Race and sex differences in bone mineral density and geometry at the femur.

INTRODUCTION: Differences in osteoporotic hip fracture incidence between American whites and blacks and between women and men are considered to result, in part, from differences in bone mineral density and geometry at the femur. The aim of this study was to quantify differences in femoral bone density and geometry between a large sample of healthy American white and black women and men. SUBJECTS AND METHODS: Healthy American white (n=612) and black (n=164) premenopausal women, aged 23 to 57 years, and healthy American white (n=492) and black (n=169) men, aged 20 to 63 years, had volumetric bone mineral density (vBMD) and geometry variables measured at the femur by computerized tomography (CT), and areal bone mineral density (aBMD) at femoral neck measured by dual X-ray absorptiometry (DXA). RESULTS: American blacks had higher vBMD at the femoral neck and femoral shaft cortex than American whites whereas femoral axis length and femoral neck area were not different. Men had lower vBMD at the femoral neck and femoral cortex than women but had greater femoral axis length and femoral neck area than women. The higher aBMD in American blacks than whites persisted after correction for measured area whereas the higher aBMD in men than women disappeared. CONCLUSIONS: At the femoral neck, American whites have lower bone density than American blacks but similar geometry. Women have higher bone density than men in both races but have smaller geometry variables. The differences in bone density may account in part for the differences in hip fracture incidence between American blacks and whites, whereas the differences in femur size may account for the differences in hip fracture rates between men and women.

Evaluation of vertebral fracture assessment by dual X-ray absorptiometry in a multicenter setting.

SUMMARY: The utility of vertebral fracture assessment (VFA) by DXA to detect prevalent vertebral fracture in a multicenter setting was investigated by comparison to conventional radiography. While limited by lower image quality, overall performance of VFA was good but had a tendency to miss mild prevalent fractures. INTRODUCTION: In osteoporosis clinical trials standardized spine radiographs are used to detect vertebral fractures as a study endpoint. Lateral spine imaging with dual X-ray absorptiometry (DXA) scanners, known as vertebral fracture assessment (VFA) by DXA, presents a potential alternative to conventional radiography with lower radiation dose and greater patient convenience. METHODS: We investigated in a multicenter setting the ability of VFA to detect fractures in comparison with conventional radiography. The study examined 203 postmenopausal women who had imaging of the spine by DXA and radiography. Three radiologists experienced in vertebral fracture assessment independently read the VFA scans and radiographs using the Genant semiquantitative method on two occasions. CONCLUSIONS: Analyzing the data from all readable vertebrae, the kappa statistic, sensitivity, and specificity ranged from 0.64-0.77, 0.65-0.84, and 0.97-0.98, respectively. Considering only moderate and severe fractures improved the kappa statistic (0.80-0.91) and sensitivity (0.70-0.86). While image quality of VFA is inferior to radiography, the detection of vertebral fractures using visual scoring is feasible. However, VFA underperformed due to unreadable vertebrae and reduced sensitivity for mild fractures. Nevertheless, VFA correctly identified most moderate and severe vertebral fractures. Despite this limitation, VFA by DXA provides an important tool for clinical research.

Effect of raloxifene after recombinant teriparatide [hPTH(1-34)] treatment in postmenopausal women with osteoporosis.

