Combined hypothalamic-pituitary-gonadal defect in a hypogonadic man with a novel mutation in the DAX-1 gene.

We have studied a 20-yr-old male patient with adrenal hypoplasia congenita and hypogonadotropic hypogonadism (HH) due to a C to A transversion at nucleotide 825 in the DAX-1 gene, resulting in a stop codon at position 197. The same mutation was detected in his affected first cousin (adrenal hypoplasia congenita and HH) and in a heterozygous state in their carrier mothers. The patient had had acute adrenal insufficiency at the age of 2 yr and 6 months, bilateral cryptorchidism corrected surgically at the age of 12 yr, and failure of spontaneous puberty. Plasma testostereone (T) was undetectable (<0.30 nmol/L), gonadotropin levels were low (LH, <0.4 IU/L; FSH, 1.5 IU/L) and not stimulated after i.v. injection of 100 microg GnRH. The endogenous LH secretory pattern was apulsatile, whereas free alpha-subunit (FAS) levels depicted erratic pulses, suggesting an incomplete deficiency of hypothalamic GnRH secretion. During i.v. pulsatile GnRH administration (10 microg/pulse every 90 min for 40 h), each GnRH pulse induced a LH response of low amplitude (0.54 +/- 0.05 UI/L), whereas mean LH (0.45 +/- 0.01 IU/L) and FAS (63 +/- 8 mU/L) levels remained low. Amplitude of LH peaks (0.83 +/- 0.09 IU/L), mean LH (0.53 +/- 0.02 IU/L), and FAS (161 +/- 18 mU/L) levels increased (P < 0.01), whereas the T concentration remained low (0.75 nmol/L) when the pulsatile GnRH regimen was raised to 20 microg/pulse for a 40-h period, suggesting a partial pituitary resistance to GnRH. Thereafter, plasma T levels remained in prepubertal value after three daily im injections of 5000 IU hCG (3.6 nmol/L) and after 1-yr treatment with weekly i.m. injections of 1500 IU hCG (1.2 nmol/L), implying Leydig cell resistance to hCG. The patient had a growth spurt, bone maturation, progression of genital and pubic hair stages, and normalization of plasma T level (15.8 nmol/L) after a 12-month treatment with twice weekly injections of hCG and human menopausal gonadotropin (75 IU International Reference Preparation 2) preparations, suggesting that, in presence of FSH, a Sertoli cell-secreted factor stimulated Leydig cell production of T. In conclusion, we report a novel mutation in the DAX-1 gene in patients with AHC and HH. Our results suggest that the hypogonadism is due to a combined hypothalamic-pituitary-gonadal defect and imply that the DAX-1 gene may play a critical role in human testicular function.     

The same molecular defects of the gonadotropin-releasing hormone receptor determine a variable degree of hypogonadism in affected kindred

Detailed endocrinological studies were performed in the three affected kindred of a family carrying mutations of the GnRH receptor gene. All three were compound heterozygotes carrying on one allele the Arg262Gln mutation and on the other allele two mutations (Gln106Arg and Ser217Arg). When expressed in heterologous cells, both Gln106Arg and Ser217Arg mutations altered hormone binding, whereas the Arg262Gln mutation altered activation of phospholipase C. The propositus, a 30-yr-old man, displayed complete idiopathic hypogonadotropic hypogonadism with extremely low plasma levels of gonadotropins, absence of pulsatility of endogenous LH and alpha-subunit, absence of response to GnRH and GnRH agonist (triptorelin), and absence of effect of pulsatile administration of GnRH. The two sisters, 24 and 18 yr old, of the propositus displayed, on the contrary, only partial idiopathic hypogonadotropic hypogonadism. They both had primary amenorrhea, and the younger sister displayed retarded bone maturation and uterus development, but both sisters had normal breast development. Gonadotropin concentrations were normal or low, but in both cases were restored to normal levels by a single injection of GnRH. In the two sisters, there were no spontaneous pulses of LH, but pulsatile administration of GnRH provoked a pulsatile secretion of LH in the younger sister. The same mutations of the GnRH receptor gene may thus determine different degrees of alteration of gonadotropin function in affected kindred of the same family.     

