Regulation of progestin receptors in medial amygdala: estradiol, phytoestrogens and sex.

Exposure to estrogens during critical developmental periods and in adulthood affects sex differences in the brain. We examined the roles of estradiol (E2) and phytoestrogens, and their interactions, on potential sex differences in brain. We used aromatase knockout (ArKO) mice, which cannot produce endogenous estrogens, along with wild type (WT) littermates. Mice were gestated, raised and maintained on a diet either rich in phytoestrogens or a diet virtually void of soy-derived phytoestrogens. Adult males and females were gonadectomized and received implants filled with 17-beta-estradiol to induce progestin receptors (PR), while controls received empty implants. Mice were sacrificed five days later and brain sections containing the posterodorsal medial amygdala (MePD) were processed for PR immunoreactivity. Activation of sex differences in PR required adult E2 treatment. A diet high in phytoestrogens was required for expression of sex differences in PR after E2 treatment. Our data underscore the important contribution of dietary phytoestrogens for the development of sex differences in PR-ir in the adult mouse medial amygdala. We hypothesize that both aromatization of androgens to estrogens and dietary sources of additional estrogens are part of the normal requirement for sex differences in the rodent brain.

Functional analysis of neurosteroidal oestrogen using gene-disrupted and transgenic mice.

The brain aromatase (oestrogen synthase) hypothesis predicts that oestrogen plays important roles in both sexual behaviours and brain sexual differentiation. To elucidate the functions of oestrogen in the brain, we generated aromatase knockout (ArKO) mice, which showed undetectable oestrogen and enhanced androgen levels in blood. These ArKO mice exhibited an enhanced appetite and disorders in sexual motivation, sexual partnership preference, sexual performance, aggressive behaviour, parental behaviour, infanticide behaviour and exploratory (anxiety) behaviour. We characterised the brain-specific promoter of the mouse aromatase gene, and identified several crucial cis-acting elements and the minimal essential promoter region for brain-specific expression. Next, we introduced a transgene of human aromatase, controlled by the minimal promoter region, into the ArKO mouse. The resulting mouse (ArKO/hArom), whose preoptic area, hypothalamus and amygdala were exposed to oestrogens only in the perinatal period, and then to enhanced androgens and no oestrogens in adulthood, showed near recovery from behavioural disorders. These results suggest that local oestrogens acting in specific brain regions are involved in the organisation of sex-specific neural networks during the perinatal period. Finally, we examined effects of oestrogens on gene expression within specific brain regions in mice during the perinatal period using DNA microarray analysis. This assay revealed both up-regulated and down-regulated brain-specific genes, including those related to neuronal function. Specifically, genes involved in energy metabolism, cell proliferation/apoptosis and secretory/transport system were altered in ArKO mice compared to wild mice. These results suggest that brain oestrogens participate in the sexual differentiation of the brain by influencing gene expression.

Effects of organisational oestradiol on adult immunoreactive oestrogen receptors (alpha and beta) in the male mouse brain.

Steroid hormones act on developing neural circuits that regulate the hypothalamic-pituitary-gonadal axis and are involved in hormone-sensitive behaviours. To test the hypothesis that developmental exposure to oestradiol (E(2)) organises the quantity of adult oestrogen receptors (ERalpha and ERbeta), we used male mice with a targeted mutation of the aromatase enzyme gene (ArKO) and their wild-type (WT) littermates. These mice are unable to aromatise testosterone to E(2), but still express both ERalpha and beta. To evaluate adult responsiveness to E(2), gonadectomised males were implanted with Silastic capsules containing E(2), or an empty implant, 5 days prior to sacrifice. Immunoreactivity for ERalpha and ERbeta was quantified in the caudal ventromedial nucleus (VMN) and the medial preoptic area (POA). Regardless of genotype, adult treatment with E(2) reduced ERalpha-immunoreactive (ir) and ERbeta-ir cell numbers in the POA, as well as ERbeta-ir, but not ERalpha-ir, cell numbers in the VMN. Genotype, and thus endogenous exposure to E(2), produced opposite effects on ER expression in the two brain areas. In the VMN, ArKO males had more ERalpha-ir and ERbeta-ir cells than did WT males. In the POA, ArKO males had fewer ERalpha-ir and ERbeta-ir cells than did WT males. Thus, numbers of immunoreactive neurones containing both ERs in the adult ArKO male were enhanced in the POA, but decreased in the VMN, and most likely these patterns were established during the developmental critical period. Furthermore, although both ERalpha and beta-ir cell numbers are altered by the disruption of the aromatase gene, ERbeta is altered in a more robust and region-specific manner.

Characterization and purification of a protein binding to the cis-acting element for brain-specific exon 1 of the mouse aromatase gene.

The functional differences between male and female brains commit to the existence of androgen that the testis secretes during the perinatal period. Androgen exerts its action on the brain after conversion to estrogen by brain aromatase. The aromatase appears in some neural nuclei such as in the hypothalamus and amygdala, and has been indicated to be involved in the expression of sexuality by the results of neurobehavioral analyses involving aromatase-knockout mice. We analyzed the brain-specific promoter in order to clarify the control mechanism for the expression of brain aromatase, which is deeply concerned in the sexual differentiation of the brain. The 202bp upstream region of brain-specific exon 1 contains at least three kinds of cis-acting elements, Arom-Aalpha, -Abeta and -B. In particular, the binding activities as to the Abeta sequence show a tissue-specific pattern. Gel shift analysis revealed that the Abeta binding factor recognizes the TTGGCCCCT sequence. Abeta binding activity is detectable at the perinatal stage, but is undetectable at the adult stage in the brain. Furthermore, a protein which binds to the Abeta sequence was purified from the fetal mouse brain. The molecular mass of the Abeta binding protein was estimated to be 49kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.