UNLABELLED: Loss of bone mineral density occurs after discontinuation of teriparatide, if no subsequent treatment is given. Sequential raloxifene prevented rapid bone loss at lumbar spine and further increased bone mineral density (BMD) at femoral neck, whether raloxifene was started immediately or after a one-year delay following teriparatide treatment. INTRODUCTION: We compared the sequential effects of raloxifene treatment with a placebo on teriparatide-induced increases in bone mineral density (BMD). A year of open-label raloxifene extended the study to assess the response with and without delay after discontinuation of teriparatide. METHODS: Following a year of open-label teriparatide 20 mug/day treatment, postmenopausal women with osteoporosis were randomly assigned to raloxifene 60 mg/day (n = 157) or a placebo (n = 172) for year 2, followed by a year of open-label raloxifene. BMD was measured by dual energy x-ray absorptiometry. RESULTS: The raloxifene and placebo groups showed a decrease in lumbar spine (LS) BMD in year 2 for raloxifene and placebo groups (-1.0 +/- 0.3%, P = 0.004; and -4.0 +/- 0.3%, P < 0.001, respectively); the decrease was less with raloxifene (P < 0.001). Open-label raloxifene treatment reversed the LS BMD decrease with a placebo, resulting in similar decreases 2 years after randomization (-2.6 +/- 0.4% (raloxifene-raloxifene) and -2.7 +/- 0.4% (placebo-placebo). At study end, LS and femoral neck (FN) BMD were higher than pre-teriparatide levels, with no significant differences between the raloxifene-raloxifene and placebo-raloxifene groups, respectively (LS: 6.1 +/- 0.5% vs. 5.1 +/- 0.5%; FN: 3.4 +/- 0.6% vs. 3.0 +/- 0.5%). CONCLUSION: Sequential raloxifene prevented rapid bone loss at the LS and increased FN BMD whether raloxifene was started immediately or after a one-year delay following teriparatide treatment.

Association studies of ALOX5 and bone mineral density in healthy adults.

UNLABELLED: Animal studies suggest that arachidonate 5-lipoxygenase (encoded by ALOX5) may be a genetic determinant of bone mineral density. We tested this hypothesis in a sample of healthy men and women and did not find consistent evidence for an association between variation in this gene and either lumbar spine or femoral neck BMD. INTRODUCTION: Phenotypic variation in bone mineral density (BMD) among healthy adults is influenced by both genetic and environmental factors. A recent mouse study implicated ALOX5, which encodes arachidonate 5-lipoxygenase, as a contributing factor to areal BMD (aBMD). METHODS: Fifteen single nucleotide polymorphisms (SNPs) distributed throughout ALOX5 were genotyped in three healthy groups: 1,688 European American, premenopausal sisters, 512 African American premenopausal sisters and 715 European American brothers. Statistical analyses were performed in the three groups to test for association between these SNPs and femoral neck and lumbar spine aBMD. RESULTS: Significant (p < or = 0.05) evidence of association was observed with three of the SNPs. However, despite the linkage disequilibrium between SNPs, adjacent SNPs did not provide statistical evidence of association in any of the three study groups. CONCLUSIONS: These data do not provide consistent evidence of association between genomic variation in ALOX5 and clinical variability in aBMD in healthy subjects.

Identification of a quantitative trait locus on rat chromosome 4 that is strongly linked to femoral neck structure and strength.

Risk factors for osteoporotic hip fracture include reduced bone mineral density and poor structure of the femoral neck, both of which are heritable traits. Previously, we showed that despite similar body size, Fischer 344 (F344) rats have significantly different skeletal traits compared with Lewis (LEW) rats. To identify a gene or genes regulating fracture risk at the femoral neck, we mapped quantitative trait loci (QTL) for femoral neck density and structure phenotypes using a 595 F2 progeny derived from the inbred F344 and LEW strains of rats. Femoral neck phenotypes included volumetric bone mineral density (vBMD), neck width, femoral neck cross-sectional area and polar moment of inertia (Ip). A 20-cM genome-wide scan was performed using 118 microsatellite markers and linkage analysis was conducted to identify chromosomal regions harbor QTL for femoral neck phenotypes. Strong evidence of linkage (P<0.01) to femoral neck vBMD was observed on chromosomes (Chrs) 1, 2, 4, 5, 7, 10 and 15. QTL affecting femoral neck structure and biomechanical properties were detected only on Chr 4 where the F344 alleles were shown to improve femoral neck structure, whereas these alleles had no effect on bone measurements at the lumbar spine and only modest effects at the femoral midshaft. In contrast, QTL on Chrs 1, 2 and 10 affected multiple skeletal sites. Several QTL regions in this study are homologous to human chromosomal regions, where linkage to femoral neck and related phenotypes has been reported previously. These findings represent an important first step in localizing and identifying genes that influence hip fragility.

