The effects of aging on the secretion of the common alpha-subunit of the glycoprotein hormones in men.

To investigate the effects of aging on the secretion of the common alpha-subunit of the glycoprotein hormones, we measured basal levels of luteinizing hormone (LH), testosterone (T) and alpha-subunit in 176 normal men aged 19 to 89 years. In addition, in two groups of young (less than 65 years; n = 25) and old (greater than 65 years; n = 15) subjects, the effects of luteinizing hormone-releasing hormone (LHRH) on LH and alpha-subunit secretion were determined. Age-related increases in serum alpha-subunit and LH were noted only in the oldest men while T levels decreased progressively with advancing age. LHRH stimulation resulted in significantly greater secretion of alpha-subunit in the old subjects while no difference in LH release between young and old men was observed. Moreover, there was a delay to peak LH and alpha-subunit levels after LHRH in the old subjects. These data suggest that the aging process in males involves deficits in both testicular and gonadotroph functions as demonstrated by (1) the relative hypogonadotropic hypogonadism seen until the ninth decade; (2) the hypergonadotropic hypogonadism apparent in men greater than 80 years; (3) the delay in the timing of peak responses of LH and alpha-subunit after LHRH administration; and (4) the disproportionate increase in the secretion of alpha subunit relative to intact LH.     

Administration of low dose pulsatile gonadotropin-releasing hormone (GnRH) to GnRH-deficient men regulates free alpha-subunit secretion

Although pharmacological doses of GnRH and TRH stimulate free alpha-subunit (alpha-subunit) secretion from the pituitary, little is known about the pattern and control of alpha-subunit release under physiological circumstances. Euthyroid men with idiopathic hypogonadotropic hypogonadism, a condition of deficient GnRH release, provide a unique opportunity to study alpha-subunit secretion before and during administration of a physiological regimen of GnRH administration. Before GnRH therapy, six euthyroid IHH men with normal endogenous TSH secretion had circulating alpha-subunit levels close to or below assay detection limits, with a mean level less than 0.5 ng/ml. During 12-42 weeks of physiological GnRH replacement, serum alpha-subunit concentrations rose to a mean value of 2.07 +/- 0.3 (+/- SEM) ng/ml (P less than 0.01). After GnRH administration, alpha-subunit was released in a pulsatile pattern following each dose of GnRH and mirrored the secretory pattern of LH. Increases in serum alpha-subunit concentrations during GnRH administration were closely correlated with increases in LH (r = 0.91; P less than 0.01), but not FSH (r = 0.24; P = NS), levels. In addition, a situation in which LH secretion was clearly predominant and FSH levels were barely detectable was created by increasing the frequency of GnRH administration to every 30 min. In this circumstance, free alpha-subunit concentrations increased in conjunction with LH levels in the face of decreased FSH levels. We conclude that replacement of GnRH regulates both the level and pattern of alpha-subunit secretion in GnRH-deficient men, and that there is tight correlation of alpha-subunit with LH, but not with FSH, secretion.     

