A mutation in the POU-homeodomain of Pit-1 responsible for combined pituitary hormone deficiency.

Pit-1 is a pituitary-specific transcription factor responsible for pituitary development and hormone expression in mammals. Mutations in the gene encoding Pit-1 have been found in two dwarf mouse strains displaying hypoplasia of growth hormone, prolactin, and thyroid-stimulating, hormone-secreting cell types in the anterior pituitary. A point mutation in this gene was identified on one allele in a patient with combined pituitary hormone deficiency. Mutant Pit-1 binds DNA normally but acts as a dominant inhibitor of Pit-1 action in the pituitary.

CREB-independent regulation by CBP is a novel mechanism of human growth hormone gene expression.

Hypothalamic growth hormone-releasing hormone (GHRH) stimulates growth hormone (GH) gene expression in anterior pituitary somatotrophs by binding to the GHRH receptor, a G-protein-coupled transmembrane receptor, and by mediating a cAMP-mediated protein kinase A (PKA) signal-transduction pathway. Two nonclassical cAMP-response element motifs (CGTCA) are located at nucleotides -187/-183 (distal cAMP-response element; dCRE) and -99/-95 (proximal cAMP-response element; pCRE) of the human GH promoter and are required for cAMP responsiveness, along with the pituitary-specific transcription factor Pit-1 (official nomenclature, POU1F1). Although a role for cAMP-response element binding protein (CREB) in GH stimulation by PKA has been suggested, it is unclear how the effect may be mediated. CREB binding protein (CBP) is a nuclear cofactor named for its ability to bind CREB. However, CBP also binds other nuclear proteins. We determined that CBP interacts with Pit-1 and is a cofactor for Pit-1-dependent activation of the human GH promoter. This pathway appears to be independent of CREB, with CPB being the likely target of phosphorylation by PKA.

Role of a pituitary-specific transcription factor (pit-1/GHF-1) or a closely related protein in cAMP regulation of human thyrotropin-beta subunit gene expression.

cAMP regulation of the human thyrotropin-beta (TSH beta) gene cAMP was studied in two heterologous cell lines, a human embryonal kidney cell line (293) and a rat pituitary cell line (GH3). In 293 cells, human TSH beta gene expression was not stimulated by the adenylate cyclase activator forskolin or the cAMP analogue 8-bromo-cAMP (8-Br-cAMP). On the other hand, these agents induced human TSH beta gene expression 4-12-fold in GH3 cells. Deletion analysis demonstrated that the regions from +3 to +8 bp and from -128 to -61 bp were both necessary for cAMP stimulation. The latter region contains three DNA sequences homologous to a pituitary-specific transcription factor, Pit-1/GHF-1, DNA-binding site. Gel-mobility assays demonstrated that a radiolabeled human TSH beta probe (-128 to -61 bp) formed five specific DNA-protein complexes with mouse thyrotropic tumor (MTT) nuclear extract and two specific complexes with in vitro translated Pit-1/GHF-1. Four of the five MTT complexes and both in vitro Pit-1/GHF-1 complexes were reduced or eliminated by excess of an unlabeled Pit-1/GHF-1 DNA-binding site from the rat growth hormone gene, but not a mutated version of the same DNA fragment, suggesting that Pit-1/GHF-1 or a closely related thyrotroph protein binds to these DNA sequences. In 293 cells, co-transfection of an expression vector containing the Pit-1/GHF-1 cDNA restored cAMP-responsiveness to the human TSH beta promoter (5.2- and 6.6-fold maximal stimulation by 8-Br-cAMP and forskolin, respectively) but not the herpes virus thymidine kinase promoter (1.2-fold maximal stimulation by either agent). Thus we conclude that the human TSH beta gene is positively regulated by cAMP in GH3 but not 293 cells. Since the human TSH beta gene contains at least one high-affinity binding site for Pit-1/GHF-1 in a region necessary for cAMP stimulation and cAMP stimulation could be restored to the human TSH beta promoter in a previously nonresponsive cell line by the addition of Pit-1/GHF-1, this suggests that Pit-1/GHF-1, or a closely related protein in the thyrotroph, may be a trans-acting factor for cAMP stimulation of the TSH beta gene.

Evidence for direct estrogen regulation of the human gonadotropin-releasing hormone gene.

