Cellular processing of growth hormone in IM-9 cells: evidence for exocytosis of internalized hormone.

IM-9 cells extensively internalize [125I]human (h) GH at physiological temperatures, yet little is known regarding the final destination of internalized hormone and its receptor. We studied this by first binding [125I]hGH to the cell surface at 4 C, and then following its fate during a subsequent incubation at 30 C in isotope-free medium. Cell-associated radioactivity decreased with time at 30 C, with a biphasic pattern suggestive of a rapid (but minor) and a slow component. The kinetics of the latter were critically influenced by NH4Cl and were abolished at 20 C. Intracellular (acid-resistant) [125I]hGH first increased with time at 30 C until it reached a maximum after 1 h, then declined continuously upon prolonged incubation. The radioactivity released by the cells was recovered in the medium as both trichloroacetic acid-precipitable material and trichloroacetic acid-soluble fragments. After sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions, one major band migrating with an estimated mol wt of 22,000 was identified, presumably corresponding to intact [125I]hGH. These data suggest exocytosis of intact hormone via recycling endosomes and degradation in the lysosomes, respectively. Computer modelling was consistent with two intracellular compartments acting partially in series and probably corresponding to these two organelles. When analyzed by computer curve fitting, this model accurately described the kinetics of [125I]hGH internalization. So, receptor-mediated endocytosis and subsequent exocytosis are part of the GH pathway in IM-9 cells. In as much as they reflect pathways of GH receptors, these processes contribute to receptor down-regulation and could provide an explanation for release into the medium of the high affinity GH-binding protein.

Serum growth hormone (GH)-binding protein and insulin-like growth factor-I levels in Turner's syndrome before and during treatment with recombinant human GH and ethinyl estradiol.

Serum levels of GH-binding protein (GH-BP) and insulin-like growth factor-I (IGF-I) were measured in 14 adolescent girls with Turner's syndrome (TS) before and during treatment with recombinant human GH (rhGH) and oral ethinyl estradiol (EE2). Before treatment, the mean +/- SE GH-BP level in TS patients was 33.2 +/- 2.0%; this was higher (P < 0.05) than that in bone age-matched (27.9 +/- 1.1%; n = 13) or chronological age-matched (28.1 +/- 0.8%; n = 17) control girls. The mean +/- SE IGF-I level in TS girls (283 +/- 26 micrograms/L) was comparable to that in bone age-matched controls (255 +/- 17 micrograms/L), but lower (P < 0.005) than that in chronological age-matched pubertal controls (568 +/- 35 micrograms/L). In 7 TS girls treated with daily sc injections of rhGH in a dose of 0.8 U/kg.week for 18 months, serum levels of IGF-I increased from 330 +/- 39 to 707 +/- 48 micrograms/L after 3 months of treatment and remained elevated for the entire observation period (P < 0.002). In contrast, GH-BP levels did not change significantly. In 7 other TS girls, puberty was induced after 2 yr of daily sc injections with rhGH (1 U/kg.week) by adding 100 ng/kg.day EE2, orally, during ongoing rhGH therapy. During 18 months of pubertal induction, serum GH-BP levels increased gradually from 31.4 +/- 2.7% at the start of EE2 treatment to a maximum of 49.2 +/- 0.8% after 1 yr (P < 0.001). Serum IGF-I levels, in contrast, did not change significantly. These results show that in adolescent TS patients 1) pretreatment serum GH-BP levels are higher than in bone age-matched or chronological age-matched control girls, and IGF-I levels are similar to those in bone age-matched but lower than those in chronological age-matched controls; 2) during rhGH treatment GH-BP levels do not change, whereas IGF-I levels increase significantly; and 3) oral EE2 treatment during ongoing rhGH treatment increases GH-BP levels markedly, but does not modify IGF-I levels.

Serum growth hormone levels measured by radioimmunoassay and radioreceptor assay: a useful diagnostic tool in children with growth disorders?

