Placental growth hormone variant: assay and clinical aspects

Human Placental Growth Hormone Variant in Pathological Pregnancies

Growth hormone (GH), an endocrine hormone, primarily secreted from the anterior pituitary, stimulates growth, cell reproduction, and regeneration and is a major regulator of postnatal growth. Humans have two GH genes that encode two versions of GH proteins: a pituitary version (GH-N/GH1) and a placental GH-variant (GH-V/GH2), which are expressed in the syncytiotrophoblast and extravillous trophoblast cells of the placenta. During pregnancy, GH-V replaces GH-N in the maternal circulation at mid-late gestation as the major circulating form of GH. This remarkable change in spatial and temporal GH secretion patterns is proposed to play a role in mediating maternal adaptations to pregnancy. GH-V is associated with fetal growth, and its circulating concentrations have been investigated across a range of pregnancy complications. However, progress in this area has been hindered by a lack of readily accessible and reliable assays for measurement of GH-V. This review will discuss the potential roles of GH-V in normal and pathological pregnancies and will touch on the assays used to quantify this hormone.

Human placental growth hormone in normal and abnormal fetal growth

Human placental growth hormone (PGH), encoded by the growth hormone (GH) variant gene on chromosome 17, is expressed in the syncytiotrophoblast and extravillous cytotrophoblast layers of the human placenta. Its maternal serum levels increase throughout pregnancy, and gradually replaces the pulsatile secreted pituitary GH. PGH is also detectable in cord blood and in the amniotic fluid. This placental-origin hormone stimulates glyconeogenesis, lipolysis and anabolism in maternal organs, and influences fetal growth, placental development and maternal adaptation to pregnancy. The majority of these actions are performed indirectly by regulating maternal insulin-like growth factor-I levels, while the extravillous trophoblast involvement indicates a direct effect on placental development, as it stimulates trophoblast invasiveness and function via a potential combination of autocrine and paracrine mechanisms. The current review focuses on the role of PGH in fetal growth. In addition, the association of PGH alterations in maternal circulation and placental expression in pregnancy complications associated with abnormal fetal growth is briefly reviewed.

Human placental growth hormone is increased in maternal serum at 20 weeks of gestation in pregnancies with large-for-gestational-age babies

To investigate the relationship between maternal serum concentrations of placental growth hormone (GH-V), insulin-like growth factor (IGF)-1 and 2, IGF binding proteins (IGFBP)-1 and 3 and birth weight in appropriate-for-gestational-age (AGA), large-for-gestational-age (LGA) and small-for-gestational-age (SGA) cases in a nested case-control study. Maternal serum samples were selected from the Screening for Pregnancy Endpoints (SCOPE) biobank in Auckland, New Zealand. Serum hormone concentrations were determined by ELISA. We found that maternal serum GH-V concentrations at 20 weeks of gestation in LGA pregnancies were significantly higher than in AGA and SGA pregnancies. Maternal GH-V concentrations were positively correlated to birth weights and customized birth weight centiles, while IGFBP-1 concentrations were inversely related to birth weights and customized birth weight centiles. Our findings suggest that maternal serum GH-V and IGFBP-1 concentrations at 20 weeks' gestation are associated with fetal growth.

Growth hormone isoforms

Human growth hormone (GH) is a heterogeneous protein hormone consisting of several isoforms. The sources of this heterogeneity reside at the level of the genome, mRNA splicing, post-translational modification and metabolism. The GH gene cluster on chromosome 17q contains 2 GH genes (GH1 or GH-N and GH2 or GH-V) in addition to 2(-3) genes encoding the related chorionic somatomammotropin. Alternative mRNA splicing of the GH1 transcript yields two products: 22K-GH (the principal pituitary GH form) and 20K-GH. Post-translationally modified GH forms include N(alpha)-acylated, deamidated and glycosylated monomeric GH forms, as well as both non-covalent and disulfide-linked oligomers up to at least pentameric GH. GH fragments generated in the course of peripheral metabolism may be measured in immunoassays for GH. The GH-N gene is expressed in the pituitary, the GH-V gene in the placenta. Secretion of pituitary GH forms is pulsatile under control from the hypothalamus, whereas secretion of placental GH-V is tonic and rises progressively in maternal blood during the 2nd and 3rd trimester. Pituitary GH forms are co-secreted during a secretory pulse; no isoform-specific stimuli have been identified. There are minor differences in somatogenic and metabolic bioactivity among the GH isoforms, depending on species and assay system used. Both 20K-GH and GH-V have poor lactogenic activity. Oligomeric GH forms have variably diminished bioactivity compared to monomeric forms. GH isoforms cross-react in most immunoassays, but assays specific for 22K-GH, 20K-GH and GH-V have been developed. The metabolic clearance of 20K-GH and GH oligomers is delayed compared to that of 22K-GH. The heterogeneous mixture of GH isoforms in blood is further complicated by the presence of two GH-binding proteins, which form complexes with GH; isoform proportions also vary depending on the lag time from a secretory pulse because of different half-lives. GH forms excreted in the urine reflect monomeric GH isoforms in blood, but constitute only a minute fraction of the GH production rate. The heterogeneity of GH is one important reason for the notorious disparity among assay results. It also presents an opportunity for distinguishing endogenous from exogenous GH.