This study is an attempt to determine whether estrogen could directly regulate human gonadotropin-releasing hormone (GnRH) gene expression. Human GnRH expression vectors were constructed by fusing various 5' flanking regions of the human GnRH gene upstream of the luciferase reporter gene (LUC) or the thymidine kinase promoter linked to the chloramphenicol acetyltransferase reporter gene (CAT). These constructs were transiently transfected into a human choriocarcinoma cell line (JEG-3) and LUC or CAT activity was measured after either no treatment or treatment with various concentrations of estradiol. A stimulatory estrogen response element (ERE) was localized to a 32-bp region between -547 and -516 bp. To determine whether estrogen receptor bound to this region of the gene, we performed DNase I footprinting using purified calf uterine estrogen receptor. DNase I footprinting demonstrates a strong footprint between -567 and -514 bp of the human GnRH gene. In addition, an avidin-biotin complex DNA-binding assay demonstrated that a biotinylated DNA fragment containing -541 to -517 bp of the human GnRH gene bound 35S-labeled estrogen receptor as well as a biotinylated DNA fragment containing the xenopus vitellogenin ERE. On the other hand, the negative control biotinylated DNA fragment derived from adenovirus 5 bound insignificant amounts of 35S-labeled estrogen receptor. Both the GnRH ERE and vitellogenin ERE bound 35S-labeled estrogen receptor with high affinity (approximately 1 nM). These data indicate that the human GnRH gene contains an ERE sufficient to mediate a stimulatory response to estrogen in heterologous cells. Based upon these data we hypothesize that the human GnRH gene might also be directly regulated by estrogen in the hypothalamus, and that this regulation may explain the GnRH hypersecretion observed at the time of the preovulatory luteinizing hormone (LH) surge.

Divergent roles for thyroid hormone receptor beta isoforms in the endocrine axis and auditory system.

Thyroid hormone receptors (TRs) modulate various physiological functions in many organ systems. The TR alpha and TR beta isoforms are products of 2 distinct genes, and the beta 1 and beta 2 isoforms are splice variants of the same gene. Whereas TR alpha 1 and TR beta 1 are widely expressed, expression of the TR beta 2 isoform is mainly limited to the pituitary, triiodothyronine-responsive TRH neurons, the developing inner ear, and the retina. Mice with targeted disruption of the entire TR beta locus (TR beta-null) exhibit elevated thyroid hormone levels as a result of abnormal central regulation of thyrotropin, and also develop profound hearing loss. To clarify the contribution of the TR beta 2 isoform to the function of the endocrine and auditory systems in vivo, we have generated mice with targeted disruption of the TR beta 2 isoform. TR beta 2-null mice have preserved expression of the TR alpha and TR beta 1 isoforms. They develop a similar degree of central resistance to thyroid hormone as TR beta-null mice, indicating the important role of TR beta 2 in the regulation of the hypothalamic-pituitary-thyroid axis. Growth hormone gene expression is marginally reduced. In contrast, TR beta 2-null mice exhibit no evidence of hearing impairment, indicating that TR beta 1 and TR beta 2 subserve divergent roles in the regulation of auditory function.

A circulating, biologically inactive thyrotropin caused by a mutation in the beta subunit gene.

Mutation of a critical carboxy-terminal cysteine residue (C105V) in the thyrotropin-beta (TSH-beta) subunit gene was found in two related families with central hypothyroidism. Affected patients had low thyroid hormone levels and radioactive iodine uptake in the thyroid gland associated with measurable serum TSH. Thyrotropin-releasing hormone-stimulated TSH secretion did not increase thyroid hormone production in these patients as compared to their unaffected siblings, suggesting that the mutant TSH was biologically inactive in vivo. Recombinant TSH harboring this mutation was confirmed to be biologically inactive in an in vitro bioassay. Based on crystallographic structure of chorionic gonadotropin, a disulfide bond between C19 and C105 in the TSH-beta subunit is predicted to form the "buckle" of a "seat belt" that surrounds the common alpha subunit and maintains the conformation and bioactivity of the hormone. This natural mutation of the TSH-beta subunit confirms the importance of the seat belt in the family of pituitary and placental glycoprotein hormones.

Kisspeptin Induces Dynamic Chromatin Modifications to Control GnRH Gene Expression.

