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Query: UMLS:C0028754 (
obesity
)
124,988
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Previous observations raised the possibility that circulating
GH-binding protein
(
GHBP
) may serve as a useful index for tissue
GH receptor
(
GHR
) responsiveness in humans. Indeed, there are many examples to indicate that across a wide scope of comparative studies, ontogenic data, experimental systems, physiological conditions, nutritional states, and diseases there is a close relationship between the concentration of
GHR
and the level of serum
GHBP
. In the present review, we discuss various aspects that might affect differentially cellular
GHR
and circulating
GHBP
, based on species and tissue divergence, regulation of cell-surface
GHR
turnover,
GHR
cleavage mechanism,
GHR
mRNA splicing, and GH insensitivity (GHI) syndrome patients with normal or high serum
GHBP
levels. Most previous experimental data were collected through comparative analysis of human
GHBP
against
GHR
and
GHBP
determinations in animal models. Yet, GHBPs possess species-specific properties, and the mechanism for their generation and regulation display evolutionary divergence. Another important aspect is tissue divergence, in terms of
GHR
regulation and its cleavage to
GHBP
. Although
GHBP
is generated mainly from the liver
GHR
, many other tissues express GHRs and probably also contribute to the total
GHBP
level. Human
GHBP
is generated by proteolytic cleavage of
GHR
at the cell-surface and, thus, occupancy or modulation of
GHR
turnover/internalization would impact the level of cell-surface
GHR
that are available for proteolysis. An additional degree of complexity arises from recent reports, implicating a protein kinase C-regulated metalloprotease activity in
GHBP
generation. This suggests that the proteolytic system, which controls the specific cleavage mechanism and switch between
GHR
proteolysis and
GHBP
shedding, is a regulated process. Finally, differential splicing regulation to the full-length, active human
GHR
(hGHR) and the inactive truncated hGHRtr isoform messenger RNA transcripts might regulate both the production of
GHBP
and
GHR
bioactivity, as hGHRtr generates large amounts of
GHBP
but has a dominant negative effect on GH signaling. Several clinical GH-resistant conditions, such as liver cirrhosis, renal insufficiency, insulin-dependent diabetes mellitus, hypothyroidism, malnutrition, or critical illness are associated with reduced
GHBP
levels. However, this is not universally true, as in other conditions (e.g. early childhood, acromegaly) decreased
GHBP
levels are not associated with GHI. Divergence between serum
GHBP
and insulin-like growth factor I, such as which occur during puberty or
obesity
, also questions whether
GHBP
levels reflect
GHR
function. Even in patients with GHI syndrome, serum
GHBP
cannot be relied on to detect all
GHR
mutations. The correct assessment of
GHR
expression and GH functionality in an individual patient will require, in parallel to measurements of serum
GHBP
, additional detailed diagnostic screening of the entire GH-insulin-like growth factor I axis.
...
PMID:Clinical review 112: Does serum growth hormone (GH) binding protein reflect human GH receptor function? 1072 17
In
obesity
, growth hormone (GH) secretion is impaired which is considered a consequence rather than a cause of
obesity
. GH regulates the expression of
GH receptor
and the synthesis of insulin-like growth factor I (IGF-I) in adipocytes. Although GH hyposecretion in
obesity
may decrease the generation of IGF-I in each adipocyte, increased amounts of IGF-I and
GH-binding protein
could be secreted from the excessively enlarged amounts of adipose tissue. This may contribute to the normal/high serum-IGF-I and high
GH-binding protein
levels in
obesity
. Hyperinsulinemia and increased
GH receptor
activity may also affect the GH-IGF-I axis. Favorable effects of GH treatment have been observed in obese children and adults. GH treatment decreases adiposity, reduces triglyceride accumulation by inhibiting lipoprotein lipase and enhances lipolysis both via increased hormone-sensitive lipase activity and via induction of beta adrenoreceptors. GH treatment also has a favorable effect on
obesity
-associated dyslipidemia, but the effects on insulin sensitivity have been conflicting.
...
