Androgens and bone density in women with hypopituitarism

Hypopituitarism is associated with osteopenia and a reduction in lean body mass. We have recently demonstrated markedly reduced serum androgen levels in women with hypopituitarism. We hypothesized that serum androgen levels and lean body mass are important determinants of bone mineral density (BMD) in women with hypopituitarism. In addition, because IGF-I may stimulate androgen secretion in women, we investigated whether GH administration results in an increase in serum androgen levels. Sixteen women with a history of pituitary disease of adult-onset and serum GH levels less than 5 ng/ml on stimulation testing underwent BMD and body composition testing by dual-energy x-ray absorptiometry. Univariate regression analysis revealed strong correlations between androgen levels and BMD [lateral spine BMD and dehydroepiandrosterone sulfate (DHEAS) (r = 0.68, P = 0.03), total hip BMD and free T (r = 0.60, P = 0.01), Ward's triangle BMD and DHEAS (r = 0.68, P = 0.004), Ward's triangle BMD and free T (r = 0.54, P = 0.03), femoral neck BMD and free T (r = 0.52, P = 0.04), and femoral neck BMD and DHEAS (r = 0.51, P = 0.04)]. When adjusted for age using Z scores, correlations at the femoral neck no longer reach significance. Correlations between androgens and BMD at other sites, including anterior-posterior spine and total body, were not significant, and neither total T nor androstenedione correlated with BMD at any site. Lean body mass strongly correlated with BMD [total hip (r = 0.80, P = 0.0002), total body (r = 0.78, P = 0.0003), trochanter (r = 0.74, P = 0.001), Ward's triangle (r = 0.56, P = 0.02), femoral neck (r = 0.53, P = 0.04), and anterior-posterior spine (r = 0.52, P = 0.04)]. In stepwise regression models, DHEAS determined 47% of the variation in Ward's triangle BMD (R(2) = 0.47, P = 0.004) and 46% of lateral spine BMD (R(2) = 0.46, P = 0.03). Lean body mass determined 64% of the variation in total hip BMD (R(2) = 0.64, P = 0.0002), 62% of total body (R(2) = 0.62, P = 0.0003), and 55% of trochanter BMD (R(2) = 0.55, P = 0.001). Subjects were then randomized to receive GH at a dose of 12.5 microg/kg per day or placebo for 12 months in a double-blind protocol. Serum androgen levels were obtained at baseline, 1, 3, 6, 9, and 12 months after initiation of GH. Androgen levels did not increase in the women receiving GH for 12 months, compared with those receiving placebo. Stimulation of androgen secretion is therefore unlikely to be a mechanism underlying the improvement in BMD, body composition, or quality of life observed with GH administration. In conclusion, androgen levels and lean body mass may be important determinants of BMD in women with hypopituitarism. It remains to be determined whether androgen replacement therapy itself or an increase in lean body mass achieved as a result of androgen administration will result in an improvement in BMD in this population.     

Androgens as anabolic agents for bone.

Androgens are classically considered anabolic agents, and in fact there is abundant evidence in many tissues that corroborates strong positive effects of androgens on proliferation and growth. In bone as well, there is clear evidence that androgen action is associated with an increase in skeletal mass, particularly during growth. Whether androgens can be considered anabolic in the skeleton later in life (when therapeutic increases in bone mass are of most clinical interest) is still a matter of some debate.     

Androgens directly stimulate proliferation of bone cells in vitro

This report describes the first observation of a direct mitogenic effect of androgens on isolated osteoblastic cells in serum-free culture. [3H]thymidine incorporation into DNA and cell counts were used as measures of cell proliferation. The percentage of cells that stained for alkaline phosphatase was used as a measure of differentiation. Dihydrotestosterone (DHT) enhanced mouse osteoblastic cell proliferation in a dose dependent manner over a wide range of doses (10(-8) to 10(-11) molar), and was maximally active at 10(-9) M. DHT also stimulated proliferation in human osteoblast cell cultures and in cultures of the human osteosarcoma cell line, TE89. Testosterone, fluoxymesterone (a synthetic androgenic steroid) and methenolone (an anabolic steroid) were also mitogenic in the mouse bone cell system. The mitogenic effect of DHT on bone cells was inhibited by antiandrogens (hydroxyflutamide and cyproterone acetate) which compete for binding to the androgen receptor. In addition to effects on cell proliferation, DHT increased the percentage of alkaline phosphatase (ALP) positive cells in all three bone cell systems tested, and this effect was inhibited by antiandrogens. We conclude that androgens can stimulate human and murine osteoblastic cell proliferation in vitro, and induce expression of the osteoblast-line differentiation marker ALP, presumably by an androgen receptor mediated mechanism.     