In vitro studies have demonstrated an increase in GnRH gene expression associated with an elevated secretory response to kisspeptin administration, suggesting that kisspeptin mediates GnRH expression at both the secretory and pretranslational levels. However, the kisspeptin-mediated intracellular mechanisms associated with the dynamic chromatin modifications modulating GnRH gene expression are unclear. The studies in this manuscript describe specific histone modifications on the enhancer and promoter of the mouse GnRH (mGnRH) gene induced by kisspeptin in GnRH neuronal cell lines (GT1-7 cells). ChIP assays followed by quantitative real-time PCR (qPCR) demonstrate that 15 and 45 min of 10(-9) M kisspeptin significantly increased histone 3 acetylation (H3Ac) at the kisspeptin response element (KsRE) contained between -3446 and -2806 bp of the mGnRH enhancer (GnRHen) in GT1-7 cells, while no changes were observed in the downstream neuron-specific element (NSE). Moreover, kisspeptin specifically induced acetylation of H3AcK14 and K27 and trimethylation of H3 lysine 4 at the KsRE (markers of active chromatin) and no changes in dimethylation of H3K9 (a marker associated with gene repression). Occupancy of RNA Pol II (RNAPII) and a differential carboxyl-terminal domain (CTD) phosphorylation pattern was observed. An interaction between the NSE and the KsRE via a chromatin loop in the mGnRH gene by kisspeptin was detected by the chromosome conformation capture assay (3C). In conclusion, these results demonstrate that kisspeptin induces histone acetylation/methylation and consequently enhances the formation of a chromatin loop in the mGnRH gene which results in known increase in kisspeptin-dependent mGnRH expression.

Development and Characterization of Novel Rat Anti-mERß Sera.

Estrogens regulate normal sexual and reproductive development in females. Their actions are mediated mainly by estrogen receptor (ER)α and ERß. Understanding the function of ERs necessitates knowing their cellular location and protein partners, which, in turn, requires reliable and specific antibodies. Several antibodies are available for ERα; however, discrepancies in immunoreactivity have been reported for ERß. Here, we have developed antisera for mouse ERß (mERß) using a specific C-terminal 18-amino acid peptide conjugated to mariculture keyhole limpet hemocyanin. Sprague Dawley rats were immunized, and the resulting antisera were characterized by Western blot analysis of nuclear extracts from tissues of wild-type (WT) mice, and mice genetically modified to lack either ERα (CERαKO) or ERß (CERßKO). An approximately 56-kDa protein was detected in the hypothalamus, uterus, ovary, mammary gland, testes, and epididymis of WT mice, consistent with the predicted molecular size of ERß. In addition, the same protein band was identified in in vitro synthesized mERß protein and in the mammary glands of CERαKO mice. The approximately 56-kDa protein was not observed in in vitro synthesized mERα protein or in any tissue examined in the CERßKO mice. Immunohistochemistry using the antisera revealed ERß staining in the granulosa cells of WT ovaries and in the mediobasal hypothalamus, paraventricular nucleus, and cerebral cortex in the WT adult mouse brain. These data suggest that the novel rat anti-mERß sera are specific to ERß to allow investigators to explore to cellular and physiological role of ERß in the brain and other mouse tissues.

GH safety workshop position paper: a critical appraisal of recombinant human GH therapy in children and adults.

Recombinant human GH (rhGH) has been in use for 30 years, and over that time its safety and efficacy in children and adults has been subject to considerable scrutiny. In 2001, a statement from the GH Research Society (GRS) concluded that 'for approved indications, GH is safe'; however, the statement highlighted a number of areas for on-going surveillance of long-term safety, including cancer risk, impact on glucose homeostasis, and use of high dose pharmacological rhGH treatment. Over the intervening years, there have been a number of publications addressing the safety of rhGH with regard to mortality, cancer and cardiovascular risk, and the need for long-term surveillance of the increasing number of adults who were treated with rhGH in childhood. Against this backdrop of interest in safety, the European Society of Paediatric Endocrinology (ESPE), the GRS, and the Pediatric Endocrine Society (PES) convened a meeting to reappraise the safety of rhGH. The ouput of the meeting is a concise position statement.

Regulation of gonadotropin-releasing hormone (GnRH) gene expression by insulin-like growth factor I in a cultured GnRH-expressing neuronal cell line.

A GnRH-expressing neuronal cell line (NLT) was used to determine whether insulin-like growth factor I (IGF-I) regulates GnRH gene expression. A receptor-binding assay demonstrated the expression of IGF-I receptors on NLT cells. Activation of IGF-I receptors induced the Ras/Raf-1/mitogen-activated protein kinase pathway and increased c-fos expression. NLT cells treated with IGF-I underwent cell proliferation and exhibited a growth-independent increase in mouse GnRH mRNA expression. In cells transfected with DNA constructs containing the human GnRH promoter, which includes a consensus AP-1 binding site fused to the luciferase reporter gene, a significant increase in reporter activities was induced by IGF-I, whereas mutation of this AP-1 site significantly reduced IGF-I-induced promoter activation. These results demonstrate that IGF-I serves as an important signal in the regulation of both human and rodent GnRH gene expression.