PMID:Growth hormone and adipocyte function in obesity. 1089 49
The possibility that the action of growth hormone (GH) on cartilage is mediated by a separate hormonal agent found in serum was suggested by incubation with hypophysectomized rat costal cartilage. The stability of this tissue permitted long incubations and the measurement of the uptake of 35S-sulfate provided a convenient index of growth stimulation. Under the conditions arbitrarily selected, normal rat serum, but not serum from hypophysectomized rats, induced a great stimulation of 35S uptake. In contrast, GH added directly to cartilage in these incubations was virtually inactive. It was suggested that a serum sulfation factor, now known as insulin-like growth factor-I (IGF-I), was a mediator of GH action. Recently it has been observed that addition of 35S-sulfate after 24 h of preincubation with GH permitted the direct effect of GH to be recognized. Other observations in intact hypophysectomized rats have established that GH can induce the expression of IGF-I in cartilage that acts in an autocrine-paracrine manner. The relative importance of the endocrine and autocrine-paracrine routes of IGF-I action on the growth of cartilage is in dispute. It is clearly established that serum IGF-I exerts a negative feedback on GH secretion by action on the hypothalamus and pituitary. Serum IGF-I concentrations reflect GH action in postnatal life. Measurement of serum IGF-I is the most-valuable index of GH hypersecretion in acromegaly and in conditions of growth impairment.
GH receptor
deficiency leads to a marked decrease in circulating IGF-I. Hypernutrition and hyperinsulinism of
obesity
directly promote hepatic IGF-I release and inhibit GH secretion by the pituitary. Differences in hepatic IGF-I synthesis in response to GH may contribute to physiological differences in stature.
...
PMID:Growth hormone axis overview--somatomedin hypothesis. 1091 14
Recently, two isoforms of the growth hormone-binding protein (GHBP), which is identical with the extracellular domain of the growth hormone receptor (GHR), have been described. One isoform contains the exon 3 (E3+GHBP) and one excludes the exon 3 (E3-GHBP). The distribution of both isoforms in peripheral blood and their functional relevance is so far unknown. To study the molecular distribution of both species we have analysed sera of 141 subjects with average weight, overweight and
obesity
by newly developed immunoassays. The relationship between the different molecular forms of GHBP and specific parameters of body composition as well as risk factors of metabolic disturbances, were then examined. The extracellular domain of the exon 3-retaining and -deleted isoforms of the GHR are released as E3+GHBP and E3-GHBP into the peripheral circulation. Furthermore, both molecular species do not show any correlation to each other (r = 0.67) and their relative proportion in blood is gender-dependent with a higher E3-GHBP proportion in females (P < 0.01). E3+GHBP appears to have a considerably stronger correlation to indicators (BMI, fat mass, waist circumference) and metabolic risk factors (fasting insulin, uric acid, triglycerides, apolipoprotein B, diastolic blood pressure) of adiposity than E3-GHBP, indicating differences in their functional significance. The availability of assays for the determination of GHBP isoforms may be very important for the study of the
GH receptor
and its soluble extracellular domain, GHBP.
...
