All issues > Volume 55(1); 2012
The genes associated with gonadotropin-releasing hormone-dependent precocious puberty
- Corresponding author: Jin Soon Hwang, MD, PhD. Department of Pediatrics, Ajou University Hospital, Ajou University School of Medicine, San 5, Woncheon-dong, Yeongtong-gu, Suwon 443-721, Korea. Tel: +82-31-219-5166, Fax: +82-31-219-5169, pedhwang@ajou.ac.kr
- Received November 18, 2011 Accepted December 19, 2011
- Abstract
-
Human puberty is a complex, coordinated biological process with multiple levels of regulations. The timing of puberty varies greatly in children and is influenced by both environmental and genetic factors. The key genes of pubertal onset, KISS1, GPR54, GNRH1 and GNRHR, may be major causal factors underlying gonadotropin-releasing hormone-dependent precocious puberty (GDPP). Two gain-of-function mutations in KISS1 and GPR54 have been identified recently as genetic causes of GDPP. GNRH1 and GNRHR are also gene candidates for GDPP; however no mutations have been identified in these genes. Presently potential genetic causes like LIN28B continues to appear; many areas of research await exploration in this context. In this review, I focus primarily on the genetic causes of GDPP.
- Introduction
- Introduction
Puberty is a complex, coordinated biological process that transits an individual from childhood to adulthood. It is initiated by the secretion of gonadotropin-releasing hormone (GnRH) from hypothalamic neurons and secreted GnRH triggers signaling cascades and gonadal activations1). GnRH, the key hormone in the onset of puberty, is mediated by kisspeptin activation of the G-protein coupled receptor-54 (GPR54), and it exercises major control over secretion of gonadotropins, luteinizing hormone (LH) and follicle stimulating hormone (FSH) from pituitary gonadotrope cell2). The secreted gonadotropins evoke steroidogenesis and gametogenesis from the gonads, and ultimately culminate in secondary sexual characteristics.Precocious puberty is defined as the onset secondary sexual characteristics in girls younger than 8 years old and in boys younger than 9 years old3). Children who experience GnRH-dependent precocious puberty (GDPP) demonstrate early activation of the hypothalamic-pituitary-gonadal axis4). Since the underlying mechanism of GDPP and normal puberty are identical, GDPP-induced sexual characteristics are appropriate for the child's gender; normal sexual characteristics develop at an abnormally early age.GDPP occurs more frequently in girls than in boys (approximately 20:1 ratio), and as many as 90% of the female cases are designated as idiopathic5-7). On the other hand, organic lesions such as hypothalamic hamartomas, occur more often in boys.Pubertal timing is regulated by genetic and environmental factors8,9) and varies among racial groups10). In addition, a positive correlation has been shown for the age of menarche between mothers and daughters. Also pubertal development in monozygotic twins exhibits greater concordance than in dizygotic twins11). Interestingly, familial GDDP can occur in up to 27.5% of cases12). The results of familial segregation analyses indicate potential an autosomal dominant transmission with incomplete sex-dependent penetrance12). These findings suggest that genetic factors play important role in GDDP.
