Luteinizing hormone

Luteinizing hormone (LH, also known as luteinising hormone[1], lutropin and sometimes lutrophin[2]) is a hormone produced by gonadotropic cells in the anterior pituitary gland. The production of LH is regulated by gonadotropin-releasing hormone (GnRH) from the hypothalamus.[3] In females, an acute rise of LH ("LH surge") triggers ovulation[4] and development of the corpus luteum. In males, where LH had also been called interstitial cell–stimulating hormone (ICSH),[5] it stimulates Leydig cell production of testosterone.[4] It acts synergistically with follicle-stimulating hormone (FSH).

Chorionic gonadotropin alpha
Identifiers
SymbolCGA
Alt. symbolsHCG, GPHa, GPHA1
NCBI gene1081
HGNC1885
OMIM118850
RefSeqNM_000735
UniProtP01215
Other data
LocusChr. 6 q14-q21
Search for
StructuresSwiss-model
DomainsInterPro
Luteinizing hormone beta polypeptide
Identifiers
SymbolLHB
NCBI gene3972
HGNC6584
OMIM152780
RefSeqNM_000894
UniProtP01229
Other data
LocusChr. 19 q13.3
Search for
StructuresSwiss-model
DomainsInterPro

Structure

LH is a heterodimeric glycoprotein. Each monomeric unit is a glycoprotein molecule; one alpha and one beta subunit make the full, functional protein.

Its structure is similar to that of the other glycoprotein hormones, follicle-stimulating hormone (FSH), thyroid-stimulating hormone (TSH), and human chorionic gonadotropin (hCG). The protein dimer contains 2 glycopeptidic subunits (labeled alpha- and beta- subunits) that are non-covalently associated:[6]

  • The alpha subunits of LH, FSH, TSH, and hCG are identical, and contain 92 amino acids in human but 96 amino acids in almost all other vertebrate species (glycoprotein hormones do not exist in invertebrates).
  • The beta subunits vary. LH has a beta subunit of 120 amino acids (LHB) that confers its specific biologic action and is responsible for the specificity of the interaction with the LH receptor. This beta subunit contains an amino acid sequence that exhibits large homologies with that of the beta subunit of hCG and both stimulate the same receptor. However, the hCG beta subunit contains an additional 24 amino acids, and the two hormones differ in the composition of their sugar moieties.

The different composition of these oligosaccharides affects bioactivity and speed of degradation. The biologic half-life of LH is 20 minutes, shorter than that of FSH (3–4 hours) and hCG (24 hours). The biological half-life of LH is 23 hours subcutaneous[7] or terminal half life of 10-12 hours.[8]

Genes

The gene for the alpha subunit is located on chromosome 6q12.21.

The luteinizing hormone beta subunit gene is localized in the LHB/CGB gene cluster on chromosome 19q13.32. In contrast to the alpha gene activity, beta LH subunit gene activity is restricted to the pituitary gonadotropic cells. It is regulated by the gonadotropin-releasing hormone from the hypothalamus. Inhibin, activin, and sex hormones do not affect genetic activity for the beta subunit production of LH.

Function

Effects of LH on the body

In both males and females, LH works upon endocrine cells in the gonads to produce androgens.

Effects in females

LH supports theca cells in the ovaries that provide androgens and hormonal precursors for estradiol production. At the time of menstruation, FSH initiates follicular growth, specifically affecting granulosa cells.[9] With the rise in estrogens, LH receptors are also expressed on the maturing follicle, which causes it to produce more estradiol. Eventually, when the follicle has fully matured, a spike in 17α-hydroxyprogesterone production by the follicle inhibits the production of estrogens, leading to a decrease in estrogen-mediated negative feedback of GnRH in the hypothalamus, which then stimulates the release of LH from the anterior pituitary.[10] However another theory of the LH peak is a positive feedback mechanism from estradiol. The levels keep rising through the follicular phase and when they reach an unknown threshold, this results in the peak of the LH.[11] This effect is opposite from the usual negative feedback mechanism presented at lower levels. In other words, the mechanism(s) are not yet clear. The increase in LH production only lasts for 24 to 48 hours. This "LH surge" triggers ovulation, thereby not only releasing the egg from the follicle, but also initiating the conversion of the residual follicle into a corpus luteum that, in turn, produces progesterone to prepare the endometrium for a possible implantation. LH is necessary to maintain luteal function for the second two weeks of the menstrual cycle. If pregnancy occurs, LH levels will decrease, and luteal function will instead be maintained by the action of hCG (human chorionic gonadotropin), a hormone very similar to LH but secreted from the new placenta.

