Relationship between characteristics of immunoreactive LH/FSH cells and the levels of gonadotropin in the female rat

Effect of exogenous gonadotropins on gonadotrophs of the rat pituitary gland

In the human in vitro fertilization (IVF) program a variety of superovulation regimens have been employed to promote follicular stimulation and the recruitment of supernumerary oocytes. This therapy, however, disturbs serum concentrations of estradiol and progesterone and may disrupt the normal feedback systems of the hypothalamo-pituitary axis. This study examines the effects of hyperstimulation on the pituitary gonadotrophs and circulating gonadotrophins. FSH and human chorionic gonadotropin (hCG) were administered to normal cycling female Sprague-Dawley rats (n = 12) in phase with their estrous cycle. Control rats (n = 12) were injected with saline. In both the experimental and control groups, six rats were mated on the evening of proestrus and killed 12 hr later, while six animals were killed prior to mating. Blood was collected at the time of sacrifice for radioimmunoassay. The pituitary glands were removed, processed for light microscopy and serially sectioned. Immunocytochemistry for LH and FSH was carried out to determine the area occupied by these cell types. Data were statistically analyzed. Findings were correlated with circulating levels of LH, FSH, estradiol and progesterone. RIA revealed that the concentration of LH, FSH, estradiol and progesterone were significantly different with respect to hyperstimulation and mating. In addition the area occupied by LH and FSH cells was significantly different with respect to both hyperstimulation and mating. Hyperstimulation affects gonadotroph content, as well as gonadotropin and sex steroid hormone concentrations and together with other factors, may disrupt the ideal environment required for implantation.

Neutral aminopeptidase activity levels during the estrous cycle and the pregnancy in the hypothalamus and the pituitary of the rat

Neutral aminopeptidase activity levels during the estrous cycle and pregnancy, in the hypothalamus and the pituitary of experimental animals, was studied in this research. The cyclic stages were the estrous, diestrous and proestrous (at morning and afternoon). The pregnancy phases were the 2nd, 7th, 14th and 20th day postinsemination. The parturition day was also studied. The higher cyclic enzyme levels were found in the proestrous stage (afternoon). No differences between estrous and diestrous were observed. During pregnancy, there was a rise at 7th and 14th day, with a decrease in the 20th day. In the hypothalamus, significant increases after parturition were shown, the latter not being observed in the pituitary. In general, the changes seem to be parallel to those of the luteinizing hormone.

Circadian rhythms in the number of gastrin cells, DNA synthesizing cells and labelling index of gastrin cells in the antral mucosa of the rat

Circadian variations of the gastrin cell (G-cell) number, the DNA synthesizing cell (S phase cell) number and labelling index of G-cell in antral mucosa were studied using the simultaneous double immunoenzymatic labelling method of gastrin and bromodeoxyuridine (BrdU) both in fed and 24 h fasted rats. No significant change was observed in the G-cell number. The S phase cell number and labelling index of G-cell showed significant circadian rhythms. Labelling index of G-cell markedly decreased in 24 h fasted rats in comparison to that in fed rats. These results suggest that DNA synthesis in G-cells has a circadian rhythm and that the activity is influenced by food ingestion.

Uptake and retention of 3H-estradiol by gonadotrophs and lactotrophs in the pituitary glands of the guinea pig, hamster and gerbil

Nuclear uptake and retention of 3H-estradiol by luteinizing hormone (LH) and prolactin (PRL) cells was examined in three species of rodents (guinea pigs, hamsters and gerbils) using the combined techniques of immunocytochemistry and autoradiography. Castrated animals were injected with 3H-estradiol and decapitated 1.5 h later. The pituitary glands were processed for thaw-mount autoradiography followed by conventional immunocytochemical staining for LH and PRL. 3H-estradiol accumulated in more than 80% of the anterior pituitary cells in the gerbils, while only 33 and 22% of the cells accumulated 3H-estradiol in the hamsters and guinea pigs, respectively. A varying percentage of immunoreactive LH and PRL cells in all three species were found also to contain binding sites for estradiol. Some LH and PRL cells in hamsters and guinea pigs and only some in PRL cells of gerbils were found to be devoid of grains. Quantitative analysis revealed that the number of grains per nucleus differed considerably from cell to cell. LH cells of guinea pigs accumulated much larger amounts of 3H-estradiol than did the PRL cells, while the LH cells in the hamsters and gerbils accumulated only slightly more 3H-estradiol than the PRL cells. These results confirm the previous observations in rats and baboons that demonstrated tremendous species differences in percentage of cells in the anterior pituitary gland that accumulated 3H-estradiol. Also, these data suggest that there are functionally heterogeneous cell types among the LH and PRL cells in hamsters, guinea pigs and gerbils as has been previously demonstrated in rats and baboons.