- KISS1 gene
- KISS1 gene
The KISS1-kisspeptin-kisspeptin receptor system functions as a major gatekeeper of the onset of puberty13,14). The KISS1 gene encodes kisspeptin which functions via kisspeptin receptor (GPR54). Kisspeptin expression is highest in the arcuate and anteroventral periventricular nuclei, which are known to project into the medial preoptic area. The medial preoptic area contains an abundance of GnRH neurons, which express GPR54 on the surface15). Thus, KISS1 directly governs the activation of GnRH neurons and downstream cascades and is obvious gene candidate for playing a role in the cause of naturally occurring GDPP16).The KISS1 gene maps to chromosome 1q32-q41 and was identified initially as a tumor metastasis suppressor by the process of subtractive hybridization and differential display following microcell-mediated transfer of chromosome 6 into human melanoma cell lines17,18). Later, KISS1 was shown in many studies to be an important reproductive regulator during the onset of puberty. The gene consists of 3 exons, 2 of which are partially translated exons (exons 2 and 3), that give rise to a 145-amino acid precursor peptide19). The precursor peptide is cleaved to 54 (68 to 121) amino acids in length, and can be truncated further to 14 (108 to 121), 13 (109 to 121), or 10 amino acid carboxyl-terminal fragments. The resulting fragments are referred to as kisspeptins, and have been shown subsequently to bind and activate GPR54 with potency equal to the non-truncated peptide (54 amino acids in length)20). In 2003, the product of KISS1, kisspeptin was demonstrated to perform a function in the reproductive axis21). KISS1 is a candidate gene for the cause of humans idiopathic hypogonadotropic hypogonadism and GDPP. KISS1 knockout mouse models have been developed; they demonstrated characteristics of idiopathic hypogonadotropic hypogodadism to varying degrees. Conversely, a specific KISS1 mutation can lead to prolonged activation of KISS1, which eventually results in GDPP. Studies on KISS1 mutations in patients with GDPP have not provided substantial evidence. Ko et al.1), Luan et al.22), and Silveria et al.23) published the studies on KISS1 mutations in patients with GDPP. However, Silveria et al.23) alone identified gain of function KISS1 mutations (p.P74S and p.H90D). The p.P74S mutation was identified in the heterozygous state from a boy with GDPP. The p.H90D mutation was identified in the homozygous state from 2 unrelated girls with GDDP23). Luan et al.22) and Ko et al.1) identified 1 potentially meaningful polymorphism (p.P110T), which was detected less frequently in GDDP patients than in controls. Moreover, when subjected to GnRH stimulation test, GDDP patients with the p.P110T polymorphism exhibited lower FSH values than those without p.P110T. Ko et al.1) suggested that p.P110T may exert a protective effect on pubertal precocity. Thus KISS1 gene alterations were shown to contribute to GDPP pathogenesis, but further study on KISS1 gene mutations is required to elucidate GDPP pathogenesis.
- GPR54 gene
- GPR54 gene
As noted earlier, GPR54 (the Kisspeptin receptor) and its ligand, kisspeptin, are major gatekeepers of puberty. The GPR54 gene is located on chromosome 19p13.324) and consists of 5 exons and 4 introns over a length of approximately 3.5 kb. GPR54 encodes a 7-transmembrane receptor that comprises 398 amino acids and has weak homology with the galanin receptors24,25). The GPR54 receptor is a member of the rhodopsin family of the G protein-coupled receptor superfamily. It was cloned initially in 1999 as an orphan receptor in rat brain24). The human GPR54 receptor is expressed widely in the brain-particularly in the hypothalamus, midbrain, pons, medulla, hippocampus, and amygdaleand in the pituitary, pancreas, placenta, and spinal cord24,25). Lower levels of expression were detected in the heart, muscle, kidney, liver, intestine, thymus, lung, and testis24,25). GPR54 inactivation had been discovered previously to causes hypogonadotropic hypogonadism in humans, which motivated a series of pharmacological and physiological studies. These studies confirmed the crucial role played by the kisspeptin/GPR54 system in hypothalamic-pituitary-gonadal axis activation. In 2003, several loss-of-function mutations in the GPR54 gene were described in patients with impaired pubertal development. Physiologic studies have demonstrated that binding to the G protein-coupled receptor in the membrane of hypothalamic GnRH neurons enables kisspeptin to function as a powerful stimulant of GnRH secretion14). The kisspeptin-GPR54 system has been implicated in the human GDPP pathogenesis since 2008, when Teles et al.26) identified activating mutation (p.R386P) in the GPR54 gene. The p.R386P mutation was identified in the carboxyterminal tail of GPR54 and responded to kisspeptin exposure with prolonged activation of intracellular signaling pathways, which resulted in significantly increased inositol phosphate accumulation for as long as 18 hours26). Recently Bianco et al.27) learned that the p.R386P mutation yielded prolonged responsiveness to kisspeptin by decreasing GPR54 degradation, which resulted in a net increase of the mutated receptor being recycled to the plasma membrane. Luna et al.28) identified 6 GPR54 polymorphisms in Chinese girls with GDPP. Only one nonsynomious change was found to correlate slightly to the disease28). Also, Ko et al.29) identified 1 known polymorphism in Korean girls with GDPP, but he was unable to determine any disease associations.