Usefulness of the free alpha-subunit to diagnose hypogonadotropic hypogonadism

OBJECTIVE: Differentiating constitutional delay of growth and puberty from hypogonadotropic hypogonadism is still a problem in clinical practice. Our previous study demonstrated that the peak/basal ratio of the free alpha-subunit of the glycoprotein hormones is higher in normal prepubertal boys than in male adults with hypogonadotropic hypogonadism. The objective of this study was to assess the performance of this ratio in normal male patients at different ages and levels of pubertal development, and in patients with hypogonadotropic hypogonadism, both isolated and combined with other pituitary hormone deficiencies. DESIGN: Cohort study. PATIENTS: Twenty-eight normal prepubertal males between 6 and 8 years; 20 normal prepubertal males between 9 and 13 years; 18 males with constitutional delay of growth and puberty; 26 normal pubertal males; 13 adult men with isolated hypogonadotropic hypogonadism; 21 adult men with complete hypogonadotropic hypogonadism combined with other hormone deficiencies; and 11 adult men with partial hypogonadotropic hypogonadism combined with other hormone deficiencies. MEASUREMENTS: Serum levels of free alpha-subunit immediately before (basal), and 30 and 60 min after 100 micro g intravenous GnRH were measured by immunofluorimetry. Median and P25-P75 range of the peak/basal ratio of the free alpha-subunit was determined for each group. A receiver operating characteristics curve was calculated. Results were compared using the Kruskal-Wallis test. RESULTS: The peak/basal ratio of the free alpha-subunit was higher in patients with constitutional delay of growth and puberty (7.46) than in those with isolated hypogonadotropic hypogonadism (2.73), complete combined hypogonadotropic hypogonadism (1.58), and partial combined hypogonadotropic hypogonadism (2.61; P < 0.001). A peak/basal ratio < 3.26 identified hypogonadotropic hypogonadism with 93.2% sensitivity and 94.4% specificity when compared to constitutional delay of growth and puberty. There was no statistical difference between the peak/basal ratio of prepubertal patients between 6 and 8 years (7.20), patients between 8 and 13 years (8.71), normal pubertal males (8.10) and those with constitutional delay of growth and puberty (7.46). In a group of boys with delayed puberty, a cut-off point of 3.69 defined hypogonadotropic hypogonadism with 95.6% sensitivity and 94.4% specificity. A cut-off point of 4.81 gave 100% sensitivity (88.9% specificity), and 3.09 gave 100% specificity (86.7% sensitivity). CONCLUSIONS: The peak/basal ratio of the free alpha-subunit can be used for the differential diagnosis of constitutional delay of growth and puberty and hypogonadotropic hypogonadism, irrespective of age. This distinction allows early investigation and treatment of patients with hypogonadotropic hypogonadism and reassurance for those with constitutional delay of growth and puberty.     

Stimulation of serum inhibin concentrations by gonadotropin-releasing hormone in men with idiopathic hypogonadotropic hypogonadism

Inhibin is a gonadal hormone thought to be important in FSH regulation. We investigated the effects of the hypogonadotropic state and subsequent GnRH-induced increases in gonadotropin levels on inhibin secretion. Serum levels of inhibin, LH, FSH, and testosterone (T) as well as sperm concentrations were measured in 5 men with idiopathic hypogonadotropic hypogonadism (IHH) before (baseline) and during 8 weeks of GnRH therapy (5 micrograms, sc, every 2 h). Baseline and peak inhibin levels were compared to those in a group of 19 normal men. Before GnRH administration, the mean serum inhibin level was significantly lower in the IHH men than in the normal men [166 +/- 56 (+/- SE) vs. 588 +/- 30 U/L; P less than 0.001]. Serum inhibin levels rose after 1 week of GnRH therapy (P less than 0.05) and remained higher than the baseline level thereafter. The mean peak inhibin level during GnRH administration was lower than the mean value in normal men (485 +/- 166 vs. 588 +/- 30 U/L; P less than 0.05). Serum LH and FSH levels rose promptly to the midnormal range or slightly above it. Serum T levels did not significantly increase until 4-5 weeks of GnRH administration and remained in the low normal range. All IHH men were azoospermic throughout the study. These data are consistent with the hypothesis that inhibin is produced by the testis under gonadotropin control. They also suggest the possibility of defective Sertoli and Leydig cell function in men with IHH, since the men's serum inhibin and T levels did not rise to the same extent as did their normalized serum gonadotropin levels during GnRH administration.     

Pituitary glycoprotein hormone alpha-subunit secretion after thyrotropin-releasing hormone stimulation in normal men and men with idiopathic hypogonadotropic hypogonadism.

