Bone morphogenetic proteins (BMPs) function during various aspects of embryonic development including skeletogenesis. However, their biological functions after birth are less understood. To investigate the role of BMPs during bone remodeling, we generated a postnatal osteoblast-specific disruption of Bmpr1a that encodes the type IA receptor for BMPs in mice. Mutant mice were smaller than controls up to 6 months after birth. Irregular calcification and low bone mass were observed, but there were normal numbers of osteoblasts. The ability of the mutant osteoblasts to form mineralized nodules in culture was severely reduced. Interestingly, bone mass was increased in aged mutant mice due to reduced bone resorption evidenced by reduced bone turnover. The mutant mice lost more bone after ovariectomy likely resulting from decreased osteoblast function which could not overcome ovariectomyinduced bone resorption. In organ culture of bones from aged mice, ablation of the Bmpr1a gene by adenoviral Cre recombinase abolished the stimulatory effects of BMP4 on the expression of lysosomal enzymes essential for osteoclastic bone resorption. These results demonstrate essential and age-dependent roles for BMP signaling mediated by BMPRIA (a type IA receptor for BMP) in osteoblasts for bone remodeling.Bone formation is a well characterized process; however, little is known about the molecular mechanisms that regulate bone remodeling, the physiological process through which bone mass is maintained constant. Remodeling consists of two distinct phases: initial bone resorption by the osteoclasts, followed by de novo bone formation by the osteoblasts (1). Differentiated osteoblasts are the only cells responsible for bone formation. Bone formation is thought to be regulated by hormones and by locally acting growth factors (2). Bone morphogenetic proteins (BMPs) 1 are secreted molecules and members of transforming growth factor- superfamily (3, 4). They were discovered by their ectopic bone formation activity when implanted locally in soft tissues (5). Over the past decade, the phenotypes of mice with mutations in genes coding for this group of proteins and their receptors uncovered the essential roles for BMPs in wide variety of developmental processes, including skeletal development and patterning (6 -9). However, despite its powerful ability to induce ectopic osteogenesis, the essential role of BMPs in bone formation and bone metabolism in the adult skeleton has not been established (10) because of embryonic lethality resulting from mutations of genes encoding the most potent BMPs for bone formation, BMP2 and BMP4, and their receptors (11-13). We previously generated a null allele for Bmpr1a that encodes a type IA receptor for BMP (BMPRIA or ALK3). Mice homozygous for this null allele died by embryonic day 8.0 (E8.0) without mesoderm formation (13). Bmpr1a is expressed in most tissues throughout development and after birth (13,14). Expression of a dominant-negative form of BMPRIA in a cultured cell line or chick limb buds suggests ...
The androgen receptor (AR), as a classic steroid receptor, generally mediates biologic responses to androgens. In bone tissue, both AR and the estrogen receptor (ER) are expressed in a variety of cell types. Because androgens can be converted into estrogen via aromatase activity, the specific role of the AR in maintenance of skeletal homoeostasis remains controversial. The goal of this study was to use skeletally targeted overexpression of AR as a means of elucidating the specific role(s) for AR transactivation in bone homeostasis. Rat AR cDNA was cloned downstream of a 3.6-kb alpha1(I)-collagen promoter fragment and used to create AR-transgenic mice. AR-transgenic males gain less weight and body and femur length is shorter than wild-type controls, whereas females are not different. AR-transgenic males also demonstrate thickened calvaria and increased periosteal but reduced endosteal labeling by fluorescent labeling and reduced osteocalcin levels. High-resolution micro-computed tomography shows normal mineral content in both male and female AR-transgenic mice, but male AR-transgenics reveal a reduction in cortical area and moment of inertia. Male AR-transgenics also demonstrate an altered trabecular morphology with bulging at the metaphysis. Histomorphometric analysis of trabecular bone parameters confirmed the increased bone volume comprised of more trabeculae that are closer together but not thicker. Biomechanical analysis of the skeletal phenotype demonstrate reduced stiffness, maximum load, post-yield deflection, and work-to-failure in male AR-transgenic mice. Steady-state levels of selected osteoblastic and osteoclastic genes are reduced in tibia from both male and female transgenics, with the exception of increased osteoprotegerin expression in male AR-transgenic mice. These results indicate that AR action is important in the development of a sexually dimorphic skeleton and argue for a direct role for androgen transactivation of AR in osteoblasts in modulating skeletal development and homeostasis.
