Prolactin

About: Prolactin is a research topic. Over the lifetime, 22356 publications have been published within this topic receiving 609537 citations. The topic is also known as: lactotropin, & PRL,.

Influence of age on serum prolactin levels in women and men.

Abstract: Case 1-A 51-year-old woman was admitted for cholecystectomy; at operation a peroperative choledochogram showed an enlarged duct with the suspicion of a stone within it. Formal supraduodenal exploration, together with transduodenal sphincterotomy, was performed and two stones removed. The post operative T-tube choledochogram showed two residual stones in the lower end of the duct. Three washouts were performed over the next few days and a T-tube choledochogram after the last washout showed no evidence of residual calculi. The T-tube was removed and the patient has remained well. Case 2-This man presented with recurrent episodes of cholangitis. At operation the choledochogram showed a stone in the lower end of the duct but none was found on exploration and transduodenal sphincterotomy. Two postoperative T-tube choledochograms showed two residual stones in the lower end of the bile duct. Re-exploration was performed and one crushed stone removed. A repeat choledochogram showed one residual stone and a biliary washout was then performed. A T-tube choledochogram two days later showed free flow of the contrast medium into the duodenum and no evidence of the residual stone. The T-tube was removed and the patient has remained well.

Quantitative immunocytochemistry of pituitary receptors for luteinizing hormone-releasing hormone.

Abstract: In Araldite sections of male rat pituitaries, stained after embedding by the unlabeled antibody enzyme method with antisera to native luteinizing hormone-releasing hormone (LH-RH) or LH-RH azo-conjugated to bovine serum albumin, localization is confined mainly to the interior of the large, and to a lesser extent to that of the small, secretion granules of the gonadotrophic cells. Plasma membranes are not demonstrated. Except for weak staining in the granules of corticotrophs, no other pituitary cell is stained. Pretreatment of sections with LH-RH (to dilutions of 4 pg/μl) increases staining intensity in the gonadotrophic granules. Other cells are unaffected. The lesser the gonadotroph staining intensity without pretreatment, the greater the increase (more than 23-fold reactivity). Augmented staining is measurable (P<0.001) to antiserum dilutions of 1∶240 000. Pretreatment with des-Glu-1-LH-RH, porcine corticotropin or rat prolactin has no effect. LH-RH-Gly-10(desamide) inhibits. Rat glycoprotein hormones enhance staining with anti-azo-conjugated LH-RH. With antinative LH-RH these hormones enhance weak staining, but inhibit strong staining. Thick vibrotome sections of male rat or rabbit pituitaries stained before embedding reveal specific localization on plasma membrane and gonadotrophic secretion granules, provided the sections have been pretreated with LH-RH (250 pg/μl). The data show that LH-RH after reaction with receptor is not sterically hindered from binding specific antibodies. Receptor may be found in secretion granules, both in the free state or combined with LH-RH. Plasma membrane receptor, on the other hand, was free under the conditions of the experiments. Immunization with LH-RH elicits not only heteroimmune antibodies specific for LH-RH, but also a group of still ill defined autoimmune antibodies, some of which may conceivably be reactive with glycoprotein hormone α-chains.

Targeting of transforming growth factor-alpha expression to pituitary lactotrophs in transgenic mice results in selective lactotroph proliferation and adenomas.

Abstract: The PRL-secreting cells of the pituitary gland normally express transforming growth factor-alpha (TGF alpha). To determine the effect of increasing TGF alpha expression in the pituitary, a transgenic mouse model was created in which overexpression of human TGF alpha was directed to the pituitary lactotrophs using the rat PRL promoter. Of the four gene-positive mouse lines, two expressed the messenger RNA corresponding to the transgenic in the pituitary glands. However, in both these lines, expression could only be detected in the female animals. Expression of the transgenic could be detected as early as 1 month of age, but no pathology or developmental abnormalities were detected until the animals reached 6 months, at which time, hyperplasia of the lactotrophs. By the age of 12 months, all of the homozygous transgenic females had developed pituitary adenomas that were immunopositive for PRL. The other hormone-producing cells of the pituitary showed no obvious pathology. The male transgenics developed neither hyperplasia nor adenomas, nor did the gene-positive transgenic lines that did not express the transgene. In no case was an aggressive pituitary tumor seen. This transgenic mouse model indicates that TGF alpha overexpression by lactotrophs stimulates the growth of these pituitary cells. Furthermore, TGF alpha has a highly localized action in the pituitary gland, resulting only in lactotroph hyperplasia and prolactinomas. These observations suggest that TGF alpha might play a role in the development of prolactinomas.

Central lactogenic regulation of maternal behavior in rats: steroid dependence, hormone specificity, and behavioral potencies of rat prolactin and rat placental lactogen I.