Although TRH stimulates the release of uncombined alpha-subunit into the circulation in patients with primary hypothyroidism, it is not clear whether alpha-subunit is released from the thyrotrophs in euthyroid subjects. We hypothesized that spontaneous fluctuations in circulating alpha-subunit released from gonadotrophs by GnRH in normal adults could obscure the detection of small changes in alpha-subunit after TRH administration. We, therefore, examined alpha-subunit responses to TRH in five euthyroid men with idiopathic hypogonadotropic hypogonadism (IHH), who produce little or no GnRH, five normal men, and four postmenopausal women. Mean (+/- SEM) basal serum alpha-subunit levels were significantly (P less than 0.05) less in men with IHH (0.26 +/- 0.07 microgram/L) than in the normal men (0.80 +/- 0.20 microgram/L) or postmenopausal women (3.54 +/- 0.60 microgram/L). alpha-Subunit levels rose after TRH administration in all men with IHH to a peak level of 0.86 +/- 0.25 ng/ml; TSH levels also increased from 1.9 +/- 0.4 to 13.0 +/- 5.6 mU/L. The increment in TSH and alpha-subunit levels was highly positively correlated (r = 0.96). alpha-Subunit levels also increased 2-fold in normal men given TRH, whereas alpha-subunit levels in postmenopausal women were unchanged. We conclude that thyrotrophs release alpha-subunit into the circulation in normal men and euthyroid men with IHH. Thus, both thyrotrophs and gonadotrophs appear to contribute to circulating alpha-subunit in men with IHH; however, most of the uncombined alpha-subunit in normal men appears to be from gonadotrophs.     

The response of free alpha-subunit of glycoprotein hormones to LH-RH administration (author's transl)

The responses of immunoreactive free alpha-subunit of glycoprotein hormones to LH-RH administration were studied in normal men and women, and in patients with hypergonadotropic hypogonadism, hypogonadotropic hypogonadism, trophoblastic disease and isolated ectopic alpha-subunit producing tumor. In patients with hypergonadotropic hypergonadism, basal levels of serum alpha-subunit were elevated and the responses to LH-RH were also excessive compared to those of normal men and women. Conversely, in hypogonadotropic hypogonadism, basal levels of alpha-subunit were significantly low and its response to LH-RH was barely detectable. The response of alpha-subunit to constant intravenous infusion of LH-RH (1 microgram/kg/h) was studied in 4 normal men. Both LH and alpha-subunit revealed biphasic patterns of elevation. Its releasing pattern suggests the possibility that two pools of gonadotropin are involved in the production and secretion of alpha-subunit. In patients with trophoblastic disease secreting low levels of hCG (18 mIU/ml), the responses of alpha-subunit as well as pituitary gonadotropin to LH-RH were normal. However, in cases of high concentrations of hCG (1000 mIU/ml), the responses of alpha-subunit and gonadotropin were suppressed. After the administration of LH-RH to a patient with an isolated ectopic alpha-subunit producing tumor, the serum concentration of pituitary gonadotropin increased within the normal range, although that of alpha-subunit did not show a significant change. These results suggest that the production of alpha-subunit by tumors may be autonomous in contrast with a regulatory production in the pituitary.     

Long-term administration of gonadotropin-releasing hormone in men with idiopathic hypogonadotropic hypogonadism. A model for studies of the hormone's physiologic effects

The effect of long-term administration of gonadotropin-releasing hormone (GnRH) for induction and maintenance of sexual maturation was characterized in 23 men with idiopathic hypogonadotropic hypogonadism. Twenty-two men achieved normal adult male serum testosterone concentrations (575 +/- 33 ng/dL; p less than 0.0001 compared with the baseline mean of 61 +/- 6 ng/dL) that were sustained in 21 men for up to 36 months with bolus doses of GnRH varying from 25 to 300 ng/kg body weight administered every 2 hours. Pulsatile luteinizing hormone (LH) secretion occurred in all 23 men, with mean levels of LH (14.7 +/- 1.3 mlU/mL) and follicle-stimulating hormone (11.3 +/- 1.3 mlU/mL) within or above the normal range for adult men. Mature sperm were observed in the ejaculates of 20 men, with counts ranging from less than 1 X 10(6) to 96 X 10(6)/mL. Increasing responsiveness of the pituitary-gonadal axis to GnRH was shown in 6 men. Men with idiopathic hypogonadotropic hypogonadism present a useful model to study the onset and maintenance of reproductive function in men.     

