Hypothalamus and
adenohypophysis functions.
Neuroendocrine regulation
THALAMUS
- NON-SPECIFIC NUCLEI
- SPECIFIC SENSORY NUCLEI
- SPECIFIC NONSENSORY NUCLEI
- ASSOCIATION NUCLEI
HYPOTHALAMUS
- SYSTEM OF SEVERAL DOZENS OF NUCLEI
- PARAVENTRICULAR
- MEDIAL
- LATERAL REGION
HYPOPHYSIS
- PARS DISTALIS (STH, PRL, TSH, FSH, LH,ACTH)
- PARS TUBERALIS (FSH, LH)
- PARS INTERMEDIA (MSH)
HypothalamusVentrolateral medulla
(heart, stomach)
Amygdala
(associative regions of neocortex,
olfactory bulb, hippocampal
formation, subcortical structures
including brain stem)
Hippocampus
(associative regions of neocortex,
thalamus, reticular formation
nuclei, etc.)
Nucleus solitarius
(viscerosensory information–
heart, lungs, GIT, blood vessels –
baro-/chemoreceptors) Locus coeruleus
(prefrontal cortex, N.
paragigantocellularis –
integration of external and
autonomic stimuli – stress,
panic)
Orbitofrontal cortex
(sensory perception, reaction to
reward/punishment)
Body temperature
regulation
Neuroendocrine
regulation
Appetitive behavior
(hunger, thirst, sexual
behavior)
Defensive reactions
Autonomic nervous
system (modulation)
Biorhythms and their
regulation
Lamina terminalis
(blood, blood
composition)
Behavior
Circumventricular organs
CC – corpus calosum
OC – chiasma opticum
ac – commisura anterior
pc – commisura posterior
AP – area postrema
CP – choroid plexus
ME – eminentia mediana
NH – neurohypophysis
OVLT – organum vasculosum
laminae terminalis
PI – pineal gland/epiphysis
SCO – subcommissural organ
SFO – subfornical organ
Eminentia mediana
- Afferent sensoric organ
- Functional connection of
hypothalamus and hypophysis
- Point of entry of some hormones from
circulation (fenestration) – leptin
- CONVERSION - HUMORAL FACTORS –
HYPOTHALAMIC REGULATION
NEURONS
OVLT
- Regulation of autonomous
processes
- Febrile regulation
- Blood osmolality
- Regulation of secretion of GnRH
stimulated by estrogens
Subfornical organ
- Body fluid homeostasis
- Blood pressure regulation (R for ANP and ATII)
- Oxytocin secretion regulation
Area postrema
- Afference (n. vagus, n.
glossopharyn-geus)
- R for GLP-1 and amylin
- Chemosensoric neurons with osmoR
- „detection“ of toxins
- coordinated regulation of blood
pressure (R for ATII, ADH, ANP)
Subcommissural organ
- Mainly unknown function
- R for neuropeptides and
neurotransmitters
- ? Production of somatostatin
- „catching“ of monoamines from CSF
Anatomical and functional connection of hypothalamus and
hypophysis
Neurosecretion
SON – supraoptic nucleus
PVH – paraventricular nucleus
PeVH – periventricular nucleus
Arc – arcuate nucleus
LHA – lateral hypothalamic region
Magnocellular and parvocellular neurons –
neurotransmitters and neuromodulators
Magnocellular neurons
Parvocellular neurons
Paraventricularnucleus
Arcuatenucleus
- Angiotensin II
- Cholecystokinin (CCK)
- Dynorphins
- Glutamate
- Nitric oxide
- Oxytocin
- ADH
- Angiotensin II
- GABA
- ANP
- CCK
- GRP
- neuromedin B
- CRH
- dopamine
- Endocannabinoids
- Enkephalins
- Galanin
- IL-1
- Neuropeptide Y
- Nitric oxide
- SST, TRH
- VIP
- Acetylcholin
- GABA
- Agouti-related peptid
- CART
- Dopamine
- Dynorphin
- Endocannabinoids
- Enkephalins
- Galanin, Galanin-like peptid (GALP)
- Glutamate
- GnRH
- GHRH
- Kisspeptins
- Melanocortins, including ACTH
- Neurokinin B
- Pancreatic polypeptide
- Prolactin
- POMC
- SST
- etc.