- GNRH1 gene
- GNRH1 gene
The GNRH1 gene is located on chromosome 8p21.2, spans about 5 kb and contains 3 exons. It encodes the GNRH1 precursor, which comprises 92 amino acids, and is processed subsequently in GNRH1, an active decapeptide29). In 2009, Bouligand et al.36) reported a homozygous GNRH1 frameshift mutation (c.18-19insA) in the amino-terminal region of GnRH's protein precursor which contains a single peptide that was obtained from a teenage brother and sister, who both had complete normosmic IHH. This report was particularly meaningful because the efforts of several precious teams had never resulted in the identification of alterations in the GNRH1 gene in patients with IHH. However loss-of-function mutations in GNRH1 gene have been identified recently as rare genetic causes of normosmic IHH. Although GDPP represents on extreme of pubertal development in contrast to IHH, the activation of GnRH1 gene to GDPP remains undefined. No reports have shown gain-of-function mutations in the GNRH1 gene until now, despite the efforts of several teams, including Ko et al.29), with GDPP patients.
- GnRHR gene
- GnRHR gene
The GnRHR gene is located on chromosome 4q13.2 and its genomic sequence encompasses about 19 kb. It includes 3 exons and encodes a heptahelical transmembrane domain G protein-coupled receptor that the intracellular carboxyl terminus normally present in other members of this family37). In 1997, GnRHR inactivating mutations are the first genetic alterations that were recognized as a monogenic cause of normosmic IHH38), several additional mutations in GnRHR have identified to date. Large-scale screening has revealed that GnRHR mutations account for about 3.5 to 16% of the sporadic cases of normosmic IHH and up to 40% of familial cases of IHH39).
- LH receptor gene
- LH receptor gene
The LH receptor is coupled to G proteins and thus spans the membrane 7 times. It is characterized by a very large N-terminal in the extracellular domain40) to which the hormone binds. The LH receptor gene is located on chromosome 2p2141) and contains 11 exons. The last exon encodes the entire transmembrane and intracellular domains whereas the first 10 exons encode monomers or polymers of leucinerich repeats that form the extracellular domain41).Constitutive activation of the receptor determines Familial Male-Limited Precocious Puberty; it exhibits autosomal dominant familial transmission and is characterized by high testosterone levels with low gonadotropins42). Puberty usually occurs between 1 and 4 years of age. Girls with these mutations do not exhibit premature puberty, probably because an increased FSH concentration is necessary to determine ovarian follicle growth and maturation42).
- The FSH receptor gene
- The FSH receptor gene
The structure of the FSH receptor closely resembles the structure of the LH receptor; the genes are in the same location on chromosome 2p2143). The FSH receptor consists of 10 exons, the last of which encodes both the transmembrane and intracellular domains. To date, little is known about activating mutations of the FSH receptor gene.
- LIN28B gene
- LIN28B gene
The LIN28B gene is located on chromosome, and it was cloned and characterized originally in human hepatocellular carcinoma cells44). LIN28B is a human homolog of lin-28 of nematode Caenorhabitidis elegans; Gain-of-function and loss-of-function mutations in LIN28 result in retarded or precocious development, respectively45). The lin-28 family regulates the biogenesis of let-7 microRNA family members, which control the timing of developmental events45). Thus LIN28B may have a role in human pubertal development and thus, is a candidate gene for precocious puberty. The UKPMC funders group carried out a genome-wide association study on the age of menarche in 4,714 women and reported an association with LIN28B46). They determined that rs314276 is a single nucleotide polymorphism (SNP) located in intron 2 of LIN28B. The SNP resides in a region of high linkage disequilibrium around 200 kb in size that includes the 5' region and the first 3 exons of LIN28B46). The rs314276 SNP is associated with the timing of pubertal growth and development in both girls and boys46).
