Chronic inhibition of ERK1/2 signaling improves disordered bone and mineral metabolism in hypophosphatemic (Hyp) mice

The X-linked hypophosphatemic (Hyp) mouse carries a loss-of-function mutation in the phex gene and is characterized by hypophosphatemia due to renal phosphate (Pi) wasting, inappropriately suppressed 1,25-dihydroxyvitamin D [1,25(OH)?D] production, and rachitic bone disease. Increased serum fibroblast growth factor-23 concentration is responsible for the disordered metabolism of Pi and 1,25(OH)?D. In the present study, we tested the hypothesis that chronic inhibition of fibroblast growth factor-23-induced activation of MAPK signaling in Hyp mice can reverse their metabolic derangements and rachitic bone disease. Hyp mice were administered the MAPK inhibitor, PD0325901 orally for 4 wk. PD0325901 induced a 15-fold and 2-fold increase in renal 1α-hydroxylase mRNA and protein abundance, respectively, and thereby higher serum 1,25(OH)?D concentrations (115 ± 13 vs. 70 ± 16 pg/ml, P < 0.05), compared with values in vehicle-treated Hyp mice. With PD0325901, serum Pi levels were higher (5.1 ± 0.5 vs. 3 ± 0.2 mg/dl, P < 0.05), and the protein abundance of sodium-dependent phosphate cotransporter Npt2a, was greater than in vehicle-treated mice. The rachitic bone disease in Hyp mice is characterized by abundant unmineralized osteoid bone volume, widened epiphyses, and disorganized growth plates. In PD0325901-treated Hyp mice, mineralization of cortical and trabecular bone increased significantly, accompanied by a decrease in unmineralized osteoid volume and thickness, as determined by histomorphometric analysis. The improvement in mineralization in PD0325901-treated Hyp mice was confirmed by microcomputed tomography analysis, which showed an increase in cortical bone volume and thickness. These findings provide evidence that in Hyp mice, chronic MAPK inhibition improves disordered Pi and 1,25(OH)?D metabolism and bone mineralization.     

Intrauterine transplantation of human fetal mesenchymal stem cells from first-trimester blood repairs bone and reduces fractures in osteogenesis imperfecta mice

The inherited skeletal dysplasia osteogenesis imperfecta (OI) results in multiple fractures and is currently treated empirically. We transplanted human first-trimester fetal blood mesenchymal stem cells (MSCs) into homozygous oim mice in utero. This resulted in a two-thirds reduction in long bone fractures (P < .01), with fewer fractures per mouse (median 1, range 0-2 in mice that received transplants vs median 3, range 1-5 in mice that did not receive transplants by 12 weeks, P < .01). Nearly all mice that did not receive transplants had fractures (47 [97.9%] of 48), in contrast to 17 (58.6%) of 29 4- to 12-week-old mice that received transplants (P < .01). Transplantation was associated with increased bone strength (P < .01), thickness (P < .01), and length (P < .01), and normalization/reduction of growth plate height in 4- to 12-week-old oim was reduced in mice that underwent transplantion (P < .001). More donor cells were found in bone tissues compared with other organs (P < .001), with cells clustered in areas of active bone formation and remodeling, and at sites of fracture healing. Donor cells found in the bone expressed osteoblast lineage genes, and produced the extracellular bone structural protein osteopontin. Finally, MSC transplantation decreased bone hydroxyproline content. In conclusion, intrauterine transplantation of fetal MSCs markedly reduced fracture rates and skeletal abnormalities in a mouse model of the intermediate severity type III OI, suggesting a scientific basis for MSC treatment of affected human fetuses.     