Two novel DAX1 gene mutations in Chinese patients with X-linked adrenal hypoplasia congenita: clinical, hormonal and genetic analysis

Mutations in the DAX1 gene result in X-linked congenital adrenal hypoplasia (AHC). Affected boys usually present with primary adrenal failure in early infancy or childhood and hypogonadotropic hypogonadism (HH) at puberty. This paper describes the clinical, hormonal, radiological, and genetic characteristics of 2 Chinese patients with X-linked AHC. Primary adrenal insufficiency occurred in the 2 patients during their childhood and HH was recognized at puberty. Genomic DNA was extracted from their peripheral blood leukocytes and coding sequence abnormalities of the DAX1 gene were assessed by PCR and direct sequencing analysis. Genetic analysis of the DAX1 gene revealed 2 novel mutations c.572-575 dupGGGC, p.Thr193Gly,fs,205X and c.773- 774 dupCC, p.Ser259Pro,fs,264X in exon 1, causing frameshifts and yeilding premature stop codons at 205 and 264, respectively. This study identifies 2 novel mutations in the DAX1 gene which can further expand the mutation database and benefit patients in the diagnosis and treatment of AHC.     

Resistance of hypogonadic patients with mutated GnRH receptor genes to pulsatile GnRH administration

We have studied a kindred with three siblings with isolated hypogonadotropic hypogonadism caused by compound heterozygote mutations in the GnRH receptor gene. The disorder was transmitted as an autosomal recessive trait. The R262Q mutation in intracellular loop 3 of the receptor was associated with a mutation in the third transmembrane domain of the receptor, A129D, that has never been described before. This A129D mutation results in a complete loss of function, indicated by the lack of inositol triphosphate (TP3) 3 production by transfected Chinese hamster ovary (CHO) cells after GnRH stimulation. The two brothers had microphallus and bilateral cryptorchidism and were referred for lack of puberty, whereas their sister had primary amenorrhea and a complete lack of puberty. Their basal gonadotropin concentrations were below the reference range, and their endogenous LH secretory patterns were abnormal, with a low-normal frequency of small pulses or no apparent LH pulse. Pulsatile GnRH administration (10 microg/pulse every 90 min for 40 h) resulted in increased mean LH without any significant changes in testosterone levels in the two brothers, whereas the LH secretory profile of their sister remained apulsatile. Larger pulses of exogenous GnRH (20 microg every 90 min for 24 h) caused the sister to produce recognizable low amplitude LH pulses. The concentrations of free alpha-subunit significantly increased in all patients during the pulsatile GnRH administration. Thus, these hypogonadal patients are partially resistant to pulsatile GnRH administration, suggesting that they should be treated with gonadotropins to induce spermatogenesis or ovulation rather than with pulsatile GnRH.     

Successful use of pulsatile gonadotropin-releasing hormone (GnRH) for ovulation induction and pregnancy in a patient with GnRH receptor mutations

GnRH receptor mutations have recently been identified in a small number of familial cases of nonanosmic hypogonadotropic hypogonadism. In the present report we studied a kindred in which two sisters with primary amenorrhea were affected with GnRH deficiency due to a compound heterozygote mutation (Gln(106)Arg, Arg(262)Gln) and performed extensive phenotyping studies. Baseline patterns of gonadotropin secretion and gonadotropin responsiveness to exogenous pulsatile GnRH were examined in the proband. Low amplitude pulses of both LH and free alpha-subunit (FAS) were detected during 24 h of every 10 min blood sampling. The proband then received exogenous pulsatile GnRH i.v. for ovulation induction, and daily blood samples for gonadotropins and sex steroids were monitored. At the conventional GnRH replacement dose for women with hypogonadotropic hypogonadism (75 ng/kg), no follicular development occurred. At a GnRH dose of 100 ng/kg, the level and pattern of gonadotropin secretion more closely mimicked the follicular phase of normal women; a single dominant follicle was recruited, and an endogenous LH surge was elicited. However, the luteal phase was inadequate, as assessed by progesterone levels. At a GnRH dose of 250 ng/kg, the gonadotropin and sex steroid dynamics reproduced those of normal ovulatory women in both the follicular and luteal phases, and the proband conceived. The FAS responses to both conventional and high dose GnRH were within the normal range. The following conclusions were made: 1) Increased doses of GnRH may be used effectively for ovulation induction in some patients with GnRH receptor mutations. 2) Higher doses of GnRH are required for normal luteal phase dynamics than for normal follicular phase function. 3) Hypersecretion of FAS in response to exogenous GnRH, which is a feature of congenital hypogonadotropic hypogonadism, was not seen in this patient with a GnRH receptor mutation.     