Placental growth hormone is increased in the maternal and fetal serum of patients with preeclampsia

OBJECTIVES

Placental growth hormone (PGH) is a pregnancy-specific protein produced by syncytiotrophoblast and extravillous cytotrophoblast. No other cells have been reported to synthesize PGH Maternal. PGH Serum concentration increases with advancing gestational age, while quickly decreasing after delivery of the placenta. The biological properties of PGH include somatogenic, lactogenic, and lipolytic functions. The purpose of this study was to determine whether the maternal serum concentrations of PGH change in women with preeclampsia (PE), women with PE who deliver a small for gestational age neonate (PE + SGA), and those with SGA alone.

STUDY DESIGN

This cross-sectional study included maternal serum from normal pregnant women (n = 61), patients with severe PE (n = 48), PE + SGA (n = 30), and SGA alone (n = 41). Fetal cord blood from uncomplicated pregnancies (n = 16) and PE (n = 16) was also analyzed. PGH concentrations were measured by ELISA. Non-parametric statistics were used for analysis.

RESULTS

(1) Women with severe PE had a median serum concentration of PGH higher than normal pregnant women (PE: median 23,076 pg/mL (3473-94 256) vs. normal pregnancy: median 12 157 pg/mL (2617-34 016); p < 0.05), pregnant women who delivered an SGA neonate (SGA: median 10 206 pg/mL (1816-34 705); p < 0.05), as well as pregnant patients with PE and SGA (PE + SGA: median 11 027 pg/mL (1232-61 702); p < 0.05). (2) No significant differences were observed in the median maternal serum concentration of PGH among pregnant women with PE and SGA, SGA alone, and normal pregnancy (p > 0.05). (3) Compared to those of the control group, the median umbilical serum concentration of PGH was significantly higher in newborns of preeclamptic women (PE: median 356.1 pg/mL (72.6-20 946), normal pregnancy: median 128.5 pg/mL (21.6-255.9); p < 0.01). (4) PGH was detected in all samples of cord blood.

CONCLUSIONS

(1) PE is associated with higher median concentrations of PGH in both the maternal and fetal circulation compared to normal pregnancy. (2) Patients with PE + SGA had lower maternal serum concentrations of PGH than preeclamptic patients without SGA. (3) Contrary to previous findings, PGH was detectable in the fetal circulation. The observations reported herein are novel and suggest that PGH may play a role in the mechanisms of disease in preeclampsia and fetal growth restriction.

Effects of sildenafil on the fetal growth of guinea pigs and their ability to survive induced intrapartum asphyxia

OBJECTIVE

Our goal was to determine whether sildenafil increased fetal weight and favored fetal tolerance to induced asphyxia at birth in guinea pigs.

STUDY DESIGN

Twenty guinea pigs were randomly allocated to placebo (n = 10) or sildenafil 50 microg/kg (n = 5) or 500 microg/kg (n = 5), starting from day 35 of gestation to delivery. Fetuses were delivered by cesarean section. Fetal asphyxia was induced by clamping the umbilical cord at birth for 5 minutes.

RESULTS

Sildenafil protected the pups against induced asphyxia at birth in a dose-dependent manner (eg, partial pressure (tension) of carbon dioxide levels were 75.9 +/- 19.3, 66.9 +/- 18.8, and 54.8 +/- 13.0 in the control and low- and high-dose sildenafil groups, respectively). The high-dose sildenafil group of piglets gained 1.5 times more body weight.