X-linked hypophosphatemic mice are not hypersensitive to parathyroid hormone

One of the hypotheses attempting to explain the etiology of the human disease X-linked hypophosphatemia (XLH) posits renal hypersensitivity to parathyroid hormone (PTH). These studies were designed to test this hypothesis in vivo, using the hemizygous hypophosphatemic (Hyp/Y) mouse as an animal model for XLH. Vehicle or 1.0 U bovine PTH (bPTH)/g BW sc was given to intact normal or Hyp mice. Two hours later a small but significant hypercalcemia was observed in both genotypes. Only normal mice remained hypercalcemic 5 h after injection. Intact normal mice, but not Hyp mice, displayed a significant bPTH-induced hypophosphatemia. Administration of bPTH caused a significant increase in both fractional excretion of phosphate (FE-P) and urinary cAMP (UcAMP) 2 h after injection. However, there was no significant differences in the magnitude of response between genotypes. In a different experiment hPTH dose-response curves (0, 0.04, 0.2, and 1.0 U bPTH/g BW sc) were constructed in normal and Hyp mice 18 h after thyroparathyroidectomy (TPTX). bPTH caused a significant hypercalcemia and hypophosphatemia in TPTX normal mice at all doses 2 h after injection. But only the highest dose of hormone caused a significant hypercalcemia in TPTX Hyp mice, and no dose caused a significant decrease in plasma P. In both genotypes a dose-dependent increase in FE-P and UcAMP was observed 2 h after bPTH administration. As with intact mice, there was no indication of a hypersensitive or exaggerated renal response in TPTX Hyp mice. In summary, results from these in vivo experiments indicate that the kidneys of Hyp mice are not hypersensitive to exogenous bPTH. Furthermore, TPTX Hyp mice appeared to exhibit "skeletal resistance" to exogenous PTH, as do osteomalacic dogs and humans. We conclude that renal hypersensitivity to PTH does not play a role in the etiology of XLH in Hyp mice.     

Quantitative histology of myeloma-induced bone changes

S ummary . In order to quantify bone changes which occur in multiple myeloma, undecalcified transiliac bone biopsies from 118 myelomatous patients were analysed by histomorphometric methods. Osteoclastic resorption surfaces were increased compared with controls, and the number of osteoclasts/mm² of bone section was significantly greater in the areas massively invaded by plasma cells than in less invaded areas. The osteoid surfaces were also increased and the percentage of trabeculae that exhibited tetracycline labelling was also greater, indicating increased formation surfaces. However, reduced thickness of the osteoid seams and a low calcification rate, measured after tetracycline double labelling, suggests a reduced activity for each osteoblast. The mean trabecular bone volume was not reduced as compared with controls, but the biopsies showed a heterogeneous distribution of osteolytic and osteosclerotic areas. In the invaded areas, no major histomorphometric difference was found between patients receiving chemotherapy and untreated patients, demonstrating that if usual chemotherapies reduce the tumour mass, they do not improve histological bone lesions in areas still invaded by plasma cells.     

Correction of copper metabolism is not sustained long term in Wilson’s disease mice post bone marrow transplantation

Purpose Alternative cell sources have been sought for the treatment of liver diseases, since liver cells are in short supply for cell transplantation. Although bone marrow-derived cells have been investigated as an alternative cell source, few studies have demonstrated long-term disease correction. Here we examined bone marrow stem cell transplantation into the toxic milk (tx) mouse model for Wilson’s disease, a mild liver disease characterized by hepatic copper accumulation. The aim of this study was to determine whether bone marrow cells engrafted in the liver could sustain correction of abnormal copper metabolism in the tx mouse. Methods Bone marrow cells were isolated from congenic normal mice, transduced to express enhanced green fluorescent protein, sorted for stem cell (Sca-1) and lineage cell (Lin) surface markers, and then transplanted into sub-lethally irradiated normal or tx mice. Analysis for donor cell activity and distribution was undertaken 5 and 9 months post-transplant to allow for sufficient time to repopulate the liver and demonstrate disease correction. Results Donor bone marrow cells engrafted in both normal and tx mouse liver within 5 months. Significantly reduced liver copper was found in tx mice with donor cell liver engraftment at 5 months post-transplant compared to controls, demonstrating partial correction of abnormal copper metabolism in the short term. However, disease correction was not maintained 9 months post-transplantation. Lin⁻Sca-1⁺ cells were more likely to partially correct disease than Lin⁺Sca-1⁻ cells in the short term. Conclusion These results demonstrate that bone marrow transplants cannot maintain disease correction in a mouse model of mild hepatic damage, although initial copper metabolism correction was observed.     