Serum GH levels were measured by RIA and RRA in 133 subjects (19 healthy controls and 114 patients with various growth disturbances, aged 2.3-24.8 yr). Serum samples obtained from 147 stimulation tests representing a total of 1065 samples were analyzed by both methods, and the results compared. The data are expressed in absolute values and in RRA/RIA ratios. The area under the curve after a stimulation test (area GH) was calculated by planimetry. RIA was performed by the classical double antibody method using a polyclonal anti-serum. For the RRA, human cultured lymphocytes (IM-9 cells) were used, and 125I-labeled human GH was purified by high performance liquid chromatography. The same human GH standard was used in both assay systems. In control subjects a significant (P less than 0.0001) positive correlation was found at all ages between GH levels measured by RIA and RRA (r = 0.69 after insulin and r = 0.77 after glucagon). The RRA/RIA ratio (mean +/- SEM) for the peak GH level was 0.88 +/- 0.05, and the area under the GH curve was 0.85 +/- 0.05. The peak mean RRA/RIA ratios were significantly lower (P less than 0.05 and P = 0.03, respectively). No relationship was found with the absolute value of either peak or area GH. In patients with growth delay and Turner's syndrome, lower GH levels were found than in control subjects in both assay systems. The RRA/RIA ratios were also lower. In the other patients with some growth disorder, normal GH levels and ratios were found. In patients with renal failure, high levels of RIA-GH and RRA-GH were found, with a normal RRA/RIA ratio. In patients with documented pituitary GH deficiency, GH-releasing factor administration resulted in an increase in GH levels that was identical in both assays. The RRA/RIA ratio remained constant throughout the test. No correlation was found between the ratio and the absolute value of either RIA-GH or RRA-GH regardless of the stimulation test used. It is concluded that the presence of an abnormal GH molecule is extremely rare in patients with short stature. Thus, the presence of a bioinactive hormone is not a common cause of growth failure. During provocative testing some changes in the ratio may occur that do not appear after GH-releasing factor, further illustrating the different mechanisms involved in GH secretion.

Growth hormone (GH) treatment in short normal children: absence of influence of time of injection and resistance to GH autofeedback.

Forty prepubertal subjects (25 boys and 15 girls) with idiopathic short stature, aged 3.8-14.6 yr, were randomly allocated to receive sc injections of recombinant human GH (hGH) 6 days/week at a dose of 3 IU (1.25 mg)/m2.day either in the morning or in the evening. After 6 months of therapy, each subject was switched over to the other schedule of injection. After 12 months, treatment was stopped, and the subjects were followed for 6 months. For the whole group, regardless of the time of injection, height velocity (centimeters per yr) was 4.3 +/- 0.9 before hGH treatment, 8.3 +/- 1.9 during the first 6 months of treatment, and 6.9 +/- 1.6 during the last 6 months of treatment. Thirty-three of 38 subjects (87%) who completed 12 months of therapy presented an increase in height velocity greater than 2 cm/yr. Two patients (5%) developed antibodies to hGH and were among the nonresponders. There was no significant difference in growth response according to the schedule of injections. GH-releasing hormone (GHRH) testing was performed before and after 6 and 12 months of hGH therapy. When the last hGH injection was performed 12 h before the GHRH test, there was a 36% decrease in the maximum GH response (P less than 0.01) and a 33% decrease (P less than 0.01) in the GH secretory area compared to those before therapy. When the last hGH injection was performed 24 h or more before the GHRH test, no significant differences were observed. Insulin-like growth factor-I levels were not significantly different when measured 12 or 24 h after hGH. During the 6 months after discontinuation of hGH therapy, catch-down growth was observed in 44% of the subjects. We conclude that the schedule of injection does not influence the growth response, which wanes after 6 months; this waning effect is not related to declining insulin-like growth factor-I levels or GH autofeedback, suggesting a peripheral mechanism. Likewise, the catch-down phenomenon after hGH is discontinued is not related to a persistent diminution of pituitary responsiveness to GHRH.

Growth-promoting effect of growth hormone and low dose ethinyl estradiol in girls with Turner's syndrome.

Forty patients with Turner's syndrome, aged 5.0-16.6 yr, were randomly allocated to receive daily sc injections of recombinant human GH (hGH) at a dose of 1 IU/kg.week alone (group I) or in combination with 25 ng/kg.day ethinyl estradiol (E2; group II). The mean pretreatment height velocity was 3.8 cm/yr for both groups. During the first year of treatment height velocity increased significantly (P less than 0.001) in both groups, to 7.5 +/- 1.3 and 8.1 +/- 1.6 cm/yr, respectively. The difference between the two groups was not significant. The mean (+/- SD) height velocity expressed as the SD score for chronological age (Turner references) was 0.0 +/- 1.2 for group I and 0.2 +/- 1.4 for group II and increased significantly (P less than 0.001) during the first year of treatment to +4.3 +/- 1.1 in group I and +5.4 +/- 1.2 in group II. The difference between both groups was statistically significant (P less than 0.01). Height SD score for chronological age (Turner references) increased from -0.2 +/- 0.9 to +0.6 +/- 1.0 in group I and from -0.2 +/- 1.0 to +0.7 +/- 1.1 in group II. Mean bone age progressed similarly in both treatment groups (1.1 +/- 0.6 yr during 1 yr of treatment). However, bone age maturation accelerated more rapidly in younger patients. Twelve girls (three in group I and nine in group II) had minor breast development. No major adverse effects were reported. We conclude that daily sc therapy with hGH stimulates height velocity in Turner's syndrome. The beneficial effect on height velocity increment of E2 addition was small. Furthermore, even very low doses of E2 may induce breast development at an early age and accelerate bone maturation. For these reasons, the addition of E2 to hGH is not warranted in young patients with Turner's syndrome.

