Growth hormone,insulin, and prolactin secretion in anorexia nervosa and obesity during bromocriptine treatment.

We studied secretion of growth hormone (GH), insulin, and prolactin in eight women with anorexia nervosa and nine women with refractory obesity before and during treatment with bromocriptine, 10 mg/day. In the anorexic patients the raised plasma GH concentrations occurring during an oral glucose tolerance test fell significantly while on bromocriptine treatment, but there was no change in plasma insulin or blood glucose concentrations. In the obese patients, however, plasma GH concentrations remained low during the oral glucose tolerance test, and were not modified by bromocriptine. Blood glucose and plasma insulin concentrations were also unchanged. Plasma GH and plasma 11-hydroxycorticosteroid responses to insulin-induced hypoglycaemia were unaffected. Serum prolactin concentrations which were raised in five anorexic patients and marginally raised in two obese subjects, fell significantly in both groups during treatment. We observed no consistent weight changes in either groups.     

Bromocriptine treatment of acromegaly.

The effects of oral bromocriptine in acromegaly have been studied. A dose of 5 mg six-hourly suppressed circulating growth hormone (GH) levels in nine out of 11 patients treated for seven to 11 weeks. This was associated with considerable clinical improvement in all patients, with abolition of excessive sweating, reduction in soft-tissue thichening, loosening of rings, decrease in shoe size, improvement in facial features, and loosening of dentures. Metabolic changes included improvement in glucose tolerance and reduction in hydroxyproline excretion. Unlike the actions of growth hormone release inhibiting hormone the suppression of GH was not accompanied by a reduction in insulin or glucagon secretion, though prolactin levels were suppressed. Side effects other than mild constipation were not seen when the full dose regimen was reached by slowly increasing the dose from 2-5 mg once daily. Bromocriptine holds promise as a safe and orally effective medical treatment to augment surgical or radiotherapeutic measures directed at the pituitary tumour. Its efficacy during longterm administration remains to be established.     

Lysosomal enzymes in the rat harderian gland are altered by either bromocriptine treatment or hypophysectomy and hormone replacement therapy

Four groups of adult male hypophysectomized rats were injected subcutaneously twice daily between 0800-0900 hr and 1600-1700 hr with either saline diluent, 150 micrograms sheep prolactin and/or growth hormone (GH); intact rats received either saline or 150 micrograms bromocriptine twice daily. After 4 days of treatment, lysosomal enzyme assays revealed significant elevations in both acid phosphatase and alpha-mannosidase enzyme activities in the Harderian glands of saline-injected hypophysectomized rats compared to those in intact controls. beta-Glucuronidase levels were depressed and hexosaminidase activity unaffected by hypophysectomy treatment alone compared to intact controls. Lysosomal enzyme activities in hypophysectomized animals treated with prolactin were not different from the hypophysectomized control animals. However, treatment with GH alone or in combination with prolactin had a significant inhibitory effect on beta-glucuronidase, hexosaminidase, and alpha-mannosidase enzyme activities in the Harderian gland of hypophysectomized animals. Bromocriptine treatment in intact rats only elevated acid phosphatase activity. In summary, the patterns of responses did not reveal a role for prolactin in the control of Harderian gland lysosomal enzyme activities by the pituitary. However, some of the influence on this target system may be exerted by growth hormone.     

Association of the antidiabetic effects of bromocriptine with a shift in the daily rhythm of monoamine metabolism within the suprachiasmatic nuclei of the Syrian hamster