The increased bone mass in deltaFosB transgenic mice is independent of circulating leptin levels

Transgenic mice overexpressing deltaFosB, a naturally occurring splice variant of FosB, develop an osteosclerotic phenotype. The increased bone formation has been shown to be due, at least in part, to autonomous effects of deltaFosB isoforms on cells of the osteoblast lineage. However, abdominal fat and marrow adipocytes are also markedly decreased in deltaFosB mice, leading to low serum leptin levels. Increased bone mass has been linked to the absence of leptin and leptin receptor signaling in ob/ob and db/db mice. Thus, in addition to affecting directly osteoblastogenesis and bone formation, deltaFosB isoforms might increase bone mass indirectly via a decrease in leptin. To test this hypothesis, we restored normal circulating levels of leptin in deltaFosB mice via sc implanted osmotic pumps. Complete histomorphometric analysis demonstrated that trabecular bone volume as well as dynamic parameters of bone formation was unchanged by this treatment in both deltaFosB transgenic mice and control littermates. This demonstration that restoring circulating levels of leptin in deltaFosB transgenic mice failed to rescue the bone phenotype further indicates that the marked increase in bone formation is autonomous to the osteoblast lineage.     

缺碘大鼠的骨发育障碍

目的　研究碘缺乏对大鼠骨发育和骨转换的影响。方法　复制生长发育期碘缺乏大鼠动物模型 ,测定血清中TT3 、TT4、FT4含量 ,对股骨远端 2 /3进行骨计量学测定。结果　碘缺乏大鼠血清TT4、FT4含量显著下降 ,TT3 含量代偿性增加。碘缺乏大鼠骨小梁骨量较正常大鼠明显减少 ,骨小梁体积(TBV) /全部骨组织体积减少约 47% ,TBV/海绵骨体积减少约 3 5 % ,平均骨小梁板厚度减少约 3 6% ,骨小梁表面 /TBV较正常大鼠增加约 3 4% (P <0 .0 1) ,骨皮质平均厚度较正常组减少了 16% (P <0 .0 5 )。碘缺乏大鼠四环素单标记线占全部骨小梁表面的百分比、四环素双标记线占全部骨小梁表面的百分比、平均类骨质宽度、骨小梁类骨质表面占骨小梁表面的百分比、矿化沉积率和组织水平骨形成率均低于正常对照组 (P <0 .0 5或P <0 .0 1) ,矿化延迟时间 (P <0 .0 5 )和类骨质成熟时间 (P <0 .0 1)大于正常大鼠。结论发育期的骨骼对T4的缺乏非常敏感。T4降低时骨骼发育不良 ,骨小梁骨量减少 ,皮质骨的生长也受到影响。碘缺乏组大鼠成骨细胞活性降低和类骨质矿化障碍     

Systemic administration of adrenomedullin(27-52) increases bone volume and strength in male mice.

