ALBERT

Notes: Abstract. Protein tyrosyl phosphorylation is a key determinant of cell proliferation and differentiation. The aim of this study was to test the hypothesis that the signal transduction pathway(s) responsible for human bone cell proliferation may involve different groups of protein tyrosine kinase (PTKs) as compared with that for differentiation. To achieve this, we investigated the effects of two structurally different PTK inhibitors, viz, tyrphostin A51 and genistein, on the proliferation ([3H]thymidine incorporation) and differentiation [alkaline phosphatase (ALP) specific activity and collagen synthesis] of two normal human bone cell types: mandible-derived and vertebra-derived bone cells. Tyrphostin A51 and genistein each markedly reduced cellular tyrosyl phosphorylation level (assessed by Western analysis using a commercial anti-phosphotyrosine antibody and the enhanced chemiluminescence detection assay), confirming that these two effectors are potent PTK inhibitors in human bone cells. Regarding bone cell proliferation, tyrphostin A51 (5–30 μM) caused, a dose-dependent inhibition of basal [3H]thymidine incorporation of both human bone cell types. In contrast, genistein (5–20 μM), not only did not inhibit, but significantly stimulated [3H]thymidine incorporation of these same cell types in a dose-dependent, biphasic manner, with the optimal stimulatory dose between 10 and 20 μM. These effects on cell proliferation were confirmed by cell number counting. In addition, whereas the mitogenic activity of 10 ng/ml epidermal growth factor (EGF) on human mandible-derived bone cells was completely abolished by 5–30 μM tyrphostin A51, genistein at 5–30 μM enhanced the EGF-induced bone cell proliferation in an additive manner. With respect to bone cell differentiation, tyrphostin A51 and genistein each significantly increased basal ALP specific activity and collagen synthesis in human bone cells. In summary, (1) PTKs are involved in human bone cell proliferation and differentiation; (2) tyrphostin A51 inhibited both basal and EGF-induced cell proliferation, thus tyrphostin-sensitive PTKs are involved in basal and EGF-induced human bone cell proliferation; (3) genistein stimulated basal proliferation and enhanced EGF-mediated cell proliferation, suggesting that genistein-sensitive PTKs may play an inhibitory role in human bone cell proliferation; and (4) these differential effects of PTK inhibitors on human bone cell proliferation and differentiation are independent of basal differentiation status of the cells.

Notes: Abstract. Normal intestinal calcium (Ca) absorption is an essential feature of bone homeostasis. As with many other organ systems, intestinal Ca absorption declines with aging, and this is one pathological factor that has been identified as a cause of senile osteoporosis in the elderly. This abnormality leads to secondary hyperparathyroidism, which is characterized by high serum parathyroid hormone (PTH) and an increase in bone resorption. Secondary hyperparathyroidism due to poor intestinal Ca absorption has been implicated not only in senile osteoporosis but also in age-related bone loss. Accordingly, in population-based studies, there is a gradual increase in serum PTH from about 20 years of age onward, which constitutes a maximum increase at 80 years of age of 50% of the basal value seen at 30 years of age. The cause of the increase in PTH is thought to be partly due to impaired intestinal Ca absorption that is associated with aging, a cause that is not entirely clear but at least in some instances is related to some form of vitamin D deficiency. There are three types of vitamin D deficiency: (1) primary vitamin D deficiency, which is due to a deficiency of vitamin D, the parent compound; (2) a deficiency of 1,25(OH)2D3 resulting from decreased renal production of 1,25(OH)2D3; and (3) resistance to 1,25(OH)2D3 action owing to decreased responsiveness to 1,25(OH)2D3 of target tissues. The cause for the resistance to 1,25(OH)2D3 could be related to the finding that the vitamin D receptor level in the intestine tends to decrease with age. All three types of deficiencies can occur with aging, and each has been implicated as a potential cause of intestinal Ca malabsorption, secondary hyperparathyroidism, and senile osteoporosis. There are two forms of vitamin D replacement therapies: plain vitamin D therapy and active vitamin D analog (or D-hormone) therapy. Primary vitamin D deficiency can be corrected by vitamin supplements of 1000 U a day of plain vitamin D whereas 1,25(OH)2D3 deficiency/resistance requires active vitamin D analog therapy [1,25(OH)2D3 or 1α(OH)D3] to correct the high serum PTH and the Ca malabsorption. In addition, in the elderly, there are patients with decreased intestinal Ca absorption but with apparently normal vitamin D metabolism. Although the cause of poor intestinal Ca absorption in these patients is unclear, these patients, as well as all other patients with secondary hyperparathyroidism (not due to decreased renal function), show a decrease in serum PTH and an increase in Ca absorption in response to therapy with 1,25(OH)2D3 or 1α(OH)D3. In short, it is clear that some form of vitamin D therapy, either plain vitamin D or 1,25(OH)2D3 or 1α(OH)D3, can be used to correct all types of age-dependent impairments in intestinal Ca absorption and secondary hyperparathyroidism during aging. However, from a clinical standpoint, it is important to recognize the type of vitamin D deficiency in patients with senile osteoporosis so that primary vitamin D deficiency can be appropriately treated with plain vitamin D therapy, whereas 1,25(OH)2D3 deficiency/resistance will be properly treated with 1,25(OH)2D3 or 1α(OH)D3 therapy. With respect to postmenopausal osteoporosis, there is strong evidence that active vitamin D analogs (but not plain vitamin D) may have bone-sparing actions. However, these effects appear to be results of their pharmacologic actions on bone formation and resorption rather than through replenishing a deficiency.