Hypothalamic hormones
Hypothalamic hormones are secreted in eminentia
mediana region and enter portal circulation via
fenestrations
Axons of oxytocin and ADH synthesizing neurons go
through eminentia mediana region. Hormones are
secreted in neurohypophysis
PIH (prolactin-inhibiting hormone) = dopamine
Environmental factors
Neural stimuli
Hormonal stimuli
Synthesis and secretion
of hypothalamic
hormones
Signal integration to regulate endocrine functions and to maintain hoemeostasis
Thyreoliberin (TRH, thyrotropin-releasing hormone)
Characteristics
- Phylogenetically very old peptide (primitive vertebrates)
- Central and peripheral effects
Hypothalamo-hypophyseal axis
- Regulation of TSH and PRL secretion (prolactinemia, galactorea)
- No effect on other AH hormones secretion (exception – stimulation of
GH secretion during acromegaly, liver diseases, anorexia nervosa,
psychotic depression; stimulation of ACTH secretion during Cushing's
syndrome)
Other places of TRH synthesis/secretion
- cortex cerebelli
- Circumventricular structures
- Neurohypophysis
- Endocrine pancreatic cells
- GIT
- Heart (positive inotropy and chronotropy)
- Neuromodulator function
- Role in central thermoregulation
Clinical significance
- In the past – hyperthyroidis
diagnosis (hypothalamic X
hypophyseal causes)
- Possible role in depression
treatment, spinal muscular atrophy
and amyotrophic lateral sclerosis
- Treatment of some syndromes
(West, Lannox-Gastaut, early
infantile epileptic encephalopathy)
Thyreoliberin
- regulation of secretion
- Neural control
- Circadian rhythm (maximum between 21:00 and
5:00 and between 16:00 and 19:00, peaks in 90–
180 min intervals
- Temperature (cold) – higher synthesis among
people from colder regions in winter – together
with autonomic nervous system (catecholamines)
- Stress – TRH synthesis and secretion inhibition
(indirect negative feedback loop between
glucocorticoids and effect on hippocampus)
- Starvation – TRH secretion decrease („saving“
energy); effect of leptin
Cortikoliberin (CRH, corticotropin-releasing hormone)
Characteristics
-Important part of CNS stress response modulation
-Group of related peptides (CRH, urocortin, urocortin II, urocortin III,
urotensin, sauvagin) with different CNA distribution and CRH-R1 and CRHR2
affinity
-Exclusively CRH-R1 corticotropic cells (AC)
-CRH-1 – neocortex, cerebellar cortex, subcortical structures of limbic
system, amygdala, ovaries, endometrium, skin
-CRH-binding protein
Hypothalamo-hypophyseal axis
- Fast ACTH secretion
Other places of CRH synthesis/secretion
- Limbic system
- Amygdala, substantia nigra
- Nucleus tractus solitarius
- Parabrachial nucleus
- Placenta (3rd trimester)
- Lymphocytes, autonomic nerves, GIT
- Cardiovascular system
- Behavior, fear, anxiety regulation
- Anorexigenic factor
- Increased sympathetic tone
Clinical significance
- Potential treatment of obesity
- CRH-R1 antagonists – anxiety and
depression treatment
- Blood pr. regulation (decrease)
- Negative chronotropy
- Immune system, reproduction
Corticoliberin –
regulation of secretion
- Neural control – various stressors
- Hypothalamo-hypophyseal axis activation
- Sympathoadrenal axis activation
- ADH and oxytocin binding
- Ensuring requirements in emergency
situations
- Inflammation and cytokines
- IL-1B and hypothalamo-hypophyseal axis
activation
- Circadian rhythms - diurnal rhythms
Somatoliberin (GHRH, growth hormone-releasing hormone)
Characteristics
- Two types present in hypothalamus
- GHRH receptor (cAMP)
- R – homology with R secretin, GLP-1, glucagon, calcitonin, PTH, PTHrP
Hypothalamo-hypophyseal axis
- Fast GH secretion
- GHRH is not the only GR secretion modulator!
