Jon E. Wergedal

Formation, mineralization, and resorption of bone in vitamin D-deficient rats.

Quantitative histologic methods have been devised to measure several processes dealing with formation and mineralization of matrix and bone resorption. In vitamin D-deficient rats, the total osteoblastic matrix formation rate was 20% less and the total osteoclastic bone resorption rate was 80% more than in pair-fed control rats. These changes were found to be primarily because of changes in the rates of matrix formation and of bone resorption per unit area of forming or resorbing surfaces rather than to changes in the areas of these surfaces. The rate of maturation of osteoid and the rate of initial mineralization both were reduced to half of normal in the vitamin D-deficient rats. These variables related to matrix formation and mineralization were significantly correlated with the concentration of calcium but not with the concentration of phosphate in serum. The occurrence of hypocalcemia is interpreted as the consequence, both of reduced calcium absorption and of inadequate resorptive response of bone cells to homeostatic stimuli, such that, although bone resorption was greater than normal, it did not adequately compensate for the reduced intestinal absorption.

TWIST, a basic helix-loop-helix transcription factor, can regulate the human osteogenic lineage.

Basic helix‐loop‐helix (bHLH) transcription factors have been shown to play an important role in controlling cell type determination and differentiation. TWIST, a member of the bHLH transcription factor family, is involved in the development of mesodermally derived tissue, including the skeleton. We examined the role of human TWIST in osteoblast metabolism using stable expression of sense and antisense TWIST in human osteoblast HSaOS‐2 cells. Changes in morphology and osteogenic phenotype characterized these stable clones. Cells that overexpressed TWIST exhibited a spindle shaped morphology, reduced levels of alkaline phosphatase, a reduced proliferation rate, and failed to respond to basic fibroblast growth factor (bFGF). In contrast, those that underexpressed TWIST demonstrated a cuboidal epithelial‐like morphology characteristic of differentiated osteoblasts. TWIST antisense cells exhibited increased levels of alkaline phosphatase and type I collagen mRNA, initiated osteopontin mRNA expression, and had a reduced proliferation rate. These results indicate that TWIST overexpressing cells may de‐differentiate and remain in an osteoprogenitor‐like state, and antisense TWIST cells progress to a more differentiated mature osteoblast‐like state. Therefore, the level of TWIST can influence osteogenic gene expression and may act as a master switch in initiating bone cell differentiation by regulating the osteogenic cell lineage. J. Cell. Biochem. 75:566–577, 1999.

Formation, mineralization, and resorption of bone in hypophosphatemic rats

Quantitative morphologic methods were used to measure the effects of feeding a low phosphorus diet to intact and thyroparathyroidectomized rats on several processes of bone mineralization and turnover. In severely hypophosphatemic animals, the matrix formation rate was decreased, the osteoid maturation rate was decreased, which indicated a delay in the onset of mineralization, the initial rate of mineralization was decreased, and the endosteal osteoclastic bone resorption rate was increased. In moderately hypophosphatemic animals, there was a substantial increase in bone resorption but no change in formation or in mineralization. The increase in endosteal bone resorption was due to an increase in the linear rate of bone resorption and particularly to an increase in the length of the endosteal resorbing surface. The magnitude of the increase in bone resorption was similar in thyroparathyroidectomized and intact rats indicating that neither parathyroid hormone nor calcitonin is involved in this change. This, together with the finding that there was a strong negative correlation (r = -0.99) between the per cent endosteal resorbing surface and the serum phosphorus, supports the view that the increased resorption was due to hypophosphatemia. This inverse relationship between endosteal resorbing surface and serum phosphorus appeared to hold for values of serum phosphorus above normal. The resorptive response to hypophosphatemia, as previously shown for the resorptive response to excess endogenous parathyroid hormone, was partially inhibited by vitamin D deficiency. Increased resorption occurred at levels of serum phosphorus where no changes were observed in bone formation, mineralization, or growth, suggesting that this resorptive response functions as a homeostatic mechanism to maintain serum and intracellular phosphorus concentrations.