Bromocriptine, a dopamine D2 agonist, inhibits seasonal fattening and improves seasonal insulin resistance in Syrian hamsters. Alterations in daily rhythms of neuroendocrine activities are involved in the regulation of seasonal metabolic changes. Changes in circadian neuroendocrine activities that regulate metabolism are believed to be modulated by central circadian oscillators within the hypothalamic suprachiasmatic nuclei (SCN) of seasonal animals. We examined the association of metabolic responses to bromocriptine with its effects on the daily rhythms of metabolic hormones and daily monoamine profiles within the SCN, a primary circadian pacemaker known to regulate metabolism, in Syrian hamsters. Obese glucose-intolerant male Syrian hamsters (body weight [BW] 185 +/- 10 g) held on 14h daily photoperiods were treated at light onset with bromocriptine (800 microg/animal/day, ip) or vehicle for 2 weeks. Animals were then subjected to a glucose tolerance test (GTT) (3 g/kg BW, ip). Different subsets of animals (n = 6) from each treatment group were sacrificed at 0h/24h, 5h, 10h, 15h, or 20h after light onset for analyses of SCN monoamines, plasma insulin, prolactin, cortisol, thyroxin (T4), triiodothyronine (T3), glucose, and free fatty acids (FFAs). Compared with control values, bromocriptine treatment significantly reduced weight gain (14.9 vs. -2.9 g, p < .01) and the areas under the GTT glucose and insulin curves by 29% and 48%, respectively (p < .05). Basal plasma insulin concentration was markedly reduced throughout the day in bromocriptine-treated animals without influencing plasma glucose levels. Bromocriptine reduced the daily peak in FFA by 26% during the late light span (p < .05). Bromocriptine significantly shifted the daily plasma cortisol peak from the early dark to the light period of the day, reduced the plasma prolactin (mean 1.8 vs. 39.4 ng/dL) and T4 throughout the day (mean 1.6 vs. 3.8 microg/dL), and selectively reduced T3 during the dark period of the day (p < .01). Concurrently, bromocriptine treatment significantly reduced SCN dopamine turnover during the light period and shifted daily peaks of SCN serotonin and 5-hydroxy-indoleacetic acid (5-HIAA) content by 12h from the light to the dark period of the day (p < .05). This was confirmed by a further in vivo microdialysis study in which bromocriptine increased SCN extracellular 5-HIAA of glucose-intolerant hamsters during the dark phase (47% increase, p < .05) toward levels observed in normal glucose-tolerant hamsters. Thus, bromocriptine-induced resetting of daily patterns of SCN neurotransmitter metabolism is associated with the effects of bromocriptine on attenuation of the obese insulin-resistant and glucose-intolerant condition. A large body of corroborating evidence suggests that such bromocriptine-induced changes in SCN monoamine metabolism may be functional in its effects on metabolism.     

Effect of glucagon on growth hormone secretion in rats

Gentled rats injected subcutaneously with glucagon (20 microgram/100 g body weight) showed a significant decrease in plasma growth hormone (GH) at 15 min after glucagon injection. A subcutaneous injection of 50% glucose did not cause the early suppression as shown at 15 min after glucagon injection, but at 30 min after glucose injection a tendency to decrease in plasma GH was observed. In urethane anesthetized rats, a subcutaneous administration of glucagon (1 microgram or 10 microgram/100 g body weight) failed to elicit an increase in plasma GH. In vitro incubation of anterior pituitary fragments with glucagon failed to decrease the release of GH, suggesting that glucagon does not act directly on the anterior pituitary.     

Influence of chronic thyroxine treatment on plasma hormone and metabolite concentrations and on responses to insulin, glucagon and thyrotrophin releasing hormone in adult sheep

Four adult sheep fed twice daily were given daily subcutaneous injections of saline for four weeks, followed by a similar period of daily L-thyroxine (T4) injection (1 mg/day). T4 treatment increased basal plasma concentrations of T4, triiodothyronine (T3), insulin and glucose, together with T3-uptake and the free thyroxine index, while cholesterol and urea concentrations decreased. T4 treatment reduced the rise in prolactin levels after the morning meal. Thyrotrophin releasing hormone (TRH) injection increased plasma T3 only in the control period and T3-uptake only in the T4 treatment period. T4 treatment did not affect the prolactin response to TRH injection or the insulin and glucose responses to glucagon injection. The increase in insulin concentrations after insulin injection and the secondary hyperglycaemia following initial insulin-induced hypoglycaemia were reduced by T4 treatment.     

Bioactivity of plasma prolactin in ovariectomized, diethylstilbestrol-treated Long-Evans and Holtzman rats after thyrotropin-releasing hormone or bromocriptine administration