- Conclusions
- Conclusions
Puberty is a complex multistage process that occurs over a 2- to 3-year period and involves growth acceleration, weight gain and the appearance of secondary sexual physical features. The timing of puberty onset varies greatly among individuals and races, and much of this variation is due to genetic factors. However, the exact causes and mechanisms underlying this variation remain largely unknown. Several genes have been implicated in the pathogenesis of GDPP; the genes are associated with the development and migration of GnRH neurons, the regulation of GnRH synthesis, secretion and action or gonadotropin cascades. Few genetic causes of GDPP have been identified thus far, but potential genetic causes continue to emerge from research studies, and many areas of research await exploration. In the near future, genetic alterations related to GDPP should be identified individually.
- References
- 1. Ko JM, Lee HS, Hwang JS. KISS1 gene analysis in Korean girls with central precocious puberty: a polymorphism, p.P110T, suggested to exert a protective effect. Endocr J 2010;57:701–709.
[Article] [PubMed]2. Silveira LF, Trarbach EB, Latronico AC. Genetics basis for GnRH-dependent pubertal disorders in humans. Mol Cell Endocrinol 2010;324:30–38.
[Article] [PubMed]3. Carel JC, Léger J. Clinical practice. Precocious puberty. N Engl J Med 2008;358:2366–2377.
[Article] [PubMed]4. Palmert MR, Boepple PA. Variation in the timing of puberty: clinical spectrum and genetic investigation. J Clin Endocrinol Metab 2001;86:2364–2368.
[Article] [PubMed]5. Teilmann G, Pedersen CB, Jensen TK, Skakkebaek NE, Juul A. Prevalence and incidence of precocious pubertal development in Denmark: an epidemiologic study based on national registries. Pediatrics 2005;116:1323–1328.
[Article] [PubMed]6. Brito VN, Latronico AC, Arnhold IJ, Mendonça BB. Update on the etiology, diagnosis and therapeutic management of sexual precocity. Arq Bras Endocrinol Metabol 2008;52:18–31.
[Article] [PubMed]7. Kakarla N, Bradshaw KD. Disorders of pubertal development: precocious puberty. Semin Reprod Med 2003;21:339–351.
[Article] [PubMed]8. Nathan BM, Palmert MR. Regulation and disorders of pubertal timing. Endocrinol Metab Clin North Am 2005;34:617–641. ix
[Article] [PubMed]9. Gajdos ZK, Hirschhorn JN, Palmert MR. What controls the timing of puberty? An update on progress from genetic investigation. Curr Opin Endocrinol Diabetes Obes 2009;16:16–24.
[Article] [PubMed]10. Parent AS, Teilmann G, Juul A, Skakkebaek NE, Toppari J, Bourguignon JP. The timing of normal puberty and the age limits of sexual precocity: variations around the world, secular trends, and changes after migration. Endocr Rev 2003;24:668–693.
[Article] [PubMed]11. Fischbein S. Intra-pair similarity in physical growth of monozygotic and of dizygotic twins during puberty. Ann Hum Biol 1977;4:417–430.
[Article] [PubMed]12. de Vries L, Kauschansky A, Shohat M, Phillip M. Familial central precocious puberty suggests autosomal dominant inheritance. J Clin Endocrinol Metab 2004;89:1794–1800.
[Article] [PubMed]13. Han SK, Gottsch ML, Lee KJ, Popa SM, Smith JT, Jakawich SK, et al. Activation of gonadotropin-releasing hormone neurons by kisspeptin as a neuroendocrine switch for the onset of puberty. J Neurosci 2005;25:11349–11356.
[Article] [PubMed] [PMC]14. Navarro VM, Castellano JM, García-Galiano D, Tena-Sempere M. Neuroendocrine factors in the initiation of puberty: the emergent role of kisspeptin. Rev Endocr Metab Disord 2007;8:11–20.
[Article] [PubMed]15. Smith JT, Clarke IJ. Kisspeptin expression in the brain: catalyst for the initiation of puberty. Rev Endocr Metab Disord 2007;8:1–9.