Polymorphisms in the bone morphogenetic protein 2 (BMP2) gene do not affect bone mineral density in white men or women.

INTRODUCTION: Peak bone mineral density (BMD) achieved during adulthood is a major determinant of osteoporotic fracture in later life. Although environmental factors affect peak BMD, it is a highly heritable trait. Recently, bone morphogenetic protein 2 (BMP2) was reported as a susceptibility gene for osteoporotic fractures and low BMD in Icelandic and Danish populations. METHODS: To determine whether polymorphisms in the BMP2 gene contribute to BMD variation in our population of healthy American whites, we tested seven single nucleotide polymorphisms (SNPs), four of which were associated with osteoporotic phenotypes in the previous study. BMD at the femoral neck and lumbar spine (L2-L4) were measured by dual energy X-ray absorptiometry (DXA) in 411 men (age 18-61) and 1,291 pre-menopausal women (age 20-50). SNP genotypes/haplotypes were tested for population-based association with BMD using analysis of variance. RESULTS: None of the polymorphisms tested reached statistical significance (all p values >0.05) for BMD at the femoral neck or lumbar spine in either gender. Two of the SNP haplotypes spanning the entire BMP2 gene were marginally associated with BMD in men (p values=0.019-0.043). However, these haplotypes would account for only a small, if any, portion of BMD variation and would not be significant after adjustment for multiple comparisons. CONCLUSIONS: These results demonstrate that genetic variations in BMP2 do not substantially contribute to BMD variation in our population of healthy American whites.

FGF-23 is elevated by chronic hyperphosphatemia.

The Identification and characterization of FGF-23 has provided an opportunity to gain new insight into phosphorus metabolism. Circulating FGF-23 promotes renal excretion of phosphorus, and FGF-23 is measurable in the serum of normal subjects. Serum levels of FGF-23 are elevated in patients with renal phosphate wasting disorders such as tumor induced osteomalacia, X-linked hypophosphatemia and fibrous dysplasia. However, the factors that alter its serum concentration are not known. The study of serum FGF-23 is confounded by the fact that high serum calcium, PTH, and any other putative phosphotonins, have similar effects on serum and urine phosphorus. To circumvent the confounding effect of serum PTH and calcium, we studied serum FGF-23 and phosphate levels in patients with chronic hypoparathyroidism and hyperphosphatemia. Serum was collected in the morning after an overnight fast from three groups: 1) 9 patients with chronic hypoparathyroidism on stable treatment with calcium and calcitriol, 2) 9 patients with primary hyperparathyroidism, and 3) 77 normal controls. Patients with hypoparathyroidism had predictably higher levels of serum phosphorus than patients with hyperparathyroidism or normal controls (5.6 +/- 1.1, 3.1 +/- 0.6, and 3.1 +/- 0.5 mg/dL, mean +/- 1 SD, respectively (p < 0.01 for hypoparathyroid vs. either group)). They also had higher levels of FGF-23 (150 +/- 120 vs. 70 +/- 60, or 55 +/- 20 RIU/ml, respectively (p < 0.05 vs. either group)). In conclusion, serum FGF-23 levels are elevated in patients with hyperphosphatemia and chronic hypoparathyroidism, suggesting a feedback system in which serum FGF-23 responds to serum phosphorus and regulates it. However, in the setting of chronic hypoparathyroidism, the degree of elevation of FGF-23 is insufficient to normalize serum phosphorus.

Resolution of severe, adolescent-onset hypophosphatemic rickets following resection of an FGF-23-producing tumour of the distal ulna.