- Synergy with estrogens, glucocorticoids and starvation
- Somatostatin, age and obesity – decreased secretion
Other functions and places of synthesis
-Sleep regulation (SCN)
-Orexigenic factor
-Wound healing - skin
-Ovaries, uterus
-Placenta
- Unknown role
- Possible alternative splicing
Clinical significance
- Nowadays without clinical significance
- GHRP
Somatostatin (GHIH, growth hormone–inhibiting hormone )
Characteristics
- SST-14 (CNS) and SST-28 (GIT)
- Neurotransmitter – neuromodulator
- SSTR1-SSTR5 (GP – cAMP – PLC, PLA, MAPK, ion channels)
- diverse receptor distribution (mainly CNS)
- SSTR5 – insulin secretion inhibition
- SSTR2 – glucagon secretion inhibition
Hypothalamo-hypophyseal axis
- GH secretion regulation
- TSH inhibition
- PRL and ACTH secretion inhibition
Other functions and places of synthesis
- Myenteric plexus
- Epithelial GIT cells
- Endocrine pancreas – autocrine and paracrine
- Cortex, lateral septum, amygdala, thalamic reticular nucleus
- Hippocampus, brain stem nuclei
- Cortistatin with SSTR1-5 affinity – neuromodulator (ant. Ach)
- neurotransmitter
- paracrine
Clinical significance
- Somatostatin analogues (octreotide,
lanreotide, vapreotide, seglitide,
pasireotide)
- Therapy of acromegaly, TSH
producing or neuroendocrine tumors
- ! Negative GIT side effects
- Imaging methods (111In-somatostatin)
- Potential use in tumor treatment
Main effects of somatostatin
Inhibition of hormone secretion GIT inhibition Other
Adenohypophysis – TSH, GH, ACTH,
PRL
Stomach and duodenal secretion
including HCl
Inhibition of activated immune
cells
GIT – gastrin, secretin, motilin,
GLP-1, GIP, VIP
Stomach emptying Inhibition of tumor growth
(proliferation)
Endocrine pancreas – insulin,
glucagon, (somatostatin)
Pancreatic enzymes and
bicarbonates secretion
Kidneys - renin Bile secretion
Decrease of GIT blood flow
Stimulation of intestinal water and
electrolytes absorption
- GHRH secretion stimulation
- Ghrelin
- Leptin
- Galanin
- GABA
 a2-adrenergic and dopaminergic input
- GRHR secretion inhibition
- CRH
 b2-adrenergic input
- Somatostatin secretion inhibition
- Ach
- 5-HT-1D
Somatoliberin, somatostatin
– regulation of secretion
Stimulation of GH secretion
Physiological factors Hormones and neurotransmitters Pathological factors
Exercise Arginin, lysin Acromegaly
Stress (various causes) Neuropeptides (ghrelin, RHRH, galanin,
opioids – m receptors, melatonin)
TRH, GnRH
Sleep Neurotransmitters (agonists a2-AR,
antagonists b-AR, M1 agonists, 5-HTD1
agonists, H1 agonists)
Glu, Arg
Decrease in postprandial glycemia GABA IL-1, 2, 6
Starvation Dopamine (D2R) Protein depletion
Insulin-induced hypoglycemia Estrogens Starvation, anorexia nervosa
Testosterone Kidney failure
Glucocorticoids (acute, not chronic) Liver cirrhosis
DM 1st type
Inhibition of GH secretion
Physiological factors Hormones and neurotransmitters Pathological factors
Postprandial hyperglycemia, glucosis
infusion
Somatostatin Acromegaly
Increased FAA in plasma Calcitonin L-DOPA
Increased GH concentration in plasma Neuropeptide Y D2R agonists
Increased IGF-1 concentration in plasma CRH Phentolamin
REM sleep Neurotransmitters (a1,2-AR
antagonists, b-AR agonists, H1
antagonists, serotonin receptor
antagonists, nicotine cholinergic
receptor agonists)
Galanin
Aging Glucocorticoids (chronic) Obesity
Hypothyroidismus
Hyperthyroidismus
Dopamine (PIH, prolactin-inhibiting hormone)
Characteristics
- D2R (G protein inhibition, AC, cAMP decrease, inhibition of shaker type
K+ channels, MAPK, PAK – proliferation!)