CONCLUSION

In guinea pigs, low doses of sildenafil administered from day 35 to the end of gestation favored fetal tolerability to induced intrapartum asphyxia. High doses of sildenafil increased fetal weight.

Small for gestational age: short stature and beyond

Depending on the definitions used, up to 10% of all live-born neonates are small for gestational age (SGA). Although the vast majority of these children show catch-up growth by 2 yr of age, one in 10 does not. It is increasingly recognized that those who are born SGA are at risk of developing metabolic disease later in life. Reduced fetal growth has been shown to be associated with an increased risk of insulin resistance, obesity, cardiovascular disease, and type 2 diabetes mellitus. The majority of pathology is seen in adults who show spontaneous catch-up growth as children. There is evidence to suggest that some of the metabolic consequences of intrauterine growth retardation in children born SGA can be mitigated by ensuring early appropriate catch-up growth, while avoiding excessive weight gain. Implicitly, this argument questions current infant formula feeding practices. The risk is less clear for individuals who do not show catch-up growth and who are treated with GH for short stature. Recent data, however, suggest that long-term treatment with GH does not increase the risk of type 2 diabetes mellitus and the metabolic syndrome in young adults born SGA.

Increased human placental growth hormone at midtrimester pregnancies may be an index of intrauterine growth retardation related to preeclampsia

OBJECTIVE

To evaluate the relationship between maternal serum and amniotic fluid levels of human Placental Growth Hormone (hPGH) with the fetal intrauterine growth retardation (IUGR) related to preeclampsia.

DESIGN

We analyzed samples in pairs of serum and amniotic fluid retrospectively from 25 women, who manifested preeclampsia and IUGR in the late second or the third trimester of gestation. The samples were obtained at 16-22 weeks' gestation during amniocentesis for fetal karyotyping. At this time, there was no clinical or sonographic evidence of preeclampsia or IUGR, respectively. Sixty-two serum samples were used as controls which were obtained at 16-22 weeks' gestation from women with singleton, uncomplicated pregnancies, with normal outcome, and appropriate for gestational age neonatal birth weight. Forty-seven amniotic fluid samples were also used as controls which were obtained at 16-22 weeks' gestation from the women that were included in the control group who underwent an amniocentesis. hPGH levels were measured by a solid phase immunoradiometric assay.

RESULTS

The mean hPGH values in the serum and the amniotic fluid of the IUGR related to preeclampsia affected pregnancies were significantly higher (P<0.05) than those of the normal pregnancies at 16-22 weeks' gestation: mean+/-SD in the serum was 13.16+/-10.52 ng/ml vs. 4.39+/-2.23 ng/ml; mean+/-SD in the amniotic fluid 2.49+/-1.6 ng/ml vs. 0.82+/-0.67 ng/ml.

CONCLUSION

hPGH levels in maternal serum and amniotic fluid were found to be higher at 16-22 weeks' gestation in pregnancies that will be complicated subsequently by IUGR related to preeclampsia. Our findings suggest that the evaluation of the changes of hPGH levels at midtrimester should be further investigated for the possibility to provide a potential predictive index of IUGR and preeclampsia.

Aspects of placental growth hormone physiology

Placental growth hormone (PGH) has been known for 20 years. Nevertheless, its physiology is far from understood. In this review, basal aspects of PGH physiology are summarised and put in relation to the highly homologous pituitary growth hormone (GH). During normal pregnancy, PGH progressively replaces GH and reach maximum serum concentrations in the third trimester. A close relationship to insulin-like growth factor (IGF)-I and -II levels is observed. Furthermore, PGH levels are positively associated to fetal growth. The potential importance of growth hormone receptors and binding protein for PGH effects is discussed. Finally, the review outlines current knowledge of PGH in pathological pregnancies.

Kinetics and secretion of placental growth hormone around parturition

OBJECTIVE

During pregnancy, placental growth hormone (PGH) is secreted into the maternal circulation, replacing pituitary GH. It is controversial whether PGH levels decline during vaginal birth. After placental expulsion, PGH is eliminated from the maternal blood. GH binding protein (GHBP) and body mass index (BMI) influence GH kinetics, but their impact on PGH kinetics is unknown. The present study was undertaken to define the kinetics of PGH during vaginal delivery and Caesarian section and to relate these kinetics to GHBP and BMI.