Gonadal steroids (estrogens and androgens) generally have negative feedback effects on GnRH-1 release at the level of the hypothalamus and at the gonadotropes, reducing their sensitivity to GnRH. Positive feedback by estrogens also occurs in the gonadal axis of female mammals and is responsible for the midcycle surge of LH that stimulates ovulation. Although estrogens inhibit kisspeptin (Kp) release from kiss1 neurons in the ARC, estrogens stimulate Kp release from the Kp neurons in the AVPV. As estrogens' levels gradually increase the positive effect predominates, leading to the LH surge. GABA-secreting neurons that innervate GnRH-1 neurons also can stimulate GnRH-1 release. These GABA neurons also possess ERs and may be responsible for the GnRH-1 surge. Part of the inhibitory action of endorphins on GnRH-1 release is through inhibition of these GABA neurons. Rupture of the ovarian follicle at ovulation causes a drastic reduction in estrogen synthesis and a marked increase in secretion of progesterone by the corpus luteum in the ovary, reinstating a predominantly negative feedback on hypothalamic secretion of GnRH-1.[12]

Effects in males

LH acts upon the Leydig cells of the testis and is regulated by gonadotropin-releasing hormone (GnRH).[13] The Leydig cells produce testosterone under the control of LH. LH binds to LH receptors on the membrane surface of Leydig cells. Binding to this receptor causes an increase in cyclic adenosine monophosphate (cAMP), a secondary messenger, which allows cholesterol to translocate into the mitochondria. Within the mitochondria, cholesterol is converted to pregnenolone by CYP11A1.[14] Pregnenolone is then converted to dehydroepiandrosterone (DHEA).[15] DHEA is then converted to androstenedione by 3β-hydroxysteroid dehydrogenase (3β-HSD)[16] and then finally converted to testosterone by 17β-hydroxysteroid dehydrogenase (HSD17B). The onset of puberty is controlled by two major hormones: FSH initiates spermatogenesis and LH signals the release of testosterone,[17] an androgen that exerts both endocrine activity and intratesticular activity on spermatogenesis.

LH is released from the pituitary gland, and is controlled by pulses of gonadotropin-releasing hormone. When bloodstream testosterone levels are low, the pituitary gland is stimulated to release LH.[13] As the levels of testosterone increase, it will act on the pituitary through a negative feedback loop and inhibit the release of GnRH and LH consequently. Androgens (including testosterone and dihydrotestosterone) inhibit monoamine oxidase (MAO) in the pineal gland, leading to increased melatonin and reduced LH and FSH by melatonin-induced increase of Gonadotropin-Inhibitory Hormone (GnIH)[18] synthesis and secretion. Testosterone can also be aromatized into estradiol (E2) to inhibit LH. E2 decreases pulse amplitude and responsiveness to GnRH from the hypothalamus onto the pituitary.[19]

Changes in LH and testosterone blood levels and pulse secretions are induced by changes in sexual arousal in human males.[20]

Normal levels

Reference ranges for the blood content of luteinizing hormone (LH) during the menstrual cycle.[21]
  • The ranges denoted By biological stage may be used in closely monitored menstrual cycles in regard to other markers of its biological progression, with the time scale being compressed or stretched to how much faster or slower, respectively, the cycle progresses compared to an average cycle.
  • The ranges denoted Inter-cycle variability are more appropriate to use in non-monitored cycles with only the beginning of menstruation known, but where the woman accurately knows her average cycle lengths and time of ovulation, and that they are somewhat averagely regular, with the time scale being compressed or stretched to how much a woman's average cycle length is shorter or longer, respectively, than the average of the population.
  • The ranges denoted Inter-woman variability are more appropriate to use when the average cycle lengths and time of ovulation are unknown, but only the beginning of menstruation is given.

LH levels are normally low during childhood and in women, high after menopause. Since LH is secreted as pulses, it is necessary to follow its concentration over a sufficient period of time to get proper information about its blood level.

During reproductive years, typical levels are between 1 and 20 IU/L. Physiologic high LH levels are seen during the LH surge (v.s.) and typically last 48 hours.

In males over 18 years of age, reference ranges have been estimated to be 1.8–8.6 IU/L.[22]

LH is measured in international units (IU). When quantifying the amount of LH in a sample in IUs, it is important to know which international standard your lot of LH was calibrated against since they can vary broadly from year to year. For human urinary LH, one IU is most recently defined as 1/189th of an ampule denoted 96/602 and distributed by the NIBSC, corresponding to approximately 0.04656 µg of LH protein for a single IU, but older standard versions are still widely in use.[23][24]

Lateral flow test strip for urine LH used to predict ovulation.