- D1R (activation)
Hypothalamo-hypophyseal axis
- Inhibition of PRL (D2R) secretion – lactotropic cells
- ! Lactotrophs with continual high PRL production
- PRL secretion regulated also on adenohypophysis level (paracrine,
autocrine)
- Neuroendocrine regulation of PRL secretion – pregnancy, lactation,
menstrual cycle, sensoric inputs
Other functions and places of synthesis
- Blood vessels – vasodilatation (physiological concentrations)
- Kidneys – sodium secretion
- Endocrine pancreas – decrease in insulin secretion
- GIT – lower motility
- Effect of dompamine on immune system
Clinical significance
- Effect of medication on dopamine
and PRL secretion
- Cardial shock
- Neurodegenerative diseases
(Parkinson)
- Antipsychotics (antag.)
- Important feedback mechanism (short loop) of PRL
secretion regulation
- Circadian rhythm (maximum in the morning)
- Nipple stimulation (1-3 min, peak 10 – 20 min)
- Relevance of studying PRL secretion and its regulation -
psychopharmaceutics!
Dopamine – regulation of
secretion
PROLACTIN-RELEASING FACTORS (PRF)
- TRH, oxytocin, VIP
- under specific conditions ADH, ATII, NPY, galanin,
substance P, GRP, neurotensin
- prolactin-releasing peptide (PrRP) – stress, satiety
(other parts of CNS)
Enkephalin, dynorfin
(m a k receptors)
Gonadoliberin (GnRH, Gonadotropin-Releasing Hormone)
Characteristics
- Specific origin of GnRH neurons outside of CNS
- GnRH-I, GnRH-II, (GnRH-III) – Gq/11 (PKC, MAPK)
- Important up- and down- regulation (steroid hormones, gonadotropic
hormones)
- Downregulation – malnutrition, lactation, seasonal effects, aging,
continual GnRH
- Upregulation – effect of GnRH on gonadotrophs (menstrual cycle)
- GNRH1 – hypothalamus; GNRH2 – other parts of CNS
Hypothalamo-hypophyseal axis
- FSH, LH
- Importance of GnRH pulses frequency (glycosylation)
- Menstrual cycle, puberty and its onset
Other functions and places of synthesis
- CNS – neurotransmitter (preoptic region)
- Placenta
- Gonads
- Tumor tissue (prostate, endometrium)
Clinical significance
- Continually distributed analogues of
GnRH – treatment of estrogen/steroiddependent
tumors of reproductive
system
- Premature puberty treatment
(leuprorelin – agonist!)- Unknown function
- Inputs from various CNS regions (brain stem,
limbic system)
- Predominant inhibitory effect of sex-hormones
with exception of estradiol (negative/positive
feedback)
- Importance of kisspeptin for females
- Inhibitory effect of PRL
- Effect of circulating substrates (FA, Glu)
- Leptin (NPY, kisspeptin)
- Stress (various causes)
- Acute – disruption of MC without effect on
fertility
- Chronic – disruption of fertility, lowering of
circulating sex-hormones levels
Gonadoliberin –
regulation of secretion
Neurohypophysis
Synthesis - magnocellular neurons (SON, PVN)
Termination (neurohypophysis, eminentia mediana)
Precursor protein (signal peptide, hormone,
neurophysin 2, glycopeptide copeptin)
Posttranslational modification – ADH/OT +
neurophysins + copeptin
Secretion – voltage-gated Ca2+ channels
Circulation – free, elimination – kidneys, liver
Neurophysins – importance – ADH transport and
secretion
Oxytocin
Characteristics
- Mechanoreceptors/tactile receptors
- Magnocellular neurons (PVN, SON)
- inhibition by endogenous opioids, NO, GABA
- Autocrine (+ ZV)
- Prolactin, relaxin (-), Estrogens (+)
- OXT receptors (Gq/11) – effect of up/down regulation
- Works together with prolactin and sex hormones
Functions
- Lactation (under 1 min)
- Childbirth
- rhythmical contractions of smooth muscles (gapjunction,