The objective of this study was to determine the effects of thyrotropin-releasing hormone (TRH) and bromocriptine on plasma levels of biologically active prolactin in ovariectomized, diethylstilbestrol (DES)-treated rats. Female Long-Evans and Holtzman rats were ovariectomized and each was given a subcutaneous implant of diethylstilbestrol (DES). One week later, groups of DES-treated rats were fitted with indwelling intra-atrial catheters, and 2 days later blood samples were withdrawn before and at 1, 2, 5, 10, and 20 min after intravenous administration of TRH (250, 500, or 1000 ng/rat). Blood samples were obtained from other groups at 4 weeks of DES treatment by orbital sinus puncture under ether anesthesia before and at 30, 60, and 120 min after bromocriptine administration (2.5 mg/rat sc). Plasma was assayed for prolactin by conventional radioimmunoassay (RIA) and by Nb2 lymphoma bioassay (BA). Holtzman rats released significantly more prolactin following TRH than did Long-Evans rats when the RIA was used to measure prolactin. However, when the BA was used to assay prolactin in the same samples, the Long-Evans rats released more prolactin than did the Holtzman rats. In addition, the ratio of the BA to RIA values was significantly increased in both strains following TRH, but the greatest increase was observed in the Long-Evans rats, in which the ratio was 4.5 at the peak of the TRH-induced rise in plasma prolactin. Gel filtration chromatography of plasma obtained at 5 min after TRH treatment in Long-Evans rats revealed large molecular forms of prolactin with BA to RIA ratios of 4-5. In addition, monomeric prolactin had a BA to RIA ratio of 2. Bromocriptine treatment reduced prolactin levels in both strains, but the effect was more rapid in Holtzman than in Long-Evans rats. In addition, bromocriptine treatment of Holtzman, but not Long-Evans, rats significantly reduced the BA to RIA ratio of plasma prolactin. The results indicate that TRH and bromocriptine affect the release of biologically active prolactin to a greater extent than prolactin detected by antibody in the RIA, and that Long-Evans and Holtzman rats respond to these secretagogues differently with regard to BA to RIA comparisons.     

Fetal and maternal endocrine responses to exercise in the pregnant ewe

Maternal and fetal concentrations of plasma insulin, pancreatic glucagon, growth hormone (GH), corticosteroids and enteroglucagon, and of blood glucose and lactate, were measured in well-fed, late pregnant ewes before, during and after walking on a treadmill at 0.7 m.s-1, 10 degrees slope for 60 min. Exercise caused rapid and substantial increases in maternal concentrations of glucose, lactate, pancreatic glucagon and corticosteroids, smaller but significant decreases in levels of GH and enteroglucagon, and no change in insulin. With the exception of GH, concentrations of these maternal hormones had returned to pre-exercise levels within 20 min of stopping exercise. The exercise-induced maternal hyperglycaemia was associated with a proportionately similar, rapid increase in fetal blood glucose; fetal blood lactate and plasma corticosteroids also increased, but at slower rates and other fetal hormone concentrations were unchanged. During recovery there was a rapid increase in fetal insulin levels. The results are discussed in terms of the regulation of exercise-induced changes in maternal energy metabolism, and fetal metabolic and hormonal sensitivity to these changes.     

Effect of neonatal hypoxia on leptin, insulin, growth hormone and body composition in the rat.

The purpose of the present study was to evaluate the effect of exposure to hypoxia from birth to 7 days of age on leptin, insulin, growth hormone (GH), insulin-like growth factor-1 (IGF-1), glucose, corticosterone, body weight, and body composition in rats studied at 7 days of age and then after return to normoxia. Hypoxia for the first 7 days of life resulted in a significant decrease in plasma leptin, body weight, and an increase in corticosterone and insulin with no change in plasma glucose, GH or IGF-1. There was no significant effect of hypoxia on % lean body mass, but a small but significant increase in % body fat. Bone mineral density (BMD) was lower in 7-day-old hypoxic rats as compared to normoxic controls. All hormonal variables and BMD had normalized by 7 days after return to normoxia. However, body weight remained lower even 5 weeks after return to normoxia. We conclude that leptin is decreased during neonatal hypoxia despite no change in adiposity. Furthermore, insulin is increased probably to overcome the effects of increased counterregulatory hormones (such as corticosterone).     

Growth hormone and prolactin actions on osmoregulation and energy metabolism of gilthead sea bream (Sparus auratus)

The gilthead sea bream (Sparus auratus) is an euryhaline fish where prolactin (PRL) and growth hormone (GH) play a role in the adaptation to different environmental salinities. To find out the role of these pituitary hormones in osmoregulation and energy metabolism, fish were implanted with slow release implants of ovine GH (oGH, 5 microg g(-1) body mass) or ovine prolactin (oPRL, 5 microg g(-1) body mass), and sampled 7 days after the start of the treatment. GH increased branchial Na(+),K(+)-ATPase activity and decreased sodium levels in line with its predicted hypoosmoregulatory action. GH had metabolic effects as indicated by lowered plasma protein and lactate levels, while glucose, triglycerides and plasma cortisol levels were not affected. Also, GH changed liver glucose and lipid metabolism, stimulated branchial and renal glucose metabolism and glycolytic activity, and enhanced glycogenolysis in brain. PRL induced hypernatremia. Furthermore, this hormone decreased liver lipid oxidation potential, and increased glucose availability in kidney and brain. Both hormones have opposite osmoregulatory effects and different metabolic effects. These metabolic changes may support a role for both hormones in the control of energy metabolism in fish that could be related to the metabolic changes occurring during osmotic acclimation.     