DESIGN

A short term, prospective cohort study.

METHODS

Twelve women had repeated blood samples drawn during vaginal delivery. From 26 women undergoing planned Caesarian delivery (CS) repeated blood samples were withdrawn before, during and after the CS, allowing PGH half-life determination.

RESULTS

During vaginal delivery, median PGH values did not change before expulsion of the placenta, although individual fluctuations were seen. Clearance of PGH from the maternal circulation was best described by a two-compartment model. The initial half-life of serum PGH was (mean +/- s.d.) 5.8 +/- 2.4 min, and the late half-life was (median) 87.0 min (range: 25.1-679.6 min). The late half-life was correlated to the pre-gestational BMI (r = 0.39, P = 0.047), but not to the serum GHBP concentration.

CONCLUSIONS

Serum PGH did not decrease significantly during vaginal delivery. Elimination of PGH fitted a two-compartment model, with an estimated initial half-life of 5.8 min. The late phase serum half-life of PGH was related to BMI, suggesting a role for maternal fat mass in PGH metabolism.

Increase in maternal placental growth hormone during pregnancy and disappearance during parturition in normal and growth hormone-deficient pregnancies

OBJECTIVE

The purpose of this study was to evaluate placental growth hormone levels in maternal circulation throughout pregnancy in normal and growth hormone-deficient women with the use of a specific assay and to determine the clearance of placental growth hormone from maternal circulation after birth.

STUDY DESIGN

Seventeen healthy pregnant women and 1 patient with growth hormone deficiency substituted with recombinant growth hormone during pregnancy participated in a longitudinal study from early pregnancy until birth with repetitive blood sampling and measurement of placental growth hormone levels throughout pregnancy. Furthermore, serial blood samples were drawn before, during, and after elective caesarean deliveries in 5 healthy women to calculate the half-life of placental growth hormone. Placental growth hormone was measured with the use of two monoclonal antibodies in a commercially available solid-phase iodine 125-labeled immunoradiometric assay (Biocode, Liège, Belgium).

RESULTS

Placental growth hormone levels were detectable from as early as 8 weeks of gestation in some of the women and increased throughout gestation, with a maximum at approximately 35 to 36 weeks of gestation (13.7 ng/mL; range, 5.9-24.4 ng/mL) and large interindividual variations. Placental growth hormone levels did not correlate with birth weight or placental weight. In the patient with isolated growth hormone deficiency, placental growth hormone levels were detectable from 11 weeks of gestation (3.4 ng/mL) and increased throughout pregnancy to 13.9 ng/mL, which is similar to values that are obtained in the healthy pregnant women. Substitution therapy with recombinant human growth hormone did not suppress the increase in placental growth hormone. We found a mean half-life of placental growth hormone of 13.8 minutes (range, 11.5-15.2 minutes) in healthy pregnant women and an apparently similar half-life of placental growth hormone (15.8 minutes) in the growth hormone-deficient patient, assuming a monoexponential disappearance of placental growth hormone during the first 30 minutes after the delivery. After the initial 30 minutes, approximately 75% (range, 65%-89%) of the placental growth hormone had been cleared from the maternal circulation.

CONCLUSION

Levels of placental growth hormone in maternal circulation increase throughout pregnancy from as early as 8 weeks of pregnancy, with maximum levels around the week 35 of gestation. The pregnancy-induced rise in placental growth hormone levels in the growth hormone-deficient patient was comparable to the rise seen during normal pregnancies and was not suppressed by the concurrent human growth hormone treatment. We speculate that maternal serum levels of placental growth hormone reflect placental function and fetal growth. However, further studies are needed to evaluate the potential clinical use of placental growth hormone determinations.

Human placental growth hormone--a review

Placental growth hormone (PGH) is the product of the GH-V gene, predominantly expressed in the syncytiotrophoblast layer of the human placenta. PGH differs from pituitary growth hormone by 13 amino acids and possesses one glycosylation site. It has high somatogenic and low lactogenic activities. In the maternal circulation from 12-20 weeks up to term, PGH gradually replaces pituitary growth hormone, which becomes undetectable. PGH is secreted by the placenta in a non-pulsatile manner. This continuous secretion appears to have important implications for physiological adjustment to gestation and especially in the control of maternal IGF1 levels. PGH secretion is regulated in vitro and in vivo by glucose. Lower maternal levels of PGH are observed in pregnancies with fetal growth retardation. PGH is one example of a trophoblast hormone, which allows maternal metabolic adaptation to pregnancy. In addition, our recent data on its expression in invasive extravillous trophoblasts suggest that the physiological role of PGH might also include a direct influence of this hormone on placental development via an autocrine or paracrine mechanism.