stimulation of prostaglandin synthesis –
extracellular matrix)
- postpartum bleeding
- uterus involution
- Ejaculation (males)
- Behavior
Other functions and places of synthesis
- CNS
- Stimulation of ACTH secretion through CRH
- Stimulation of ADH/induced vasoconstriction
- Stimulation of prolactin secretion
- Memory traces recollection inhibition
- Maternal behavior
Clinical significance
- Oxytocin analogues
OT receptors
- OXT receptors (Gq/11)
- Myoepithelial cells
- Myometrium
- Endometrium
- CNS
- PLC, IP3, Ca2+
- Target molecule – MLCK (myosin
light chain kinase)
Antidiuretic hormone (ADH, vasopresin, AVP)
Characteristics
- Magnocellular neurons (PVN, SON)
- AVP receptors (G protein)
- V1R - V1a (Gq/11) – liver, smooth muscles, CNS, adrenal glands –
only ligand ADH
- V2R (Gs) – kidneys
- V3R - V1b (Gq/11) – corticotropic cells (CNS), kidneys, thymus,
heart, lungs, pancreas, uterus
Function
- Water reabsorption (distal tubule, collecting tubule) –
tubular system with different water permeability in different
parts
- AQP1 – proximal tubule, HL descending limb HK – 90 % of
water reabsorption
- AQP2 – collecting tubule (only ADH; acute X chronic effect)
- AQP3, AQP4
- Vasoconstriction (hemorrhagic shock, sepsis)
Other functions and places of synthesis
- CNS – increased recollection of memory traces
- Periphery – stimulation production of factor VIII and von
Willebrand factor
phosphorylation
ADH - regulation of secretion
- Osmotic regulation
- Regulation volume-pressure
- Predominantly inhibitory effect of R on
magnocellular N
ADH is the main hormone regulating water
homeostasis and osmolality, RAAS is the main
regulatory system of blood volume and pressure.
ADH – osmotic regulation of secretion
- Organum vasculosum laminae terminalis (OVLT) – „Osmostat“
- Insensitivity to urea and glucose
- AQP2
- Acute effect (min.)
- Chronic effect – circulating ADH (together with AQP3) – stays up to
24 hours
plasma
urine
urine
Thirst
- Increase of plasma osmolality (2 – 3 %)
- Lower IVF volume (over 10 %, usually 20 – 30 %)
- Frontal region of hypothalamus – osmoreceptors
- Low- and high-pressure baroreceptors
- Together with ATII
Max. 1.0 – 0,5 pg/ml
Pregnancy – RESET OSMOSTAT
- Decresed osmolality, increased IVF volume
- from 5th – 8th week to 2nd week after birth
- Vasodilatation
- Effect of relaxin (+) and estrogens (+ NO)
Old age – lower sensitivity to ADH, hypo-/hypernatremia
Vasoconstrictive effect of ADH
Ca2+.CaM
MLCK activation
Increased activity of myosin
ATPase
IP3 and mobilization of Ca2+
ADH – clinical aspects
Diabetes insipidus (DI)
- Primary polydipsia
- Decreased ADH synthesis/secretion (ADH gene)
(neurogenic)
- Decreased kidney sensitivity (nephrogenic)
SIADH – Syndrome of Inappropriate Antidiuretic
Hormone Secretion
- Increased ADH synthesis/secretion
- Absence of physiological ADH secretion stimuli
Absence of thirst after osmotic stimulation
Ethanol lowers ADH secretion
Unregulated ADH secretion
Increased basal
ADH secretion
Reset of osmostat
Decreased ADH
secretion
Adenohypophysis
HORMONE PRODUCTION UNDER DIRECT HYPOTHALAMIC CONTROL
- ACTH – adrenocorticotropic hormone
- TSH – thyreotropic hormone
- GH – growth (somatotropic) hormone
- PRL – prolactin
- LH – luteinizing hormone
- FSH – follicle-stimulating hormone
Adenohypophyseal
cells
Represent
ation
Hypothalamic
hormone(s)
Adenohypophyseal
hormones
Localization
Lactotropic Up to 25 % Dopamine prolactin whole AH
Cortikotropic Ca 20 % CRH POMC – ACTH, bLPH,
a-MSH, b-end.