Oncogenic hypophosphatemic osteomalacia (OHO) is an uncommon hypophosphatemic syndrome characterized by bone pain, proximal muscle weakness and rickets. It has been postulated that OHO results from overproduction of a humoral phosphaturic factor by an occult tumour. Recently, some OHO tumours have been shown to elaborate fibroblast growth factor-23 (FGF-23), which causes renal phosphate wasting when administered to mice. The purpose of this study was to undertake detailed investigations to confirm the diagnosis of OHO in a pediatric patient and to document the biochemical, radiographic and bone histological phenotype before and after tumour removal. We describe an 11-year-old, previously healthy girl with significant pain and functional disability associated with hypophosphatemic rickets. Circulating 1,25-(OH)(2) vitamin D was very low (14 pM; N: 40-140) while the FGF-23 serum level was markedly elevated [359.5 reference units (RU)/ml, N: 33-105]. An iliac bone biopsy revealed severe osteomalacia, but periosteocytic lesions, as are typical for X-linked hypophosphatemic rickets, were not seen. Sequence analyses of the PHEX and FGF23 genes were normal. A radiographic skeletal survey revealed a small exostosis of the left, distal ulnar metaphysis. A tumour was subsequently removed from this site and the pathology was consistent with benign, fibro-osseous tissue. Serum FGF-23 was normal when measured at 7 h post-operatively, while serum phosphate reached the low-normal range at 16 days following surgery. An iliac bone biopsy taken 5 months after the operation showed improvement, but not yet resolution, of the osteomalacia. Biochemical parameters of bone and mineral metabolism suggested that complete resolution of the osteomalacia was not achieved until 12 months following surgery. One year after tumour removal, the patient was pain-free and had resumed a normal level of activity. The rapid normalization of FGF-23 levels following removal of a benign tumour and the subsequent improvement in the biochemical and histological parameters of bone and mineral metabolism suggest that FGF-23 played a key role in this girl's disease.

Linkage of structure at the proximal femur to chromosomes 3, 7, 8, and 19.

Risk for osteoporotic fracture is determined in part by femoral structure, which is under genetic control. We conducted a genome scan in 638 sister-pairs for structure phenotypes. Significant evidence of linkage was detected with several chromosomal regions, including confirmation of our prior linkage findings. Bone strength and resistance to fracture at the proximal femur is determined in part by structural variables. We previously reported that several structural variables, including pelvic axis length, femur axis length, femur head width, and femur midshaft width, had significant or suggestive linkage to regions of chromosomes 3, 4, 5, 7, 9, 17, and 19 in a sample of 309 white premenopausal sister pairs. We now report the results of a genome-wide linkage analysis of femoral structure variables in 437 white and 201 black healthy premenopausal sister pairs, of which 191 white pairs overlapped with our previously published sample. Multipoint quantitative linkage analysis was performed using microsatellite markers genotyped throughout the genome. In the current sample, linkage of femoral structure to chromosomes 3, 7, and 19 was confirmed in the white sister pairs, and a new linkage to chromosome 8 was identified. There was linkage at chromosome 3 to femoral head width (logarithm of the odds [LOD] = 5.0) and femur shaft width (LOD = 3.6). On chromosome 19, there was linkage to femoral neck axis length (LOD = 3.2); on chromosome 7, to femoral head width (LOD = 5.0); and on chromosome 8, to femoral head width (LOD = 6.0). The current findings emphasize the importance of increasing sample size to replicate linkage findings and identify new regions of linkage.

Autosomal-dominant hypophosphatemic rickets (ADHR) mutations stabilize FGF-23.

