Alison J. Moore

Osteoblast deletion of exon 3 of the androgen receptor gene results in trabecular bone loss in adult male mice.

The mechanism of androgen action on bone was studied in male mice with the AR deleted in mature osteoblasts. These mice had decreased trabecular bone volume associated with a decrease in trabecular number, suggesting that androgens may act directly on osteoblasts to maintain trabecular bone.

Mineralization and bone resorption are regulated by the androgen receptor in male mice.

Androgens play a key role in skeletal growth and bone maintenance; however, their mechanism of action remains unclear. To address this, we selectively deleted the androgen receptor (AR) in terminally differentiated, mineralizing osteoblasts using the Cre/loxP system in mice (osteocalcin‐Cre AR knockouts [mOBL‐ARKOs]). Male mOBL‐ARKOs had decreased femoral trabecular bone volume compared with littermate controls because of a reduction in trabecular number at 6, 12, and 24 wk of age, indicative of increased bone resorption. The effects of AR inactivation in mineralizing osteoblasts was most marked in the young mutant mice at 6 wk of age when rates of bone turnover are high, with a 35% reduction in trabecular bone volume, decreased cortical thickness, and abnormalities in the mineralization of bone matrix, characterized by increased unmineralized bone matrix and a decrease in the amount of mineralizing surface. This impairment in bone architecture in the mOBL‐ARKOs persisted throughout adulthood despite an unexpected compensatory increase in osteoblast activity. Our findings show that androgens act through the AR in mineralizing osteoblasts to maintain bone by regulating bone resorption and the coordination of bone matrix synthesis and mineralization, and that this action is most important during times of bone accrual and high rates of bone remodeling.

Vitamin D Depletion Induces RANKL-Mediated Osteoclastogenesis and Bone Loss in a Rodent Model†

The association between increased risk of hip fracture and low vitamin D status has long been recognized. However, the level of vitamin D required to maintain bone strength is controversial. We used a rodent model of vitamin D depletion to quantify the 25‐hydroxyvitamin D (25D) levels required for normal mineralization. Six groups of 10‐wk‐old male Sprague‐Dawley rats (n = 42) were fed a diet containing 0.4% calcium and various levels of dietary vitamin D3 for 4 mo to achieve stable mean serum 25D levels ranging between 10 and 115 nM. At 7 mo of age, animals were killed, and the histomorphometry of distal and proximal femora and L2 vertebra was analyzed. Total RNA was extracted from whole femora for real‐time RT‐PCR analyses. In the distal femoral metaphysis, trabecular bone mineral volume (BV/TV) showed a significant positive association with circulating 25D levels (r2 = 0.42, p < 0.01) in the animals with serum 25D levels between 20 and 115 nM. Osteoclast surface (Oc.S) levels were positively associated with RANKL:OPG mRNA ratio, higher in groups with lower serum 25D levels, and were independent of serum 1,25D levels. Serum 25D levels <80 nM gave rise to osteopenia as a result of increased osteoclastogenesis, suggesting that levels of 25D >80 nM are needed for optimal bone volume. These data indicate that serum 25D levels are a major determinant of osteoclastogenesis and bone mineral volume and are consistent with the levels of 25D recommended to reduce the risk of fracture in humans.

Calcitonin Receptor Plays a Physiological Role to Protect Against Hypercalcemia in Mice

It is well established that calcitonin is a potent inhibitor of bone resorption; however, a physiological role for calcitonin acting through its cognate receptor, the calcitonin receptor (CTR), has not been identified. Data from previous genetically modified animal models have recognized a possible role for calcitonin and the CTR in controlling bone formation; however, interpretation of these data are complicated, in part because of their mixed genetic background. Therefore, to elucidate the physiological role of the CTR in calcium and bone metabolism, we generated a viable global CTR knockout (KO) mouse model using the Cre/loxP system, in which the CTR is globally deleted by >94% but <100%. Global CTRKOs displayed normal serum ultrafiltrable calcium levels and a mild increase in bone formation in males, showing that the CTR plays a modest physiological role in the regulation of bone and calcium homeostasis in the basal state in mice. Furthermore, the peak in serum total calcium after calcitriol [1,25(OH)2D3]‐induced hypercalcemia was substantially greater in global CTRKOs compared with controls. These data provide strong evidence for a biological role of the CTR in regulating calcium homeostasis in states of calcium stress.