Comparative study of the lipolytic potencies of pituitary-derived and biosynthetic human growth hormone in hypopituitary children.

Whether stimulation of lipolysis is an intrinsic property of the human growth hormone (hGH) molecule or is due to contaminants of pituitary origin is controversial. We compared the rises in plasma FFA levels 4 h after an im injection of 0.2 U/kg of either pituitary hGH (n = 5) or biosynthetic methionyl hGH (n = 32) to hypopituitary patients. In each patient, plasma FFA levels also were measured during a similar period of fasting alone, without hGH injection. Plasma FFA levels rose between 0800 and 1230 h in both subgroups of patients during fasting alone. Injection of either pituitary or biosynthetic methionyl hGH led to a greater increase in plasma FFA than that induced by fasting alone, and the percent increases over baseline plasma FFA levels induced by either pituitary or synthetic hGH were similar. Triceps skinfold thickness before and after 3 months of treatment with biosynthetic hGH in 20 patients diminished by a mean of 2.5 mm, a decrease similar to that reported with pituitary hGH. We conclude that the acute and chronic lipolytic effect of hGH in man is an intrinsic property of the hGH molecule.

Perinatal growth hormone (GH) physiology: effect of GH-releasing factor on maternal and fetal secretion of pituitary and placental GH.

To study regulation of the secretion of human pituitary GH (hGH) and placental GH (hPGH) in the pregnant woman and human fetus, the GH-releasing factor Sermorelin [GRF-(1-29)-NH2] was administered to pregnant women at term (n = 5), just before elective cesarean section; saline was administered in control studies (n = 5). The effects of GRF-(1-29)-NH2 administration on maternal and fetal serum concentrations of hGH and GRF-(1-29)-NH2 and maternal serum levels of hPGH were evaluated at birth. The mean time span between injection and birth was 20 min (range, 15-25 min). Cord serum hGH concentrations were similar in infants of GRF-(1-29)-NH2-injected mothers and control infants. GRF-(1-29)-NH2 elicited a consistent but small rise in maternal hGH serum concentrations (P = 0.08), whereas hPGH concentrations remained unaltered. Finally, GRF-(1-29)-NH2 concentrations were undetectable in cord serum, but readily detectable in concomitantly obtained maternal serum. In conclusion, these data suggest that hGH secretion in the pregnant woman at term is suppressed at the pituitary level, that GRF does not affect hPGH secretion, and that fetal hGH secretion is independent of circulating maternal GRF, probably because of lack of transplacental GRF passage.

Hypopituitarism and idiopathic delayed puberty: a longitudinal study in an attempt to diagnose gonadotropin deficiency before puberty.

Fifty-five hypopituitary patients (43 boys and 12 girls) treated with human GH were studied longitudinally before and during puberty, occurring either spontaneously or induced with testosterone enanthate (100 mg/month, im) in boys and ethinylestradiol (10 micrograms/day, orally) in girls. In addition, 53 boys with idiopathic delayed puberty (IDP) were studied. Gonadotropin integrated responses (IRs) during 90 min after the iv injection of 25 micrograms/m2 LRH, bone ages (BA), and plasma levels of dehydroepiandrosterone sulfate and testosterone were determined at least yearly. Prepubertal hypopituitary patients with gonadotropin deficiency were characterized by: 1) a lowered FSH IR to LRH in most boys and in all girls; 2) a low LH IR for BA; 3) adrenarche either absent or delayed BA; 4) height age close to BA; and 5) the presence of several pituitary deficiencies. In contrast, most prepubertal hypopituitary patients without gonadotropin deficiency showed: 1) a normal FSH IR to LRH; 2) a normal or intermediate (greater than or equal to 75 mIU/ml . 90 min) LH IR for BA; 3) a normal adrenarche for BA; 4) a height age below BA; and 5) isolated GH or GH plus TSH deficiencies. A significant linear correlation was found between LH IR and the logarithm of plasma testosterone. The slopes and levels were similar in controls and hypopituitary boy without gonadotropin deficiency. In IDP, the level was significantly higher. All data obtained in these patients show that the increase in plasma testosterone and the clinical onset of puberty are delayed for the observed pubertal pattern of LH responsiveness. It is concluded that the study of several clinical and biological features, especially the gonadotropin IR to LRH, are of predictive value for the diagnosis of normal or deficient gonadotropic function in prepubertal patients with IDP and hypopituitarism.