BACKGROUND: The gene for the renal phosphate wasting disorder autosomal-dominant hypophosphatemic rickets (ADHR) is FGF23, which encodes a secreted protein related to the fibroblast growth factors (FGFs). We previously detected missense mutations R176Q, R179W, and R179Q in FGF23 from ADHR kindreds. The mutations replace R residues within a subtilisin-like proprotein convertase (SPC) cleavage site 176RHTR-179 (RXXR motif). The goal of these studies was to determine if the ADHR mutations lead to protease resistance of FGF-23. METHODS: The ADHR mutations were introduced into human FGF-23 cDNA clones with or without an N-terminal FLAG tag by site-directed mutagenesis and were transiently transfected into HEK293 cells. Protein expression was determined by Western analyses. RESULTS: Antibodies directed toward the C-terminal portion of FGF-23 revealed that the native FGF-23 protein resolved as 32 kD and 12 kD species in HEK293 conditioned media; however, the three mutated proteins were detected only as the 32 kD band. An N-terminal FLAG-tagged native FGF-23 resolved as two bands of 36 kD and 26 kD when detected with a FLAG antibody, whereas the R176Q mutant resolved primarily as the 36 kD protein species. Cleavage of FGF-23 was not enhanced by extracellular incubation of FGF-23 with HEK293 cells. Native and mutant FGF-23s bound heparin. CONCLUSIONS: FGF-23 proteins containing the ADHR mutations are secreted, and produce polypeptides less sensitive to protease cleavage than wild-type FGF-23. Therefore, the ADHR mutations may protect FGF-23 from proteolysis, thereby potentially elevating circulating concentrations of FGF-23 and leading to phosphate wasting in ADHR patients.

Genome screen for quantitative trait loci underlying normal variation in femoral structure.

Femoral structure contributes to bone strength at the proximal femur and predicts hip fracture risk independently of bone mass. Quantitative components of femoral structure are highly heritable traits. To identify genetic loci underlying variation in these structural phenotypes, we conducted an autosomal genome screen in 309 white sister pairs. Seven structural variables were measured from femoral radiographs and used in multipoint sib-pair linkage analyses. Three chromosomal regions were identified with significant evidence of linkage (log10 of the odds ratio [LOD] > 3.6) to at least one femoral structure phenotype. The maximum LOD score of 4.3 was obtained for femur neck axis length on chromosome 5q. Evidence of linkage to chromosome 4q was found with both femur neck axis length (LOD = 3.9) and midfemur width (LOD = 3.5). Significant evidence of linkage also was found to chromosome 17q, with a LOD score of 3.6 for femur head width. Two additional chromosomal regions 3q and 19p gave suggestive (LOD > 2.2) evidence of linkage with at least two of the structure phenotypes. Chromosome 3 showed evidence of linkage with pelvic axis length (LOD = 3.1), midfemur width (LOD = 2.8), and femur head width (LOD = 2.3), spanning a broad (60 cm) region of chromosome 3q. Linkage to chromosome 19 was supported by two phenotypes, femur neck axis length (LOD = 2.8) and femur head width (LOD = 2.8). This study is the first genome screen for loci underlying variation in femoral structure and represents an important step toward identifying genes contributing to the risk of osteoporotic hip fracture in the general population.

The autosomal dominant hypophosphatemic rickets (ADHR) gene is a secreted polypeptide overexpressed by tumors that cause phosphate wasting.

The gene mutated in autosomal dominant hypophosphatemic rickets (ADHR), a phosphate wasting disorder, has been identified as FGF-23, a protein that shares sequence homology with fibroblast growth factors (FGFs). Patients with ADHR display many of the clinical and laboratory characteristics that are observed in patients with oncogenic hypophosphatemic osteomalacia (OHO), a disorder thought to arise by the secretion of a phosphate wasting factor from different mesenchymal tumors. In the present studies, we therefore investigated whether FGF-23 is a secreted factor and whether it is abundantly expressed in OHO tumors. After transient transfection of OK-E, COS-7, and HEK293 cells with the plasmid encoding full-length FGF-23, all three cell lines efficiently secreted two protein species into the medium that were approximately 32 and 12 kDa upon SDS-PAGE and subsequent Western blot analysis using an affinity-purified polyclonal antibody to FGF-23. Furthermore, Northern blot analysis using total RNA from five different OHO tumors revealed extremely high levels of FGF-23 mRNA, and Western blot analysis of extracts from a sixth tumor detected the 32 kDa FGF-23 protein species. In summary, FGF-23, the gene mutated in ADHR, is a secreted protein and its mRNA is abundantly expressed by several different OHO tumors. Our findings indicate that FGF-23 may be a candidate phosphate wasting factor, previously designated "phosphatonin".