DNA-binding-dependent androgen receptor signaling contributes to gender differences and has physiological actions in males and females.

We used our genomic androgen receptor (AR) knockout (ARKO) mouse model, in which the AR is unable to bind DNA to: 1) document gender differences between males and females; 2) identify the genomic (DNA-binding-dependent) AR-mediated actions in males; 3) determine the contribution of genomic AR-mediated actions to these gender differences; and 4) identify physiological genomic AR-mediated actions in females. At 9 weeks of age, control males had higher body, heart and kidney mass, lower spleen mass, and longer and larger bones compared to control females. Compared to control males, ARKO males had lower body and kidney mass, higher splenic mass, and reductions in cortical and trabecular bone. Deletion of the AR in ARKO males abolished the gender differences in heart and cortical bone. Compared with control females, ARKO females had normal body weight, but 14% lower heart mass and heart weight/body weight ratio. Relative kidney mass was also reduced, and relative spleen mass was increased. ARKO females had a significant reduction in cortical bone growth and changes in trabecular architecture, although with no net change in trabecular bone volume. In conclusion, we have shown that androgens acting via the genomic AR signaling pathway mediate, at least in part, the gender differences in body mass, heart, kidney, spleen, and bone, and play a physiological role in the regulation of cardiac, kidney and splenic size, cortical bone growth, and trabecular bone architecture in females.

The role of the calcitonin receptor in protecting against induced hypercalcemia is mediated via its actions in osteoclasts to inhibit bone resorption

Despite the therapeutic value of calcitonin in treating bone disease, a biological role of endogenous calcitonin is controversial. Having previously demonstrated that the CTR has a biological role in protecting against calcium stress using a global CTRKO mouse model, the purpose of this study was to determine whether the protection conferred by the CTR during induced hypercalcemia is mediated via CTR expression on osteoclasts. Mice were generated, in which the CTR was deleted specifically within osteoclasts (OCL-CTRKOs) and compared with mice in which the CTR was deleted globally (global CTRKOs). Significantly, peak serum calcium levels following induced hypercalcemia were >18% higher in global-CTRKOs and OCL-CTRKOs than controls (P<0.01) due to increased bone resorption (P<0.05). Peak serum calcium levels relative to controls were greater in global-CTRKO males than OCL-CTRKO males (P<0.001), which may, at least in part, be due to increased reabsorption of calcium in the kidney (P<0.01). Controls for all analyses were sex-matched littermates with normal CTR expression. In conclusion, the CTR protects against hypercalcemia predominantly via its inhibitory action on osteoclasts.

Effects of Amylin Deficiency on Trabecular Bone in Young Mice Are Sex-Dependent

Amylin deficiency in mice results in late-onset osteopenia. Sex differences have been identified in insulin secretion in Amylin-overexpressing transgenic mice, suggesting a possible interaction of sex steroids, growth factors, or cytokines and amylin. The aim of the current study was to compare the effects of amylin deficiency on bone in young and adult male and female mice. The metaphyses of the distal femora from male and female Amylin-deficient mice at 4, 6, and 26 weeks of age were assessed by bone histomorphometry. Femoral length was increased in Amylin-deficient male mice compared to wild-type (WT) mice at 26 weeks of age (P < 0.005) but not in females. This was associated with an increase in growth plate height in Amylin-deficient males at 4 (P < 0.01) and 6 (P < 0.05) weeks of age. Furthermore, young Amylin-deficient males had decreased trabecular number at 4 weeks of age (P < 0.05) and increased trabecular thickness at 4 and 6 weeks of age (P < 0.05) compared to WT mice, with no net change in trabecular bone volume. These effects of amylin deficiency were not observed in female mice. In conclusion, this study demonstrates that amylin deficiency exerts effects on bone during growth that are sex-dependent and suggest a possible interaction between amylin and testosterone, growth factors, or cytokines to regulate bone cell metabolism.