Maintenance of spermatogenesis in hypogonadotropic hypogonadal men with human chorionic gonadotropin alone

OBJECTIVE: It is generally accepted that both gonadotropins LH and FSH are necessary for initiation and maintenance of spermatogenesis. We investigated the relative importance of FSH for the maintenance of spermatogenesis in hypogonadotropic men. SUBJECTS AND METHODS: 13 patients with gonadotropin deficiency due to idiopathic hypogonadotropic hypogonadism (IHH), Kallmann syndrome or pituitary insufficiency were analyzed retrospectively. They had been treated with gonadotropin-releasing hormone (GnRH) (n=1) or human chorionic gonadotropin/human menopausal gonadotropin (hCG/hMG) (n=12) for induction of spermatogenesis. After successful induction of spermatogenesis they were treated with hCG alone for maintenance of secondary sex characteristics and in order to check whether sperm production could be maintained by hCG alone. Serum LH, FSH and testosterone levels, semen parameters and testicular Volume were determined every three to six Months. RESULTS: After spermatogenesis had been successfully induced by treatment with GnRH or hCG/hMG, hCG treatment alone continued for 3-24 Months. After 12 Months under hCG alone, sperm counts decreased gradually but remained present in all patients except one who became azoospermic. Testicular Volume decreased only slightly and reached 87% of the Volume achieved with hCG/hMG. During treatment with hCG alone, FSH and LH levels were suppressed to below the detection limit of the assay. CONCLUSION: Once spermatogenesis is induced in patients with secondary hypogonadism by GnRH or hCG/hMG treatment, it can be maintained in most of the patients qualitatively by hCG alone, in the absence of FSH, for extended periods. However, the decreasing sperm counts indicate that FSH is essential for maintenance of quantitatively normal spermatogenesis.     

Gonadotropin and alpha-subunit responses to chronic gonadotropin-releasing hormone analog administration in patients with glycoprotein hormone-secreting pituitary tumors

Pituitary tumors secreting intact glycoprotein hormones (LH, FSH, and TSH) and/or alpha-subunit are being increasingly recognized. Because chronic administration of GnRH analogs decreases gonadotropin secretion in normal subjects, we investigated gonadotropin and alpha-subunit responses to chronic GnRH analog administration in five men with glycoprotein hormone-secreting pituitary tumors. Two patients (patients A and B) received the GnRH agonist analog (D-Trp6-Pro9-NEt-LHRH) for 4 weeks as a daily sc dose (8 micrograms/kg.day). In both, secretion of LH and/or alpha-subunit increased markedly. Subsequently, three patients received a higher analog dose (32 micrograms/kg.day) for a longer duration (8 weeks). One patient with a LH- and FSH-secreting tumor (patient C) had a highly significant (P less than 0.001) fall in serum LH and FSH concentrations; however, alpha-subunit secretion increased. During a subsequent study, when this patient received a lower dose (8 micrograms/kg.day) for 8 weeks, gonadotropin suppression also occurred. In two additional patients who received this dose (32 micrograms/kg.day), it had a persistent agonist effect on FSH beta (patient D) and alpha-subunit secretion (patient E). A marked increase in alpha-subunit secretion occurred in all five patients, regardless of whether basal serum alpha-subunit concentrations were elevated. These patients received the GnRH analog at doses 2-8 times greater than those that suppress gonadotropin secretion in normal men. Serum LH and FSH concentrations decreased in only one patient with a gonadotropin-secreting adenoma. The serum LH and FSH responses to acute GnRH stimulation did not predict the gonadotropin responses to chronic GnRH analog administration. Thus, gonadotropin and alpha-subunit production by most pituitary adenomas is augmented during chronic GnRH analog administration, consistent with defective GnRH desensitization in the adenomatous tissue. Despite the heterogeneous gonadotropin responses to the GnRH analog in these patients, serum alpha-subunit levels increased in all patients, indicating dissociation in the secretion of intact gonadotropins and alpha-subunit.     

