Gene Genes for human growth hormone, known as
growth hormone 1 (somatotropin; pituitary growth hormone) and
growth hormone 2 (placental growth hormone; growth hormone variant), are localized in the q22-24 region of chromosome 17 and are closely related to
human chorionic somatomammotropin (also known as
placental lactogen) genes. GH, human chorionic somatomammotropin, and
prolactin belong to
a group of homologous hormones with growth-promoting and lactogenic activity.
Structure The major isoform of the human growth hormone is a protein of 191
amino acids and a molecular weight of 22,124
daltons. The structure includes four helices necessary for functional interaction with the GH receptor. It appears that, in structure, GH is evolutionarily homologous to prolactin and chorionic somatomammotropin. Despite marked structural similarities between growth hormone from different
species, only human and
Old World monkey growth hormones have significant effects on the human
growth hormone receptor. Several
molecular isoforms of GH exist in the pituitary gland and are released to blood. In particular, a variant of approximately 20 kDa originated by an alternative splicing is present in a rather constant 1:9 ratio, while recently an additional variant of ~ 23-24 kDa has also been reported in post-exercise states at higher proportions. This variant has not been identified, but it has been suggested to coincide with a 22 kDa glycosylated variant of 23 kDa identified in the pituitary gland. Furthermore, these variants circulate partially bound to a protein (
growth hormone-binding protein, GHBP), which is the truncated part of the
growth hormone receptor, and an acid-labile subunit (ALS).
Regulation Secretion of growth hormone (GH) in the pituitary is regulated by the
neurosecretory nuclei of the
hypothalamus. These cells release the peptides
growth hormone-releasing hormone (GHRH or
somatocrinin) and
growth hormone-inhibiting hormone (GHIH or
somatostatin) into the
hypophyseal portal venous blood surrounding the pituitary. GH release in the pituitary is primarily determined by the balance of these two peptides, which in turn is affected by many physiological stimulators (e.g., exercise, nutrition, sleep) and inhibitors (e.g., free fatty acids) of GH secretion.
Somatotropic cells in the
anterior pituitary gland then synthesize and secrete GH in a pulsatile manner, in response to these stimuli by the hypothalamus. The largest and most predictable of these GH peaks occurs about an hour after onset of sleep with plasma levels of 13 to 72 ng/mL. Maximal secretion of GH may occur within minutes of the onset of
slow-wave (SW) sleep (stage III or IV). Otherwise there is wide variation between days and individuals. Nearly fifty percent of GH secretion occurs during the third and fourth
NREM sleep stages. Surges of secretion during the day occur at 3- to 5-hour intervals. Between the peaks, basal GH levels are low, usually less than 5 ng/mL for most of the day and night. A number of factors are known to affect GH secretion, such as age, sex, diet, exercise, stress, and other hormones. Sleep deprivation generally suppresses GH release, particularly after early adulthood. Stimulators of growth hormone (GH) secretion include: • Peptide hormones •
GHRH (
somatocrinin) through binding to the growth hormone-releasing hormone receptor (
GHRHR) •
Ghrelin through binding to growth hormone secretagogue receptors (
GHSR) • Sex hormones • Increased
androgen secretion during puberty (in males from testes and in females from adrenal cortex) •
Testosterone and
DHEA •
Estrogen •
Clonidine,
moxonidine and
L-DOPA by stimulating GHRH release •
α4β2 nicotinic agonists, including
nicotine, which also act synergistically with
clonidine or
moxonidine. •
Hypoglycemia,
arginine,
pramipexole,
ornitine,
lysine,
tryptophan,
γ-Aminobutyric acid and
propranolol by inhibiting
somatostatin release •
Glucagon •
Sodium oxybate or
γ-Hydroxybutyric acid •
Niacin as nicotinic acid (vitamin B3) •
Fasting •
Insulin • Vigorous
exercise Inhibitors of GH secretion include: •
GHIH (
somatostatin) from the
periventricular nucleus • circulating concentrations of GH and
IGF-1 (
negative feedback on the pituitary and
hypothalamus) •
Dihydrotestosterone •
Phenothiazines In addition to control by endogenous and stimulus processes, a number of foreign compounds (
xenobiotics such as drugs and
endocrine disruptors) are known to influence GH secretion and function.
Function Effects of growth hormone on the tissues of the body can generally be described as
anabolic (building up). Like most other peptide hormones, GH acts by interacting with a specific
receptor on the surface of cells. Increased height during childhood is the most widely known effect of GH. Height appears to be stimulated by at least two mechanisms: • Because
polypeptide hormones are not fat-
soluble, they cannot penetrate
cell membranes. Thus, GH exerts some of its effects by binding to receptors on target cells, where it activates the
MAPK/ERK pathway. Through this mechanism GH directly stimulates division and multiplication of
chondrocytes of
cartilage. • GH also stimulates, through the
JAK-STAT signaling pathway, The
liver is a major target organ of GH for this process and is the principal site of IGF-1 production. IGF-1 has growth-stimulating effects on a wide variety of tissues. Additional IGF-1 is generated within target tissues, making it what appears to be both an
endocrine and an
autocrine/
paracrine hormone. IGF-1 also has stimulatory effects on
osteoblast and
chondrocyte activity to promote bone growth. In addition to increasing height in children and adolescents, growth hormone has many other effects on the body: • Increases
calcium retention, and strengthens and increases the
mineralization of bone • Increases
muscle mass through
sarcomere hypertrophy • Promotes
lipolysis • Increases protein synthesis • Stimulates the growth of all internal organs excluding the
brain • Plays a role in
homeostasis • Reduces
liver uptake of
glucose • Promotes
gluconeogenesis in the liver • Contributes to the maintenance and function of
pancreatic islets • Stimulates the
immune system • Increases deiodination of T4 to T3 • Induces insulin resistance ==Biochemistry==