TNF-related weak inducer of apoptosis (TWEAK) is a potent skeletal muscle-wasting cytokine

TWEAK cytokine has been implicated in several biological responses including inflammation, angiogenesis, and osteoclastogenesis. We have investigated the role of TWEAK in regulating skeletal muscle mass. Addition of soluble TWEAK protein to cultured myotubes reduced the mean myotube diameter and enhanced the degradation of specific muscle proteins such as CK and MyHCf. The effect of TWEAK on degradation of MyHCf was stronger than its structural homologue, TNF‐α. TWEAK increased the ubiquitination of MyHCf and the transcript levels of atrogin‐1 and MuRF1 ubiquitin ligases. TWEAK inhibited phosphor‐ylation of Akt kinase and its downstream targets GSK‐3β, FOXO1, mTOR, and p70S6K Furthermore, TWEAK increased the activation of NF‐κB transcription factor in myotubes. Adenoviral‐mediated overexpression of IκBαΔN (a degradation‐resistant mutant of NF‐κB inhibitory protein ΙκBα) in myotubes blocked the TWEAK‐induced degradation of MyHCf. Chronic administration of TWEAK in mice resulted in reduced body and skeletal muscle weight with an associated increase in the activity of ubiquitin‐proteasome system and NF‐κB. Finally, muscle‐specific transgenic overexpression of TWEAK decreased the body and skeletal muscle weight in mice. Collectively, our data suggest that TWEAK induces skeletal muscle atrophy through inhibition of the PI3K/Akt signaling pathway and activation of the ubiquitin‐proteasome and NF‐kB systems.—Dogra, C., Changotra, H., Wedhas, N., Qin, X., Wergedal, J. E., Kumar, A. TNF‐related weak inducer of apoptosis (TWEAK) is a potent skeletal muscle‐wasting cytokine. FASEB J. 21, 1857–1869 (2007)

Structural model analysis of multiple quantitative traits.

We introduce a method for the analysis of multilocus, multitrait genetic data that provides an intuitive and precise characterization of genetic architecture. We show that it is possible to infer the magnitude and direction of causal relationships among multiple correlated phenotypes and illustrate the technique using body composition and bone density data from mouse intercross populations. Using these techniques we are able to distinguish genetic loci that affect adiposity from those that affect overall body size and thus reveal a shortcoming of standardized measures such as body mass index that are widely used in obesity research. The identification of causal networks sheds light on the nature of genetic heterogeneity and pleiotropy in complex genetic systems.

A New Standard Genetic Map for the Laboratory Mouse

Genetic maps provide a means to estimate the probability of the co-inheritance of linked loci as they are transmitted across generations in both experimental and natural populations. However, in the age of whole-genome sequences, physical distances measured in base pairs of DNA provide the standard coordinates for navigating the myriad features of genomes. Although genetic and physical maps are colinear, there are well-characterized and sometimes dramatic heterogeneities in the average frequency of meiotic recombination events that occur along the physical extent of chromosomes. There also are documented differences in the recombination landscape between the two sexes. We have revisited high-resolution genetic map data from a large heterogeneous mouse population and have constructed a revised genetic map of the mouse genome, incorporating 10,195 single nucleotide polymorphisms using a set of 47 families comprising 3546 meioses. The revised map provides a different picture of recombination in the mouse from that reported previously. We have further integrated the genetic and physical maps of the genome and incorporated SSLP markers from other genetic maps into this new framework. We demonstrate that utilization of the revised genetic map improves QTL mapping, partially due to the resolution of previously undetected errors in marker ordering along the chromosome.

Characterization of Cells Isolated and Cultured from Human Bone

Abstract Cells isolated from samples of human iliac crest and human femoral heads by collagenase digestion have been successfully cultured in Fitton-Jackson modified BGJb culture medium supplemented with penicillin (100 units/ml), streptomycin (100 Mg/ml), and fetal calf serum (10%). Although only a low proportion of the cells survived the initial plating (<1%), cells established in culture were readily passaged. Examination of cells obtained at intervals during the collagenase digestion showed that the percentage of cells that attached increased with time of digestion. Rapid sample preparation of rat bone did not substantially increase the number of cells attaching. Thus, it seems unlikely that the low survival was due to loss of viability during sample transportation and preparation. Of several media tested BGJb supplemented with 10% fetal calf serum supported the best growth. Population doubling time averaged 104 hr. Cultured human bone cells were assayed for alkaline phosphatase activity using the azo dye method with naphthol ASTR phosphate as the substrate. A portion of the cells (19%) demonstrated high activity in all cultures examined regardless of the passage number of the culture. Autoradiography of cells exposed to [3H]thymidine showed incorporation of the label into both alkaline phosphate-positive and -negative cells. The stimulation of cell proliferation by growth factors was studied by determining the incorporation of [3H]thymidine into DNA. The specific skeletal growth factor from human bone stimulated cell proliferation several-fold with a half-maximal effect at 5 μg/ ml. Insulin, epidermal growth factor, and a crude preparation of somatomedin C also stimulated cell proliferation.