PMID:The exon 3-retaining and the exon 3-deleted forms of the growth hormone-binding protein (GHBP) in human serum are regulated differently. 1116 27
Neuroendocrine axes function as an ensemble of regulatory loci which communicate and maintain homeostasis via time-delayed blood-borne signals. The growth hormone (GH)-insulin-like growth factor I (IGF-I) feedback axis sustains a vividly pulsatile mode of interglandular signalling. Pulsatility is driven jointly by hypothalamic GH-releasing hormone (GHRH) and GH-releasing peptide (GHRP), and modulated by somatostatinergic restraint. Paradoxically, intermittent somatostatin inputs also facilitate somatotrope-cell responses to recurrent secretagogue stimuli, thereby amplifying pulsatile GH secretion. A concurrent low basal (8-12% of normal total) rate of GH release is controlled positively by GHRH and GHRP and negatively by somatostatin. Sex-steroid hormones (such as oestradiol and aromatizable androgen) and normal female and male puberty augment GH secretory-burst mass 1.8- to 3.5-fold, whereas ageing, relative
obesity
, physical inactivity, hypogonadism, and hypopituitarism mute the amplitude/mass of pulsatile GH output. An abrupt rise in circulating GH concentration stimulates rapid internalization of the
GH receptor
in peripheral target tissues, and evokes second-messenger nuclear signalling via the STAT 5b pathway. Discrete GH peaks stimulate linear (skeletal) growth and drive muscle IGF-I gene expression more effectually than basal (time-invariant) GH exposure. A brief pulse of GH can saturate the plasma
GH-binding protein
system and achieve prolonged plasma GH concentrations by convolution with peripheral distribution and clearance mechanisms. A single burst of GH secretion also feeds back after a short latency on central nervous system (CNS) regulatory centres via specific brain GH receptors to activate somatostatinergic and reciprocally subdue GHRH outflow. This autoregulatory loop probably contributes to the time-dependent physiologically pulsatile dynamics of the GH axis. More slowly varying systemic IGF-I concentrations may also damp GH secretory pulse amplitude by delayed negative-feedback actions. According to this simplified construct, GH pulsatility emerges due to time-ordered multivalent interfaces among GHRH/GHRP feedforward and somatostatin, GH and IGF-I feedback signals. Resultant GH pulses trigger tissue-specific gene expression, thereby promoting skeletal and muscular growth, metabolic and body compositional adaptations, and CNS reactions that jointly maintain health and homeostasis.
...
PMID:Neurophysiological regulation and target-tissue impact of the pulsatile mode of growth hormone secretion in the human. 1152 85
Present knowledge on the effects of growth hormone (GH)/insulin-like growth hormone (IGF)1 deficiency on ageing and lifespan are reviewed. Evidence is presented that isolated GH deficiency (IGHD), multiple pituitary hormone deficiencies (MPHD) including GH, as well as primary IGE1 deficiency (GH resistance, Laron syndrome) present signs of early ageing such as thin and wrinkled skin,
obesity
, hyperglycemia and osteoporosis. These changes do not seem to affect the lifespan, as patients reach old age. Animal models of genetic MPHD (Ames and Snell mice) and
GH receptor
knockout mice (primary IGF1 deficiency) also have a statistically significant higher longevity compared to normal controls. On the contrary, mice transgenic for GH and acromegalic patients secreting large amounts of GH have premature death. In conclusion longstanding GH/IGF1 deficiency affects several parameters of the ageing process without impairing lifespan, and as shown in animal models prolongs longevity. In contrast high GH/IGF1 levels accelerate death.
...
PMID:Effects of growth hormone and insulin-like growth factor 1 deficiency on ageing and longevity. 1185 84
Obese
patients show marked impairment in spontaneous secretion as well as in the somatotroph responsiveness to all provocative stimuli. GH insufficiency in obese patients has been reported reversible after long-term diet and marked weight loss but somatotroph secretion is not restored by fasting. Among potential neuroendocrine causes, GHRH hypoactivity has been shown but it is likely that alterations in the influence of ghrelin, the gastric-derived natural ligand of the GHS-R, and or of the NPY/leptin interplay could have a role. Among metabolic alterations, the chronic elevation of FFA levels and hyperinsulinism probably have a key role in causing GH insufficiency in
obesity
. Despite marked GH insufficiency, total IGF-I levels are basically preserved while free IGF-I levels are even increased thus questioning real hypoactivity of GH/IGF-I axis in
obesity
. Peripheral GH hypersensitivity due to increased
GH receptor
status, hyperinsulinism and reduced IGFBP-I levels likely explain almost normal total IGF-I and increased free IGF-I levels which, in turn, probably exert an increased negative feedback action on somatotroph cells.
...
