It is well established that spermatogenesis is controlled by gonadotrophins and testosterone. However, a role for estrogens in male reproduction recently was suggested in adult mice deficient in estrogen receptor ␣. . Despite the demonstration of the aromatase enzyme, which converts androgens to estrogens, and estrogen receptors within the rodent seminiferous epithelium, the role of aromatase and estrogen in germ cell development is unknown. We have investigated spermatogenesis in mice that lack aromatase because of the targeted disruption of the cyp19 gene (ArKO). Male mice deficient in aromatase were initially fertile but developed progressive infertility, until their ability to sire pups was severely impaired. The mice deficient in aromatase developed disruptions to spermatogenesis between 4.5 months and 1 year, despite no decreases in gonadotrophins or androgens. Spermatogenesis primarily was arrested at early spermiogenic stages, as characterized by an increase in apoptosis and the appearance of multinucleated cells, and there was a significant reduction in round and elongated spermatids, but no changes in Sertoli cells and earlier germ cells. In addition, Leydig cell hyperplasia͞hypertrophy was evident, presumably as a consequence of increased circulating luteinizing hormone. Our findings indicate that local expression of aromatase is essential for spermatogenesis and provide evidence for a direct action of estrogen on male germ cell development and thus fertility.
A detailed understanding of the hormonal regulation of spermatogenesis is required for the informed assessment and management of male fertility and, conversely, for the development of safe and reversible male hormonal contraception. An approach to the study of these issues is outlined based on the use of well-defined in vivo models of gonadotropin/androgen deprivation and replacement, the quantitative assessment of germ cell number using stereological techniques, and the directed study of specific steps in spermatogenesis shown to be hormone dependent. Drawing together data from rat, monkey, and human models, we identify differences between species and formulate an overview of the hormonal regulation of spermatogenesis. There is good evidence for both separate and synergistic roles for both testosterone and follicle-stimulating hormone (FSH) in achieving quantitatively normal spermatogenesis. Based on relatively selective withdrawal and replacement studies, FSH has key roles in the progression of type A to B spermatogonia and, in synergy with testosterone, in regulating germ cell viability. Testosterone is an absolute requirement for spermatogenesis. In rats, it has been shown to promote the adhesion of round spermatids to Sertoli cells, without which they are sloughed from the epithelium and spermatid elongation fails. The release of mature elongated spermatids from the testis (spermiation) is also under FSH/testosterone control in rats. Data from monkeys and men treated with steroidal contraceptives indicate that impairment of spermiation is a key to achieving azoospermia. The contribution of 5␣-reduced androgens in the testis to the regulation of spermatogenesis is also relevant, as 5␣-reduced androgens are maintained during gonadotropin suppression and may act to maintain low levels of germ cell development. These concepts are also discussed in the context of male hormonal contraceptive development.
Although it has been known for many years that estrogen administration has deleterious effects on male fertility, data from transgenic mice deficient in estrogen receptors or aromatase point to an essential physiological role for estrogen in male fertility. This review summarizes the current knowledge on the localization of estrogen receptors and aromatase in the testis in an effort to understand the likely sites of estrogen action. The review also discusses the many studies that have used models employing the administration of estrogenic substances to show that male fertility is responsive to estrogen, thus providing a mechanism by which inappropriate exposure to estrogenic substances may cause adverse effects on spermatogenesis and male fertility. The reproductive phenotypes of mice deficient in estrogen receptors alpha and/or beta and aromatase are also compared to evaluate the physiological role of estrogen in male fertility. The review focuses on the effects of estrogen administration or deprivation, primarily in rodents, on the hypothalamo-pituitary-testis axis, testicular function (including Leydig cell, Sertoli cell, and germ cell development and function), and in the development and function of the efferent ductules and epididymis. The requirement for estrogen in normal male sexual behavior is also reviewed, along with the somewhat limited data on the fertility of men who lack either the capacity to produce or respond to estrogen. This review highlights the ability of exogenous estrogen exposure to perturb spermatogenesis and male fertility, as well as the emerging physiological role of estrogens in male fertility, suggesting that, in this local context, estrogenic substances should also be considered "male hormones."
Haploid round spermatids undergo a remarkable transformation during spermiogenesis. The nucleus polarizes to one side of the cell as the nucleus condenses and elongates, and the microtubule-based manchette sculpts the nucleus into its species-specific head shape. The assembly of the central component of the sperm flagellum, known as the axoneme, begins early in spermiogenesis, and is followed by the assembly of secondary structures needed for normal flagella. The final remodelling of the mature elongated spermatid occurs during spermiation, when the spermatids line up along the luminal edge, shed their residual cytoplasm and are ultimately released into the lumen. Defects in spermiogenesis and spermiation are manifested as low sperm number, abnormal sperm morphology and poor motility and are commonly observed during reproductive toxicant administration, as well as in genetically modified mouse models of male infertility. This chapter summarizes the major physiological processes and the most commonly observed defects in spermiogenesis and spermiation, to aid in the diagnosis of the potential mechanisms that could be perturbed by experimental manipulation such as reproductive toxicant administration. Signature LesionThere are a number of signature lesions that could indicate a disturbance in spermiogenesis or spermiation. These would include misshapen heads and/or tails of elongating/elongated spermatids. Multinucleated round spermatids may reflect disturbances in spermiogenesis, but could also reflect altered Sertoli cell function. Disruption of spermiation could present itself as spermatid retention at the lumen of post stage VIII tubules, failure of elongated spermatids to ascend to the lumen of stage VII/ VIII tubules, or phagocytosis of mature spermatids at the base of tubules in stages VII through to approximately XII (in mice) or XIV (in rats). The changes might occur in isolation or in combination with one another.
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Testosterone (T) has been shown to be essential for the completion of spermiogenesis. Our previous studies showed that when intratesticular T was suppressed for 11 wk, the conversion of round spermatids between stages VII and VIII of the spermatogenic cycle was markedly suppressed and that elongated spermatids were undetectable. The fate of the round spermatids that did not proceed through this conversion was unclear. The current study aimed to investigate this T-dependent loss of round spermatids during stages VII and VIII. Adult male Sprague-Dawley rats received 24-cm T implants for 1 wk to suppress LH while maintaining spermatogenesis. The T24 implants were removed and replaced with 3-cm T plus 0.4-cm estradiol (TE treatment) to suppress intratesticular T and spermatogenesis, and animals were killed at 0 and 4 days and 1, 2, 3, 4, and 6 wk later. The number of homogenization-resistant elongated spermatids in the testis was counted, and round spermatid populations in stages VII and VIII were quantified using stereological techniques. The hourly production rates (HPR) were calculated, and a ratio was made between the HPR of round spermatids in stages VII and VIII to assess the efficiency of their conversion through these stages. Testicular T levels were suppressed to 2-4% of control values by TE treatment. After 2 wk of TE treatment, the number of homogenization-resistant elongated spermatids was significantly suppressed, falling to < 0.5% of the control value by 6 wk. The HPR of round spermatids in stages VII and VIII was not affected by up to 2 wk of TE treatment, nor was the conversion between these stages interrupted. After 3 wk of TE treatment, the HPR of round spermatids in stages VII and VIII was significantly suppressed, as was the conversion between these stages, the ratio falling to 27% of the control value by 6 wk. In rats treated with TE, histological examination of the cauda epididymidis showed occasional round spermatids after 3 wk of treatment, and large numbers after 6 wk. We conclude that the failure of round spermatids to complete spermiogenesis following T withdrawal is due to stage-specific detachment of round spermatids between stages VII and VIII.
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