Isolation and characterization of the human gonadotropin-releasing hormone gene in the hypothalamus and placenta.

The GnRH gene has been cloned in several species, but the location of the promoter and the exact start of transcription have not previously been determined. To characterize the low abundance human GnRH mRNA in the hypothalamus and placenta, we have employed the polymerase chain reaction. The hypothalamus was found to have a 61-base pair first exon, and its transcriptional start site was determined. The human hypothalamic GnRH cDNAs isolated thus far have all contained a short 5' untranslated region which would correspond to this start site. However, all human placental GnRH cDNAs reported to date have a long 5' untranslated region, which extends more than 140-base pairs 5' to this start site in the hypothalamus, suggesting the utilization of an alternative promoter in the placenta. In addition, the human GnRH gene undergoes differential splicing in these tissues. The first intron is removed from the hypothalamic, but retained in the placental, GnRH mRNA. Thus, the placenta has a very long first exon, while the hypothalamus has a comparatively short first exon, followed by a long first intron. This characterization of the human GnRH gene will now allow hormonal regulatory studies to be performed using gene transfer techniques.

Phorbol ester regulation of the gonadotropin-releasing hormone (GnRH) gene in GnRH-secreting cell lines: a molecular basis for species differences.

Phorbol ester 12-O-tetradecanoyl phorbol-13-acetate (TPA) regulation of the GnRH gene was studied in two mouse GnRH neuronal cell lines, Gn11 and NLT. TPA treatment of NLT cells grown in low serum conditions did not alter endogenous mouse GnRH mRNA levels, indicating that the endogenous mouse gene is not regulated by phorbol esters under these conditions. This result is confirmed in transfection studies in which TPA treatment did not change expression of a mouse GnRH-luciferase reporter gene construct. In contrast, TPA treatment stimulated expression of a human GnRH-luciferase reporter construct, correlating with the expression of the protoon-cogenes c-fos and c-jun. TPA stimulation of the human GnRH gene is mediated by a consensus AP-1 site located at -402 to -396 bp, TGACTCA, which specifically binds c-fos and c-jun in Gn11 and NLT cells and recombinant c-jun in gel mobility shift studies. In contrast, the rodent GnRH genes, when aligned for maximum homology, contain a DNA sequence with a 1-bp difference, TGTCTCA from the human gene. In gel mobility shift studies, this DNA sequence does not form a complex with Gn11 or NLT nuclear extract or with recombinant c-jun. This is the first demonstration of species-specific differences in phorbol ester regulation of GnRH gene transcription and could, in part, explain differences in reproductive function among mammals.

Cloning and structure of human genomic DNA and hypothalamic cDNA encoding human prepro thyrotropin-releasing hormone.

The gene encoding human preproTRH was isolated from a human lung fibroblast genomic DNA library with a rat prepro TRH cDNA fragment. The transcriptional unit is 3.3 kilobases in size and contains three exons interrupted by two introns of approximately 1050 and 650 base pairs, respectively. Exon 1 encodes the 5'-untranslated region of the mRNA, exon 2 the putative signal sequence and the initial portion of propeptide, and exon 3 encodes the remainder of the propeptide, which contains six copies of the TRH sequence in contrast to five copies in the rat preproTRH gene. The predicted human preproTRH peptide structure has 242 amino acids compared to 255 amino acids in the rat. Homology with rat preproTRH is 73.3% and 59.5% at the nucleic acid and amino acid levels, respectively. Intron-exon splicing sites and 5' and 3' mRNA borders were confirmed rigorously by sequencing a human preproTRH cDNA using the polymerase chain reaction and human hypothalamic cDNA.

Defective retinoic acid regulation of the Pit-1 gene enhancer: a novel mechanism of combined pituitary hormone deficiency.

Pit-1 is a pituitary-specific transcription factor responsible for pituitary development and hormone expression in mammals. Pit-1 contains two protein domains, termed POU-specific and POU-homeo, which are both necessary for DNA binding and activation of the GH and PRL genes and regulation of the PRL, TSH-beta subunit (TSH-beta), and Pit-1 genes. Pit-1 is also necessary for retinoic acid induction of its own gene during development through a Pit-1-dependent enhancer. Combined pituitary hormone deficiency is caused by defective transactivation of target genes in the anterior pituitary. In the present report, we provide in vivo evidence that retinoic acid induction of the Pit-1 gene can be impaired by a Pit-1 gene mutation, suggesting a new molecular mechanism for combined pituitary hormone deficiency in man.