Differential effects on bone of estrogen receptor α and androgen receptor activation in orchidectomized adult male mice

Androgens may regulate the male skeleton either directly by stimulation of the androgen receptor (AR) or indirectly by aromatization of androgens into estrogens and, thereafter, by stimulation of the estrogen receptors (ERs). To directly compare the effect of ER activation on bone in vivo with the effect of AR activation, 9-month-old orchidectomized wild-type and ER-inactivated mice were treated with the nonaromatizable androgen 5α-dihydrotestosterone, 17β-estradiol, or vehicle. Both ERα and AR but not ERβ activation preserved the amount of trabecular bone. ERα activation resulted both in a preserved thickness and number of trabeculae. In contrast, AR activation exclusively preserved the number of trabeculae, whereas the thickness of the trabeculae was unaffected. Furthermore, the effects of 17β-estradiol could not be mediated by the AR, and the effects of 5α-dihydrotestosterone were increased rather than decreased in ER-inactivated mice. ERα, but not AR or ERβ, activation resulted in preserved thickness, volumetric density, and mechanical strength of the cortical bone. ERα activation increased serum levels of insulin-like growth factor I, which were positively correlated with all the cortical and trabecular bone parameters that were specifically preserved by ERα activation but not by AR activation, suggesting that insulin-like growth factor I might mediate these effects of ERα activation. Thus, the in vivo bone-sparing effect of ERα activation is distinct from the bone-sparing effect of AR activation in adult male mice. Because these two pathways are clearly distinct from each other, one may speculate that a combined treatment of selective ER modulators and selective AR modulators might be beneficial in the treatment of osteoporosis.

Ex vivo gene therapy with stromal cells transduced with a retroviral vector containing the BMP4 gene completely heals critical size calvarial defect in rats

In order to develop a successful gene therapy system for the healing of bone defects, we developed a murine leukemia virus (MLV)-based retroviral system expressing the human bone morphogenetic protein (BMP) 4 transgene with high transduction efficiency. The bone formation potential of BMP4 transduced cells was tested by embedding 2.5 × 106 transduced stromal cells in a gelatin matrix that was then placed in a critical size defect in calvariae of syngenic rats. Gelatin matrix without cells or with untransduced stromal cells were the two control groups. The defect area was completely filled with new bone in experimental rats after 4 weeks, while limited bone formation occurred in either control group. Bone mineral density (BMD) of the defect in the gene therapy group was 67.8 ± 5.7 mg/cm2 (mean ± s.d., n = 4), which was 119 ± 10% of the control BMD of bone surrounding the defect (57.2 ± 1.5 mg/cm2). In contrast, BMD of rats implanted with untransduced stromal cells was five-fold lower (13.8 ± 7.4 mg/cm2, P < 0.001). Time course studies revealed that there was a linear increase in BMD between 2–4 weeks after inoculation of the critical size defect with 2.5 × 106 implanted BMP4 cells. In conclusion, the retroviral-based BMP4 gene therapy system that we have developed has the potential for regeneration of large skeletal defects.

Histomorphometric studies show that bone formation and bone mineral apposition rates are greater in C3H/HeJ (high-density) than C57BL/6J (low-density) mice during growth

High-density C3H/HeJ (C3H) and low-density C57BL/6J (B6) mice, with femoral bone density differing by 50%, were chosen as a model to investigate the mechanisms controlling peak bone density and to map peak bone density genes. The present longitudinal study was undertaken to further establish the bone biologic phenotypes of these two inbred strains of mice. To evaluate phenotypic differences in bone formation parameters in C3H and B6 mice between the ages of 6 and 26 weeks, undecalcified ground sections from the diaphyses of the tibia and femur were prepared from mice receiving two injections of tetracycline. Histomorphometric analyses revealed that the cortical bone area was significantly greater (16%-56%, p < 0.001) in both the femur and tibia of the C3H mice than in the B6 mice at all timepoints. This difference in cortical bone area was due to significantly smaller medullary areas in the C3H mice than in the B6 mice. The bone formation rates (BFR) at the endosteum in both the femur and tibia were significantly greater (28%-117%,p < 0.001) in the young C3H mice (6-12 weeks old) than in B6 mice. The higher bone formation in C3H mice was associated with higher values of the bone mineral apposition rate (25%-94%, p < 0.001), and was not associated with higher values of the forming surface length as measured by tetracycline label length. Similar interstrain differences in mineral apposition and bone formation rates were observed in the periosteum of the femur and tibia. In conclusion, the greater bone area in the high-density C3H mice vs. the low-density B6 mice was, in part, due to the greater periosteal and endosteal bone formation rates during growth in the C3H mice. Because the C3H and B6 mice were maintained under identical environmental conditions (diet, lighting, etc.), the observed interstrain differences in bone parameters were the result of the action of genetic factors. Consequently, these two inbred strains of mice are suitable as a model to identify genetic factors responsible for high bone formation rates.