Hormonal responses in pubertal males to pulsatile gonadotropin releasing hormone (GnRH) administration

Twenty-two boys (9 with delayed puberty and 13 with short stature) ages 12.3 - 17.8 yr, and 10 adult males with idiopathic hypogonadotropic hypogonadism (ages 17.3 - 41.1 yr) have been studied following pulsatile, sc GnRH therapy (240 ng/kg/pulse) over 6 days. Mean pre- and post-therapy LH and FSH concentrations were estimated by 15 min blood sampling over 3-h periods immediately before and at the end of the treatment period. There were significant correlations between the mean pre- and posttreatment LH and FSH concentrations (r = 0.82, p less than 0.001 and r = 0.51, p less than 0.02, respectively) for the 2 groups of peripubertal boys when assessed together. Nine of the 10 adults with hypogonadism showed proportionately greater gonadotropin increments following pulsatile therapy when compared with the peripubertal boys. Standard bolus GnRH tests (100 micrograms iv) did not differentiate between the three groups of patients before pulsatile GnRH therapy. Bolus GnRH tests could predict the subsequent response to pulsatile therapy in the peripubertal boys only. There was no significant change in LH increments following the GnRH bolus tests in either group, after pulsatile GnRH administration (p greater than 0.1). Early response to pulsatile GnRH administration is dependent upon the maturity of the hypothalamic-pituitary-testicular axis in males with delayed puberty or short stature. Patients with hypogonadotropic hypogonadism do not show this relationship.     

DAX1 and X-linked adrenal hypoplasia congenita: clinical and molecular analysis in five patients

OBJECTIVE: Mutations in the gene coding for the orphan nuclear receptor DAX1 cause X-linked adrenal hypoplasia congenita (AHC). Affected boys usually present with primary adrenal failure in early infancy or childhood. Impaired sexual development due to hypogonadotropic hypogonadism becomes manifest at the time of puberty. Moreover, evidence from Dax1 knockout mice and a limited number of patients with AHC, suggests that mutations in DAX1 may directly cause abnormalities in spermatogenesis. The aim of this study was to characterize clinically and genetically five patients with AHC. DESIGN: DNA sequencing analysis, endocrine testing, testicular ultrasound and semen analysis with 1-year follow-up after gonadotropin treatment. METHODS: We report on five men with classic AHC manifestations. Genomic DNA was extracted from patients' peripheral blood leukocytes and the coding region, splice sites, and promoter (-240 bp) region of DAX1 were directly sequenced. RESULTS: Three known and two novel mutations were detected in the DAX1 coding sequence in these patients. Semen analysis was performed in four of the five patients and showed azoospermia. Twelve-month treatment with gonadotropins did not restore fertility in these patients. All patients showed a normal testicular Doppler ultrasound, in contrast with that observed in Dax1-deficient mice, which display abnormalities in the rete testis. CONCLUSIONS: These cases further expand the number of DAX1 mutations reported in the literature, as well as our clinical knowledge of this rare disease.     