Adrenomedullin is a 52-amino acid peptide first described in a human phaeochromocytoma but since been found to be present in many tissues, including the vascular system and bone. Because of its structural similarity to amylin and calcitonin gene-related peptide, both of which have actions on bone cells, we have previously assessed the effects of adrenomedullin on the skeleton, and found that it increases osteoblast proliferation in vitro and bone formation following local injection in vivo. The present study carries this work forward by assessing the effects on bone of the systemic administration of a fragment of this peptide lacking the structural requirements for vasodilator activity. Two groups of 20 adult male mice received 20 injections of human adrenomedullin(27-52) 8.1 microg or vehicle over a 4-week period and bone histomorphometry and strength were assessed. In the tibia, adrenomedullin(27-52) produced increases in the indices of osteoblast activity, osteoid perimeter and osteoblast perimeter (P<0.05 for both using Student's t-test). Osteoclast perimeter was not affected. There was a 21% increase in cortical width and a 45% increase in trabecular bone volume in animals treated with adrenomedullin(27-52) (P<0.002 for both). Assessment of bone strength by three-point bending of the humerus showed both the maximal force and the displacement to the point of failure were increased in the animals treated with adrenomedullin(27-52) (P<0.03 for both). There was also a significant increase in the thickness of the epiphyseal growth plate. No adverse effects of the treatment were noted. It is concluded that adrenomedullin(27-52) acts as an anabolic agent on bone. These findings may be relevant to the normal regulation of bone mass and to the design of agents for the treatment of osteoporosis.     

The fate of bone marrow-derived cells carrying a polycystic kidney disease mutation in the genetically normal kidney

ABSTRACT: BACKGROUND: Polycystic Kidney Disease (PKD) is a genetic condition in which dedifferentiated and highly proliferative epithelial cells form renal cysts and is frequently treated by renal transplantation. Studies have reported that bone marrow-derived cells give rise to renal epithelial cells, particularly following renal injury as often occurs during transplantation. This raises the possibility that bone marrow-derived cells from a PKD-afflicted recipient could populate a transplanted kidney and express a disease phenotype. However, for reasons that are not clear the reoccurrence of PKD has not been reported in a genetically normal renal graft. We used a mouse model to examine whether PKD mutant bone marrow-derived cells are capable of expressing a disease phenotype in the kidney. METHODS: Wild type female mice were transplanted with bone marrow from male mice homozygous for a PKD-causing mutation and subjected to renal injury. Y chromosome positive, bone marrow-derived cells in the kidney were assessed for epithelial markers. RESULTS: Mutant bone marrow-derived cells were present in the kidney. Some mutant cells were within the bounds of the tubule or duct, but none demonstrated convincing evidence of an epithelial phenotype. CONCLUSIONS: Bone marrow-derived cells appear incapable of giving rise to genuine epithelial cells and this is the most likely reason cysts do not reoccur in kidneys transplanted into PKD patients.     

Correction of symptoms of platelet storage pool deficiency in animal models for Chediak-Higashi syndrome and Hermansky-Pudlak syndrome

Two human diseases of platelet storage pool deficiency (SPD), Hermansky- Pudlak syndrome and Chediak-Higashi syndrome, are recessively inherited disorders characterized by hypopigmentation, prolonged bleeding, and normal platelet counts accompanied by a reduction in dense granule number. We have recently described seven independent recessive mutations in the mouse regulated by separate genes which are likely animal models for human SPD. Reciprocal bone marrow transplants were carried out between normal C57BL/6J mice and two of these mutants, beige and pallid, in order to test whether the platelet defects are due to a defect in platelet progenitor cells or to humoral factors. Normal and congenic mutant mice were transplanted with marrow after 950 rad whole body radiation. The long bleeding times and low serotonin concentrations of the two mutants were converted to normal values after transplantation with normal marrow. Likewise, normal mice displayed symptoms of SPD when transplanted with mutant marrow. These studies demonstrate that with each of the two mutations, platelet SPD results from a defect in bone marrow precursor cells. Also, the studies suggest that in severe cases, platelet SPD may be successfully treated by bone marrow transplantation.     