Aromatase inhibitors and enzyme stability.

The effects of two steroidal (4-hydroxyandrostenedione and atamestane) and three non-steroidal (fadrozole, vorozole, and pentrozole) aromatase inhibitors on the levels of aromatase mRNA and protein were examined in vitro and in vivo. Immunocytochemistry revealed increased quantities of immunoreactive aromatase in human choriocarcinoma-derived JEG-3 cells in response to pretreatment with the non-steroidal inhibitors. To elucidate this effect in detail, aromatase protein in JEG-3 cells after treatment with various inhibitors was quantified using an enzyme-linked immunosorbent assay (ELISA). A time-dependent increase in aromatase protein in the cells was observed with all the aromatase inhibitors except 4-hydroxyandrostenedione, whereas aromatase mRNA levels in the cells remained unchanged during the inhibitor treatment. The three non-steroidal agents caused an approximately fourfold increase in aromatase protein in the cells 24 h after the treatment, as compared with untreated controls. The increase in aromatase protein in the cells was not blocked by treatment with cycloheximide, an inhibitor of protein synthesis. The inhibitors also appeared to block the rapid degradation observed in JEG-3 cells after induction by forskolin. In vivo, daily injection of the inhibitors into adult female mice caused increases in levels of both aromatase mRNA and protein in the ovary. The increase in aromatase mRNA in this in vivo study could be explained by an increase in gonadotropin concentrations in response to decreased plasma concentrations of estrogens. In conclusion, we suggest that aromatase inhibitors increase aromatase protein through stabilization and reduced protein turnover.

Interpretations on chloroplast reproduction derived from correlations between cells and chloroplasts.

The size ranges of chloroplasts in living mesophyll cells of Spinacia oleracea, Allium cepa, Beta vulgaris (Swiss chard and red beet) and Nicotiana glutinosa are extremely wide, e.g., ranging from about 6 µ(2) to 103 µ(2) in face area for spinach. Moreover, the size distributions are positively skewed. We interpret the size range and skewed size distributions primarily to reflect an enormous growth of the bulk of the chloroplasts from small, equal-sized chloroplasts produced by fission of a small sub-population of constricted mature chloroplasts. While actual fission has never been observed, a slow division rate of the constricted chloroplasts in N. glutinosa can account for the increase in chloroplast numbers per cell during leaf development and for the presence of small, non-constricted chloroplasts after the small chloroplasts which developed during the initial meristem activity have enlarged. Chloroplast numbers and total amount of chloroplast material per cell face were positively correlated with mesophyll-cell face size. However, the fraction of the cell face occupied with chloroplasts was essentially constant and independent of cell size and cell age while being markedly different for different species of plants. There appear to be some family characteristics in that closely related species have similar size-distributions and ranges of chloroplast sizes. The observations are discussed with respect to the ontogeny of chloroplasts in higher plants.

Studies on ultrastructure and purification of isolated plant mitochondria.

Sweetpotato mitochondria, that showed respiratory control, were studied with respect to ultrastructure. If fixed in media containing sucrose at 0.4 M, the cristae were dilated and the matrix was highly condensed. A more orthodox ultrastructural form was observed when the mitochondria were fixed in a medium containing sucrose at 0.25 M, i.e., the matrix was more expanded, the cristae were less dilated, and peripherally, the inner membrane element lay adjacent to the outer membrane element. These results are discussed in terms of a sucrose-accessible space (space between outer and inner membrane elements including intracristal space), and a space relatively inaccessible to sucrose (matrix). Ultrastructural shifts were not observed with change in metabolic steady state of the mitochondria. High resolution electron micrographs showed that the ultrastructure of sweetpotato mitochondria is very similar to that of animal mitochondria.Purity and homogeneity of mitochondrial fractions were followed both by phase-contrast and electron microscopy. Preparations from sweetpotato, using older methods, were relatively homogeneous with respect to particle type and size, whereas avocado preparations contained a high proportion of chloroplasts and cellular debris. A method of purification involving sucrose-density-gradient centrifugation was developed. Purified mitochondria exhibited respiratory control and appeared similar to unpurified mitochondria under the electron microscope.

Reversible swelling and contraction of isolated spinach chloroplasts.

By use of a micro technique for producing extracts of spinach mesophyll cells, chloroplasts were isolated in a state wherein they displayed microscopically visible, reversible osmotic properties. Swollen spherical chloroplasts treated with hypertonic sucrose or mannitol media, but not NaCl, could be shrunken to a state resembling their disk appearance in living cells. Reversible osmotic behavior was more easily demonstrated when the chloroplasts were initially isolated from cells in a relatively low osmolar concentration in contrast to using 0.25 m sucrose or more concentrated media. Individual chloroplasts could be swollen and contracted repeatedly through as many as 4 cycles. The relationship between the capacity for osmotic behavior and chloroplast appearance in cell extracts is discussed.