Androgens regulate bone resorption activity of isolated osteoclasts in vitro

For many years it has been recognized that sex steroids have profound effects on bone metabolism. The current perception is that estrogen decreases bone resorption and androgen increases bone deposition. To investigate the potential for androgens to directly modulate bone resorption, we have examined avian osteoclast and human and mouse osteoclast-like cells for androgen responsiveness. There was a dose-dependent decrease in resorption activity in response to α-dihydrotestosterone (α-DHT), β-DHT, testosterone, or the synthetic androgen RU1881. This decrease was blocked by cotreatment with the specific androgen antagonist hydroxyflutamide. Further examination of avian osteoclasts revealed that the cells exhibited specific and saturable nuclear binding of tritiated RU1881 and that α-DHT stimulated the activity of the androgen response element as measured by using a chloramphenicol acetyltransferase reporter plasmid. In addition, avian osteoclasts responded to androgen treatment with elevated production and secretion of transforming growth factor β, a well documented response to androgen exposure in other cell systems. Treatment with either α-DHT or β-DHT for 24 hours resulted in a significant dose-dependent decrease in secretion of cathepsin B and tartrate-resistant acid phosphatase. This response to β-DHT, a stereoisomer of α-DHT that is inactive in other androgen receptor-dependent systems, supports the hypothesis that the osteoclast androgen receptor has unusual ligand-binding properties. Taken together, these results confirm the presence of functional androgen receptors in these cells and support the conclusion that osteoclasts are able to respond directly to androgens in vitro and thus are potential androgen target cells in vivo.     

Androgens and puberty

Growth, adolescent sexual development and changes in body composition are described in male adolescents. The underlying changes in the hypothalamic-pituitary gonadal and the GH/IGF-I axes that underline the physical changes are then described. Finally, how high energy output, at a time of low energy input, using, as an example, scholastic male wrestlers, is described.     

Androgens and alopecia

Androgens have profound effects on scalp and body hair in humans. Scalp hair grows constitutively in the absence of androgens, while body hair growth is dependent on the action of androgens. Androgenetic alopecia, referred to as male pattern hair loss (MPHL) in men and female pattern hair loss (FPHL) in women, is due to the progressive miniaturization of scalp hair. Observations in both eunuchs, who have low levels of testicular androgens, and males with genetic 5alpha-reductase (5alphaR) deficiency, who have low levels of dihydrotestosterone (DHT), implicate DHT as a key androgen in the pathogenesis of MPHL in men. The development of finasteride, a type 2-selective 5alphaR inhibitor, further advanced our understanding of the role of DHT in the pathophysiology of scalp alopecia. Controlled clinical trials with finasteride demonstrated improvements in scalp hair growth in treated men associated with reductions in scalp DHT content, and a trend towards reversal of scalp hair miniaturization was evident by histopathologic evaluation of scalp biopsies. In contrast to its beneficial effects in men, finasteride did not improve hair growth in postmenopausal women with FPHL. Histopathological evaluation of scalp biopsies confirmed that finasteride treatment produced no benefit on scalp hair in these women. These findings suggest that MPHL and FPHL are distinct clinical entities, with disparate pathophysiologies. Studies that elucidate the molecular mechanisms by which androgens regulate hair growth would provide greater understanding of these differences.     

Androgens and spermatogenesis

Male infertility contributes to 50% of all cases of infertility. The main cause is low quality and quantity of sperm. In humans, spermatogenesis starts at the beginning of puberty and lasts lifelong. It is under the control of FSH and testicular androgens, and mainly testosterone (T), and therefore requires a normal gonadotroph axis, intratesticular T production by Leydig cells and functional androgen receptors (ARs) within testicular Sertoli cells. Various clinical cases illustrate the roles of T in human spermatogenesis. Men with complete congenital hypogonadotropic hypogonadism (HH) are usually azoospermic. Treatment by exogenous testosterone injection and FSH is not able to produce sperm. However, combined treatment with FSH and hCG is effective. This example shows that intratesticular T plays a major role in spermatogenesis. Furthermore, testicular histology of men with LH receptor mutations shows Leydig cell hypoplasia/agenesis/dysplasia with conserved Sertoli cell count. The sperm count is reduced, as in males with partial inactivating mutation of the androgen receptor. Some protocols of hormonal male contraception or exogenous androgen abuse induce negative feedback in the hypothalamic pituitary axis, decreasing FSH, LH and T levels and inducing sperm defects and testicular atrophy. The time to recovery after cessation of drug abuse is around 14 months for sperm output and 38 months for sperm motility. In summary, abnormal androgen production and/or AR signaling impairs spermatogenesis in humans. The minimal level of intratesticular T for normal sperm production is a matter of debate. Interestingly, some animal models showed that completely T-independent spermatogenesis is possible, potentially through strong FSH activation. Finally, recent data suggest important roles of prenatal life and minipuberty in adult spermatogenesis.     

