On the correlation between FSH, LH and prolactin serum levels.

In 188 males FSH, LH, and prolactin serum levels determined from a single blood sample were found to be closely correlated. No correlation appeared to testosterone levels. The same correlation is observed, if serum levels of FSH, LH, and prolactin are measured after stimulation with LH-RH and TRH. In order to explain the close correlation, in five young men hormone levels were measured at 2-min-intervals over a period of 2 hours. Peaks of prolactin often correspond to those of FSH and LH, and a statistical correlation was found in two cases between FSH and prolactin. Results suggest a common releasing mechanism, which is superposed to the main mediating mechanism.     

Low serum levels of FSH, LH and prolactin in luteal phase inadequacy

In order to elucidate the relationship between prolactin (PRL) levels and corpus luteum function in humans, assessment of temporal relationship between levels of PRL, LH, FSH, estradiol and progesterone was made in eleven normal cycling women and six short luteal women. All hormones were determined by specific radioimmunoassay. The mean PRL level in the luteal phase was higher than that in the follicular phase in normal women. On the other hand, no difference mean was seen between the PRL levels of follicular and luteal phases in short luteal women. In addition, follicular and luteal phase secretion of PRL in the short luteal phase (SLP) was lower than that in the normal control. LH and FSH in the follicular and luteal phases, estradiol secretion in the late follicular and early to mid-luteal phases in SLP were also lower than those in the control. These observations were consistent with the hypothesis that SLP is a sequel to aberrant folliculogenesis. In addition, it is inferred that low PRL levels in the SLP might be due to inadequate augmentation by estrogen, rather than giving PRL any positive controlling role in the maintenance of corpus luteum function.     

Effects of pargyline on hypothalamic biogenic amines and serum prolactin. LH and TSH in male rats.

The time course effects of pargyline on hypothalamic biogenic amines and serum prolactin (PRL), LH and TSH were studied in adult male rats. The rats were killed at intervals of 1–6 hrs after pargyline injection. Hypothalamic dopamine (DA) rose 79% by 1 hr and was 41% above “0” time by 6 hrs. Norepinephrine (NE) increased 31% by 1 hr and remained at about this level through 6 hrs, whereas serotonin (5HT) increased from 42% by 1 hr and to 95% by 6 hrs. Serum PRL LH and TSH fell significantly during the first 2 hrs, but all had returned to pretreatment values by 4 hrs. Serum PRL was about 4-fold above pretreatment values by 6 hrs, but LH and TSH remained at pretreatment levels. Stimulation by pargyline of PRL release was potentiated by Lilly compound 110140, a serotonin reuptake inhibitor, and blocked by parachlorophenylalanine, a serotonin synthesis inhibitor. These results suggest that the inhibitory effects of pargyline on PRL, LH, and TSH release during the first 2 hrs were associated mainly with a rapid increase in DA, and subsequent elevation of PRL release was related to the increase in 5HT. Return of serum LH and TSH to pretreatment levels at 4 and 6 hrs appeared to be associated mainly with the decrease in DA and perhaps to elevated NE levels. These results suggest that changes in relative concentrations of hypothalamic amines are related to differential release of PRL, LH and TSH.     

Effects of oestradiol on LH, FSH and prolactin in ovariectomized ewes

This study was conducted to test the hypothesis that the rate (dose/time) at which oestradiol-17 beta (oestradiol) is presented to the hypothalamo-pituitary axis influences secretion of LH, FSH and prolactin. A computer-controlled infusion system was used to produce linearly increasing serum concentrations of oestradiol in ovariectomized ewes over a period of 60 h. Serum samples were collected from ewes every 2 h from 8 h before to 92 h after start of infusion, and assayed for oestradiol, LH, FSH and prolactin. Rates of oestradiol increase were categorized into high (0.61-1.78 pg/h), medium (0.13-0.60 pg/h) and low (0.01-0.12 pg/h). Ewes receiving high rates of oestradiol (N = 11) responded with a surge of LH 12.7 +/- 2.0 h after oestradiol began to increase, whereas ewes receiving medium (N = 15) and low (N = 11) rates of oestradiol responded with a surge of LH at 19.4 +/- 1.7 and 30.9 +/- 2.0 h, respectively. None of the surges of LH was accompanied by a surge of FSH. Serum concentrations of FSH decreased and prolactin increased in ewes receiving high and medium rates of oestradiol, when compared to saline-infused ewes (N = 8; P less than 0.05). We conclude that rate of increase in serum concentrations of oestradiol controls the time of the surge of LH and secretion of prolactin and FSH in ovariectomized ewes. We also suggest that the mechanism by which oestradiol induces a surge of LH may be different from the mechanism by which oestradiol induces a surge of FSH.     

Alterations in the proestrous pattern of median eminence LHRH, serum LH, FSH, estradiol and progesterone concentrations in middle-aged rats

The purpose of the following study was to assess the changes in the proestrous hormone profile in middle-aged cycling rats to better understand the inter-relationship and possible interaction of these hormones during the transition to estrous acyclicity. Median eminence LHRH concentrations and serum LH, FSH, estradiol and progesterone concentrations were measured in young (3-4 months old) and middle-aged (8-10 months old) proestrous rats at 0900, 1200, 1500 and 1800h. The data demonstrate that (1) baseline hormone concentrations prior to the surge at 0900h are the same in middle-aged and young rats; (2) the proestrous gonadotropin surge is temporally delayed in middle-aged rats; (3) this delay is preceded by lower median eminence LHRH concentrations and serum estradiol concentrations at 1200h; (4) serum progesterone concentrations are lower in middle-aged rats during the preovulatory gonadotropin surge (at 1500 and 1800h) probably as a consequence of the delayed LH surge.     