A novel mechanism for cyclic adenosine 3',5'-monophosphate regulation of gene expression by CREB-binding protein.

The pituitary-specific transcription factor, Pit-1, is necessary to mediate protein kinase A (PKA) regulation of the GH, PRL, and TSH-beta subunit genes in the pituitary. Since these target genes lack classical cAMP DNA response elements (CREs), the mechanism of this regulation was previously unknown. We show that CREB binding protein (CBP), through two cysteine-histidine rich domains (C/H1 and C/H3), specifically and constitutively interacts with Pit-1 in pituitary cells. Pit-1 and CBP synergistically activate the PRL gene after PKA stimulation in a mechanism requiring both an intact Pit-1 amino-terminal and DNA-binding domain. A CBP construct containing the C/H3 domain [amino acids (aa) 1678-2441], but not one lacking the C/H3 domain (aa 1891-2441), is sufficient to mediate this response. Neither construct augments PKA regulation of CRE-containing promoters. Fusion of either CBP fragment to the GAL4 DNA-binding domain transferred complete PKA regulation to a heterologous promoter. These findings provide a mechanism for CREB-independent regulation of gene expression by cAMP.

Combined pituitary hormone deficiency due to the F135C human Pit-1 (pituitary-specific factor 1) gene mutation: functional and structural correlates.

The pituitary-specific transcription factor Pit-1 (pituitary-specific factor 1) is known to play a key role in the differentiation of PRL-, GH-, and TSH-secreting cells, and in the regulation of expression of the corresponding genes. In recent years, 12 distinct mutations of the Pit-1 gene have been shown to be responsible for a phenotype of multiple congenital pituitary hormone deficiency involving PRL, GH, and TSH. We had previously identified, in four siblings with GH, PRL, and TSH deficiencies, a mutation (F135C) resulting in a single amino acid change within the POU-specific binding domain of the Pit-1 molecule. In the present report, we have explored the functional effect of the F135C mutation. In vitro activity tests performed by transfection in human HeLa cells showed decreased transactivation capacity on the PRL, GH, and Pit-1 genes. The DNA binding experiments performed by gel shift showed that the F135C mutation generated a protein capable of binding to DNA response elements. To analyze how the F135C mutation might affect functionality of the transcription factor despite a normal DNA binding, we used a structure modelization approach and also analyzed two other Pit-1 mutant proteins (F135A and F135Y). The loss of functionality in these two mutants was similar to that of F135C. This finding was in keeping with our molecular modeling studies. According to structural data derived from the crystallographic analysis of the DNA/Pit-1 POU domain complex, the conformation of the first helix of the F135C-mutated POU-specific domain could be perturbed to such an extent that any interaction with other transcription cofactors might be definitively prevented.

Cloning of the human thyrotropin beta-subunit gene and transient expression of biologically active human thyrotropin after gene transfection.

A 17 kilobase pair fragment of DNA containing the human TSH (hTSH) beta-subunit gene was isolated from a human leukocyte genomic library. Using a 621 base pair human CG alpha-subunit cDNA and a 2.0 kilobase pair genomic fragment of hTSH beta containing both coding exons, we constructed hCG alpha and hTSH beta expression vectors containing either the early promoter of simian virus 40 or the promoters of adeno-associated virus. Cotransfection of two adeno-associated virus vectors, each containing one subunit of hTSH, together with a plasmid containing the adenovirus VA RNA genes produced hTSH as well as free human alpha- and TSH beta-subunits in an adenovirus transformed human embryonal kidney cell line (293). The levels of protein expression in this system were 10- to 100-fold greater than that found in a simian virus transformed monkey kidney cell line (COS) using vectors containing the early promoter of simian virus 40. The hTSH synthesized in 293 cells was glycosylated as indicated by complete binding to concanavalin A-Sepharose but was larger in apparent molecular weight than a standard hTSH preparation on gel chromatography suggesting an altered glycosylation pattern. However, it was immunologically and biologically indistinguishable from two pituitary hTSH standards in an immunoradiometric and in vitro iodide trapping assay, respectively.

Leptin levels in children with central precocious puberty.

