Prolactin

PRL
Available structures
PDBOrtholog search: PDBe RCSB
Identifiers
Aliases PRL, GHA1, prolactin
External IDs MGI: 97762 HomoloGene: 732 GeneCards: PRL
Genetically Related Diseases
mammary Paget's disease[1]
Orthologs
Species Human Mouse
Entrez

5617

19109

Ensembl

ENSG00000172179

ENSMUSG00000021342

UniProt

P01236

P06879

RefSeq (mRNA)

NM_000948
NM_001163558

NM_001163530
NM_011164

RefSeq (protein)

NP_000939.1
NP_001157030.1

n/a

Location (UCSC) Chr 6: 22.29 – 22.3 Mb Chr 13: 27.06 – 27.07 Mb
PubMed search [2] [3]
Wikidata
View/Edit HumanView/Edit Mouse

Prolactin (PRL), also known as luteotropic hormone or luteotropin, is a protein that in humans is best known for its role in enabling mammals, usually females, to produce milk. It is influential in over 300 separate processes in various vertebrates.[4] Prolactin is secreted from the pituitary gland in response to eating, mating, estrogen treatment, ovulation and nursing. Prolactin is secreted in pulses in between these events. Prolactin plays an essential role in metabolism, regulation of the immune system and pancreatic development.

Discovered in non-human animals around 1930 by Oscar Riddle[5] and confirmed in humans in 1970 by Henry Friesen[6] prolactin is a peptide hormone, encoded by the PRL gene.[7]

It is associated with human milk production. In fish it is thought to be related to control of water and salt balance. Prolactin also acts in a cytokine-like manner and as an important regulator of the immune system. It has important cell cycle-related functions as a growth-, differentiating- and anti-apoptotic factor. As a growth factor, binding to cytokine-like receptors, it influences hematopoiesis, angiogenesis and is involved in the regulation of blood clotting through several pathways. The hormone acts in endocrine, autocrine and paracrine manner through the prolactin receptor and a large number of cytokine receptors.[4]

Pituitary prolactin secretion is regulated by endocrine neurons in the hypothalamus. The most important ones are the neurosecretory tuberoinfundibulum (TIDA) neurons of the arcuate nucleus that secrete dopamine (aka Prolactin Inhibitory Hormone) to act on the D2 receptors of lactotrophs, causing inhibition of prolactin secretion. Thyrotropin-releasing factor (thyrotropin-releasing hormone) has a stimulatory effect on prolactin release, however Prl is the only adenohypophyseal hormone whose principal control is inhibitory.

Several variants and forms are known per species. Many fish have variants prolactin A and prolactin B. Most vertebrates including humans also have the closely related somatolactin. In humans, three smaller (4, 16 and 22 kDa) and several larger (so called big and big-big) variants exist.

Functions

Prolactin has a wide variety of effects. It stimulates the mammary glands to produce milk (lactation): increased serum concentrations of prolactin during pregnancy cause enlargement of the mammary glands and prepare for milk production, which normally starts when the levels of progesterone fall by the end of pregnancy and a suckling stimulus is present. Sometimes, newborns (males as well as females) secrete a milky substance from their nipples known as witch's milk. This is in part caused by maternal prolactin and other hormones. Prolactin plays an important role in maternal behavior.[8]

Prolactin provides the body with sexual gratification after sexual acts: The hormone counteracts the effect of dopamine, which is linked to sexual arousal. This is thought to cause the sexual refractory period. The amount of prolactin can be an indicator for the amount of sexual satisfaction and relaxation. Unusually high amounts are suspected to be responsible for impotence and loss of libido (see hyperprolactinemia symptoms).

Elevated levels of prolactin decrease the levels of sex hormones — estrogen in women and testosterone in men.[9] The effects of mildly elevated levels of prolactin are much more variable, in women, substantially increasing or decreasing estrogen levels.