A case of latent Addison's disease with hypogonadotropic hypogonadism and dwarfism]

A case of latent Addison's disease accompanied by hypogonadotropic hypogonadism and dwarfism is described. A 20-year-old man was admitted to our department complaining of short stature and immature development of the external genitalia. Pigmentation was most evident on the fingers and face. Endocrinologically, serum ACTH level was very high, and serum cortisol level was in the lower limit of the normal range. Serum aldosterone and adrenal androgen levels were below their normal ranges. Based on these clinical and laboratory findings, the patient was diagnosed as having latent Addison's disease. Serum LH did not respond to a bolus injection of LH-RH. However, after 3 days administration of LH-RH, the response of serum LH to a bolus injection of LH-RH was enhanced. Serum testosterone level was not increased after the administration of hCG. These findings suggested a hypothalamic cause for the hypogonadism. It was indicated that short stature was apparently caused by GH neurosecretory dysfunction, since nocturnal GH secretion was below that in normal males and the response of GH to the administration of arginine was normal. In regard to the thyroid function, the peak of serum TSH after a bolus injection of TRH was delayed compared with normal subjects, and although serum T4 level was high, the basal metabolic rate was very low. This suggests that there is tissue resistance to the elevated thyroid hormone.     

Secretion of glycoprotein hormone alpha-subunit by pituitary tumors

Serum glycoprotein hormone alpha-subunit levels were determined in 165 patients with pituitary adenomas. Elevated serum alpha-subunit levels were found in 17 patients (acromegaly, 5 of 58; prolactinoma, 6 of 56; nonfunctioning adenoma, 5 of 32; and ACTH-producing adenoma, 1 of 19), most of whom had normal serum TSH and gonadotropin levels. When TRH (0.5 mg) was injected iv in the 6 prolactinoma patients with elevated serum alpha-subunit levels, serum PRL and alpha-subunit levels increased in only 1 patient. Four acromegalic patients with high serum alpha-subunit levels received TRH; serum GH and alpha-subunit increased in 1 patient and did not change in 2, and only serum GH increased in the remaining patient. Oral administration of bromocriptine (5 mg), on the other hand, consistently decreased serum alpha-subunit and PRL levels in 2 patients with prolactinoma and alpha-subunit and GH levels in 1 acromegalic patient. When serum from 3 patients was subjected to Sephadex G-100 gel filtration, immunoreactive alpha-subunit eluted in a single peak, which emerged in fractions corresponding to [125I]TSH alpha. Concanavalin A (Con A) affinity chromatography revealed that the major portion of immunoreactive alpha-subunit was retained to Con A. A pituitary adenoma removed at surgery from a patient with acromegaly was studied in monolayer cell culture. Secretion of both alpha-subunit and GH from cultured adenoma cells was stimulated by TRH and suppressed by dopamine in a dose-dependent manner. Immunohistochemistry of the pituitary adenomas removed from patients with prolactinoma and acromegaly who had high serum alpha-subunit levels demonstrated alpha-subunit-containing cells as well as PRL- or GH-containing cells. These results suggest that elaboration of glycoprotein hormone alpha-subunit occurs without concurrent production of glycoprotein hormones in a substantial number of patients with pituitary adenomas and that alpha-subunit responses to stimuli in such adenomas are generally parallel with those of the concomitantly produced hormones.     

Pulsatile gonadotropin secretion after discontinuation of long term gonadotropin-releasing hormone (GnRH) administration in a subset of GnRH-deficient men