ASSOCIATION OF THE ANTIDIABETIC EFFECTS OF BROMOCRIPTINE WITH A SHIFT IN THE DAILY RHYTHM OF MONOAMINE METABOLISM WITHIN THE SUPRACHIASMATIC NUCLEI OF THE SYRIAN HAMSTER

Bromocriptine, a dopamine D₂ agonist, inhibits seasonal fattening and improves seasonal insulin resistance in Syrian hamsters. Alterations in daily rhythms of neuroendocrine activities are involved in the regulation of seasonal metabolic changes. Changes in circadian neuroendocrine activities that regulate metabolism are believed to be modulated by central circadian oscillators within the hypothalamic suprachiasmatic nuclei (SCN) of seasonal animals. We examined the association of metabolic responses to bromocriptine with its effects on the daily rhythms of metabolic hormones and daily monoamine profiles within the SCN, a primary circadian pacemaker known to regulate metabolism, in Syrian hamsters. Obese glucose-intolerant male Syrian hamsters (body weight [BW] 185 ± 10 g) held on 14h daily photoperiods were treated at light onset with bromocriptine (800 μg/animal/day, ip) or vehicle for 2 weeks. Animals were then subjected to a glucose tolerance test (GTT) (3 g/kg BW, ip). Different subsets of animals (n = 6) from each treatment group were sacrificed at 0h/24h, 5h, 10h, 15h, or 20h after light onset for analyses of SCN monoamines, plasma insulin, prolactin, cortisol, thyroxin (T₄), triiodothyronine (T₃), glucose, and free fatty acids (FFAs). Compared with control values, bromocriptine treatment significantly reduced weight gain (14.9 vs. ?2.9 g, p <. 01) and the areas under the GTT glucose and insulin curves by 29% and 48%, respectively (p <. 05). Basal plasma insulin concentration was markedly reduced throughout the day in bromocriptine-treated animals without influencing plasma glucose levels. Bromocriptine reduced the daily peak in FFA by 26% during the late light span(p <. 05). Bromocriptine significantly shifted the daily plasma cortisol peak from the early dark to the light period of the day, reduced the plasma prolactin (mean 1.8 vs. 39.4 ng/dL) and T₄ throughout the day (mean 1.6 vs. 3.8 μg/dL), and selectively reduced T₃ during the dark period of the day (p <. 01). Concurrently, bromocriptine treatment significantly reduced SCN dopamine turnover during the light period and shifted daily peaks of SCN serotonin and 5-hydroxy-indoleacetic acid (5-HIAA) content by 12h from the light to the dark period of the day (p <. 05). This was confirmed by a further in vivo microdialysis study in which bromocriptine increased SCN extracellular 5-HIAA of glucose-intolerant hamsters during the dark phase (47% increase, p <. 05) toward levels observed in normal glucose-tolerant hamsters. Thus, bromocriptine-induced resetting of daily patterns of SCN neurotransmitter metabolism is associated with the effects of bromocriptine on attenuation of the obese insulin-resistant and glucose-intolerant condition. A large body of corroborating evidence suggests that such bromocriptine-induced changes in SCN monoamine metabolism may be functional in its effects on metabolism. (Chronobiology International, 17(2), 155–172, 2000)     

Verification of NB2 lymphoma cell bioassay for the measurement of plasma and pituitary prolactin in the Mongolian gerbil (Meriones unguiculatus)

Serum and pituitary glands were taken from male Mongolian gerbils which had received bromocriptine implants, ether stress or no treatment (controls). Pituitary prolactin (Prl) and growth hormone (GH) mRNA were analyzed by Northern hybridization using rat cDNA probes. Pituitary and plasma Prl content were analyzed with the Nb2 lymphoma cell growth bioassay. These assays were sensitive to the decreases in Prl caused by bromocriptine and the elevation of Prl caused by ether stress. The inhibition of pituitary and plasma Prl levels by bromocriptine correlated with a marked inhibition of pituitary Prl mRNA content. In contrast, levels of GH mRNA did not change with treatment, indicating that gerbil GH does not contribute to the lactogenic activity measured in the Nb2 lymphoma cell bioassay. The results indicate that this bioassay is suitable for the measurement of gerbil pituitary and plasma Prl.     