Androgens.

Testosterone is synthesised mainly if not entirely by the leydig cells and secreted episodically with a slight circadian variation. Only the free, nonprotein-bound fraction of the testosterone in the circulation is biologically active. This free testosterone passes into the target cells and is taken up by specific receptors in the muscle. In some other target tissues, testosterone is first reduced to 5alpha-dihydrotestosterone which is then taken up by specific receptors in the cytoplasm and transferred to the nucleus. Anti-androgens appear to act principally by inhibiting this uptake.     

Androgens and the skeleton

Loss of estrogens or androgens causes bone loss by increasing the rate of bone remodeling, and also causes an imbalance between resorption and formation by prolonging the lifespan of osteoclasts and shortening the lifespan of osteoblasts. Conversely, treatment with androgens, as well as estrogens, maintains cancellous bone mass and integrity, regardless of age or sex. Both androgens, via the androgen receptor (AR), and estrogens, via the estrogen receptors (ERs) can exert these effects, but the relative contribution of these 2 pathways remains uncertain. Androgens, like estrogens, stimulate endochondral bone formation at the start of puberty, whereas they induce epiphyseal closure at the end of puberty, thus, they have a biphasic effect. Androgen action on the growth plate is, however, clearly mediated via aromatization into estrogens and interaction with ER alpha. Androgens increase, while estrogens decrease radial growth. This differential effect of the sex steroids may be important because bone strength in males seems to be determined by higher periosteal bone formation and, therefore, greater bone dimensions. Experiments in mice suggest that both the AR and ER alpha pathways are involved in androgen action on radial bone growth. ER beta may mediate growth-limiting effects of estrogens in the female but does not seem to be involved in the regulation of bone size in males. In conclusion, androgens may protect men against osteoporosis via maintenance of cancellous bone mass and expansion of cortical bone. This androgen action on bone is mediated by the AR and ER alpha.     

Androgens and aging men

This article underlines the hormonal and clinical events characterizing the so-called andropause, as they may be described from an extensive review of the literature and some data obtained with the French colleagues of the author. Evidence-based hormonal intervention has to be positioned against anti-aging entrepreneurs who peddle hormones at random. The desequilibrium in aging men between the unchanged level of plasma cortisol and the profound decrease of androgens deserves cautious studies to eventually oppose this unbalanced hormonal situation effectively and safely.     

Androgens and cardiovascular disease

Globally, cardiovascular disease will continue causing most human deaths for the foreseeable future. The consistent gender gap in life span of approximately 5.6 yr in all advanced economies must derive from gender differences in age-specific cardiovascular death rates, which rise steeply in parallel for both genders but 5-10 yr earlier in men. The lack of inflection point at modal age of menopause, contrasting with unequivocally estrogen-dependent biological markers like breast cancer or bone density, makes estrogen protection of premenopausal women an unlikely explanation. Limited human data suggest that testosterone exposure does not shorten life span in either gender, and oral estrogen treatment increases risk of cardiovascular death in men as it does in women. Alternatively, androgen exposure in early life (perinatal androgen imprinting) may predispose males to earlier onset of atherosclerosis. Following the recent reevaluation of the estrogen-protection orthodoxy, empirical research has flourished into the role of androgens in the progression of cardiovascular disease, highlighting the need to better understand androgen receptor (AR) coregulators, nongenomic androgen effects, tissue-specific metabolic activation of androgens, and androgen sensitivity. Novel therapeutic targets may arise from understanding how androgens enhance early plaque formation and cause vasodilatation via nongenomic androgen effects on vascular smooth muscle, and how tissue-specific variations in androgen effects are modulated by AR coregulators as well as metabolic activation of testosterone to amplify (via 5alpha-reductase to form dihydrotestosterone acting on AR) or diversify (via aromatization to estradiol acting upon estrogen receptor alpha/beta) the biological effects of testosterone on the vasculature. Observational studies show that blood testosterone concentrations are consistently lower among men with cardiovascular disease, suggesting a possible preventive role for testosterone therapy, which requires critical evaluation by further prospective studies. Short-term interventional studies show that testosterone produces a modest but consistent improvement in cardiac ischemia over placebo, comparable to the effects of existing antianginal drugs. By contrast, testosterone therapy has no beneficial effects in peripheral arterial disease but has not been evaluated in cerebrovascular disease. Erectile dysfunction is most frequently caused by pelvic arterial insufficiency due to atherosclerosis, and its sentinel relationship to generalized atherosclerosis is insufficiently appreciated. The commonality of risk factor patterns and mechanisms (including endothelial dysfunction) suggests that the efficacy of antiatherogenic therapy is an important challenge with the potential to enhance men's motivation for prevention and treatment of cardiovascular diseases.