Pulsatile gonadotropin-releasing hormone treatment in idiopathic delayed puberty

Idiopathic delayed male puberty is defined as a delay of puberty beyond the age of 16, with prepubertal testosterone levels, normal gonadotropin responses to GnRH (excluding pituitary failure), and normal androgen responses to a single hCG injection (excluding testicular Leydig cell dysfunction), in absence of serious disease. Ten boys with this condition were evaluated as to their spontaneous LH, FSH, and PRL secretory patterns during a 24-h sampling period (20-min intervals). After this all patients were treated with pulsatile infusions of GnRH (25 ng/kg . pulse every 90 min for 10 days. Two groups could be distinguished by means of their pretreatment LH secretory pattern. Five patients had nighttime pulsatile elevation of LH levels, as usually occurs in early puberty. The other five patients did not have such a pattern (prepubertal type). The GnRH treatment resulted in increased LH and testosterone levels in both groups. All patients with pretreatment nighttime pulsatile LH secretion had steady pubertal development during the post-GnRH treatment observation period, whereas the other patients did not. In conclusion, among a number of tests, including chronic pulsatile GnRH treatment for 10 days, only the nocturnal LH secretory pattern differentiated delayed puberty from permanent hypothalamic hypogonadism in boys.     

Two-year comparison of testicular responses to pulsatile gonadotropin-releasing hormone and exogenous gonadotropins from the inception of therapy in men with isolated hypogonadotropic hypogonadism

Men with the complete form of isolated hypogonadotropic hypogonadism (initial mean testes volume less than 4 mL) require 2 or more yr of exogenous gonadotropin therapy combining hCG and human menopausal gonadotropin (hMG) to achieve maximal, but subnormal, testis size and sperm output. To test whether pulsatile GnRH therapy, which more closely mimics normal hormonal stimulation, would accelerate or further augment testicular growth, hasten the onset of sperm production, and/or increase sperm output more than occurs during conventional exogenous gonadotropin therapy, we administered either hCG/hMG or GnRH from the inception of therapy to 2 comparable groups of men with complete IHH (initial testicular volume, less than 4 mL) and compared their testicular responses during the first 2 hr of therapy. Five men were treated with pulsatile GnRH in doses of 143-714 ng/kg every 2 h, sc, while 11 other men received hCG (2000 IU) and hMG (75 IU FSH and 75 IU LH) im 3 times/week. In the GnRH-treated men, the mean plasma total and free testosterone levels during therapy rose to within the normal range, but were significantly lower (P less than 0.01 and P less than 0.02, respectively) than those in the hCG/hMG-treated men. The mean plasma estradiol concentrations during therapy were within the high normal range and were similar in the two groups. The mean plasma FSH levels achieved in the GnRH-treated men were significantly (P less than 0.01) and 1.3- to 3.2-fold higher than those in the hCG/hMG-treated men. The mean testicular size achieved in the GnRH-treated men was not significantly different from that in the hCG/hMG-treated men (P = 0.08); the mean testicular volumes after 2 yr were 4.8- and 4.3-fold the pretreatment values in the GnRH and hCG/hMG groups, respectively. After 12 months of therapy, sperm production had occurred in one man in the GnRH group and in no subject in the hCG/hMG group. After 24 months, two men in the GnRH group and eight men in the hCG/hMG group produced sperm. Thus, 40% of the GnRH-treated men and 80% of the hCG/hMG-treated men (P = NS) produced sperm after 2 yr of therapy. The sperm concentrations in all men were below 5 million/mL and were comparable in the two groups (P = NS). These results suggest that pulsatile sc GnRH therapy for the first 2 yr does not accelerate or enhance testicular growth, hasten the onset of sperm production, or increase sperm output significantly compared to hCG/hMG.     