PMID:Neuroendocrine and metabolic determinants of the adaptation of GH/IGF-I axis to obesity. 1199 78
Obesity
and starvation have opposing affects on normal physiology and are associated with adaptive changes in hormone secretion. The effects of
obesity
and starvation on thyroid hormone, GH, and cortisol secretion are summarized in Table 1. Although hypothyroidism is associated with some weight gain, surveys of obese individuals show that less than 10% are hypothyroid. Discrepancies have been reported in some studies, but in untreated
obesity
, total and free T4, total and free T3, TSH levels, and the TSH response to TRH are normal. Some reports suggest an increase in total T3 and decrease in rT3 induced by overfeeding. Treatment of
obesity
with hypocaloric diets causes changes in thyroid function that resemble sick euthyroid syndrome. Changes consist of a decrease in total T4 and total and free T3 with a corresponding increase in rT3. untreated
obesity
is also associated with low GH levels; however, levels of IGF-1 are normal.
GH-binding protein
levels are increased and the GH response to GHRH is decreased. These changes are reversed by drastic weight reduction. Cortisol levels are abnormal in people with abdominal obesity who exhibit an increase in urinary free cortisol but exhibit normal or decreased serum cortisol and normal ACTH levels. These changes are explained by an increase in cortisol clearance. There is also an increased response to CRH. Treatment of
obesity
with very low calorie diets causes a decrease in serum cortisol explained by a decrease in cortisol-binding proteins. The increase in cortisol secretion seen in patients with abdominal obesity may contribute to the metabolic syndrome (insulin resistance, glucose intolerance, dyslipidemia, and hypertension). States of chronic starvation such as seen in anorexia nervosa are also associated with changes in thyroid hormone, GH, and cortisol secretion. There is a decrease in total and free T4 and T3, and an increase in rT3 similar to findings in sick euthyroid syndrome. The TSH response to TRH is diminished and, in severe cases, thyroid-binding protein levels are decreased. In regards to GH, there is an increase in GH secretion with a decrease in IGF-1 levels. GH responses to GHRH are increased. The [table: see text] changes in cortisol secretion in patients with anorexia nervosa resemble depression. They present with increased urinary free cortisol and serum cortisol levels but without changes in ACTH levels. In contrast to the findings observed in
obesity
, the ACTH response to CRH is suppressed, suggesting an increased secretion of CRH. The endocrine changes observed in
obesity
and starvation may complicate the diagnosis of primary endocrine diseases. The increase in cortisol secretion in
obesity
needs to be distinguished from Cushing's syndrome, the decrease in thyroid hormone levels in anorexia nervosa needs to be distinguished from secondary hypothyroidism, and the increase in cortisol secretion observed in anorexia nervosa requires a differential diagnosis with primary depressive disorder.
...
PMID:Effect of obesity and starvation on thyroid hormone, growth hormone, and cortisol secretion. 1205 88
Simple childhood
obesity
is characterized by normal or even accelerated growth in spite of reduced growth hormone (GH) secretion. There are conflicting reports on the effects of
obesity
upon components of the GH-insulin-like growth factor-I (IGF-I)-IGF binding proteins (IGFBPs) system. In the present study we aimed to determine GH, IGF-I, IGFBP-3 and IGFBP-2 as well as some of the less explored components of this axis (IGFBP-3 proteolytic activity, IGFBP-3 plasma fragments, and total acid labile subunit [ALS]) in 22 obese and 17 age-matched control children. We also evaluated not only total GH binding protein (GHBP) serum levels but also GHBP bound to GH (complexed) in both groups.
Obese
and control groups strongly differed in BMI (obese: 4.7 +/- 0.36 vs control: 0.37 +/- 0.25 SDS, p <0.0001). In the obese group, we found lower GH serum levels, but normal serum levels of GH-GHBP complex, IGF-I, IGFBP-3, IGF-I/IGFBP-3 molar ratio, IGFBP-3 proteolytic activity, IGFBP-3 plasma fragments and total ALS.