Normal pituitary and gonadal function can be maintained with long term pulsatile GnRH administration in men with idiopathic hypogonadotropic hypogonadism (IHH), and both pituitary and gonadal priming occur during the process of GnRH-induced sexual maturation. Still, the long term effects of discontinuing GnRH therapy in IHH men have not been examined. Therefore, we evaluated the patterns of gonadotropin and alpha-subunit secretion before and after a prolonged period of pulsatile GnRH administration in 10 IHH men. Before exogenous GnRH stimulation, no patient had any detectable LH pulsations. In 6 of these men, who were typical of most of our IHH patients (group I), no LH pulsations were detectable after cessation of GnRH administration. However, in the other 4 men (group II), LH pulsations were easily detectable despite cessation of exogenous GnRH stimulation, and the amplitude (9.3 +/- 3.5 IU/L) and frequency (13.8 +/- 1.7 pulses/day) of these LH pulses were similar to those in 20 normal men (10.6 +/- 0.7 IU/L and 11.0 +/- 0.7 pulses/day). Three of these 4 men in group II maintained normal serum testosterone levels after discontinuation of GnRH delivery. To determine if there were any characteristics that might be useful in predicting which IHH men could maintain normal pituitary-gonadal function after long term GnRH administration, we evaluated various clinical and hormonal parameters at the time of initial presentation. Mean alpha-subunit levels (P less than 0.01) and alpha-subunit pulse amplitude (P less than 0.02) were significantly higher in the group II than the group I men, suggesting that the group II patients had partial, rather than complete, deficiency of endogenous GnRH secretion. None of the other parameters that were assessed distinguished the two groups. We conclude that gonadotropin and sex steroid levels return to their pretreatment state in the majority of IHH men when long term GnRH administration is discontinued. Normal pituitary-gonadal function can be maintained after discontinuation of long term GnRH administration in a rare subset of IHH men who present with higher levels of alpha-subunit. We hypothesize that these latter IHH men have an incomplete GnRH deficiency and that long term exogenous GnRH administration induces pituitary and gonadal priming, which subsequently enables them to sustain normal pituitary and gonadal function in response to their own enfeebled GnRH secretion.     

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.     

The effects of synthetic alpha-subunit peptides on thyrotropin interaction with its receptor

Synthetic peptides of the alpha-subunit of human glycoprotein hormones have been shown previously to inhibit binding of [125I]iodo-hCG to ovarian membranes, thus indicating the importance of the alpha-subunit in the structure-function relationships of the gonadotropic hormone. These same synthetic alpha-subunit peptides, the sequences of which are common to all human glycoprotein hormones, were found to inhibit the binding of [125I]iodo-TSH to human thyroid membrane preparations and FRTL-5 rat thyroid cells. The active portions of the subunit were represented in synthetic peptides alpha 21-35, alpha 31-45, alpha 26-46, and alpha 81-92, indicating that 2 separate sites within the alpha-subunit have binding activity for TSH. Peptides alpha 26-46 and alpha 31-45 were also found to potently inhibit the stimulation of adenylate cyclase activity by bovine TSH in TSH bioassay using FRTL-5 cells. Seven other synthetic peptides, including the remainder of the 92-amino acid sequence of the alpha-subunit, demonstrated little or no ability to inhibit binding of the tracer or inhibit the bioactivity of intact TSH. The findings were very similar to those of previous studies involving hCG binding, except that the two active sites appeared to be somewhat shifted towards the COOH-terminal end of the subunit. These studies support the concept of the importance of the alpha-subunit in receptor binding of all glycoprotein hormones and demonstrate the utility of the overlapping synthetic peptide strategy in investigations of protein structure-function relationships.     

The antigenic structure of the human glycoprotein hormone alpha-subunit. I. Characterization of anti-alpha monoclonal antibodies.

The glycoprotein hormones CG, LH, FSH, and TSH are composed of two noncovalently linked subunits, alpha and beta. The beta-subunit confers hormone specificity, while the alpha-subunit is homologous within a species. To help in determining the antigenic structure of the common alpha-subunit, six monoclonal antibodies (mAbs) to the free or heterodimeric alpha-subunit of human (h) gonadotropic hormones have been prepared and, along with two previously isolated mAbs, have been characterized for binding specificity to alpha- and beta-subunits and the human glycoprotein hormones, CG, LH, FSH, and TSH. Each mAb was derived from hybidomas of FO myeloma cells fused with spleen cells from mice immunized with free alpha-subunit, hCG or hFSH. mAbs A101, A102, and E512 were specific for the alpha-subunit but showed the highest affinity for the intact hormone; K2.18, K94.6, E501, E502, and E511 were specific for free alpha. All of the antibodies inhibited binding of 125I-hCG to luteal membrane receptor, and 125I-labeled mAbs did not recognize hCG/receptor complex. Characterization by two-site binding assays using alpha, hCG, or hFSH as antigen revealed that all the mAbs bind to unique sites on alpha which may be overlapping, and which are modified in the intact hormone. The antigenic sites for mAbs E502, E511, and K2.18 are at least partially linear because they bind to reduced, carboxymethylated alpha.     