Central adrenergic suppression augments the insulin and glucagon secretory, and the glycogenolytic responses in streptozotocin-diabetic rats.

It has been suggested that the increased activity of the sympathetic nervous system and the resultant increase in the tissue catecholamine levels contribute to the pathogenesis of diabetes. In this study we evaluated the effect of clonidine, a central adrenergic agonist that decreases sympathetic tone, on the serum levels of glucose, insulin, glucagon and norepinephrine and on the hepatic glycogen content in normal and streptozotocin-diabetic rats. The animals were treated with clonidine 25 micrograms/kg/day interperitoneally for 3 weeks to suppress the central adrenergic impulses. Clonidine treatment significantly increased the weight gain, but did not affect plasma glucose, insulin, glucagon and norepinephrine in the diabetic animals. Pancreatic insulin and liver glycogen contents were significantly higher in the clonidine-treated than in the untreated diabetic rats. However, clonidine did not affect pancreatic insulin and liver glycogen content of nondiabetic animals. The intravenous administration of glucagon increased plasma glucose in the clonidine-treated, but not in the saline-treated diabetic rats. Insulin-induced hypoglycemia significantly enhanced glucagon release in clonidine-treated but not in saline-treated diabetic rats. We conclude that the suppression of central adrenergic activity may ameliorate the effects of insulin insufficiency on pancreatic hormone secretion and hepatic glycogen content.     

Reductions of body fat stores and total plasma cholesterol and triglyceride concentrations in several species by bromocriptine treatment

Administrations (injections and in feed) of bromocriptine, a dopamine agonist that inhibits prolactin secretion, reduced body fat stores and plasma total cholesterol and triglyceride concentrations in several rodent species (Syrian hamsters, Djungarian hamsters, Swiss Webster mice and obese Zucker rats). Body fat indices were reduced by at least 50% in the hamsters and mice within 10-15 days of treatment and by 29% in 8 weeks in the rats. Bromocriptine reduced total plasma cholesterol concentration by 17% in Syrian hamsters, 41% in mice and 30% in rats fasted before blood sampling. In nonfasted obese rats, bromocriptine dramatically reduced both cholesterol (from 440 to 130 mg/dl) and triglyceride (from 1570 to 540 mg/dl) levels compared with controls. These findings offer further evidence for a primary role of prolactin in lipid metabolism and indicate that bromocriptine may be useful for treating obesity and lipid-based cardiovascular disorders.     

Glucagon secretion during the development of insulin-secreting tumors induced by streptozotocin and nicotinamide.

Serial oral glucose tolerance tests in rats treated with streptozotocin and nicotinamide showed that blood glucose levels after glucose loading were suppressed significantly 7 months after treatment as compared to those of earlier stages. Post-glucose plasma insulin levels were significantly elevated at the 9th to 12th month and concomitantly fasting plasma glucagon levels rose significantly. At that time pancreatic islet cell tumors were demonstrated in all of the rats in this experiment. Post-glucose plasma glucagon levels, however, did not show remarkable changes throughout the observation. In spite of hyperinsulinemia, post-glucose plasma glucagon levels of tumor-bearing rats were significantly lower than those of body weight adjusted controls. It is inferred from the study that secretory activity of pancreatic A-cells of tumor-bearing rats is restrained by excess insulin released from islet cell tumors.     

Comparative hormonal profile of two newly developed obese congenic rat strains

1. The effect of feeding diets containing either 54% sucrose or cooked corn starch for 12 weeks on levels of fasting plasma insulin, corticosterone, growth hormone and glucagon were compared in two newly developed genetically obese rat strains--the normoglycemic LA/N-cp and the diabetic SHR/N-cp. 2. In corpulent rats of either strain, levels of plasma insulin and corticosterone were greater when compared to the lean littermates. Corpulent LA/N-cp rats had lower levels of plasma glucagon and higher levels of plasma growth hormone than did lean LA/N-cp rats. 3. SHR/N-cp rats fed sucrose had greater levels of corticosterone and glucagon than did SHR/N-cp rats fed starch.     