The androgen receptor (AR) is expressed in the uterus; however, the role of AR in female reproductive physiology is poorly understood. Here we examined the effects of androgens on uterine growth and gene expression in adult ovariectomized rats. Nonaromatizable AR-selective agonists potently stimulate hypertrophy and induce significant myometrial expansion distinct from that induced by 17beta-estradiol (E2). In the endometrium, androgens only modestly increase epithelial cell height and antagonize the trophic effects of E2. To identify underlying mechanisms, global changes in RNA levels 24 h after stimulation with E2 and 5alpha-dihydrotestosterone (DHT) were compared. A total of 491 genes were differentially expressed after E2 treatment, including key regulators of tissue remodeling, cell signaling, metabolism, and gene expression. Of the 164 transcripts regulated by DHT, 86% were also affected by E2, including trophic genes like IGF-I and epithelial secretory genes such as uterocalin. In estrogen receptor (ER)alpha knockout mice, DHT cannot induce uterine growth, suggesting a key role for ERalpha. However, DHT appears not to activate ERalpha directly because DHT induction of IGF-I is blocked by the AR antagonist bicalutamide, and multiple genes regulated directly by ERalpha were not induced by DHT. The similarity between estrogens and androgens instead could reflect general trophic signaling in reproductive tissues because 93 of the 503 genes regulated in the uterus are similarly affected during prostate growth. Thus androgens regulate the trophic environment and architecture of the rodent uterus via a gene expression program that is overlapping but distinct from the estrogen response.
Androgen replacement therapy is a promising strategy for the treatment of frailty; however, androgens pose risks for unwanted effects including virilization and hypertrophy of reproductive organs. Selective Androgen Receptor Modulators (SARMs) retain the anabolic properties of androgens in bone and muscle while having reduced effects in other tissues. We describe two structurally similar 4-aza-steroidal androgen receptor (AR) ligands, Cl-4AS-1, a full agonist, and TFM-4AS-1, which is a SARM. TFM-4AS-1 is a potent AR ligand (IC 50 , 38 nM) that partially activates an AR-dependent MMTV promoter (55% of maximal response) while antagonizing the N-terminal/C-terminal interaction within AR that is required for full receptor activation. Microarray analyses of MDA-MB-453 cells show that whereas Cl-4AS-1 behaves like 5␣-dihydrotestosterone (DHT), TFM-4AS-1 acts as a geneselective agonist, inducing some genes as effectively as DHT and others to a lesser extent or not at all. This gene-selective agonism manifests as tissue-selectivity: in ovariectomized rats, Cl-4AS-1 mimics DHT while TFM-4AS-1 promotes the accrual of bone and muscle mass while having reduced effects on reproductive organs and sebaceous glands. Moreover, TFM-4AS-1 does not promote prostate growth and antagonizes DHT in seminal vesicles. To confirm that the biochemical properties of TFM-4AS-1 confer tissue selectivity, we identified a structurally unrelated compound, FTBU-1, with partial agonist activity coupled with antagonism of the N-terminal/C-terminal interaction and found that it also behaves as a SARM. TFM-4AS-1 and FTBU-1 represent two new classes of SARMs and will allow for comparative studies aimed at understanding the biophysical and physiological basis of tissue-selective effects of nuclear receptor ligands.Androgens, primarily testosterone (T) 7 and its more potent derivative, 5␣-dihydrotestosterone (DHT), induce male reproductive physiology and secondary sexual traits such as facial hair and deepened voice. Additionally, in both genders androgens regulate bone and muscle anabolism, adipose mass, lipoprotein metabolism, and behavior (1-3). Androgens decline with age in both men and women (4), which contributes to age-related bone and muscle loss and increases in fat mass (5). Several studies report low testosterone as a risk factor for age-related diseases including osteoporosis (6), sarcopenia (7), atherosclerosis (8), type II diabetes/metabolic syndrome and obesity (9), cognitive impairment (10), and depression (11). Restoring androgens to youthful levels could thus slow unfavorable changes in body composition and improve mood, motivation, and general health. Unfortunately, current androgens induce male secondary sexual traits such as acne and hirsutism, an effect known as virilization, (12) and pose concerns related to unwanted effects in the prostate and other reproductive organs (13-15). Therefore, androgens are limited by concerns over safety and tolerability.Androgens exert their physiological effects by activating the androgen receptor ...
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