Predicting ovulation

Chance of fertilization by menstrual cycle day relative to ovulation.[25]

The detection of a surge in release of luteinizing hormone indicates impending ovulation. LH can be detected by urinary ovulation predictor kits (OPK, also LH-kit) that are performed, typically daily, around the time ovulation may be expected.[26] A conversion from a negative to a positive reading would suggest that ovulation is about to occur within 24–48 hours, giving women two days to engage in sexual intercourse or artificial insemination with the intention of conceiving.[27]

The recommended testing frequency differs between manufacturers. For example, the Clearblue test is taken daily, and an increased frequency does not decrease the risk of missing an LH surge.[28] On the other hand, the Chinese company Nantong Egens Biotechnology recommends using their test twice per day.[29] If testing once per day, no significant difference has been found between testing LH in the morning versus in the evening, in relation to conception rates,[30] and recommendations of what time in the day to take the test varies between manufacturers and healthcare workers.[31] Tests may be read manually using a color-change paper strip, or digitally with the assistance of reading electronics.

Tests for luteinizing hormone may be combined with testing for estradiol in tests such as the Clearblue fertility monitor.

The sensitivity of LH tests are measured in milli international unit, with tests commonly available in the range 10–40 m.i.u. (the lower the number, the higher the sensitivity).

As sperm can stay viable in the woman for several days, LH tests are not recommended for contraceptive practices, as the LH surge typically occurs after the beginning of the fertile window.

Disease states

Excess

In children with precocious puberty of pituitary or central origin, LH and FSH levels may be in the reproductive range instead of the low levels typical for their age.

During the reproductive years, relatively elevated LH is frequently seen in patients with polycystic ovary syndrome; however, it would be unusual for them to have LH levels outside of the normal reproductive range.

Persistently high LH levels are indicative of situations where the normal restricting feedback from the gonad is absent, leading to a pituitary production of both LH and FSH. While this is typical in menopause, it is abnormal in the reproductive years. There it may be a sign of:

  1. Premature menopause
  2. Gonadal dysgenesis, Turner syndrome, Klinefelter syndrome
  3. Castration
  4. Swyer syndrome
  5. Polycystic ovary syndrome
  6. Certain forms of congenital adrenal hyperplasia
  7. Testicular failure
  8. Pregnancy - BetaHCG can mimic LH so tests may show elevated LH

Note: A medical drug for inhibiting luteinizing hormone secretion is Butinazocine.[32]

Deficiency

Diminished secretion of LH can result in failure of gonadal function (hypogonadism). This condition is typically manifest in males as failure in production of normal numbers of sperm. In females, amenorrhea is commonly observed. Conditions with very low LH secretions include:

  1. Pasqualini syndrome[33][34][35]
  2. Kallmann syndrome
  3. Hypothalamic suppression
  4. Hypopituitarism
  5. Eating disorder
  6. Female athlete triad
  7. Hyperprolactinemia
  8. Hypogonadism
  9. Gonadal suppression therapy
    1. GnRH antagonist
    2. GnRH agonist (inducing an initial stimulation (flare up) followed by permanent blockage of the GnRH pituitary receptor)

As a medication

LH is available mixed with FSH in the form of menotropin, and other forms of urinary gonadotropins. More purified forms of urinary gonadotropins may reduce the LH portion in relation to FSH. Recombinant LH is available as lutropin alfa (Luveris).[36] All these medications have to be given parenterally. They are commonly used in infertility therapy to stimulate follicular development, the notable one being in IVF therapy.

Often, HCG medication is used as an LH substitute because it activates the same receptor. Medically used hCG is derived from urine of pregnant women, is less costly, and has a longer half-life than LH.

Role in phosphorylation

Phosphorylation is a biochemical process that involves the addition of phosphate to an organic compound. Steroidogenesis entails processes by which cholesterol is converted to biologically active steroid hormones. Recent study shows that LH via a PKA signaling pathway regulates the phosphorylation and localization of DRP1 within mitochondria of the steroidogenic cells of the ovary.[37]