Effects of dopamine and somatostatin on pulsatile pituitary glycoprotein secretion.

The hypothalamic factors dopamine (DA) and somatostatin (SRIH) inhibit pituitary glycoprotein secretion, but little is known regarding the effects of these factors on glycoprotein pulses. To address this question, 12 healthy volunteers underwent frequent blood sampling over 12 h at baseline and during 12-h infusions of DA and/or SRIH. TSH, LH, FSH, and alpha-subunit (alpha) levels were measured in all samples, and hormone pulses were located by Cluster analysis. Both DA and SRIH suppressed TSH pulse amplitude by 70%, while SRIH decreased TSH pulse frequency as well. Both infusions decreased LH pulse amplitude by 30-35%, but had no effect on pulse frequency. In contrast, neither infusion significantly altered FSH pulse parameters, although mean FSH levels declined 15%. DA had no effect on pulsatile alpha secretion, while SRIH decreased alpha pulse frequency. Serum thyroid hormone levels declined during both infusions, but there were no major changes in serum sex steroid levels. Thus, the hypothalamic inhibitory factors DA and SRIH had divergent effects on glycoprotein hormone pulses. The major effects on pulse amplitude, rather than frequency, imply that these factors do not play major roles in the generation of glycoprotein pulses, although SRIH may directly affect the TSH and alpha pulse generators.     

Conformation of the alpha-subunit of glycoprotein hormones: a study using polyclonal and monoclonal antibodies.

The conformation of the common alpha-subunit of human glycoprotein hormones, luteinizing hormone (hLH), follicle-stimulating hormone (hFSH), thyroid-stimulating hormone (hTSH) and chorionic gonadotropin (hCG) was probed using a highly specific polyclonal antiserum against the alpha-subunit of hCG and several monoclonal antibodies (MAbs) produced against hCG which recognized the alpha-subunit in free and combined form. The alpha-subunit was found to be conformationally altered (compared to its conformation in the isolated state) when it was in combination with various beta-subunits as indicated by shifts in the displacement curves of binding of [125I]hCG alpha to the polyclonal antiserum. The extent of the change was dependent on the beta-subunit present with minimum change being observed with hLH beta, intermediate with hCG beta and maximum change with hFSH and TSH beta-subunits. However, the affinity constants of this antiserum for all four hormones were nearly similar. Further, it was also found that binding of any one of the glycoprotein hormones to this antibody could be completely inhibited by any other hormone suggesting that the conformation of the alpha-subunit in all the four hormones is probably very similar. This was further investigated using five hCG MAbs capable of recognizing the alpha-subunit, but with different epitope specificities. All these MAbs could recognize all the four hormones suggesting the presence of the epitopes in these proteins. These epitopes were conformation specific since the MAbs did not bind reduced and carboxymethylated alpha-subunit. Displacement analysis using [125I]hCG as the tracer showed that two epitopes have nearly the same conformation in all the four hormones, while two were partially modified depending on the beta-subunit present. Based on these results, it is concluded that the alpha-subunit of glycoprotein hormones has nearly the same conformation, though subtle differences do exist.     