[Article] [PubMed]16. Teles MG, Silveira LF, Tusset C, Latronico AC. New genetic factors implicated in human GnRH-dependent precocious puberty: the role of kisspeptin system. Mol Cell Endocrinol 2011;346:84–90.
[Article] [PubMed]17. Lee JH, Welch DR. Suppression of metastasis in human breast carcinoma MDA-MB-435 cells after transfection with the metastasis suppressor gene, KiSS-1. Cancer Res 1997;57:2384–2387.
[PubMed]18. Li D, Mitchell D, Luo J, Yi Z, Cho SG, Guo J, et al. Estrogen regulates KISS1 gene expression through estrogen receptor alpha and SP protein complexes. Endocrinology 2007;148:4821–4828.
[Article] [PubMed]19. West A, Vojta PJ, Welch DR, Weissman BE. Chromosome localization and genomic structure of the KiSS-1 metastasis suppressor gene (KISS1). Genomics 1998;54:145–148.
[Article] [PubMed]20. Kotani M, Detheux M, Vandenbogaerde A, Communi D, Vanderwinden JM, Le Poul E, et al. The metastasis suppressor gene KiSS-1 encodes kisspeptins, the natural ligands of the orphan G protein-coupled receptor GPR54. J Biol Chem 2001;276:34631–34636.
[Article] [PubMed]21. de Roux N, Genin E, Carel JC, Matsuda F, Chaussain JL, Milgrom E. Hypogonadotropic hypogonadism due to loss of function of the KISS1-derived peptide receptor GPR54. Proc Natl Acad Sci U S A 2003;100:10972–10976.
[Article] [PubMed] [PMC]22. Luan X, Zhou Y, Wang W, Yu H, Li P, Gan X, et al. Association study of the polymorphisms in the KISS1 gene with central precocious puberty in Chinese girls. Eur J Endocrinol 2007;157:113–118.
[Article] [PubMed]23. Silveira LG, Noel SD, Silveira-Neto AP, Abreu AP, Brito VN, Santos MG, et al. Mutations of the KISS1 gene in disorders of puberty. J Clin Endocrinol Metab 2010;95:2276–2280.
[Article] [PubMed] [PMC]24. Lee DK, Nguyen T, O'Neill GP, Cheng R, Liu Y, Howard AD, et al. Discovery of a receptor related to the galanin receptors. FEBS Lett 1999;446:103–107.
[Article] [PubMed]25. Muir AI, Chamberlain L, Elshourbagy NA, Michalovich D, Moore DJ, Calamari A, et al. AXOR12, a novel human G protein-coupled receptor, activated by the peptide KiSS-1. J Biol Chem 2001;276:28969–28975.
[Article] [PubMed]26. Teles MG, Bianco SD, Brito VN, Trarbach EB, Kuohung W, Xu S, et al. A GPR54-activating mutation in a patient with central precocious puberty. N Engl J Med 2008;358:709–715.
[Article] [PubMed] [PMC]27. Bianco SD, Vandepas L, Correa-Medina M, Gereben B, Mukherjee A, Kuohung W, et al. KISS1R intracellular trafficking and degradation: effect of the Arg386Pro disease-associated mutation. Endocrinology 2011;152:1616–1626.
[Article] [PubMed] [PMC]28. Luan X, Yu H, Wei X, Zhou Y, Wang W, Li P, et al. GPR54 polymorphisms in Chinese girls with central precocious puberty. Neuroendocrinology 2007;86:77–83.
[Article] [PubMed]29. Ko JM, Lee HS, Lee HS, Hwang JS. Genetic variations of GNRH1, GnRHR and GPR54 genes in Korean girls with central precocious puberty. J Korean Soc Pediatr Endocrinol 2011;16:38–45.
[Article]30. Seminara SB, Messager S, Chatzidaki EE, Thresher RR, Acierno JS Jr, Shagoury JK, et al. The GPR54 gene as a regulator of puberty. N Engl J Med 2003;349:1614–1627.
[Article] [PubMed]31. Cerrato F, Shagoury J, Kralickova M, Dwyer A, Falardeau J, Ozata M, et al. Coding sequence analysis of GnRHR and GPR54 in patients with congenital and adult-onset forms of hypogonadotropic hypogonadism. Eur J Endocrinol 2006;155(Suppl 1): S3–S10.