Dose-dependent catch-up growth after 2 years of growth hormone treatment in intrauterine growth-retarded children. Belgian and French Pediatric Clinics and Sanofi-Choay (France).

This study reports the results of a 2-yr clinical trial with GH in 95 short prepubertal children with non-GH-deficient intrauterine growth retardation. This randomized, double blind, controlled study compared the effects of placebo (restricted to the first 6 months) and two doses of GH (0.4 and 1.2 IU/kg.week) given sc 6 days/week for 2 yr. A significant GH dose-dependent growth acceleration was observed. Mean height gain (SDS/CA) was 0.66 +/- 0.07 in group I (low dose, 0.4 IU/kg.week) compared to 1.25 +/- 0.07 in group II (high dose, 1.2 IU/kg.week). Mean bone maturation progression (expressed in months) was 26.2 +/- 1.7 and 30.2 +/- 1.5 over 24 months in groups I and II, respectively. Onset of puberty was observed in some patients of both groups. Whether chronic use of a high GH dose will advance the onset of puberty remains to be established. A great variability of growth acceleration was seen among GH dose groups, suggesting that factors in addition to GH dose might modulate individual responses to treatment. In conclusion, it is suggested that in these patients, dose-dependent catch-up growth could be induced by GH treatment.

Pubertal growth and final height in hypopituitary boys: a minor role of bone age at onset of puberty.

Twenty-two hypopituitary boys treated with human GH were studied longitudinally before and during puberty. Eight patients entered spontaneous puberty at a mean bone age of 12.4 +/- 1.0 (+/- SD) yr. Height velocity reached a mean peak of 6.8 cm/yr during the second year of spontaneous puberty. In these patients, the mean total height gain throughout puberty was 22.8 +/- 5.2 cm, and the mean final height was 158.6 +/- 7.2 cm. Fourteen patients received testosterone enanthate (100 mg/month, im) starting at a mean bone age of 13.6 +/- 1.1 yr. Height velocity was maximal (7.5 cm/yr) during the first year of therapy. The mean final height was 162.9 +/- 5.0 cm, with a mean pubertal gain of 15.9 +/- 3.8 cm. Genital development, peak height velocity, and increase in plasma testosterone levels occurred earlier during testosterone therapy than during spontaneous puberty. In both groups of patients, there was a positive correlation between the bone age at onset of puberty and the height at onset of puberty (r = 0.65). There was also a negative correlation between bone age and total pubertal height gain (r = -0.73). This reduction in pubertal height increase was less than expected for bone age at onset of puberty, which can be explained by a decrease in bone age velocity in relation to bone age at onset of puberty (r = -0.81). Therefore, advancement in bone age at the onset of testosterone therapy did not impair final height, whereas it may increase height at onset of puberty, which is the major factor in final height. We conclude that in GH- and gonadotropin-deficient boys 1) a reduced dosage of testosterone enanthate (25 mg twice a month, im) should be used to induce pubertal development, and 2) the major criterion to decide when to give testosterone is height reached at that time regardless of bone age.

Age and height at diagnosis in Turner syndrome: influence of parental height.

Age and height at diagnosis was studied in 100 patients with Turner syndrome: 41 with the 45,X karyotype and 59 with various other karyotypes. In 15 patients diagnosis was made at birth. In the remaining patients median age at diagnosis was 12.9 years in those with 45,X karyotype and 11.6 years in the others. Mean +/- SD height standard deviation score at diagnosis was -3.2 +/- 0.9 for the patients with 45,X karyotype and -2.8 +/- 0.9 for the others. A significantly negative correlation was found between age and height standard deviation score at diagnosis (r = - .51; P less than .005). Corrected mid parental height was significantly correlated with height standard deviation score at diagnosis (r = .49; P less than .005), but not with age at diagnosis (r = -.08). It is concluded that although Turner syndrome is a congenital disorder, the diagnosis is usually made too late, at a chronological age when a marked height deficit is present. To make an early diagnosis, a cytogenetic examination should be recommended for all girls with height more than 2 SD below the mean for age or more than 2 SD below corrected mid parental height.

Non-endemic Burkitt's lymphoma in a patient with Bloom's syndrome.