Dietary thyrotropin-releasing hormone stimulates growth rate and increases the insulin: glucagon molar ratio of broiler chickens

The effects of thyroid manipulation on growth, feed efficiency, and plasma hormone levels were determined in rapidly growing chickens. Beginning at 3 weeks of age, eight broiler cockerels were provided with control feed (CF) or feed containing either 1 ppm of triiodothyronine (T3), 1 ppm of thyroxine (T4), 0.3% propylthiouracil (PTU), or 5 ppm of thyrotropin-releasing hormone (TRH) for 3 weeks. Blood samples were taken at 4, 5, and 6 weeks for determination of plasma levels of growth hormone, insulin-like growth factor, T3, T4, insulin, glucagon, glucose, and nonesterified fatty acids. Dietary TRH increased (P less than 0.05) the growth rate of chickens by 14% when compared with the CF group. Plasma growth hormone levels were reduced (P less than 0.05) 65% by dietary T3 and 33% by treatment with either T4 or TRH when compared with the CF group. Plasma insulin-like growth factor levels were 16% lower (P less than 0.05) in PTU-fed birds than the other treatment groups. Plasma T3 levels were elevated (P less than 0.05) 3-fold by dietary T3 and 38% by TRH whereas plasma T3 in the PTU group was 38% below the average of CF birds. Plasma T4 levels were increased (P less than 0.05) by 12-fold in T4-fed birds, decreased 48% in TRH-fed birds, and nondetectable in birds treated with either T3 or PTU. Compared with the other treatments, dietary PTU increased (P less than 0.01) plasma insulin levels 4.3-fold whereas TRH provided a 2.7-fold increase in plasma insulin. Plasma glucagon levels were 26% higher (P less than 0.05) in T3-fed birds than those fed either T4 or PTU. These observations indicate that thyroid activity plays an important role in regulating secretion of GH and the pancreatic hormones. Furthermore, our study demonstrates the potential use of TRH as an orally active growth promoter for poultry.     

The role of cortisol and growth hormone in the counter-regulation of insulin-induced hypoglycemia.

Four normal volunteers underwent a control insulin tolerance test (ITT) and an insulin tolerance test (ITT) after two days administration of the serotonin antagonist cyproheptadine (Cypro). Cypro administration resulted in an 81 +/- 11.4% (M +/- SEM) reduction in cortisol secretion and a 73 +/- 15.1% reduction in growth hormone (GH) secretion. Despite the reduction in hypoglycemia-induced cortisol and GH secretion, there was a similar decline and recovery of plasma glucose in the control ITT and the ITT after Cypro administration. Although previous studies indicate that normal basal levels of cortisol and growth hormone are needed for normla counter-regulation after insulin-induced hypoglycemia, augmented secretion of these hormones is probably not essential for this response. Hypoglycemia-induced increases in epinephrine and glucagon, secretion may contribute to the restoration of the normal plasma glucose concentration after insulin-induced hypoglycemia.     

Carbohydrate intolerance in gonadal dysgenesis: evidence for insulin resistance and hyperglucagonemia

To determine the pathogenesis of carbohydrate intolerance associated with gonadal dysgenesis, plasma glucose, insulin, glucagon, and growth hormone responses to oral glucose and intravenous tolbutamide, arginine and insulin were evaluated in 21 nonobese patients, 7-19 years old. Glucose intolerance was present in 9 of 21 nonobese patients (42.8%). Insulin levels, the area under the insulin curve after oral glucose and intravenous tolbutamide and the insulin to glucose ratio were significantly greater in patients than in controls (p less than 0.005). The decrease in plasma glucose following intravenous tolbutamide was significantly less in patients than in controls (p less than 0.05) despite insulin levels which were greater than in controls (p less than 0.05). After intravenous insulin, plasma glucose fell significantly less in patients than in controls (p less than 0.01). Plasma glucagon levels and the area under the glucagon curve after oral glucose and arginine infusion were significantly greater in patients than in controls (p less than 0.005 and p less than 0.01, respectively). The increase in glucagon after insulin-induced hypoglycemia was significantly less in patients than in controls (p less than 0.025). Fasting and stimulated growth hormone levels and the mean 24-hour growth hormone concentration were similar in patients and controls. These results indicate that glucose intolerance occurs frequently in gonadal dysgenesis and is associated with normal or increased insulin secretory responses. These abnormalities are probably due to insulin resistance and hyperglucagonemia. The decrease in insulin action does not appear to result from excessive growth hormone secretion or treatment with anabolic steroids or estrogen-progesterone medications.