[Article] [PubMed]32. Semple RK, Achermann JC, Ellery J, Farooqi IS, Karet FE, Stanhope RG, et al. Two novel missense mutations in g protein-coupled receptor 54 in a patient with hypogonadotropic hypogonadism. J Clin Endocrinol Metab 2005;90:1849–1855.
[Article] [PubMed]33. Tenenbaum-Rakover Y, Commenges-Ducos M, Iovane A, Aumas C, Admoni O, de Roux N. Neuroendocrine phenotype analysis in five patients with isolated hypogonadotropic hypogonadism due to a L102P inactivating mutation of GPR54. J Clin Endocrinol Metab 2007;92:1137–1144.
[Article] [PubMed]34. Teles MG, Trarbach EB, Noel SD, Guerra-Junior G, Jorge A, Beneduzzi D, et al. A novel homozygous splice acceptor site mutation of KISS1R in two siblings with normosmic isolated hypogonadotropic hypogonadism. Eur J Endocrinol 2010;163:29–34.
[Article] [PubMed]35. Lanfranco F, Gromoll J, von Eckardstein S, Herding EM, Nieschlag E, Simoni M. Role of sequence variations of the GnRH receptor and G protein-coupled receptor 54 gene in male idiopathic hypogonadotropic hypogonadism. Eur J Endocrinol 2005;153:845–852.
[Article] [PubMed]36. Bouligand J, Ghervan C, Tello JA, Brailly-Tabard S, Salenave S, Chanson P, et al. Isolated familial hypogonadotropic hypogonadism and a GNRH1 mutation. N Engl J Med 2009;360:2742–2748.
[Article] [PubMed]37. Kakar SS, Musgrove LC, Devor DC, Sellers JC, Neill JD. Cloning, sequencing, and expression of human gonadotropin releasing hormone (GnRH) receptor. Biochem Biophys Res Commun 1992;189:289–295.
[Article] [PubMed]38. de Roux N, Young J, Misrahi M, Genet R, Chanson P, Schaison G, et al. A family with hypogonadotropic hypogonadism and mutations in the gonadotropin-releasing hormone receptor. N Engl J Med 1997;337:1597–1602.
[Article] [PubMed]39. Beranova M, Oliveira LM, Bédécarrats GY, Schipani E, Vallejo M, Ammini AC, et al. Prevalence, phenotypic spectrum, and modes of inheritance of gonadotropin-releasing hormone receptor mutations in idiopathic hypogonadotropic hypogonadism. J Clin Endocrinol Metab 2001;86:1580–1588.
[Article] [PubMed]40. McFarland KC, Sprengel R, Phillips HS, Köhler M, Rosemblit N, Nikolics K, et al. Lutropin-choriogonadotropin receptor: an unusual member of the G protein-coupled receptor family. Science 1989;245:494–499.
[Article] [PubMed]41. Rousseau-Merck MF, Misrahi M, Atger M, Loosfelt H, Milgrom E, Berger R. Localization of the human luteinizing hormone/choriogonadotropin receptor gene (LHCGR) to chromosome 2p21. Cytogenet Cell Genet 1990;54:77–79.
[Article] [PubMed]42. de Roux N, Milgrom E. Inherited disorders of GnRH and gonadotropin receptors. Mol Cell Endocrinol 2001;179:83–87.
[Article] [PubMed]43. Rousseau-Merck MF, Atger M, Loosfelt H, Milgrom E, Berger R. The chromosomal localization of the human follicle-stimulating hormone receptor gene (FSHR) on 2p21-p16 is similar to that of the luteinizing hormone receptor gene. Genomics 1993;15:222–224.
[Article] [PubMed]44. Guo Y, Chen Y, Ito H, Watanabe A, Ge X, Kodama T, et al. Identification and characterization of lin-28 homolog B (LIN28B) in human hepatocellular carcinoma. Gene 2006;384:51–61.
[Article] [PubMed]