A homozygous R262Q mutation in the gonadotropin-releasing hormone receptor presenting as constitutional delay of growth and puberty with subsequent borderline oligospermia

CONTEXT: The GnRH receptor plays a central role in regulating gonadotropin synthesis and release, and several mutations in the GNRHR gene have been reported in patients with idiopathic or familial forms of isolated hypogonadotropic hypogonadism (IHH). OBJECTIVE: The objective of the study was to investigate whether partial loss-of-function mutations in the GnRH receptor might be responsible for delayed puberty phenotypes. PATIENTS: Patients included sibling pairs with delayed puberty (n = 8) or those in whom one brother had delayed puberty and another had hypogonadotropic hypogonadism (n = 3). METHODS: Methods included mutational analysis of the GNRHR gene. RESULTS: A homozygous R262Q mutation in the GnRH receptor was identified in two brothers from one family. In this kindred, the proband presented at 15 yr of age with delayed puberty. After a short course of testosterone, he seemed to be progressing through puberty appropriately and was discharged from follow-up. His younger brother was also referred with delayed puberty but showed little progress after treatment. Frequent sampling revealed detectable but apulsatile LH and FSH release. His clinical progress was consistent with IHH, and he requires ongoing testosterone replacement. CONCLUSIONS: Homozygous partial loss-of-function mutations in the GnRH receptor, such as R262Q, can present with variable phenotypes including apparent delayed puberty. Ongoing clinical vigilance might be required when patients are discharged from follow-up, especially when there is a family history of delayed puberty or IHH because oligospermia and reduced bone mineralization can occur with time.     

Differentiation of male hypogonadotropic hypogonadism and constitutional delay of puberty by pulsatile administration of gonadotropin-releasing hormone

It is not possible to differentiate reliably between male idiopathic hypothalamic hypogonadism (HH) and severe constitutional delay of puberty (CD) on the basis of a standard GnRH bolus test (GBT) or other known endocrine or clinical parameters. Therefore, we studied the response of 17 hypogonadal men, 8 with a diagnosis of HH (age, 15.5-41; bone age, 12.5-19 yr; testes, 1-4 ml) and 9 with CD (age, 14.5-20; bone age, 11-15 yr, testes, 2-10 ml) to pulsatile GnRH stimulation. Basal and peak LH and FSH levels after a single dose of GnRH greatly overlapped between the two groups. In each patient, a spontaneous nocturnal plasma profile of LH and FSH, sampled every 20 min, was followed by a pulsatile GnRH stimulation (5 micrograms iv every 90 min) via a portable minipump for 36 h. Before and after this pulsatile GnRH stimulation, a GBT (60 micrograms/m2 iv) was performed and plasma LH, FSH, testosterone, androstenedione, and dehydroepiandrosterone sulfate were measured. Pulse analysis revealed 0-5 spontaneous nocturnal LH peaks in the CD patients but only one in all of the HH patients. During the 36 h of pulsatile GnRH, mean LH and FSH levels were significantly higher (P less than 0.0001) than during the spontaneous nocturnal profile in all patients (except 1 from each group for LH). The GBT after pulsatile stimulation caused significantly higher (P less than 0.001) LH increments in CD than in HH patients, with no overlap between the two groups (range, 4.1-15.6 in CD vs. 0.8-2.4 mIU/ml in HH). Plasma testosterone rose significantly (P less than 0.01) during pulsatile GnRH from 67 to 155 ng/dl (median) in the CD men, but did not change in the HH group (21 to 22.5 ng/dl). Plasma androstenedione and dehydroepiandrosterone sulfate did not rise in either group. We conclude that, in contrast to other parameters investigated so far, the LH increment in the second GBT after 36 h of pulsatile GnRH allows clear-cut differentiation between CD and HH. These results indicate significantly lower pituitary LH reserve in patients with permanent HH after short term priming of the pituitary by pulsatile GnRH administration.     

Hypogonadotropic hypogonadism: hormonal responses to low dose pulsatile administration of gonadotropin-releasing hormone