Prolactin is sometimes classified as a gonadotropin[10] although in humans it has only a weak luteotropic effect while the effect of suppressing classical gonadotropic hormones is more important.[11] Prolactin within the normal reference ranges can act as a weak gonadotropin, but at the same time suppresses GnRH secretion. The exact mechanism by which it inhibits GnRH is poorly understood. Although expression of prolactin receptors (PRL-R) have been demonstrated in rat hypothalamus, the same has not been observed in GnRH neurons.[12] Physiologic levels of prolactin in males enhance luteinizing hormone-receptors in Leydig cells, resulting in testosterone secretion, which leads to spermatogenesis.[13]

Prolactin also stimulates proliferation of oligodendrocyte precursor cells. These cells differentiate into oligodendrocytes, the cells responsible for the formation of myelin coatings on axons in the central nervous system.[14]

Other actions include contributing to pulmonary surfactant synthesis of the fetal lungs at the end of the pregnancy and immune tolerance of the fetus by the maternal organism during pregnancy. Prolactin delays hair regrowth in mice.[15] Prolactin promotes neurogenesis in maternal and fetal brains.[16][17]

Regulation

In humans, prolactin is produced at least in the anterior pituitary, decidua, myometrium, breast, lymphocytes, leukocytes and prostate.[18][19]

Pituitary PRL is controlled by the Pit-1 transcription factor that binds to the prolactin gene at several sites. Ultimately dopamine, extrapituitary PRL is controlled by a superdistal promoter and apparently unaffected by dopamine.[19] The thyrotropin-releasing hormone and the vasoactive intestinal peptide stimulate the secretion of prolactin in experimental settings, however their physiological influence is unclear. The main stimulus for prolactin secretion is suckling, the effect of which is neuronally mediated.[20] A key regulator of prolactin production is estrogens that enhance growth of prolactin-producing cells and stimulate prolactin production directly, as well as suppressing dopamine.

In decidual cells and in lymphocytes the distal promoter and thus prolactin expression is stimulated by cAMP. Responsivness to cAMP is mediated by an imperfect cAMP–responsive element and two CAAT/enhancer binding proteins (C/EBP).[19] Progesterone upregulates prolactin synthesis in the endometrium and decreases it in myometrium and breast glandular tissue.[21] Breast and other tissues may express the Pit-1 promoter in addition to the distal promoter.

Extrapituitary production of prolactin is thought to be special to humans and primates and may serve mostly tissue specific paracrine and autocrine purposes. It has been hypothesized that in vertebrates such as mice a similar tissue specific effect is achieved by a large family of prolactin-like proteins controlled by at least 26 paralogous PRL genes not present in primates.[19]

Vasoactive intestinal peptide and peptide histidine isoleucine help to regulate prolactin secretion in humans, but the functions of these hormones in birds can be quite different.[22]

Prolactin follows diurnal and ovulatory cycles. Prolactin levels peak during REM sleep and in the early morning. Many mammals experience a seasonal cycle.

During pregnancy, high circulating concentrations of estrogen and progesterone increase prolactin levels by 10- to 20-fold. Estrogen and progesterone inhibit the stimulatory effects of prolactin on milk production. The abrupt drop of estrogen and progesterone levels following delivery allow prolactin—which temporarily remains high—to induce lactation.

Sucking on the nipple offsets the fall in prolactin as the internal stimulus for them is removed. The sucking activates mechanoreceptors in and around the nipple. These signals are carried by nerve fibers through the spinal cord to the hypothalamus, where changes in the electrical activity of neurons that regulate the pituitary gland increase prolactin secretion. The suckling stimulus also triggers the release of oxytocin from the posterior pituitary gland, which triggers milk let-down: Prolactin controls milk production (lactogenesis) but not the milk-ejection reflex; the rise in prolactin fills the breast with milk in preparation for the next feed.

In usual circumstances, in the absence of galactorrhea, lactation ceases within one or two weeks following the end of breastfeeding.