References

  1. GCSE Science Revision Biology "The Menstrual Cycle", retrieved 2022-03-23
  2. Ujihara M, Yamamoto K, Nomura K, Toyoshima S, Demura H, Nakamura Y, et al. (June 1992). "Subunit-specific sulphation of oligosaccharides relating to charge-heterogeneity in porcine lutrophin isoforms". Glycobiology. 2 (3): 225–31. doi:10.1093/glycob/2.3.225. PMID 1498420.
  3. Stamatiades, George A.; Kaiser, Ursula B. (2018-03-05). "Gonadotropin regulation by pulsatile GnRH: Signaling and gene expression". Molecular and Cellular Endocrinology. Signaling Pathways Regulating Pituitary Functions. 463: 131–141. doi:10.1016/j.mce.2017.10.015. ISSN 0303-7207. PMC 5812824. PMID 29102564.
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  5. Louvet JP, Harman SM, Ross GT (May 1975). "Effects of human chorionic gonadotropin, human interstitial cell stimulating hormone and human follicle-stimulating hormone on ovarian weights in estrogen-primed hypophysectomized immature female rats". Endocrinology. 96 (5): 1179–86. doi:10.1210/endo-96-5-1179. PMID 1122882.
  6. Jiang X, Dias JA, He X (January 2014). "Structural biology of glycoprotein hormones and their receptors: insights to signaling". Molecular and Cellular Endocrinology. 382 (1): 424–451. doi:10.1016/j.mce.2013.08.021. PMID 24001578.
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  9. Bowen R (13 May 2004). "Gonadotropins: Luteinizing and Follicle Stimulating Hormones". Colorado State University. Retrieved 12 March 2012.
  10. Mahesh VB (January 2012). "Hirsutism, virilism, polycystic ovarian disease, and the steroid-gonadotropin-feedback system: a career retrospective". American Journal of Physiology. Endocrinology and Metabolism. 302 (1): E4–E18. doi:10.1152/ajpendo.00488.2011. PMC 3328092. PMID 22028409.
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  16. Liu L, Kang J, Ding X, Chen D, Zhou Y, Ma H (2015). "Dehydroepiandrosterone-Regulated Testosterone Biosynthesis via Activation of the ERK1/2 Signaling Pathway in Primary Rat Leydig Cells". Cellular Physiology and Biochemistry. 36 (5): 1778–92. doi:10.1159/000430150. PMID 26184424. S2CID 13816368.
  17. Oduwole OO, Peltoketo H, Huhtaniemi IT (2018). "Role of Follicle-Stimulating Hormone in Spermatogenesis". Frontiers in Endocrinology. Nutrients. 9: 763. doi:10.3389/fendo.2018.00763. PMC 6302021. PMID 30619093.
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  19. Pitteloud N, Dwyer AA, DeCruz S, Lee H, Boepple PA, Crowley WF, Hayes FJ (March 2008). "Inhibition of luteinizing hormone secretion by testosterone in men requires aromatization for its pituitary but not its hypothalamic effects: evidence from the tandem study of normal and gonadotropin-releasing hormone-deficient men". The Journal of Clinical Endocrinology and Metabolism. 93 (3): 784–91. doi:10.1210/jc.2007-2156. PMC 2266963. PMID 18073301.
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  21. Häggström M (2014). "Reference ranges for estradiol, progesterone, luteinizing hormone and follicle-stimulating hormone during the menstrual cycle". WikiJournal of Medicine. 1 (1). doi:10.15347/wjm/2014.001. ISSN 2002-4436.
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  31. Page 67 in: Godwin I. Meniru (2001). Cambridge Guide to Infertility Management and Assisted Reproduction. Cambridge University Press.
  32. U.S. Patent 4,406,904
  33. Weiss J, Axelrod L, Whitcomb RW, Harris PE, Crowley WF, Jameson JL (January 1992). "Hypogonadism caused by a single amino acid substitution in the beta subunit of luteinizing hormone". The New England Journal of Medicine. 326 (3): 179–83. doi:10.1056/NEJM199201163260306. PMID 1727547.
  34. Valdes-Socin H, Salvi R, Daly AF, Gaillard RC, Quatresooz P, Tebeu PM, et al. (December 2004). "Hypogonadism in a patient with a mutation in the luteinizing hormone beta-subunit gene". The New England Journal of Medicine. 351 (25): 2619–25. doi:10.1056/NEJMoa040326. PMID 15602022.
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  36. Luveris information Archived June 18, 2006, at the Wayback Machine
  37. Plewes MR, Hou X, Talbott HA, Zhang P, Wood JR, Cupp AS, Davis JS (February 2020). "Luteinizing hormone regulates the phosphorylation and localization of the mitochondrial effector dynamin-related protein-1 (DRP1) and steroidogenesis in the bovine corpus luteum". FASEB Journal. Federation of American Societies for Experimental Biology. 34 (4): 5299–5316. doi:10.1096/fj.201902958R. PMC 7136153. PMID 32077149.
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