Patients with isolated gonadotropin deficiency were studied to determine whether pulsatile low dose gonadotropin-releasing hormone (GnRH) could induce the hormonal changes seen during normal puberty. Four male and two female patients with immature responses to a standard GnRH test (2.5 micrograms/kg) were given GnRH (0.025 micrograms/kg) iv every 2 h for 5 days. FSH responses varied between the sexes, and FSH concentrations in males rose continuously to 17.2 +/- 4.7 mIU/ml on day 5. In the females, FSH peaked at 13.8 and 15.8 mIU/ml on days 3-4 and then declined. The males showed increasing and the females decreasing incremental FSH responses to GnRH. LH concentrations and incremental responses to GnRH rose throughout the study in both sexes. Plasma testosterone rose slightly in the males to 0.7 +/- 0.2 ng/ml (P < 0.05), but in females estradiol increased to follicular range concentrations of 128 and 102 pg/ml. Standard GnRh tests on day 6 revealed maturation of gonadotropin responses in all patients. After termination of pulsatile GnRH, four patients were given single low dose GnRH injections on two to seven occasions over a period of 2-32 days. Initial LH responses were 2- to 14-fold greater than those seen on day 5 of pulsatile GnRH, and decreased over the next 3 weeks. FSH responses showed less initial augmentation and declined more slowly. Low dose pulsatile administration of GnRH to patients with isolated gonadotropin deficiency results in changing patterns of hormone secretion similar to those seen during puberty. Exaggerated pituitary sensitivity to GnRH may be present long after a brief period of GnRH stimulation, and may indicate previous rather than current secretion of GnRH.     

Identification of a novel missense mutation that is as damaging to DAX-1 repressor function as a nonsense mutation

Mutations in the DAX-1 (NROB1) gene result in X-linked congenital adrenal hypoplasia (AHC) and hypogonadotropic hypogonadism. The clinical presentation is usually as adrenal insufficiency in early life, with hypogonadotropic hypogonadism detected at the time of expected puberty. In this study we identified mutations in the DAX-1 gene of two patients with AHC. One mutation, Y399X, resulted in a premature stop codon and was associated with loss of Leydig cell responsiveness to human chorionic gonadotropin. The second, L297P, was a missense mutation, and human chorionic gonadotropin responsiveness was maintained. Kindred analysis established that the mutations had been inherited from the proband's mothers. The L297P has not been described previously and occurs within a highly conserved binding motif (LLXLXL). Transient transfection assays demonstrated that both mutations resulted in a severe loss of DAX-1 repressor activity. Immunohistochemical analysis of testicular tissue obtained from an affected sibling of the subject with the Y399X mutation, who had died with adrenal failure as a neonate, showed normal testicular morphology and expression of DAX-1, steroidogenic factor-1, and anti-Mullerian hormone protein. These data extend the clinical and molecular information on DAX-1 mutations, confirm normal testicular development at the neonatal stage, and illustrate variability in Leydig cell function.     

Novel DAX1 mutations in X-linked adrenal hypoplasia congenita and hypogonadotrophic hypogonadism

OBJECTIVE: Mutations of the DAX1 gene (Dosage-sensitive sex reversal-Adrenal hypoplasia congenita critical region on the X chromosome gene 1), which encodes a novel orphan nuclear receptor, have been identified in patients with X-linked adrenal hypoplasia congenita (AHC) and hypogonadotrophic hypogonadism (HHG). We have investigated two kindreds with AHC and HHG for DAX1 mutations. METHODS: Two kindreds with five affected males, four carrier females and four unaffected males were investigated. The gonadotrophin deficiency in three of the boys was observed to be partial until mid-puberty. DAX1 mutations in the entire 1413 bp coding region were sought by DNA sequence analysis. RESULTS: Two DAX1 mutations, situated within exon 1, were detected. These consisted of an insertional mutation at codon 183 that led to a frameshift and a premature Stop at codon 184, and a missense mutation Leu278Pro that involved a highly conserved leucine residue within the proposed ligand binding domain. Co-segregation of these mutations with the disease in each family, and their absence from 107 alleles in 73 (39 males and 34 females) unrelated control individuals, was demonstrated by allele specific oligonucleotide hybridization (ASO) analysis for the insertional mutation, and by Ban I restriction endonuclease analysis for the missense mutation. CONCLUSIONS: Two novel DAX1 mutations have been detected in two families with adrenal hypoplasia and hypogonadotrophic hypogonadism. The finding of partial gonadotrophin deficiency in the affected males from these families is notable and an early recognition of such a possibility in a patient, which may be facilitated by DAX1 mutational analysis, may help to prevent the sequelae of delayed androgen replacement therapy.     