Human placental growth hormone causes severe insulin resistance in transgenic mice

OBJECTIVE

The insulin resistance of pregnancy is considered to be mediated by human placental lactogen, but the metabolic effects of human placental growth hormone have not been well defined. Our aim was to evaluate the effect of placental growth hormone on insulin sensitivity in vivo using transgenic mice that overexpress the human placental growth hormone gene.

STUDY DESIGN

Glucose and insulin tolerance tests were performed on 5 transgenic mice that overexpressed the human placental growth hormone variant gene and 6 normal littermate controls. The body composition of the mice was assessed by dual-energy radiograph absorptiometry, and free fatty acid levels were measured as a marker of lipolysis.

RESULTS

The human placental growth hormone levels in the transgenic mice were comparable to those attained in the third trimester of pregnancy. These mice were nearly twice as heavy as the control mice, and their body composition differed by a significant increase in bone density and a small decrease in percentage of body fat. Fasting insulin levels in the transgenic mice that overexpressed placental growth hormone were approximately 4-fold higher than the control mice (1.57 +/- 0.22 ng/mL vs 0.38 +/- 0.07 ng/mL; P <.001) and 7 times higher 30 minutes after glucose stimulation (4.17 +/- 0.54 ng/mL vs 0.62 +/- 0.10 ng/mL; P <.0001) with no significant difference in either fasting or postchallenge glucose levels. Insulin sensitivity was markedly decreased in the transgenic mice, as demonstrated by an insignificant decline in glucose levels after insulin injection compared with the control mice, which demonstrated more than a 65% reduction in glucose levels (P <.001).

CONCLUSION

Human placental growth hormone causes insulin resistance as manifested by fasting and postprandial hyperinsulinemia and minimal glucose lowering in response to insulin injection. Human placental growth hormone is a highly likely candidate to mediate the insulin resistance of pregnancy.

Maternal endocrine adaptations to placental hormones in humans

The remarkable endocrine alterations that are characteristic of human pregnancy are attributable to the placenta. In this tissue, steroid and peptide hormones are produced in extraordinary amounts. In addition, the haemomonochorioendothelial placentation of human pregnancy contributes to the unique distribution of products formed in trophoblasts into maternal and fetal compartments. In this review, the partial control exerted by the trophoblast on maternal metabolism is illustrated by the replacement in the maternal compartment of pituitary growth hormone (GH) with the trophoblast's own product, human placental GH. Placental GH differs from pituitary GH by 13 amino acids, has high somatogenic and low lactogenic activities and is secreted by the syncytiotrophoblast in a non-pulsatile manner. This continuous secretion appears to have important implications for the control of maternal levels of insulin-like growth factor I. Placental GH secretion is inhibited by glucose in vitro and in vivo, and is significantly decreased in the maternal circulation in cases of pregnancies with intrauterine growth retardation.

Placental hormones during induced hypoglycaemia in pregnant women with insulin-dependent diabetes mellitus: evidence of an active role for placenta in hormonal counter-regulation

OBJECTIVE

To study the effect of induced hypoglycaemia on serum levels of the placental hormones oestriol, human placental lactogen, placental growth hormone and progesterone in the third trimester of pregnancy.

DESIGN

A prospective experimental investigation.

SETTING

High risk pregnancy unit and diabetes research unit at Karolinska Institutet Danderyd Hospital, a university hospital.

PARTICIPANTS

Ten women with insulin-dependent diabetes mellitus in the third trimester of pregnancy.

METHODS

Venous blood samples were collected every 15 minutes for analyses of oestriol, progesterone, human placental lactogen and placental growth hormone, during the 150 min of a hyperinsulinaemic hypoglycaemic clamp, which maintained arterial blood-glucose level of about 2.2 mmol/l.

MAIN OUTCOME MEASURES

Levels of analysed placental hormones during hypoglycaemia.