Effects of naloxone infusion on plasma levels of LH, FSH, and in addition TSH and prolactin in males, before and after oestrogen or anti-oestrogen treatment

The inhibitory action of endogenous opioids on gonadotrophin release is now well documented. Since LHRH-producing neurons do not possess oestrogen-receptors, it is likely that some other compound mediates the negative feedback action of oestrogens on the gonadotrophin release in the male. To test the hypothesis that endogenous opioids are implicated in this negative feedback action in the human male, the opioid receptor antagonist naloxone (2 mg/h for 4 h) was infused into 7 normogonadotrophic oligozoospermic men before and after 6 weeks of treatment with the oestrogen-receptor antagonist tamoxifen (TAM) (10 mg twice daily) and 6 eugonadal transsexual males before and after 6 weeks of administration of ethinyloestradiol (EE) (10 micrograms three times a day). The effects of naloxone on TSH and prolactin (PRL) release were also studied. Naloxone administration resulted in a significant release of gonadotrophins, but not of TSH and PRL. Administration of oestrogen and anti-oestrogen did not significantly affect the response of gonadotrophins to naloxone infusion and no evidence of consistently antagonistic effects of oestrogen and anti-oestrogen on the naloxone-induced gonadotrophin release was obtained. This shows that endogenous opioids are probably not intermediary in the negative feedback control of oestrogens on gonadotrophin release in the human male. Surprisingly, in contrast to the eugonadal transsexual males, FSH levels in the oligozoospermic men did not respond to naloxone administration. As naloxone is thought to exert its action on gonadotrophin release via a disinhibition of endogenous LHRH release, this finding is unexpected. Exogenous LHRH administration leads to a normal response of FSH in normogonadotrophic oligozoospermic men. No plausible explanation for this finding can presently be offered.     

Effects of hypothalamic-releasing hormones on LH, FSH, and prolactin in pituitary monolayer cultures.

Four-day-old pituitary monolayer cultures were incubated with various hypothalamic releasing hormones. Rat hypothalamic extract stimulated the release of LH, FSH, and PRL by these cultures in a dose-related fashion. Synthetic LH-RH stimulated the release of LH and FSH but not of PRL. Synthetic TRH increased the release of PRL but had no effect on LH or FSH. At 10(-8) M, somatostatin did not affect any of the three adenohypophyseal hormones. Incubation with DBcAMP or theophylline also stimulated PRL release without any detectable effect on LH and FSH release. These data suggest the involvement of cyclic AMP--adenylate cyclase system in the mechanism of PRL release, but their involvement in gonadotropin release requires further studies.     

Effect of ethanol in preovulatory periods on LH, FSH, prolactin and ovulation in rats

The effect of ethanol (4 g/kg) as well as the role of serotoninergic neurons on the rate of ovulation and plasma LH, FSH and prolactin secretion have been studied in rats at preovulatory periods (18th hour of diestrus). It has been found that administration of ethanol in preovulatory periods decreased the number of ovules per rat (p less than 0.001), the number of ovulating rats and LH levels (p less than 0.001). These effects were accompanied by an increase in prolactin concentration (0.05 greater than p greater than 0.02), which was followed by a diffuse luteinization in the ovarian tissue. These results showed that ethanol had an effect of central depression in preovulatory periods. These effects could be mediated through the hypothalamic releasing factors. Under previous serotonin depletion with p-chlorophenylalanine (PCPA: 300 mg/kg), ethanol caused similar effects on LH and FSH levels as compared with the control group with PCPA. However, prolactin concentration was not increased. These results showed that serotoninergic neurons could be mediated in changes caused by ethanol on prolactin secretion, but do not affect directly in changes caused on LH and FSH secretion.     

Effects of naloxone, metaclopramide and domperidone on plasma levels of prolactin and LH following suckling in the female rabbit

Saline, naloxone, domperidone or metaclopramide was injected into lactating rabbits immediately before suckling. Blood samples were taken prior to injection (0 minutes) and then at 15, 30, 45 and 60 minutes after the start of suckling, after which the samples were assayed for plasma prolactin and LH concentrations. In all the does there was a significant increase in prolactin concentration, which was highest 15 minutes after the start of suckling, and which declined exponentially thereafter to levels significantly higher than before suckling. The increase in prolactin concentration was similar in does given saline and naloxone, but it was significantly enhanced in does given metaclopramide; with domperidone the increase was intermediate and not significantly different from that following treatment with saline. In does given saline, domperidone, and metaclopramide plasma LH concentrations declined slowly during the hour after suckling but the concentration was increased significantly in does given naloxone. The inverse correlations between prolactin and LH were low weak and were not significant.     

Carbidopa elevates hypothalamic dopa and serum prolactin in rats.

The administration of carbidopa (MK-486, α-methyl-L-dopa hydrazine; 100–200 mg/kg, intraperitoneally) causes several-fold increases in hypothalamic dopa and serum prolactin levels in male rats within 2 hours; these changes are not reversed by the administration of pyridoxine. These observations suggest that high doses of carbidopa can affect catecholamine synthesis within the hypothalamus.