Compared to un-mated males, fathers and expectant fathers have increased prolactin concentrations.[23]

Levels can rise after exercise, high-protein meals,[24] sexual intercourse, breast examination,[24] minor surgical procedures,[25] following epileptic seizures[26] or due to physical or emotional stress.[24][27] In a study on female volunteers under hypnosis, prolactin surges resulted from the evocation, with rage, of humiliating experiences, but not from the fantasy of nursing.[27]

Prolactin levels have also been found to rise with use of the drug MDMA (Ecstasy), leading to speculation that prolactin may have a role in the post-orgasmic state as well as decreased sexual desire.[28]

Hypersecretion is more common than hyposecretion. Hyperprolactinemia is the most frequent abnormality of the anterior pituitary tumors, termed prolactinomas. Prolactinomas may disrupt the hypothalamic-pituitary-gonadal axis as prolactin tends to suppress the secretion of GnRH from the hypothalamus and in turn decreases the secretion of follicle-stimulating hormone (FSH) and luteinizing hormone (LH) from the anterior pituitary, therefore disrupting the ovulatory cycle.[29] Such hormonal changes may manifest as amenorrhea and infertility in females as well as impotence in males. Inappropriate lactation (galactorrhoea) is another important clinical sign of prolactinomas.

Structure and isoforms

The structure of prolactin is similar to that of growth hormone and placental lactogen. The molecule is folded due to the activity of three disulfide bonds. Significant heterogeneity of the molecule has been described, thus bioassays and immunoassays can give different results due to differing glycosylation, phosphorylationsandulfation, as well as degradation. The non-glycosylated form of prolactin is the dominant form at is secreted by the pituitary gland.

The three different sizes of prolactin are:

The levels of larger ones are somewhat higher during the early postpartum period.[33]

Prolactin receptor

Main article: Prolactin receptor

Prolactin receptors are present in the mammillary glands, ovaries, pituitary glands, heart, lung, thymus, spleen, liver, pancreas, kidney, adrenal gland, uterus, skeletal muscle, skin and areas of the central nervous system.[34] When prolactin binds to the receptor, it causes it to dimerize with another prolactin receptor. This results in the activation of Janus kinase 2, a tyrosine kinase that initiates the JAK-STAT pathway. Activation also results in the activation of mitogen-activated protein kinases and Src kinase.[34]

Human prolactin receptors are insensitive to mouse prolactin.[35]

Diagnostic use

Prolactin levels may be checked as part of a sex hormone workup, as elevated prolactin secretion can suppress the secretion of FSH and GnRH, leading to hypogonadism and sometimes causing erectile dysfunction.

Prolactin levels may be of some use in distinguishing epileptic seizures from psychogenic non-epileptic seizures. The serum prolactin level usually rises following an epileptic seizure.[36]

Units and unit conversions

The serum concentration of prolactin can be given in mass concentration (µg/L or ng/mL), molar concentration (nmol/L or pmol/L) or in international units (typically mIU/L). The current IU is calibrated against the third International Standard for Prolactin, IS 84/500.[37][38] Reference ampoules of IS 84/500 contain 2.5 µg of lyophilized human prolactin[39] and have been assigned an activity of .053 International Units.[37][38] Measurements that are calibrated against the current international standard can be converted into mass units using this ratio of grams to IUs;[40] prolactin concentrations expressed in mIU/L can be converted to µg/L by dividing by 21.2. Previous standards use other ratios.[41][42][43][44]

The first International Reference Preparation (or IRP) of human Prolactin for Immunoassay was established in 1978 (75/504 1st IRP for human Prolactin) at a time when purified human prolactin was in short supply.[40][41] Previous standards relied on prolactin from animal sources.[44] Purified human prolactin was scarce, heterogeneous, unstable and difficult to characterize. A preparation labelled 81/541 was distributed by the WHO Expert Committee on Biological Standardization without official status and given the assigned value of 50 mIU/ampoule based on an earlier collaborative study.[40][42] It was determined that this preparation behaved anomalously in certain immunoassays and was not suitable as an IS.[40]