Osteomalacia in hyp mice is associated with abnormal phex expression and with altered bone matrix protein expression and deposition

To explore how the loss of Phex function contributes to the pathogenesis of osteomalacia, we examined the abnormalities of mineralization, Phex, and bone matrix protein expression occurring in Hyp mice in vivo and in ex vivo bone marrow cell cultures. The results in vivo show that mineralization was decreased significantly in Hyp mouse bone. Phex protein was identifiable in osteoblasts and osteocytes in wild-type mice, but not in Hyp mice. In Hyp mice, osteocalcin, bone sialoprotein, and vitronectin expression were down-regulated, whereas biglycan and fibrillin-1 expression were up-regulated in osteocytes and bone matrix relative to those in their wild-type counterparts. Parallel studies ex vivo demonstrated that cells derived from 18-day Hyp mouse bone marrow cell cultures had a 3'-Phex deletion, no Phex protein expression, decreased alkaline phosphatase activity, collagen deposition, and calcium accumulation, and reduced osteocalcin, bone sialoprotein, and vitronectin at both the protein and messenger RNA levels. Furthermore conditioned medium from Hyp mouse bone marrow cultures could induce analogous defects in bone marrow cell cultures of wild-type cells. These novel findings indicate that there is an intrinsic osteogenic cell differentiation defect in addition to the known hypomineralization of bone in Hyp mice, which may be inducible by an autocrine/paracrine secreted factor. These results suggest that alterations in the Phex gene may control bone matrix mineralization indirectly by regulating the synthesis and deposition of bone matrix proteins.     

Effects of etidronate-mediated suppression of bone remodeling on aluminum-induced de novo bone formation.

The mechanism by which aluminum chloride stimulates de novo bone formation is unknown. To evaluate the role of bone remodeling and mature osteoblastic function in aluminum-induced neoosteogenesis, we compared the osteogenic effects of aluminum in normal beagles to those in animals with low turnover osteomalacia induced by treatment with etidronate [1-hydroxyethane-1,1-diphosphoric acid (HEBP)]. As assessed by quantitative bone histomorphology, beagles treated with HEBP developed low turnover osteomalacia characterized by a 78% reduction in osteoblast number, a 5.5-fold increase in osteoid volume, complete absence of active mineralization, and diminished resorption surfaces compared to untreated controls. The iv administration of aluminum chloride to normal dogs generated new trabecular structures in the marrow cavity consistent with induction of de novo bone formation. This response consisted of increased trabecular bone volume and number, accumulation of woven osteoid, and increased number of bone-forming cells. The concomitant administration of HEBP failed to prevent induction of de novo bone formation by aluminum. Instead, the neoosteogenic process was superimposed on low turnover osteomalacia in HEBP-treated dogs. Serum aluminum concentrations were increased 2-fold, whereas bone aluminum accumulation was reduced by 58% in HEBP- and aluminum-treated dogs compared to that in aluminum-treated controls. These findings indicate that aluminum stimulation of neoosteogenesis in beagles is independent of mature osteoblast function, normal bone remodeling, and total bone aluminum accumulation. Rather, aluminum-induced de novo bone formation appears to result from stimulation of mesenchymal precursors to form a primitive type of bone which is distinct from coupled bone formation.     

Normal calcitonin stimulation of serum calcitriol in patients with X-linked hypophosphatemic rickets.

Patients with X-linked hypophosphatemic rickets (XLH) have normal or low calcitriol concentrations despite manifesting hypophosphatemia, a known stimulus of 25-hydroxyvitamin D-1 alpha-hydroxylase activity. In accord, administration of pharmacological doses of PTH results in a markedly blunted stimulation of calcitriol levels. In the murine homolog of the human disorder, the Hyp mouse, regulation of 25-hydroxyvitamin D-1 alpha-hydroxylase activity is defective in response to hypophosphatemia and PTH administration, but not in response to calcitonin administration. In the current study we administered calcitonin to controls and patients with XLH to test the hypothesis that calcitonin-stimulatable 25-hydroxyvitamin D-1 alpha-hydroxylase activity is normal in patients with XLH. We found that calcitriol concentrations increased in both groups to a similar degree (78.5 +/- 20.9 pmol/L in patients and 49.9 +/- 19.7 pmol/L in controls) and with a similar time course. Our results indicate that the complex and incomplete defect in the regulation of 25-hydroxyvitamin D-1 alpha-hydroxylase observed in Hyp mice also exists in humans.     