Obese
children presented higher total circulating GHBP (6.0 +/- 0.44 vs 2.9 +/- 0.29 nmol/l, p <0.001) and insulin levels (10.5 +/- 1.5 vs 5.1 +/- 0.8 mU/l, p <0.001), while IGFBP-2 (4.6 +/- 0.5 vs 6.6 +/- 0.7%, p <0.05) and the ratio IGFBP-2/IGF-I (0.032 +/- 0.019 vs 0.095 +/- 0.01, p = 0.013) were lower than in controls. BMI and insulin were directly, and IGFBP-2 serum levels inversely, correlated to total GHBP serum levels when multiple regression analysis was performed (r = 0.74, p <0.001). By stepwise regression analysis, insulin (r = -0.37, p <0.05) and BMI (r = -0.52, p <0.01) inversely determined IGFBP-2. In summary, obese children present normal growth in spite of reduced GH secretion, probably because the combination of increased total GHBP and normal GH-GHBP complex serum levels (suggesting increased
GH receptor
[GHR] number and a normal serum GH reservoir, respectively) allow for the achievement of normal levels of IGF-I, IGFBP-3, IGFBP-3 proteolytic activity, IGFBP-3 plasma fragments and total ALS. Reduced IGFBP-2 serum levels and a lower ratio of IGFBP-2/IGF-I in obese children may suggest an increase of tissue IGF-I bioavailability, thus promoting its action. Normal IGF-I and GH availability may be contributing to maintain normal growth in obese children.
...
PMID:Differential impact of simple childhood obesity on the components of the growth hormone-insulin-like growth factor (IGF)-IGF binding proteins axis. 1523 10
Reduced GH levels are found in
obesity
; despite which IGF-I levels are reported as low normal or normal. Previously peripheral responsiveness to GH has been investigated and reported to be increased in obese men and premenopausal women; however, the use of weight-based GH doses in these studies made data interpretation difficult. GH binding protein (GHBP) measurement constitutes an indirect estimate of
GH receptor
number. GHBP has been reported to be elevated in
obesity
; however, results from a recent study implied that this was only in men and premenopausal but not postmenopausal women. Therefore, we pursued this question further by challenging a cohort of healthy normal-weight and obese subjects with a non-weight-based dose of GH and examined the relationship of GHBP with the IGF-I response in the context of their body composition. Ninety-eight (40 male) healthy subjects with a wide range of ages and body mass index (BMI) were studied. Ninety-one (34 male) of these subjects were divided into groups of similar age: men and women with a BMI less than 30 [normal-weight men (NM), BMI 26 (22-29) kg/m(2) (n = 19) and women (NW), BMI 24 (19-29) kg/m(2) (n = 23) and with a BMI > 30 (obese men (OM), 41 (30-72) kg/m(2) (n = 15) and women (OW), 43 (30-68) kg/m(2) (n = 34)]. Fat mass and percentage fat were measured by a bioelectrical impedance analyzer. An IGF-I generation test, which involved a sc injection of 21 IU (7 mg) GH, was performed. At baseline serum samples were assayed for GHBP; serum IGF-I and IGFBP3 levels were measured both at baseline and 24 h after GH administration. There was a higher increment IGF-I in obese men and women, compared with the equivalent normal-weight subjects [NM vs. OM: 245 (33-342) vs. 291 (192-427) ng/ml (P < 0.05); NW vs. OW: 220 (103-435) vs. 315 (144-450) ng/ml (P < 0.0005)]. Increment IGF-I was negatively correlated with baseline IGF-I (F = 12.1) and positively correlated with GHBP (F = 18.2) (R(2) = 0.29). GHBP levels were significantly higher in OM and OW (pre- and postmenopausal) than in the equivalent normal-weight groups [NM vs. OM: 2175 (995-4190) vs. 3030 (1540-5470) pmol/liter (P < 0.05); NW vs. OW: 2131 (1010-5040) vs. 3585 (1540-5740) pmol/liter (P < 0.0005)]. GHBP levels correlated highly with BMI, percentage fat, and fat mass (R > 0.6, P < 0.0001). Baseline IGF-I was not affected by body composition. In conclusion, in obese compared with normal-weight healthy subjects, there is a larger increment IGF-I to a single bolus of GH in men, and irrespective of menopausal status, women. Increment IGF-I is associated positively with GHBP level, which in turn is associated with markers of increasing
obesity
in men and women. GH responsiveness is increased in
obesity
.
...
PMID:Insulin-like growth factor-I response to a single bolus of growth hormone is increased in obesity. 1552 43
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