Aromatase and 5β-reductase activity in cultures of developing zebra finch brain: An investigation of sex and regional differences

Estrogen treatment of hatchling female zebra finches causes the masculine development of singing behavior and of the telencephalic brain regions involved in the control of song. However, early estrogen treatment of males also blocks masculine development of copulatory behavior, presumably controlled by diencephalic regions. In an effort to determine whether the differences in estrogen action are related to sex and regional differences in androgen metabolism (estrogen synthesis or androgen inactivation), we measured aromatase and 5β-reductase activity in dissociated-cell cultures made separately from the telencephalon, diencephalon, and also cerebellum of hatching zebra finches under a variety of conditions. Cultures from all three brain regions express high levels of aromatase and 5β-reductase activity. Comparisons between telencephalic and diencephalic cultures of the activity and kinetics of aromatase suggest that the telencephalic cultures convert androgen to estrogen more efficiently than diencephalic cultures, which might be important in the differential action of estrogen in the two brain regions. However, the activity of neither aromatase nor 5β-reductase was significantly different between the sexes in either telencephalic or diencephalic cultures. Thus, comparisons between the sexes do not support the idea that differences in posthatching aromatase or 5β-reductase activity account for the pattern of sexual differentiation of the song and copulatory systems. © 1995 John Wiley & Sons, Inc.     

Endocrine regulation of sex differences in hepatic histidase activity.

Hepatic histidase activity in adult female rats is twice that in adult male rats. Hypophysectomy and thyroidectomy result in a significant increase in hepatic histidase activities in males, but not in females. This effect on histidase is reversed by the exogenous administration of tri-iodothyronine, but not by ectopic pituitary glands or purified pituitary hormones.     

Hormonal regulation of sex expression in Momordica charantia

Sex expression in a monoecious cucurbit, Momordica charantia L. (long–fruited variety 'Karela') can be regulated by application of gibberellin A₃ (GA₃), indole-3-acetic acid (IAA) and 3-hydroxymethyl oxindole (HMO), an oxidation product of IAA, all of which promote female flowering. Both IAA and HMO accelerated ethylene evolution in the seedlings of this plant. While a low concentration of Ethrel promotes flowering, the effect was reversed with increased concentrations. Surprisingly, GA₃ was the most effective growth regulator in increasing, femaleness. In untreated plants, levels of endogenous GA-like substance increased progressively up to the age of 60 days, at which the ratio of male to female flowers was minimum.     

Hormonal control of sex differences in ultrasound production by hamsters

Male and female hamsters differ in the stimulus control of the ultrasounds they produce during courtship and mating. In particular, untreated males show greater increases in ultrasound rate after exposure to stimulus females than after contact with other males. Conversely, estrous females are more responsive to stimulus males than females. This sex difference reflects both organizational and activational effects of gonadal hormones. Thus, responses to early castration or treatment with testosterone propionate (TP), estradiol benzoate (EB), or dihydrotestosterone propionate suggest that the development of male-like patterns of ultrasound production is facilitated by perinatal exposure to aromatizable androgen. However, even neonatally feminized subjects will show male-like calling if tested during adult treatment with TP. In contrast, the same subjects respond like naturally estrous females during adult treatment with EB plus progesterone (P). The contrasting responses of neonatally feminized subjects to later TP and EB + P treatments suggest that female hamsters retain a greater capacity for heterotypical patterns of ultrasound production than do males. This obviously differs from the common observation of greater "bipotentiality" for mating behavior in males. In turn, this suggests that the mechanisms controlling sexual bipotentiality are specific to their target behaviors, yielding distinct patterns of hormonal control for at least ultrasound production and lordosis.     

Hormonal regulation of serine dehydratase activity in primary cultures of adult rat hepatocytes

The capacity of the following peptides to stimulate steroidogenesis in suspensions of capsule (largely glomerulosa) and fasciculata/reticularis cells from rat adrenals was studied: ACTH_1–24, ACTH_1–13-amide, α-MSH, γ₁-MSH, γ-MSH precursor, ACTH_4–10, CLIP, and ovine and human β-lipotropin. Only α-MSH and ACTH_1–13-amide stimulated glomerulosa cells alone, without effect on fasciculata/reticularis cells. Like ACTH_1–24 the two samples of β-lipotropin stimulated both capsule and inner zone cell types in a similar manner. Their activity is attributable to slight ACTH_1–39 contamination, as shown by HPLC fractionation. The other peptides lacked any activity. It is likely that the predicted specific glomerulosa stimulant from the pituitary closely resembles α-MSH.     

