Comparison of the effects of 3,5,3'-triiodothyroacetic Acid and triiodothyronine on goiter prevention and involution and on hepatic and skeletal parameters in rats.

3,5,3'-triiodothyroacetic acid (TRIAC) has been used to suppress pituitary TSH secretion with reported attenuation of extrapituitary effects. We investigated whether equivalent doses of T (3) and TRIAC preventing the induction of goiter by methimazole (MMI) had a different or similar impact on peripheral tissues, such as liver and bone. In particular, we compared the effects of both compounds on the activity of the hepatic thyroid hormone-responsive enzymes, malic enzyme and L-glicerol-3-P dehydrogenase; bone mineral density and biochemical parameters of bone turnover, such as bone alkaline phosphatase (b-ALP) and the carboxy-terminal telopeptide region of type I collagen (beta-CTX); and the activity of thyroid ornithine decarboxylase (ODC). We also compared the effects of T (3) and TRIAC on the involution of MMI-induced goiter. Our results showed that TRIAC was more effective than T (3) to reduce MMI-induced goiter in a short-term goiter involution assay. TRIAC increased hepatic enzymes activity and beta-CTX levels, a parameter of bone resorption, more than T (3). However, bone mineral density was not altered by either treatment. Both compounds even reduced ODC activity at doses that were not effective at the pituitary level. These results demonstrate increased TRIAC hepatic and antigoitrogenic activity compared to T (3). TRIAC induces an imbalance in bone remodeling without affecting bone mineral density. Further studies are required to clarify this point.

Gonadotropins and inhibins along the development of a luteinized rat ovarian tumor.

Luteinized intrasplenic ovarian tumors develop in response to high circulating gonadotropins. The relationship between tumor development, gonadotropins and inhibins was studied. Tumor-bearing animals were sacrificed weekly along the first 6 weeks of development. Inhibins were measured by enzyme-linked immunosorbent assay (ELISA), serum gonadotropins, GH and IGF-1 by RIA. Inhibin subunit mRNAs were determined by Northern blot. Tumor histology was examined. Ovarian grafts grew significantly along development. LH increased ten-fold on week 1; a further significant increment was observed on week 3. FSH peaked on weeks 1 and 2 and fell significantly thereafter. Serum inhibins markedly increased on weeks 3-5. Tumor inhibin A content and mRNA levels for alpha and beta A subunits also increased on week 3. Inverse correlations between inhibins and FSH and direct correlations between inhibins and LH were observed. Tumor inhibin A and IGF-1 contents correlated significantly. Increasing levels of luteinization were observed along tumor development. These luteinized tumors develop mainly in response to LH, since growth continues under FSH inhibition. The active inhibin secretion and the positive correlation between inhibins and LH suggests that LH may be the main driving force behind this production, while growth factors produced by the gonads may also participate in their regulation.

Brain sexual differentiation and gonadotropins secretion in the rat.