Evaluation of stem cell reserve using serial bone marrow transplantation and competitive repopulation in a murine model of chronic hemolytic anemia

Serial transplantation and competitive repopulation were used to evaluate any loss of self-replicative capacity of bone marrow stem cells in a mouse model with increased and persistent hemopoietic demands. Congenic marrows from old control and from young and old mice with hereditary spherocytic anemia (sphha/sphha) were serially transplanted at 35-day intervals into normal irradiated recipients. Old anemic marrow failed or reverted to recipient karyotype at a mean of 3.5 transplants, and young anemic marrow reverted at a mean of 4.0 transplants, whereas controls did so at a mean of 5.0 transplants. In a competitive assay in which a mixture of anemic and control marrow was transplanted, the anemic marrow persisted to 10 months following transplantation; anemic marrow repopulation was greater if anemic marrow sex matched with the host. It is possible that lifelong stress of severe anemia decreases stem cell reserve in the anemic sphha/sphha mouse marrow. However, marginal differences in serial transplantation number and the maintenance of anemic marrow in a competition assay would suggest that marrow stem cells, under prolonged stress, are capable of exhibiting good repopulating and self-replicating abilities.     

Normal and leukemic SCID-repopulating cells (SRC) coexist in the bone marrow and peripheral blood from CML patients in chronic phase, whereas leukemic SRC are detected in blast crisis

Progress in understanding the abnormal regulation of hematopoiesis in chronic myelogenous leukemia (CML) would be facilitated if neoplastic cells, at all stages of the disease, could be studied in an animal model. In this report, we show that irradiated severe combined immunodeficient (SCID) mice can be transplanted with both normal (Philadelphia chromosome [Ph]-negative) and neoplastic (Ph+) cells from CML patients with either chronic or blast phase disease. Mice transplanted with peripheral blood (PB) or bone marrow (BM) cells from 9 of 12 chronic phase CML patients were well engrafted with human cells including multilineage colony-forming progenitors and CD34+ cells for at least 90 days posttransplantation. Repeated posttransplant injections of cytokines did not enhance the number of engrafted human cells. Interestingly, approximately 70% of the human progenitors found in the engrafted SCID BM were Ph-, suggesting that the growth of primitive normal cells is favored in this in vivo transplant model. A similar number of normal cells were found in mice transplanted with either PB or BM cells, suggesting that elevated numbers of primitive normal cells are present in CML PB. When cells from patients with CML in either myeloid or lymphoid blast crisis were transplanted into SCID mice, the BM of these mice was more rapidly repopulated and to a higher level than that observed with transplants of chronic phase cells. Moreover, all human colony-forming progenitors present in the BM of mice transplanted with blast crisis cells were Ph+, and the majority of cells showed the same morphological features of the blast crisis cells originally transplanted. These experiments provide a starting point for the creation of an animal model of CML and establish the feasibility of using this model for the future characterization of transplantable CML stem cells during disease progression.     

Formation of hematopoietic territories and bone by transplanted human bone marrow stromal cells requires a critical cell density

OBJECTIVE: Bone marrow stromal cells (BMSCs) include multipotent cells with the ability to form mature bone organs upon in vivo transplantation. Hematopoiesis in these bone organs has been ascribed to the action of skeletal stem cells, which are capable of differentiating towards bone and hematopoiesis-supporting stroma. Yet, the creation of hematopoietic territories may be in part a natural consequence of the formation of a sufficiently mature and large bone microenvironment. Here, we describe, for the first time, a relationship between BMSC numbers and the extent of bone/hematopoiesis formation in heterotopic transplants. METHODS: Human BMSCs were transplanted along with hydroxyapatite/tricalcium phosphate, utilizing a spectrum of dosages, into immunotolerant mice; the transplants were followed for up to 29 months. RESULTS: The extent of bone and hematopoiesis formation increased with increasing BMSC numbers; however, the relationship was sigmoid in character, and a threshold number of BMSCs was necessary for extensive bone formation or any hematopoiesis. Hematopoiesis only occurred in conjunction with extensive bone formation, and no hematopoiesis occurred where bone formation was poor. Consistent with our earlier studies of long-term BMSC transplantation, the transplants underwent a change in bone morphology but not bone content after 8 weeks. CONCLUSION: Our results have provided evidence that the formation of both hematopoiesis and a mature bone organ is as much a consequence of a sufficiently high local density of bone marrow stromal cells as it is the product of skeletal stem cell action.     