Multifaceted origins of sex differences in the brain

Studies of sex differences in the brain range from reductionistic cell and molecular analyses in animal models to functional imaging in awake human subjects, with many other levels in between. Interpretations and conclusions about the importance of particular differences often vary with differing levels of analyses and can lead to discord and dissent. In the past two decades, the range of neurobiological, psychological and psychiatric endpoints found to differ between males and females has expanded beyond reproduction into every aspect of the healthy and diseased brain, and thereby demands our attention. A greater understanding of all aspects of neural functioning will only be achieved by incorporating sex as a biological variable. The goal of this review is to highlight the current state of the art of the discipline of sex differences research with an emphasis on the brain and to contextualize the articles appearing in the accompanying special issue.     

Aromatase immunolocalization and activity in the lizard's brain: Dynamic changes during the reproductive cycle

The purpose of the present study is to highlight the role of aromatase in the neuroendocrine control of the reproductive cycle of the male lizard Podarcis sicula during the three significant phases, i.e. the pre-reproductive, reproductive, and post-reproductive stages. Using immunohistochemical, biochemical, and hormonal tools, we have determined the localization and the activity of P450 aromatase (P450 aro) in the lizard's brain together with the determination of hormonal profile of sex steroids, i.e. testosterone and 17β-estradiol. The present data demonstrated that the localization of P450 is shown in brain regions involved in the regulation of the reproductive behavior (medial septum, preoptic area, and hypothalamus). Its activity, as well as the intensity of the signal, is modified according to the period of reproduction, resulting in functional dynamic changes. P450 aro activity and signal intensity decrease in the pre-reproductive period and progressively increase during the reproductive stage until it reaches the maximum peak level at the post-reproductive phase. P450 aro determines a local estrogen synthesis, balancing the testosterone and estradiol levels, and therefore its role is crucial, since it plays an important role in the neuroendocrine/behavioral regulation of the reproductive processes in the male lizard P. sicula.     

Aromatase activity in the breast and other peripheral tissues and its therapeutic regulation

Studies using [³H]androstenedione (A) demonstrated that this substrate can be aromatized to estrone (E₁) in homogenates of breast carcinoma tissue and breast adipose tissue, in breast carcinoma and breast adipose stromal cells in culture, and in cultured adipose stromal cells from sites remote from the tumor. Using cultured breast carcinoma cells, it was shown that estrogen formation was stimulated by Cortisol (10⁻⁶ M) and inhibited by endogenous 5-reduced androgens: 5-androstene-dione>androsterone>dihydrotestosterone>epiandrosterone>3- and 3β-androstanediol. It was also shown that 19-nortestosterone and 19-norandrostenedione (10⁻⁶ M) inhibited E₁ formation by 80%. Progesterone (10⁻⁶ M) had no effect on aromatase activity, while the progestational agent R5020 (10⁻⁶ M) caused a 70% inhibition. These studies emphasize that a variety of compounds can influence aromatase activity and that drugs which are used as aromatase inhibitors in patients with breast carcinoma may have multiple sites of action.     

Hormonal control of glycerolphosphate dehydrogenase in the rat brain

—Following hypophysectomy or adrenalectomy, glycerolphosphate dehydrogenase (GPDH) (EC 1.1.1.8) activity decreased exponentially in the cerebral hemispheres and brain stem of adult male rats. The latter region was more affected than the former. Malate dehydrogenase (EC 1.1.1.40), isocitrate dehydrogenase (EC 1.1.1.42), lactate dehydrogenase (EC 1.1.1.27) and mitochondrial glycerolphosphate dehydrogenase (EC 1.1.95.5) activities remained unchanged. Injection of adrenocorticotrophic hormone or cortisol in hypophysectomized rats or cortisol in adrenalectomized rats restored GPDH activity. Thyroidectomy and gonadectomy had no effect on GPDH activity. Liver GPDH was not decreased by hypophysectomy or adrenalectomy. Muscle GPDH was diminished slightly by adrenalectomy and as much as brain GPDH by hypophysectomy. In young rats GPDH developmental increase in activity was inhibited by hypophysectomy. These results clearly show that brain GPDH activity is specifically regulated by cortisol (and probably closely related corticosteroids).