Anteromedial
region
Thyreotropic Ca 5 % TRH TSH Anteromedial
region
Gonadotropic Up to 15 % GnRH LH/FSH Posterolateral
region
Somatotropic Ca 40 % GHRH/GHIH GH Posterolateral
region
Adenohypophyseal hormones
Nerveendings–eminentiamediana
neurohormones
+/- Receptor(Gprot.)
Suprachiasmatic nucleus Circulating hormones Feedback system
Circadian
rhythms
Sleep
(dwaves
Sleep–TSH
(st.1st,2ndNREM)
Physiologicaleffect–homeostasismaintainance
Adenohypophyseal hormones
G protein-coupled receptors
JAK/STAT signaling
Glycoproteins - TSH
Characteristics
- Heterodimer
 b subunit – transcriptional factors GATA2 and Pit1
- Negative feedback T3 – inhibition of a subunit transcription;
dopamine (a and b)
- Positive feedback – TRH
- Co-translational glycosylation and folding (- T3, + TRH)
Function
- Stimulation of thyroid hormones synthesis
- Growth hormone for thyroid gland
Secretion regulation
- 2-3 h pulse + tonic non-pulsatile secretion
- Peak between 23:00 and 5:00
- Stable for 24 hrs. Secretion without other factors (gender, BMI, etc)
- TRH (paracrine), transporters OATP and MCT
- T3 – deiodinases 2 (+T3) and 3 (-T3) with different expression
- Catecholamines – increased of setpoint for TRH inhibition
- Somatostatin (-), glucocorticoids (-), NSA (-)
- Dopamine (-)
Clinical significance
- TSH deficiency (mutation in genes coding
TRH and TSH receptors)
- Analogues of somatostatin
- ! (+) cortisol metabolism
Glycoproteins – FSH a LH
Characteristics
- Heterodimer, different expression of subunits, glycosylation
- Structurally close to hCG (placenta)
Regulation of secretion
- sex hormones, local factors – paracrine (activins, inhibins,
follistatin)
- (+) – glutamate, noradrenaline, leptin
- (-) – GABA, opioids
- Key role of kisspeptins, neurokinin B and substance P in
GnRH secretion – FSH/LH
- Estrogens, progesterone, androgens – direct influence on
gonadotrophs, indirect influence through GnRH
- Estrogens (-) – inhibition of transcription (a),
kisspeptin – NEG
- Estrogens (+) shift
- Progesterone (-) – influences pulsatile secretion of
GnRH
- Testosterone, estradiol (-) – males, kisspeptin neurons
and AR
- GnRHR – Ca2+ mobilization
- Different half-life for circulating LH and FSH
Activins and inhibins
Inhibins
– dimeric peptides (a + 1 or two bA or bB)
– circulating hormones produced by gonads
– inhibin A – dominant follicle, corpus luteum
– inhibin B – testes, luteal and early follicular phase of MC
Activins
– dimeric peptides – dimers of b subunits
–FSH stimulation
– autocrine/paracrine factors
– other tissues – growth and differentiation
Folllistatin
– monomeric polypeptide
– FSH inhibition
- „supplementary “ regulation of FSH and LH secretion
- activins = regulation of transcription, follistatin and inhibins =
inhibition of activins through appropriate activin-receptor binding
FSH and LH functions
FEMALES
- FSH
- Growth and development of follicular cell (maturation)
- Biosynthesis of estradiol
- Regulation of inhibin synthesis during follicular phase
- Upregulation of LH receptors (preovulatory follicles)
- Selection of dominant follicle
- Recruitment of follicles for next cycle
- LH
- Stimulation of estrogen synthesis on various levels (theca)
- Oocyte maturation (preovulatory follicle)
- Rupture of ovulatory follicle, ovulation
- Conversion of follicle wall to corpus luteum
Clinical significance
- Possible deficiency of gonadotropins
- Hypogonadotropic hypogonadism
- Kallmann syndrome
- Syndrome Prader-Willi
- Reproductive dysfunction