THERAPY OF PRIMARY HYPOTHYROIDISM WITH L-TRIIODOTHYRONINE: DISCORDANT CARDIAC AND PITUITARY RESPONSES

Cardiac systolic time intervals were studied in ten patients with primary hypo-thyroidism before and during therapy with increasing doses of oral L-triiodo-thyronine (L-T3). Therapy was increased sequentially from 10, 20, 25 to 50 μg of L-T3 daily on a monthly basis. On L-T3, 20 to 25 μg/day, cardiac systolic time intervals and other peripheral responses to thyroid hormone including serum cholesterol concentration, serum creatine phosphokinase (CPK) activity, and basal metabolic rate had normalized. However, serum thyrotrophin (TSH) levels and peak TSH responses to thyrotrophin-releasing hormone (TRH) remained elevated on these doses of L-T3. As the dose of L-T3 was increased from 20 to 50 μg/day, mean basal serum TSH levels decreased from 55 to 16 μu/ml, and the peak TSH response to TRH decreased from 243 to 58 μu/ml ( P < 0.001) while systolic time intervals did not decrease further. Changing to L-thyroxine (L-T4) therapy at this point resulted in further suppression of TSH secretion, without significantly altering systolic time intervals or the other peripheral responses to thyroid hormone. These data suggest (a) that some biological responses to thyroid hormone were normalized on lower doses of L-T3 than were required to normalize TSH secretion, and (b) that higher doses of L-T3 or substituting L-T4 therapy could suppress TSH secretion further without altering the other peripheral responses to thyroid hormone.     

Synthetic alpha-subunit peptides stimulate testosterone production in vitro by rat Leydig cells.

The glycoprotein hormones (LH, hCG, FSH, and TSH) have a common 92-amino acid alpha-subunit which is noncovalently linked to a hormone-specific beta-subunit. Synthetic peptides of the alpha-subunit have been shown to inhibit binding of [125I]iodo-hCG to rat ovarian membrane and [125I]iodo-TSH to human thyroid membrane preparations. Synthetic overlapping peptides of the alpha-subunit of hCG were prepared by solid phase techniques and tested in a standard in vitro rat Leydig cell bioassay. Three regions in the alpha-subunit (alpha 1-15, alpha 30-45, and alpha 71-85) were found to stimulate testosterone production. All three regions correlate with inhibition of hCG binding to ovarian receptors, but subtle differences exist between the binding sites and effector sites. These data indicate that the glycoprotein alpha-subunit has intrinsic bioactivity.     

Endocrine and immunohistochemical studies on thyrotropin (TSH)-secreting pituitary adenomas: responses of TSH, alpha-subunit, and growth hormone to hypothalamic releasing hormones and their distribution in adenoma cells.

Endocrine and immunohistochemical studies were performed in two cases of TSH-secreting pituitary adenomas. The patients had elevated serum TSH and alpha-subunit concentrations despite high serum thyroid hormone levels. In addition, one patient (no. 1) had elevated serum GH levels with clinical evidence of acromegaly. GH-releasing hormone infusion increased serum levels of TSH, alpha-subunit and GH in the two patients. TRH injection increased serum TSH levels in both patients and, concomitantly, serum alpha-subunit and GH levels in patient 1. Basal TSH levels and their responses to TRH changed reciprocally to changes in serum thyroid hormone levels, although TRH-induced GH release did not. The administration of GnRH also increased serum TSH, alpha-subunit, and GH levels in patient 1. In accordance with these in vivo results, pituitary adenoma cells in culture obtained from patient 1 responded to GH-releasing hormone, TRH, or GnRH to secrete TSH, alpha-subunit, and GH. Incubation of cells with dexamethasone resulted in inhibition of TSH and stimulation of GH secretion without a significant change in alpha-subunit secretion. On the basis of light microscopic and electron microscopic double gold immunohistochemistry, the tumor from patient 1 was a bimorphous adenoma composed of two separate cell types: cells with TSH beta-subunit (TSH beta) and alpha-subunit, and those with GH and alpha-subunit. The remainder consisted mainly of cells with TSH beta and alpha-subunit. The coproduction of the unusual combination of two hormones such as GH and alpha-subunit in a single-type of adenoma cell and the coexistence of thyrotrophs and somatotrophs in one pituitary adenoma along with the aberrant responses of TSH beta, alpha-subunit, and GH to multiple hypothalamic hormones suggest the dedifferentiation of pituitary cells to multipotential progenitor cells by neoplastic transformation.