Bloom's syndrome is an autosomal recessive disorder characterized by intrauterine growth retardation, typical physical signs, immunodeficiency and an increased risk of developing neoplasms at a young age, compared to the general population. Factors possibly involved in the pathogenesis of non-endemic Burkitt's lymphoma in a five year old girl with Bloom's syndrome are discussed. These include immunodeficiency, upregulated c-myc expression and an Epstein-Barr viral infection.

Growth hormone deficiency: a hidden obstetrical trauma?

Fetal presentation, mode of delivery and onset of labour were reviewed in 177 patients with documented growth hormone deficiency. Non-cephalic presentations were about ten times more frequent in this group of patients than in a control population. All children with breech position were delivered vaginally and spontaneously, suggesting a pituitary insult during vaginal delivery. 'True idiopathic' isolated growth hormone deficiency was frequently found in association with induction of labour. The data indicate that even a mild birth trauma may result in growth hormone deficiency.

Intelligence, behaviour and psychosocial development in Turner syndrome. A cross-sectional study of 50 pre-adolescent and adolescent girls (4-20 years).

In this paper we report the findings and data on a cross-sectional study of 50 pre-adolescent and adolescent girls with Turner syndrome. We confirm the presence of a typical cognitive profile in the different age groups with normal verbal intelligence contrasting with lower results on performal IQ subtests, related to relative weaknesses on visuospatial subtests i.e. "Block Design" and "Object Assembly". 5% of the girls with a "classical" Turner syndrome karyotype (i.e. 2/40) were mentally retarded versus 30% (i.e. 3/10) in the group with "rare" karyotypic anomalies. We noted a positive influence of hormonal therapy on the visuospatial functioning. No evidence was found for a high risk for behavioural problems. Hyperactive behaviour was seen in the youngest patients contrasting with a tendency to hypoactivity around the age of normal puberty. Problems in social development were noted from the age of primary school on resulting in social immaturity and even isolation. A proposal for guidance of Turner girls during the different developmental periods is given.

[TSH-response to TRH in active coeliac disease in infants (author's transl)]. / Réponse hypophysaire en TSH après administration de TRH chez des enfants souffrant de maladie coeliaque active.

In 11 infants of 3-19 months of age with active gluten-induced enteropathy, an exaggerated and sustained response of plasma TSH to TRH was observed as compared to controls. In these same patients, there was a decrease in total and free T4 and T3 concentrations. All these values were statistically different from controls.

The effect of simple obesity on growth and growth hormone.

Simple obesity is characterized by a normal or increased growth rate with an acceleration of bone age maturation. When longitudinal growth slows down in the presence of obesity, a hormonal disturbance should be sought. Despite normal growth, simple obesity is characterized by a reduced GH secretion evaluated by standard provocative tests, the administration of GH-releasing hormone or spontaneous 24-hour secretion. In obese children GH secretion may be as low as in poorly growing children with classical GH deficiency. The endocrine abnormalities along the GH axis seem to involve complex mechanisms at the hypothalamic, pituitary and peripheral level. Recent data suggest that simple obesity is associated with an increase in GH clearance and a decrease in GH synthesis and secretion. It is also associated with high insulin and insulin-like growth factor I levels which may interfere in the complex endocrine interactions. In conclusion, simple obesity is characterized by normal growth in the presence of 'hyposomatotropism'.

Assessment of growth hormone secretion: what are we looking for practically?

GH is a dominant factor in determining growth during childhood. Hence, the assessment of GH secretion is of major importance in the diagnosis of growth disorders. Since GH is secreted in a pulsatile fashion, a truly accurate production rate can only be calculated by using very frequent or continuous blood sampling over a 24-hour period. Several standard provocative tests have been established to evaluate GH secretory status. They remain the cornerstone in the assessment. Recent data have shown the existence of a wide spectrum of GH secretory disturbances ranging from severe GH deficiency to partial insufficiency and neurosecretory dysfunction. There is no well-defined cut-off point at which a particular child can be regarded as GH insufficient or sufficient for optimal growth. In clinical practice, the assessment of GH secretion starts with the careful analysis of the growth chart and height velocity. Careful clinical examination of the patient is essential for the proper diagnosis, and to exclude diseases influencing GH secretion. Additional biochemical tests may be required for the differential diagnosis. Thus, assessment of GH secretion in children requires auxological, clinical and biochemical data. GH insufficiency is documented by additional testing of pituitary secretory capacity either by standard provocative tests, by studying 24-hour GH profile or by measuring 24-hour production rate. The main goal is to detect those children who will benefit from treatment with hGH. The final assessment might consist in the response of growth velocity to exogenous hGH.