MALES
- LH
- Intratesticular synthesis of testosterone (Leydig cells)
- FSH
- Spermatogenesis (Sertoli cells)
Proopiomelanocortin
- POMC
Characteristics
-Adenohypophysis - short transcript
-CNS
-Placenta
-Skin
-Gonads
-GIT
-Liver
-Kidneys
-Adrenal medulla
-Lungs
-Lymphocytes
Stimulation of expression
-CRH, cytokines, ADH, catecholamines, VIP
Posttranslational modification
- Role of prohormone convertases (PCs)
long transcript with synthesis of
products regulating energetic
metabolism
Functions of POMC-derived peptides
Adrenal glands - ACTH
- the only POMC hormone with effect on adrenal
glands
- MC2R receptor for melanocortin)
- Glucocorticoids, androgens, (mineralocorticoids)
- Mitogennic effect on adrenal glands (N terminal
peptide)
Skin pigmentation – ACTH, b-LPH, g-LPH
- MC1R
- Paracrine regulation (melanocytes, keratinocytes)
Regulation of appetite – a-MSH
- Inhibition of inhibitory effect of leptin
- Activation of MC3R and MC4R (hypothalamus)
Immune functions – a-MSH
- Inhibition of leukocyte migration
- Inhibition of macrophage functions
- Modulation of antigen-presenting and T cells
Analgesia – b-endorphin
- Circulating probably without effect on CNS
Placental POMC
- 2nd trimester
- Decrease 3 days after birth
- No correlation to ACTH/cortisol of mother
- Unknown physiological function
Ectopic synthesis of POMC/ACTH
- Mainly tumors with ability of posttranslational
changes
ACTH
Secretion
-Circadian and ultradian rhythms
-Rise from 16:00 with peak before 19:00
-Lowest levels between 23:00 and 3:00
-pulsatile secretion (ca 40/day, higher in males)
ACTH and stress
- Complex – peripherial and central stress adaptors
- Vasovagal and sympathetic activation (catecholamines), cytokine secretion
- Pain, infection, inflammation, bleeding, hypovolemia, trauma, hypoglycemia, psychological stress
- Higher amplitude of ACTH pluses
Secretion regulation
- Very complex - neuroendocrine control of stress response and homeostasis
- Regulatory molecules – CNS, hypothalamus (CRH, ADH, dopamine) – corticotropic cells
- Cytokines (IL-6, LIF), growth factors – adenohypophysis – local control (paracrine)
- Glucocorticoids
- Negative feedback mechanism – inhibition of CRH secretion, decrease of basal
ACTH secretion
- Modulation of somatostatin inhibitory effect (downregulation of R)
- Dopamine
- Physiological regulation of secretion – exercise (athletes – hypercortisolism)
Function
- Adrenal glands size,
structure and function
- Steroidogenesis stimulation
Clinical significance
- Deficiency ACTH
- Hypersecretion of ACTH
- Testing - insulin
Prolactin - PRL
Characteristics
- Lactotropic cells (only PRL)
- Mammosomatotropic cells (PRL and GH)
- Hyperplasia – pregnancy and lactation
- Expression regulated by estrogens, dopamine, TRH, thyroid hormones
- Polypeptide circulating in three forms (mono-, di-, polymer)
- Monomeric PRL with highest biological activity
- Monomeric prolactin further spliced (8/16 kDA)
- 16 kDA PRL – antiangiogenic function
- PRLR – mammary gl., adenohypophysis, adrenal gl., liver, prostate,
ovaries, testicles, small intestine, lungs, myocardium, SNS, lymphocytes
Regulation of secretion
- pulsatile secretion – 4 – 14 pulses/day
- Highest levels during sleep (REM, nonREM)
- Lowest between 10:00 and 12:00
- Lower secretion with aging
- TIDA cells – dopamine (-, D2R)
- Paracrine – endothelin-1, TGF-b1, calcitonin, histamine (-)
- FGF, EGF (+)
- TRH, estrogens, VIP, serotonin, GHRH in higher concentrations (+)
- Cholecystokinin - ?