Alpha-subunit secretion in men with idiopathic hypogonadotropic hypogonadism

We studied the regulation of glycoprotein hormone alpha-subunit secretion in four men with idiopathic hypogonadotropic hypogonadism due to presumed GnRH deficiency. Immunoreactive alpha-subunit was present at low but usually detectable levels in blood samples drawn at 10- to 20-min intervals for 12-24 h; however, no characteristic pattern of pulsatile alpha-subunit secretion was found. Serum from each man was examined by gel filtration chromatography. Each sample tested contained an immunoreactive alpha-subunit peak with a slightly lower elution volume than [125I]hCG alpha, as we had previously found in serum from normal men. To determine if this peak represented TSH alpha, two men were treated with 0.3 mg L-T4 daily for 7-14 days. Serum TSH levels decreased to less than 1.5 mU/L, and neither TSH nor alpha-subunit levels increased after the iv administration of 500 micrograms TRH. An alpha-subunit peak that eluted before [125I]hCG alpha was again found in the serum of T4-treated men. We conclude that glycoprotein hormone alpha-subunit is present in the serum of men with idiopathic hypogonadotropic hypogonadism in whom TSH secretion is completely suppressed by L-T4. The gonadotrophs represent the most likely source of this alpha-subunit. The finding of more normal alpha-subunit than LH secretion in these men indicates that the production of the gonadotropin subunits is differentially regulated in man and supports the hypothesis that factors in addition to GnRH regulate alpha-subunit gene expression.     

The importance of signal pattern in the transmission of endocrine information: pituitary gonadotropin responses to continuous and pulsatile gonadotropin-releasing hormone

We tested the hypothesis that pulsatile GnRH stimulation of the pituitary is required for normal gonadotropin secretion in humans. We administered GnRH in pulsatile and continuous regimens in varying order to each of five women with hypothalamic amenorrhea and presumed endogenous GnRH deficiency. Mean serum levels of GnRH were similar during the pulsatile and continuous regimens. All women ovulated during the pulsatile regimen (progesterone, greater than 31.8 nmol/L (10 ng/mL); none ovulated during the continuous regimen. Compared to pretreatment levels, FSH and estradiol, as measured by RIA, and LH, as measured by bioassay, increased significantly during the pulsatile GnRH regimen, but not during the continuous regimen. However, LH and alpha-subunit, as measured by RIA, increased significantly during both continuous and pulsatile GnRH administration. We conclude that a pulsatile pattern of GnRH is essential to normal functioning of the human female reproductive axis. Continuous administration of GnRH, producing mean serum levels of the peptide indistinguishable from those found during pulsatile administration, stimulates some rise in a nonbioactive form of radioimmunoassayable LH-like material and alpha-subunit, but does not stimulate bioactive LH, FSH, estradiol, or progesterone and does not lead to ovulation.     

What is the optimal therapy for young males with hypogonadotropic hypogonadism?

Hypogonadotropic hypogonadism (HH), consequent to congenital or acquired disorders of the hypothalamic–pituitary axis, presents as absent/delayed/arrested sexual maturation and infertility. Optimal management includes: (a) confirmation of the diagnosis and prognosis, (b) timing and choice of therapeutic intervention and (c) consideration of future fertility prospects. Therapy is usually initiated with testosterone to induce development of secondary sexual characteristics, taking the patient (often diagnosed late) through puberty. Monitoring of the impact of the condition on long‐term health and psychosocial function is necessary. Treatment is likely to be life‐long, requiring regular monitoring for its optimization and avoidance of adverse responses. Induction of spermatogenesis requires either pulsatile gonadotropin releasing hormone (GnRH) or gonadotropin administration. Gonadotropins can be self‐administered subcutaneously and are not inferior to the more costly GnRH. ‘Reversible genetic hypogonadotropic hypogonadism’ is a recently described entity which has implications for the long‐term management of patients with HH.