Three different human pituitary extracts containing prolactin were subsequently obtained as candidates for an IS. These were distributed into ampoules coded 83/562, 83/573 and 84/500.[37][38][40][43] Collaborative studies involving 20 different laboratories found little difference between these three preparations. 83/562 appeared to be the most stable. This preparation was largely free of dimers and polymers of prolactin. On the basis of these investigations 83/562 was established as the Second IS for human Prolactin.[43] Once stocks of these ampoules were depleted, 84/500 was established as the Third IS for human Prolactin.[37][40]

Reference ranges

General guidelines for diagnosing prolactin excess (hyperprolactinemia) define the upper threshold of normal prolactin at 25 µg/L for women and 20 µg/L for men.[34] Similarly, guidelines for diagnosing prolactin deficiency (hypoprolactinemia) are defined as prolactin levels below 3 µg/L in women[45][46] and 5 µg/L in men.[47][48][49] However, different assays and methods for measuring prolactin are employed by different laboratories and as such the serum reference range for prolactin is often determined by the laboratory performing the measurement.[34][50] Furthermore, prolactin levels also vary factors including age,[51] sex,[51] menstrual cycle stage[51] and pregnancy.[51] The circumstances surrounding a given prolactin measurement (assay, patient condition, etc.) must therefore be considered before the measurement can be accurately interpreted.[34]

The following chart illustrates the variations seen in normal prolactin measurements across different populations. Prolactin values were obtained from specific control groups of varying sizes using the IMMULITE assay.[51]

Typical prolactin values
Proband Prolactin, µg/L
women, follicular phase (n = 803)
12.1
women, luteal phase (n = 699)
13.9
women, mid-cycle (n = 53)
17
women, whole cycle (n = 1555)
13.0
women, pregnant, 1st trimester (n = 39)
16
women, pregnant, 2nd trimester (n = 52)
49
women, pregnant, 3rd trimester (n = 54)
113
Men, 21–30 (n = 50)
9.2
Men, 31–40 (n = 50)
7.1
Men, 41–50 (n = 50)
7.0
Men, 51–60 (n = 50)
6.2
Men, 61–70 (n = 50)
6.9

Inter-method variability

The following table illustrates variability in reference ranges of serum prolactin between some commonly used assay methods (as of 2008), using a control group of healthy health care professionals (53 males, age 20–64 years, median 28 years; 97 females, age 19–59 years, median 29 years) in Essex, England:[50]

Assay method Mean
Prolactin
Lower limit
2.5th percentile
Upper limit
97.5th percentile
µg/L mIU/L µg/L mIU/L µg/L mIU/L
Females
Centaur 7.92 168 3.35 71 16.4 348
Immulite 9.25 196 3.54 75 18.7 396
Access 9.06 192 3.63 77 19.3 408
AIA 9.52[52] 257[52] 3.89[52] 105[52] 20.3[52] 548[52]
Elecsys 10.5 222 4.15 88 23.2 492
Architect 10.6 225 4.62 98 21.1 447
Males
Access 6.89 146 2.74 58 13.1 277
Centaur 7.88 167 2.97 63 12.4 262
Immulite 7.45 158 3.30 70 13.3 281
AIA 7.81[52] 211[52] 3.30[52] 89[52] 13.5[52] 365[52]
Elecsys 8.49 180 3.40 72 15.6 331
Architect 8.87 188 4.01 85 14.6 310

An example usage of table above is, if using the Centaur assay to estimate prolactin values in µg/L for females, the mean is 7.92 µg/L and the reference range is 3.35–16.4 µg/L.