Notes: Abstract. The mouse is frequently used as an animal model to study skeletal mechanisms relevant to humans. Biochemical markers of bone formation and resorption provide one of the key parameters for assessing skeletal metabolism. One biochemical marker that has proven to be useful in the studies of mouse skeletal metabolism is osteocalcin. Assay for osteocalcin is available in the mouse. The present study describes development of an osteocalcin radioimmunoassay (RIA) using a synthetic peptide. Intact osteocalcin purified from mouse bone extracts shows parallel displacement with synthetic peptide. Sensitivity of the RIA was 19 ng/ml. The average (n = 9) intra- and interassay coefficient of variation for two controls was less than 10%; the averaged recoveries were 106%. The osteocalcin concentration measured by peptide RIA shows a high correlation (r = 0.88, n = 117, P 〈 0.0001) with an intact osteocalcin assay. In addition, when the intact assay and peptide assays were applied to evaluate skeletal perturbation, similar results were obtained. Accordingly, osteocalcin levels measured by both intact and peptide-based RIA in 8-week C57BL/6J (n = 8) mice treated with PTH 1-34 were twofold higher compared with the vehicle-treated control group. Further studies of the application of the peptide-based RIA for osteocalcin revealed that osteocalcin levels in 4-week postovariectomized (OVX) C57BL/6N mice (n = 10) were 80% higher than the sham-operated (n = 10) mice receiving vehicle. OVX mice receiving weekly injections of estradiol (400 μg/kg body weight) were 38% lower compared with the OVX group treated with vehicle. In conclusion, the peptide-based RIA has analytical and a discriminative power similar to that of the intact osteocalcin assay but has the advantage that the resources for this assay are much easier to accrue.

Notes: Summary Bone formation, mineralization, and resorption were measured in vitamin D-deficient, azotemic rats given two different dosages of 24,25(OH)2D3 daily and in vehicle-treated controls (C). The intraperitoneal administration of 65 pmol over a 10 day period corrected the hypocalcemia observed in C, whereas 130 pmol produced mild hypercalcemia. Both dosages reduced osteoid width, osteoid area, and mineralization front width form control values. The rates of bone and matrix formation were unaffected by treatment. In C, matrix formation exceeded bone formation and resulted in osteoid accumulation; both dosages of 24,25(OH)2D3 reversed this relationship such that bone formation exceeded matrix formation in each treatment group. The rates of osteoid maturation and initial mineralization increased during repletion with 24,25(OH)2D3 at both dosage levels. However, the serum calcium concentration was correlated with both osteoid maturation rate (r=0.68,P〈0.01) and initial mineralization rate (r=0.63,P〈0.01) when all three experimental groups were considered. Bone resorption was unchanged from control values during treatment with 24,25(OH)2D3. The results suggest that 24,25(OH)2D3 promotes the maturation and mineralization of osteoid, and that this metabolite differs in its effects on bone formation and resorption. It is not clear, however, that the changes in bone dynamics observed are independent of the calcemic response induced by metabolite repletion under the conditions of this experiment.