Abstract: Adult virgin female rats display maternal behavior when continuously exposed to foster young for 5-6 days. Central infusions of PRL or placental lactogens (PLs) together with systemic treatment of progesterone (P) and estradiol (E2) stimulate maternal behavior in 1-2 days. In the present set of studies, it was asked whether the actions of lactogenic hormones are dependent upon both E2 and P and specific to lactogenic molecules. Moreover, we wanted to know whether central infusions of rat (r) PRL and PLs were equally effective in inducing maternal behavior. In the first study, adult virgin rats were ovariectomized (ovx) and stereotaxically fitted with bilateral cannulas directed at the medial preoptic area (MPOA). Rats were then assigned to one of four groups: P plus E2, blank (B) plus E2, P plus B, and B plus B. P-filled or B capsules were implanted sc on treatment day 1 and removed on day 11, whereas E2 or B capsules were implanted on day 11. All groups were infused with rPRL (40 ng/side) five times from days 11-13 and injected with bromocriptine (CB-154) sc (days 11-17) to suppress endogenous PRL release. Behavioral testing was conducted daily from days 12-17. It was found that exposure to both P and E2 was necessary to induce a fast onset of maternal behavior in PRL-infused females; priming with P or E2 alone in PRL-treated rats failed to stimulate a fast onset of behavior relative to that in nonsteroid-treated controls. In the second experiment to determine the biochemical specificity of PRL's action, adult nulliparous rats were ovx, implanted with bilateral cannulas directed at the MPOA, treated with both P and E2, injected with CB-154, and infused centrally (five times) with 40 ng (per side) of bovine GH, ovine LH, or vehicle. Central infusions of either bovine GH or ovine LH failed to stimulate maternal behavior, suggesting that the stimulatory actions of PRL are related to its lactogenic properties. In the final study, rats were ovx, fitted with bilateral cannulas directed at the MPOA; treated with P, E2, and CB-154; and given a single set of bilateral infusions of rPL-I or rPRL (40 ng/side.infusion) on day 11, three sets of infusions of rPL-I or rPRL (days 11 and 12), or vehicle infusions. Rats given three infusions of rPL-I and rPRL responded faster than controls, although the effect was not as robust as that in animals given five infusions in the initial study. rPL-I and rPRL groups did not differ from one another. Together these studies indicate that 1) both P and E2 are required for lactogenic stimulation of maternal behavior; 2) the stimulatory actions of PRL and rPLs on maternal behavior are related to their lactogenic properties; 3) extended treatment of females with lactogenic hormones is more effective in stimulating the onset of maternal behavior; and 4) the neural potencies of rPRL and rPL-I are similar. These findings provide support for the idea that the induction of maternal behavior is stimulated by the central actions of lactogenic hormones.

Endocrinologic control of normal canine ovarian function.

Abstract: In dogs, the termination of the 3-10-month obligate anoestrus involves selection of a cohort of LH-sensitive follicles, presumably from a wave of dominant small antral follicles that would otherwise undergo atresia. The number and size of such follicles appears to increase, especially during the last 50 days of anoestrus when the already elevated concentrations of FSH become further elevated. The final selection and eventual terminal development of these follicles is caused by an increased frequency of high-amplitude LH pulses at the end of anoestrus. Concomitant increases in FSH are typically small or negligible. High concentrations of FSH in anoestrus are likely to be important in maintaining, if not stimulating, overlapping waves of dominant follicles throughout anoestrus, their expression of aromatase activity and basal oestradiol secretion sufficient to suppress LH by negative feedback. An attractive hypothesis is that late anoestrus increases in LH-stimulate synthesis of precursor androgen for already available FSH-dependent aromatase. After 7 or more days of elevated LH, and perhaps 2-5 days of semi-autonomous growth, with maximal oestradiol production reached, follicle capacity to further increase oestradiol becomes limited and excess progesterone becomes increasingly secreted. The pre-ovulatory LH surge and oestrus onset are then triggered - often synchronously and in concert with the terminal maturation of the follicles - by central effects of the large decrease in the oestrogen to progestin ratio. Follicular endocrine and paracrine events during and following the LH surge are likely similar to those reported for other species. The prolonged luteal phase lengths of 55-75 days in non-pregnant bitches bracket the 64 +/- 1 day in pregnancy and represent a genetically programmed luteal cell lifespan approximating gestation length as occurs in the luteal phase of hysterectomized animals of most polyoestrous artiodactyls and rodents. The 30-40-day slow regression after day 20 to 30 involves periodic cell death, diminution in cell size, low levels of apoptosis and minimal or modest involvement of endogenous prostaglandin F (PGF) production. The canine corpus luteum (CL) is dependent on both LH and prolactin as stimulating luteotrophins by day 15, and as required luteotrophins by days 20-25, if not earlier. Thereafter, both luteotrophins likely have cellular mechanisms of action similar to those reported for other species. Progesterone secretion during pregnancy is greatly enhanced by characteristic, and probably relaxin-stimulated, increases in prolactin concentration starting at or after day 25, and persisting to term. Near term, foetoplacental maturation results in the placental release of large, luteolytic amounts of PGF for 1-2 days pre-partum. Pre-partum luteolysis, like that induced by exogenous prostaglandin, likely involves a cascade enhanced by the removal of progesterone inhibition of PGF release and some degree of intra-luteal PGF synthesis. That a likely twofold or greater increase in progesterone production by the CL of pregnancy does not result in significantly higher serum progesterone than in non-pregnant metoestrus relates to several biological changes, including a large increase in plasma volume of distribution, increased metabolism of progesterone by increased uterine, placental and mammary masses and increased liver clearance and excretion of progesterone and progesterone metabolite. Anoestrus length and ovarian cycle intervals, variable within and among bitches, are likely affected by neuroendocrine components of an endogenous circannual cycle, albeit only photo-entrained in the Basenji breed. This may be modified by the prior luteal phase, exposure to oestrus female pheromones and as yet unknown mechanisms that likely operate via inhibitory opioidergic and/or stimulatory dopaminergic hypothalamic pathways affecting late anoestrus increases in LH.