1. The present work deals with sexual differences in gonadotropin regulation in the rat and the role of sexual organization of the hypothalamus in determining such differences. 2. Sex differences between male and female rats, with regard to their control of gonadotropin secretion, go beyond whether or not gonadotropins are released cyclically. Rats show additional sex differences (a) in the response of gonadotropins to removal and imposition of negative feedback signals and (b) in the ontogeny of gonadotropin regulation from birth to puberty. 3. There is a sensitive developmental period during which sexual differentiation of neural substrates proceeds irreversibly under the influence of gonadal hormones. In the rat this period starts a few days before birth and ends approximately 10 days after birth. Female rats treated during this sensitive period with androgens or estrogens will permanently lose the capacity to release GnRH in response to estrogenic stimulation. 4. Nevertheless although sexual differentiation is dramatically affected by events during the neonatal period, recent data question the "critical" nature of this period, as it has been shown that testosterone can still act on neural substrates well beyond (15 to 30 days of age) the neonatal period to defeminize and masculinize endocrine and behavioral functions. 5. Furthermore, the capacity for the normal display of female sexual behavior and for the cyclic release of gonadotropins is not, as has been assumed, inherent to central nervous tissue but depends on active hormonal estrogenic induction during a sensitive period of development. 6. Besides, during differentiation of male sexual brain function estrogens may be supportive, rather than directive, to the primary action of androgens. 7. Serotonergic, noradrenergic, and opioid systems participate in the sexual dimorphism in gonadotropin control in adult rats. 8. The sex difference in the postcastration LH rise is dependent on the early sexual organization of the hypothalamus, even though in adulthood it can also be influenced by a variety of factors such as the stage of the estrous cycle, age of the animal, estradiol pretreatment, and history of release from feedback inhibition. 9. The characteristic pattern of gonadotropin secretion in the female infantile rat, which is sexually differentiated, can be related to an increase in hypophyseal receptors coupled to an increase in the intracellular calcium response to GnRH. Such events depend on the sexual organization of the hypothalamus. In males the greater sensitivity to GnRH at 30 days is reflected in an increase in pituitary GnRH receptors but not in an increase in the magnitude of Ca2+ mobilization induced by GnRH, therefore it is probable that in this situation alternative second messengers may modulate high sensitivity. Neonatal androgenization of the hypothalamus may decrease the hypophyseal response to GnRH by an alteration in receptor concentration and signal transduction during the infantile period. 10. Finally, serotonergic, dopaminergic, opioid, and noradrenergic regulation of GnRH varies with increasing age, and the sexual organization of the hypothalamus by testosterone or estrogens is a determinant in such regulation.

Anterior pituitary estradiol receptors associated with the reinstatement of ovulatory cycles after lactation interruption in the rat.

The participation of adenohypophyseal estradiol receptors in the reinstatement of ovulatory cycles after lactation interruption was investigated. In rats whose pups were removed on day 13 postpartum (LRX), prolactin levels fell as from 1600 h on the same day, estradiol peaked on the morning of day 15 and gonadotropins and prolactin (PRL) surged on the afternoon of day 15. No significant changes in gonadotropins or estradiol levels were observed in rats which remained with their litters (LRP); in these rats daily afternoon surges of PRL were detected. No significant variations in anterior pituitary nuclear or cytosolic estradiol receptors were determined in LRP rats. In the nuclear fraction of LRX rats, an important increase (430.8 +/- 124.9%) in receptor titers was observed on day 15. In these animals a significant increase (34.8 +/- 1.3%) in cytosolic estradiol receptors was observed on day 14, followed by a fall on day 15 (-31.6 +/- 6.6%) in comparison to day 13 levels. The receptor variations observed on day 15 closely resemble estrous cyclic changes determined in adult females. However, an observation which does not resemble those cycle variations is the increase in cytosolic receptors observed on day 14 in LRX rats. This increase may be the consequence of a decrease in dopamine levels induced by pup removal. To our knowledge this is the first time that the involvement of pituitary estradiol receptors in the reinstatement of ovulatory cycles after lactation interruption has been described.

Prolactin-releasing effect of buspirone in developing and adult male and female rats.

The prolactin-releasing effects of buspirone, an azaspirodecanedione anxiolytic drug unrelated to the benzodiazepines in structure and pharmacologic properties, was examined in developing and adult male and female rats. The possibility that effects of this drug on hormone release could be modulated by neonatal brain sexual differentiation was also evaluated. A single injection of buspirone, 2 or 10 mg/kg body wt, increased serum prolactin (PRL) levels in both sexes; the increase was significant from Day 12 onward. The PRL-releasing effect increased with age. No significant sexual differences were observed in younger rats, but in peripubertal and adult animals, the hyperprolactinemic response was higher in the female. Neonatal androgenization of females or orchidectomy of males failed to modify the PRL-releasing action of buspirone. Serum titers of luteinizing hormone and follicle-stimulating hormone were not modified by buspirone at any age. The present results show for the first time the ontogeny of the PRL-releasing effect of buspirone in male and female rats, and provide evidence that the response is higher in the female and that the effect does not depend on brain sexual differentiation.