Disorders of phosphate metabolism.

Correct identification of the disorders of hypophosphatemia and hyperphosphatemia is important for determining therapy. Further research will provide insights into normal phosphate homeostasis, a complex and fascinating process.

Genome screen for QTLs contributing to normal variation in bone mineral density and osteoporosis.

A major determinant of the risk for osteoporosis is peak bone mineral density (BMD), which is largely determined by genetic factors. We recently reported linkage of peak BMD in a large sample of healthy sister pairs to chromosome 11q12-13. To identify additional loci underlying normal variations in peak BMD, we conducted an autosomal genome screen in 429 Caucasian sister pairs. Multipoint LOD scores were computed for BMD at four skeletal sites. Chromosomal regions with LOD scores above 1.85 were further pursued in an expanded sample of 595 sister pairs (464 Caucasians and 131 African-Americans). The highest LOD score attained in the expanded sample was 3.86 at chromosome 1q21-23 with lumbar spine BMD. Chromosome 5q33-35 gave a LOD score of 2.23 with femoral neck BMD. At chromosome 6p11-12, the 464 Caucasian pairs achieved a LOD score of 2.13 with lumbar spine BMD. Markers within the 11q12-13 region continued to support linkage to femoral neck BMD, although the peak LOD score was decreased to 2.16 in the sample of 595 sibling pairs. Our study is the largest genome screen to date for genes underlying variations in peak BMD and represents an important step toward identifying genes contributing to osteoporosis in the general population.

MEPE, a new gene expressed in bone marrow and tumors causing osteomalacia.

Oncogenic hypophosphatemic osteomalacia (OHO) is characterized by a renal phosphate leak, hypophosphatemia, low-serum calcitriol (1,25-vitamin-D3), and abnormalities in skeletal mineralization. Resection of OHO tumors results in remission of the symptoms, and there is evidence that a circulating phosphaturic factor plays a role in the bone disease. This paper describes the characterization and cloning of a gene that is a candidate for the tumor-secreted phosphaturic factor. This new gene has been named MEPE (matrix extracellular phosphoglycoprotein) and has major similarities to a group of bone-tooth mineral matrix phospho-glycoproteins (osteopontin (OPN; HGMW-approved symbol SPP1), dentin sialo phosphoprotein (DSPP), dentin matrix protein 1 (DMP1), bone sialoprotein II (IBSP), and bone morphogenetic proteins (BMP). All the proteins including MEPE contain RGD sequence motifs that are proposed to be essential for integrin-receptor interactions. Of further interest is the finding that MEPE, OPN, DSPP, DMP1, IBSP, and BMP3 all map to a defined region in chromosome 4q. Refined mapping localizes MEPE to 4q21.1 between ESTs D4S2785 (WI-6336) and D4S2844 (WI-3770). MEPE is 525 residues in length with a short N-terminal signal peptide. High-level expression of MEPE mRNA occurred in all four OHO tumors screened. Three of 11 non-OHO tumors screened contained trace levels of MEPE expression (detected only after RT-PCR and Southern 32P analysis). Normal tissue expression was found in bone marrow and brain with very-low-level expression found in lung, kidney, and human placenta. Evidence is also presented for the tumor secretion of clusterin (HGMW-approved symbol CLU) and its possible role as a cytotoxic factor in one of the OHO patients described.

Heterogeneity in Paget disease of the bone.

Paget disease of the bone is a common skeletal disorder. Recently, a gene for Paget disease was localized to 18q with subsequent evidence for linkage heterogeneity. We report the identification and clinical characterization of a large pedigree of Paget disease and demonstrate that the Paget disease gene in this pedigree is not linked to the region on 18q, thus confirming linkage heterogeneity.