Notes: Abstract The aim of this study was to develop a routine and reliable radioimmunoassay (RIA) for dog osteocalcin. Two peaks of dog osteocalcin were purified to apparent homogeneity according to N-terminal sequence analysis. Amino acid composition analysis suggested that the second peak was intact dog osteocalcin whereas the first peak could be a truncated molecule. High titer (〉1:5,000) anti-dog osteocalcin antisera were produced in rabbits. The antiserum recognized dog and rat osteocalcins but not that in serum of human, bovine, rabbit, mouse, guinea pig, or goat. A homologous RIA using anti-dog osteocalcin as the antibody and dog osteocalcin as the tracer and standard was developed. Taking advantages of the facts that (1) anti-dog osteocalcin crossreacted in parallel with rat osteocalcin and (2) purified rat osteocalcin is commercially available, we devised an approach that used rat osteocalcin as the tracer and standard, and anti-dog osteocalcin as the antibody to develop a heterologous RIA. This assay recognized dog serum osteocalcin and diluted in parallel with rat and dog osteocalcins. Quantitation was done using rat osteocalcin to construct standard curves, and results were expressed in ng/ml of rat osteocalcin-equivalent. The detection limit of the assay was 5 ng/ml rat osteocalcin-equivalent, and half-maximal displacement was seen at 30–40 ng/ml rat osteocalcin-equivalent. The inter-and intraassay variations were 16.1% and 8.5%, respectively. The assay accurately determined the amount of exogenously added dog osteocalcin in serum. The results quantitated with this RIA correlated well (r-0.975, n=86) with those obtained with the homologous RIA. Application of the heterologous assay to dogs of different age revealed that young dogs (3 months old) had 15-fold higher serum osteocalcin level than adult (〉2 years old) dogs. In summary, we have (1) purified dog osteocalcin; (2) produced an antiserum against it; and (3) developed a heterologous RIA that could accurately measure dog osteocalcin, and could be used routinely to measure dog osteocalcin.

Notes: Abstract Previous studies have demonstrated that when cells of the mouse osteoblastic cell line MC3T3-E1 are exposed to IGF-I and IGF-II they exhibit rapid and transient induction of the transcript from the proto-oncogene c-fos [8]. To clarify the relationship between induction of cell proliferation and proto-oncogene expression in MC3T3-E1 cells, the acute affects of IGF-I and IGF-II, growth factors that stimulate cell proliferation, and of TGF-β1, which inhibits cell proliferation, northern analyses with cDNA-derived probes for the proto-oncogenes c-jun, jun-B, and jun-D were undertaken. Concurrent northern analyses with a probe for c-fos extended our previous results to include the effect of TGF-β1 on c-fos. IGF-I does not induce the c-jun, jun-B, or jun-D transcripts, the former and latter being produced at detectable levels constitutively. After 1 hour of exposure to IGF-II the c-jun transcript response ranges from onefold to 13-fold and the jun-D transcript response ranges around twofold. After 1 hour of exposure to TGF-β1, the jun-B transcript response ranges from eightfold to 24-fold, the c-fos transcript response ranges between sixfold and sevenfold. The differences observed in the magnitude and kinetics of the induction provoked by these growth factors is consistent with the presence of a regulatory circuit acting through the Jun family members which may act to stimulate transcription differentially when bound to DNA either as homodimers or, with Fos family proteins, as heterodimers.