Conditions

Elevated levels

Hyperprolactinaemia, or excess serum prolactin, is associated with hypoestrogenism, anovulatory infertility, oligomenorrhoea, amenorrhoea, unexpected lactation and loss of libido in women and erectile dysfunction and loss of libido in men.[53]

Physiological

  • Coitus
  • Exercise
  • Lactation
  • Pregnancy
  • Sleep
  • Stress
  • Depression

Pharmacological

Pathological

 

Decreased levels

Main article: Hypoprolactinemia

Hypoprolactinemia, or serum prolactin deficiency, is associated with ovarian dysfunction in women,[45][46] and arteriogenic erectile dysfunction, premature ejaculation,[47] oligozoospermia, asthenospermia, hypofunction of seminal vesicles and hypoandrogenism[48] in men. In one study, normal sperm characteristics were restored when prolactin levels were raised to normal values in hypoprolactinemic men.[49]

Hypoprolactinemia can result from hypopituitarism, excessive dopaminergic action in the tuberoinfundibular pathway and ingestion of D2 receptor agonists such as bromocriptine.

While there is evidence that women who smoke tend to breast feed for shorter periods, there is a wide variation of breast-feeding rates in women who do smoke. This suggest that psychosocial factors rather than physiological mechanisms (e.g., nicotine suppressing prolactin levels) are responsible for the lower rates of breast feeding in women who do smoke.[54][55]

In medicine

Prolactin is available commercially for use in animals, but not in humans.[56] It is used to stimulate lactation in animals.[56] The biological half-life of prolactin in humans is around 15–20 minutes.[57] The D2 receptor is involved in the regulation of prolactin secretion, and agonists of the receptor such as bromocriptine and cabergoline decrease prolactin levels while antagonists of the receptor such as domperidone, metoclopramide, haloperidol, risperidone, and sulpiride increase prolactin levels.[58] D2 receptor antagonists like domperidone, metoclopramide, and sulpiride are used as galactogogues to increase prolatin secretion and induce lactation in humans.[59]

See also

References

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  50. 1 2 Table 2 in Beltran L, Fahie-Wilson MN, McKenna TJ, Kavanagh L, Smith TP (Oct 2008). "Serum total prolactin and monomeric prolactin reference intervals determined by precipitation with polyethylene glycol: evaluation and validation on common immunoassay platforms". Clinical Chemistry. 54 (10): 1673–81. doi:10.1373/clinchem.2008.105312. PMID 18719199.
  51. 1 2 3 4 5 Prolaktin at medical.siemens.com—reference ranges as determined from the IMMULITE assay method
  52. 1 2 3 4 5 6 7 8 9 10 11 12 The AIA essay values are also from Table 2 in Beltran 2008, like the other values, but it uses a different conversion factor of 27.0 mIU/L per µg/L, taken from the second international standard, IS 83/562).
  53. Melmed S, Kleinberg D 2008 Anterior pituitary. 1n: Kronenberg HM, Melmed S, Polonsky KS, Larsen PR, eds. Willams textbook of endocrinology. 11th ed. Philadelphia: Saunders Elsevier; 185-261
  54. Amir LH (2001). "Maternal smoking and reduced duration of breastfeeding: a review of possible mechanisms". Early Human Development. 64 (1): 45–67. doi:10.1016/S0378-3782(01)00170-0. PMID 11408108.
  55. Amir LH, Donath SM (2002). "Does maternal smoking have a negative physiological effect on breastfeeding? The epidemiological evidence". Birth (Berkeley, Calif.). 29 (2): 112–23. doi:10.1046/j.1523-536X.2002.00152.x. PMID 12000412.
  56. 1 2 R. T. Coutts; G. A. Smail (12 May 2014). Polysaccharides Peptides and Proteins: Pharmaceutical Monographs. Elsevier. pp. 153–. ISBN 978-1-4831-9612-1.
  57. D.F. Horrobin (6 December 2012). Prolactin: Physiology and Clinical Significance. Springer Science & Business Media. pp. 13–. ISBN 978-94-010-9695-9.
  58. Martin H. Johnson (14 December 2012). Essential Reproduction. John Wiley & Sons. pp. 40–. ISBN 978-1-118-42388-2.
  59. Jan Riordan (January 2005). Breastfeeding and Human Lactation. Jones & Bartlett Learning. pp. 468–. ISBN 978-0-7637-4585-1.

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