Development and validation of a radioimmunoassay for mouse osteocalcin: paradoxical response in the Hyp mouse.

The hypophosphatemic (Hyp) mouse is a model for human familial hypophosphatemic rickets. To test the hypothesis that there is an osteoblastic defect in these animals, serum osteocalcin levels were measured in Hyp mice and their normal littermates. Furthermore, the effects of phosphorus deprivation, phosphorus loading, and 1,25-dihydroxyvitamin D3 administration on serum osteocalcin levels were examined. Osteocalcin was purified from mouse hindlimbs, and a polyclonal antibody to this material was produced in a goat. The antibody recognized native and decarboxylated mouse osteocalcin, but could not recognize osteocalcin from several other species. A RIA was developed which had a minimal detection limit of 0.4 nmol/liter (2.2 micrograms/liter) and half-maximal displacement at 2.7-3.3 nmol/liter (14.8-18.2 micrograms/liter). The intraassay coefficient of variation was 6.4%, while the interassay coefficient of variation was 12%. Dilutions of mouse serum samples varied by less than 15%. Analytical recovery was typically greater than 90%. Serum osteocalcin concentrations in Hyp and normal mice were shown to decrease with age. However, circulating osteocalcin levels in Hyp mice were higher than those in their normal littermates regardless of the age of the animal (P less than 0.001). One week of a high phosphorus diet resulted in an increase in serum phosphate in normal and Hyp mice, but serum osteocalcin concentrations were unaffected. On the other hand, dietary phosphorus deprivation for 4 weeks resulted in comparable hypophosphatemia in both Hyp and normal mice, and serum osteocalcin increased in both groups of animals. Intraperitoneal injection of 30 ng/day 1,25-dihydroxyvitamin D3 for 7 days resulted in a 215 +/- 33% increase in serum osteocalcin in normal animals, while the same regimen produced a 250 +/- 29% decrease in the Hyp mouse. Our results are consistent with the hypothesis that abnormal osteoblastic activity is present in Hyp mice. Furthermore, hypophosphatemia may be a general regulator of osteocalcin synthesis or secretion in the mouse.     

Pregnancy-associated plasma protein-A increases osteoblast proliferation in vitro and bone formation in vivo

Pregnancy-associated plasma protein (PAPP)-A, a protease for IGF binding protein (IGFBP)-2, -4, and -5, may enhance IGF action by increasing its bioavailability. Here we have determined the role and mechanism of action of PAPP-A in the regulation of osteoblast proliferation in vitro and bone metabolism in vivo. Recombinant PAPP-A (100 ng/ml) significantly increased osteoblast proliferation and free IGF-I concentration. These effects were abolished by noncleavable IGFBP-4, suggesting that PAPP-A promotes osteoblast proliferation by increasing IGF bioavailability. To determine whether PAPP-A exerts an anabolic effect on bone in vivo, we developed transgenic mice that overexpress PAPP-A in osteoblasts using the 2.3-kb rat type I collagen promoter. Consistent with the increase in IGFBP-4 proteolysis, free IGF-I concentration was significantly increased in the conditioned medium of cultured osteoblasts derived from transgenic mice compared with the wild-type littermates. Calvarial bone thickness, bone marrow cavity, and skull bone mineral density were significantly increased in transgenic mice. Bone size-related parameters in femur and tibia such as total bone area and periosteal circumference as determined by peripheral quantitated computed tomography and histological analysis were significantly increased in transgenic mice. Bone formation rate and osteoid surface were increased by more than 2-fold, whereas bone resorbing surface was unaffected. These anabolic effects were sustained with aging. These findings provide strong evidence that PAPP-A acts as a potent anabolic factor in the regulation of bone formation. Thus, enhancing IGF bioavailability by PAPP-A can be a powerful strategy in the treatment of certain metabolic diseases such as osteoporosis.     