Several studies have suggested that sufficient serum leptin levels may be involved in the initiation of puberty. To assess further the relationship between leptin and the onset of puberty in humans, we measured the serum leptin concentration in children with central precocious puberty (CPP). We studied 65 children with either idiopathic (IPP; n = 50 girls and 3 boys) or neurogenic central precocious puberty (NPP; n = 5 girls and 7 boys). The serum leptin levels in these patients were compared with normative data from healthy children and adolescents using SD scores that adjust for body mass index (BMI) and Tanner stage. The mean SD scores of IPP and NPP girls were +0.4 +/- 0.1 and +1.0 +/- 0.5, respectively, compared with that of age-matched prepubertal girls and +0.7 +/- 0.2 and +1.6 +/- 0.6 compared with that of girls matched for pubertal stage. The CPP girls with lower BMIs contributed larger SD scores, such that the leptin SD score was negatively correlated with BMI. A similar, modest increase in leptin levels in the CPP girls was evident when additional normative data were considered. The mean leptin SD scores of IPP and NPP boys were -0.9 +/- 0.5 and +0.7 +/- 0.3, respectively, compared with that of normal boys at Tanner stage 3-4. Serum leptin levels in the boys with CPP were not different from those in healthy boys in any of the normative studies. These data should be interpreted cautiously, but they suggest that girls with CPP have modestly elevated serum leptin concentrations compared with those in healthy children and adolescents. In addition, the negative correlation between the leptin SD score and BMI suggests that sufficient leptin levels may be associated with initiation of puberty in girls.

The impact of reversible gonadal sex steroid suppression on serum leptin concentrations in children with central precocious puberty.

Serum leptin concentrations increase during childhood in both sexes. During sexual maturation, levels rise further in girls, but decrease in boys. These data suggest that testosterone either directly suppresses leptin levels or induces changes in body composition that result in lower leptin concentrations. To examine further the relationship between sex steroids and leptin, we performed a longitudinal study in children with central precocious puberty (28 girls and 12 boys) before, during, and after discontinuation of GnRH agonist-induced pituitary-gonadal suppression. Nighttime and daytime leptin levels were measured to determine whether the activity of the pituitary-gonadal axis affects their diurnal variation. In the boys, suppression of testosterone increased leptin levels, whereas resumption of puberty was associated with decreased leptin levels [3.5 +/- 0.8 vs. 9.5 +/- 3.1 ng/dL (P = 0.005) and 12.2 +/- 4.5 vs. 7.0 +/- 2.6 ng/dL (P = 0.012), respectively]. Serum leptin levels did not change in the girls with alteration of the pituitary-ovarian axis and consistently exceeded those in boys. Nighttime levels were consistently greater than daytime values by an average of 38.3% in the girls and 29.4% in the boys. These serial observations during reversible pituitary-gonadal suppression suggest that testosterone decreases leptin concentrations, but that estrogen, at least in this childhood model, has no discernible effect. In addition, our data indicate that the presence of the diurnal rhythm in leptin concentrations is independent of the state of the reproductive axis.

Analysis of gonadotropin-releasing hormone gene structure in families with familial central precocious puberty and idiopathic hypogonadotropic hypogonadism.

We examined the GnRH gene structure in a family with familial central precocious puberty (eight members, four affected) and a family with idiopathic hypogonadotropic hypogonadism (eight members, three affected) using Southern blot analysis and sequencing of cloned polymerase chain reaction products. Genomic DNA samples were digested with restriction enzymes and hybridized to the human placental GnRH cDNA probe. BamHI digests revealed 6.5- and 2.7-kilobase (kb) bands; BglII, 6.0- and 4.0-kb bands; Ncol, 8.0- and 3.5-kb bands; Pstl, 4.2-kb, 2.8-kb, 1.3-kb and 950-basepair bands; XbaI, 6.5- and 5.0-kb bands. These sizes were the same as those found by this analysis in normal individuals. All family members with familial central precocious puberty or idiopathic hypogonadotropic hypogonadism showed the same size bands, except for one unaffected member of the family with idiopathic hypogonadotropic hypogonadism who had an additional band at 5.5 kb after digestion with NcoI, which is thought to be a rare polymorphism. Sequencing of exon 2 of the GnRH gene from these families, including the exon-intron borders, revealed a polymorphism in the signal sequence of GnRH that predicts an amino acid change from tryptophan (nucleotide sequence: TGG) to serine (TCG) at the -8 position of the GnRH preprohormone. Although this polymorphism did not cosegregate with the clinical disorder in either family, this novel polymorphism may prove useful in the evaluation of linkage to the GnRH gene in other families with pubertal disorders. No other nucleotide sequence abnormality was found in 1.2 kb of the 5' flanking region or the four exons and their splice sites.