RESULTS

A statistically significant increase was observed in placental growth hormone during hypoglycaemia (P < 0.0001), whereas the placental hormones progesterone, human placental lactogen and oestriol did not show changes of clinical significance.

CONCLUSIONS

The increase in placental growth hormone indicates that the placenta is an endocrine organ which may take an active part in acute metabolic processes, such as here in the hormonal counterregulation of hypoglycaemia.

Physiological role of human placental growth hormone

Placental growth hormone (PGH) is the product of the GH-V gene specifically expressed in the syncytiotrophoblast layer of the human placenta. PGH differs from pituitary growth hormone by 13 amino acids. It has high somatogenic and low lactogenic activities. Assays of PGH by specific monoclonal antibodies reveal that in the maternal circulation from 15-20 weeks up to term, PGH gradually replaces pituitary growth hormone which becomes undetectable. It is secreted by the placenta in a non-pulsatile manner. This continuous secretion appears to have important implications for physiological adjustment to gestation and especially in the control of maternal IGF1 levels. PGH secretion is inhibited by glucose in vitro and in vivo, and is significantly decreased in the maternal circulation in cases of pregnancies with intrauterine growth retardation. PGH does not appear to have a direct effect on fetal growth, as this hormone is not detectable in the fetal circulation. However the physiological role of PGH might also include a direct influence on placental development via an autocrine or paracrine mechanism as suggested by the presence of specific GH receptors in this tissue.

The Growth Hormone Research Society consensus guidelines for the diagnosis and treatment of adult GH deficiency

The Growth Hormone Research Society (GRS) convened a workshop in Port Stephens, Australia in April 1997 to establish consensus guidelines for the diagnosis and treatment of adults with GH deficiency (GHD). Scientists with expertise in the field, representatives from industry involved in the manufacture of GH and representatives from health authorities from a number of countries participated in the workshop. The workshop considered the following questions: (1) How should adult GHD be defined? (2) Who should be tested for adult GHD? (3) How should the diagnosis of adult GHD be established? (4) How should GH and insulin-like growth factor-I (IGF-I) assays be standardized? (5) Who should be treated for adult GHD? (6) What dose of GH should be used for treatment of adult GHD? (7) How should treatment of adult GHD be monitored? (8) What are the contraindications to treatment of adult GHD? (9) What safety issues need to be considered? (10) How long should treatment of adult GHD be continued? The consensus guidelines developed at this workshop and the rationale for some of these recommendations will be reviewed in this paper.

Human placental growth hormone

Placental growth hormone is the product of the GH-V gene specifically expressed in the syncytiotrophoblast layer of the human placenta. Placental growth hormone differs from pituitary growth hormone by 13 amino acids. It has high somatogenic and low lactogenic activities. Assays by specific monoclonal antibodies reveal that in the maternal circulation from 15 to 20 weeks up to term placental growth hormone gradually replaces pituitary growth hormone, which becomes undetectable. It is secreted by the placenta in a nonpulsatile manner. This continuous secretion appears to have important implications for physiologic adjustment to gestation and especially in the control of maternal insulin-like growth factor-I levels. Placental growth hormone secretion is inhibited by glucose in vitro and in vivo and is significantly decreased in the maternal circulation in pregnancies with intrauterine growth restriction. Placental growth hormone does not appear to have a direct effect on fetal growth because this hormone is not detectable in the fetal circulation. However, the physiologic role might also include a direct influence on placental development through an autocrine or paracrine mechanism, as suggested by the presence of specific growth hormone receptors in this tissue.

The growth without growth hormone syndrome

The phenomenon of growth without GH has been recognized for over a quarter of a century in various physiologic or near-physiologic situations, including the fetal state and obesity, and in various obviously pathologic states, including postsurgical resection of suprasellar/hypothalamic tumors, most notably craniopharyngiomas, and in acromegaloidism. The mechanism or mechanisms responsible for this fascinating clinical syndrome are unknown. The available data implicate, at least in some of these subjects, a role for hypothalamic injury leading to obesity and insulin resistance which, in turn, leads to elevated circulating concentrations of insulin to which the body retains mitogenic sensitivity. Alternatively, in other subjects with this syndrome, evidence exists to support the presence of a circulating as yet incompletely characterized potent growth-promoting factor which appears in the serum. Further studies of this syndrome should help to enhance our knowledge of the mechanisms governing both normal and abnormal human growth.