Glucocorticoids act directly on osteoblasts and osteocytes to induce their apoptosis and reduce bone formation and strength

Whether the negative impact of excess glucocorticoids on the skeleton is due to direct effects on bone cells, indirect effects on extraskeletal tissues, or both is unknown. To determine the contribution of direct effects of glucocorticoids on osteoblastic/osteocytic cells in vivo, we blocked glucocorticoid action on these cells via transgenic expression of 11beta-hydroxysteroid dehydrogenase type 2, an enzyme that inactivates glucocorticoids. Osteoblast/osteocyte-specific expression was achieved by insertion of the 11beta-hydroxysteroid dehydrogenase type 2 cDNA downstream from the osteoblast-specific osteocalcin promoter. The transgene did not affect normal bone development or turnover as demonstrated by identical bone density, strength, and histomorphometry in adult transgenic and wild-type animals. Administration of excess glucocorticoids induced equivalent bone loss in wild-type and transgenic mice. As expected, cancellous osteoclasts were unaffected by the transgene. However, the increase in osteoblast apoptosis that occurred in wild-type mice was prevented in transgenic mice. Consistent with this, osteoblasts, osteoid area, and bone formation rate were significantly higher in glucocorticoid-treated transgenic mice compared with glucocorticoid-treated wild-type mice. Glucocorticoid-induced osteocyte apoptosis was also prevented in transgenic mice. Strikingly, the loss of vertebral compression strength observed in glucocorticoid-treated wild-type mice was prevented in the transgenic mice, despite equivalent bone loss. These results demonstrate for the first time that excess glucocorticoids directly affect bone forming cells in vivo. Furthermore, our results suggest that glucocorticoid-induced loss of bone strength results in part from increased death of osteocytes, independent of bone loss.     

A prospective trial of phosphate and 1,25-dihydroxyvitamin D3 therapy in symptomatic adults with X-linked hypophosphatemic rickets.

Current treatment of X-linked hypophosphatemia (XLH) employs the combined administration of oral phosphate and 1,25-dihydroxyvitamin D3 [1,25-(OH)2D3]. Although this drug regimen significantly improves the clinical course of the disease in children, the value of medical treatment in symptomatic adults with XLH has not been established. We, therefore, investigated the clinical, biochemical, and histological responses to phosphate and 1,25-(OH)2D3 in 16 symptomatic adult patients with XLH followed for a mean of 4.2 yr. Eighty-seven percent of the patients had an improvement in bone or joint pain with therapy. There was a significant increase in mean serum phosphate (from 0.61 +/- 0.03 to 0.77 +/- 0.03 mmol/L) and urinary calcium excretion (from 2.45 +/- 0.38 to 4.39 +/- 0.44 mmol/day) with treatment. Pretreatment bone biopsies demonstrated findings characteristic of osteomalacia, including abnormally increased osteoid volume and decreased mineral apposition rates. Treatment was accompanied by a significant decrease in osteoid thickness as well as a reduction in mean osteoid volume. However, therapy did not completely normalize these parameters. Disease severity, as assessed by histomorphometric parameters, did not correlate with any pretreatment serum or urinary biochemical measurement, but did seem to correlate with symptom score. Although most patients tolerated therapy without difficulty, 1 patient developed tertiary hyperparathyroidism during treatment and renal insufficiency that progressed despite cessation of therapy. This study provides evidence that therapy with oral phosphate and 1,25-(OH)2D3 in symptomatic adults with XLH can result in significant clinical and histomorphometric improvement.