6, 9, and 14 days plus or minus low-dose or high-dose 17 beta estradiol (E). Cells were immunolocalised for CD61, CD41, ER alpha and beta. ER mRNA expression was assessed by RT-PCR. Cells formed more CD61 positive MK colonies with low- and high-dose E treatment (P < 0.001) at 6 and 9 days. CD41 expression was increased dose-dependently in MK (3- and 5-fold P < 0.001) at 9 days. E-stimulated ER alpha expression at 6 days (P < 0.001) whilst ER beta was dose-dependently increased only at 9 days (P < 0.01). ER alpha mRNA was increased at 6 days but not at 14 days whilst ER beta mRNA expression was only increased at 14 days with E treatment. These results demonstrate that E stimulates the colony forming potential of CD34(+) cells to a more megakaryocytic phenotype in vitro. This finding together with the stimulation of ER protein and mRNA expression adds to the increasing evidence for a role for MKs in estrogen-induced bone formation.

Hydrocortisone increases the rate of differentiation of cultured human osteoblasts.

Reduced bone formation is the main finding in glucocorticoid-induced osteoporosis. The aim of this study was to determine whether differentiation of cultured human osteoblasts is inhibited by high concentrations of hydrocortisone. We measured the levels of mRNAs for three markers of cellular differentiation, type 1 collagen (COL1), alkaline phosphatase (ALP), and osteocalcin (OC), in four lines of human osteoblasts from female donors cultured with doses of hydrocortisone from 0 microM to 4 microM. The change in ALP/COL1 mRNA ratio over a given time was used to determine the average rate of differentiation of the cells in a culture. Although basal expression profiles and their changes with time were different for the different cell lines, all cell lines showed a dose-dependent rise in the rate of increase of ALP mRNA relative to COL1 mRNA. However, increase in OC mRNA with time, seen here only in young donor hOBs, was significantly inhibited by 4 microM hydrocortisone, indicating that hydrocortisone can inhibit OC expression while promoting cellular differentiation. The data suggest that increasing concentrations of glucocorticoid, including concentrations similar to plasma levels in patients receiving oral glucocorticoid therapy, increase the rate of cellular differentiation.

Effects of estrogen on collagen synthesis by cultured human osteoblasts depend on the rate of cellular differentiation.

Estrogen is known to act on osteoblasts according to their stage of differentiation and estrogen receptor (ER) isoform expression. The aim of this study was to determine when type I collagen (COL1) synthesis by cultured low-passage, human bone-derived osteoblasts (hOBs) is upregulated in response to estrogen. Cell lines from female donors aged 1 and 66 years were cultured for 11 days on collagen in growth medium supplemented with human serum, hydrocortisone, and beta-glycerophosphate. Young-donor hOBs grew more quickly than old-donor hOBs and did not mineralize. Old-donor hOBs formed mineralized nodules 5 days after reaching confluence. Changes in mRNA levels with time for ERs, type I collagen, and alkaline phosphatase reflected the faster differentiation of the old-donor cells. The ERbeta/ERalpha ratio fell threefold in young-donor hOBs but rose 300-fold in old-donor hOBs. Increased ERbeta/ERalpha ratios prevented ligand-dependent downregulation of ERalpha transcription, resulting in reduced proliferation in old-donor hOBs. Upregulation of COL1 mRNA expression in response to estrogen was confined to intermediate stages of differentiation, resulting in significant increases in COL1 mRNA by estradiol only in young-donor cells. Since the young and old-donor hOBs were cultured under identical conditions, our results indicate that the response of hOBs to estrogen is largely dependent on intracellular mechanisms that control the timing of cellular differentiation.