Notes: Abstract. Biochemical markers applicable to the ovariectomized rat model can provide important tools for studying the bone remodeling process in this animal model of postmenopausal osteoporosis. We describe the development and application of two biochemical markers, a C-telopeptide (of type-I collagen) enzyme-linked immunosorbent assay (ELISA) for measuring bone resorption and an osteocalcin radioimmunoassay (RIA) for measuring bone formation in rat serum. The C-telopeptide ELISA is based on an affinity purified polyclonal antibody generated against human sequence DFSFLPQPPQEKAHDGGR. The antibody epitope involves amino acid sequence, which is similar in rat and human carboxyl terminal peptide of type-I (alpha 1) collagen. Sensitivity of the ELISA was 0.3 ng/ml. The averaged intra- and interassay variation was CV 〈7%. Averaged dilution and spiked recoveries were 91% and 105%, respectively. The second marker developed is a synthetic peptide-based osteocalcin RIA, which does not require isolation and purification of intact osteocalcin from rat bone. Osteocalcin antiserum used in the RIA was generated in rabbits against a synthetic peptide comprising amino acids 33–49 of the rat osteocalcin sequence. The sensitivity of the RIA was 0.15 ng/ml of peptide. The averaged intra (n = 10) and interassay variations for two controls were CV 〈9% and 12%, respectively. The averaged dilution and spiked recoveries were 99.6%. In vivo validation of the C-telopeptide ELISA and osteocalcin RIA was performed in an ovariectomized (OVX) rat model. In 12-week-old OVX Sprague Dawley rats, the C-telopeptide and osteocalcin concentrations were approximately 65% and 40%, respectively, higher than the sham group. Estradiol repletion significantly lowered the C-telopeptide and osteocalcin concentration to the levels of the sham group. In addition, changes in serum C-telopeptide concentration correlated negatively with trabecular BMD measured by pQCT (r =−0.51, P 〈 0.001). In conclusion, the C-telopeptide ELISA and osteocalcin RIA exhibited required sensitivity, accuracy, and adequate discriminatory power to be used for measuring bone resorption and bone formation in the ovariectomized rat model.

Notes: Summary Thyroparathyroidectomized rats fed a diet containing 1.2% calcium, 0.55% phosphorus maintain normal serum levels of these ions. Treatment of such rats with parathyroid extract (PTE; 20 U/100 g twice daily; 10 days) has no statistically significant effect on rates of bone formation, matrix apposition, or osteoid maturation. Significant decreases in osteoid width and mineralizing front width, as well as a 60% increase in the rate of initial mineralization were observed in the PTE-treated group. Conversion of3H-25-hydroxyvitamin D3 to3H-1,25-dihydroxyvitamin D3 was 4-fold higher in the PTE-treated group than in the untreated animals. Increased formation of 1,25-dihydroxyvitamin D3 in response to treatment with PTE may play a major role in correcting the mineralizing defect resulting from thyroparathyroidectomy.

Notes: Summary Clinical studies on the use of sodium fluoride (NaF) in osteoporotic patients have demonstrated increased spinal bone mass without a reduction in vertebral fracture incidence, and a trend towards reduced appendicular bone mass with an increase in peripheral fracture incidence. As previous reports have suggested that NaF becomes incorporated into bone's crystal structure, possibly affecting bone strength, we sought to examine the relationship among bone fluoride content, bone mass, and skeletal fragility. Twenty-one-day-old female Sprague-Dawley rats were treated with four different doses of NaF. The tibiae were subjected to histomorphometric and biochemical analyses, and the femora were tested in torsion for the properties of strength, stiffness, energy storage capacity, and angular deformation. The results showed that over 50% of the skeleton in these rats was turned over in the presence of NaF. The four different doses resulted in a linear increase in bone F concentration and suggested excellent absorption and incorporation of this drug. No changes in histomorphometric indices of bone formation or turnover were found. Despite the large fraction of bone formed during NaF treatment, and the linear increase in bone fluoride content in relation to dose, there were no changes observed in any of the mechanical properties. These results suggest that, even extensive incorporation of fluoride into bone, in the absence of an effect on bone mass or remodeling, does not significantly alter its capacity to withstand mechanical loads.