Prolactin - functions
Production of breast milk during pregnancy and lactation =
function necessary for survival
Other functions – metabolic, melanin synthesis, maternal
behavior
Development of mammary gland and lactation
- Puberty – development of mammary gland due to GH
and IGF-1
- Effect of estrogens and progesterone
- At age 8 – 13
- During pregnancy proliferation of alveoli and
production of breast milk proteins and colostrum
- During third trimester – colostrum production (PRL,
estrogens, progesterone, GH, IGF-1, placental
hormones)
- Lactation – increase of PRL after birth, without breastfeeding
decrease after ca 7 days
- Accumulation of breast milk stops further production
- Role of OT
Reproductive function of PRL
- Lactation = amenorrhea and secondary infertility
- Inhibition of GnRH secretion
- Role of kisspeptin neurons (PRLR)
- Possible role of metabolic factors
Immune function of PRL
- Antiinflammatory effect ?
Clinical significance
- hyperprolactinemia – drugs including some
antihypertensives, chronic kidney failure
- Macroprolactinemia
- Galactorrhea – role of GH (acromegaly)
- PRL deficiency
Growth hormone (GH)
Characteristics
-hGH genome – 5 products including human chorionic
somatomammotropin
-hGH-N – somatotrophs – 20/22 kDA
-hGH-V – placenta – feedback regulation
-Circulating GH:
- 20 (25 %) and 22 kDA (75 %) monomers
- Acetylated 22 kDA form
- Deaminated forms
Regulation of secretion
-GHRH, somatostatin, ghrelin, IGH-1, thyroid hormones,
glucocorticoids
-Relatively complicated system of regulation:
- Neuropeptides
- Neurotransmitters
- Endogenic opioids
Growth hormone (GH) – regulation of secretion
- GHRH (continual), somatostatin (pulsatile secretion)
- Desensitization of R for GHRH
- IGF-1 - somatostatin
- Ghrelin
- GHS receptors – stimulation of GHRH secretion
- Synthesis – stomach and CNS, regulation of
food intake
- Diurnal rhythm with maximum during sleep (first
episode of slow-wave sleep)
- Very low basal secretion, decrease with age (peak
in puberty, then decrease)
Growth hormone (GH) – regulation of secretion
- „jet lag“
- exercise
- physical stress including infection, sepsis
- Malnutrition (+)
- Obesity (-)
- Glucose (-)
- Arginine, leucine (+)
- FFA (-)
- leptin
GH and interaction with other hormanal axes
ACTH – Glucocorticoids
- Acute (+) – effect after ca 3 hours
- Chronic (-)
TRH – TSH – thyroid hormones
- Necessary for GH secretion
- Hypothyroidismus (-)
GnRH – FSH a LH – sex hormones
- Testosterone (+)
- Estrogens (+) – only p.o. – decreased inhibition of
IGF-1 + feedback
- aromatization of androgens affects GH synthesis
and secretion (paracrine effect of estrogens in CNS)
TRANSPORT
-GHBPs
-20 kDA with low affinity
-60 kDa with high affinity
-Obesity (+)
-Pregnancy (+)
-p.o. estrogens (+)
-Malnutrition (-)
-Cirrhosis (-)
-Hypothyroidism (-)
-Androgens (-)
-Glucocorticoids (-)
GH – receptors and cell signaling
- GHR (dimer)
- JAK-STAT
- Liver
- Adipose tissue
- Skeletal muscles
- Mutual integration of
signaling pathways?
GH and its effects
METABOLIC
-Energetic metabolism
-Together with insulin (metabolism of sugars, fats, proteins)
-Lipolysis and FA oxidation(+) (hormone-sensitive lipase, + LDL)
-Glucose – direct or indirect effect,
- (+) uptake of Glu
- (-) Glu oxidation
- (+) gluconeogenesis
-Proteins
- (+) anabolism, (-) urea
- (+) AA transport
- (+) incorporation of AA to proteins
- (-) protein oxidation
GROWTH
-Mediated by IGF-1 (auto-/paracrine)
GH – clinical aspects
GH deficiency – gained or congenital – often tumors or inflammation
- nonspecific symptoms (i.e. loss of energy, social isolation, loss of focus)
- myocardium changes (left ventricle)
GHR – mutation
Significance of markers (IGF-1, IGFBP3)
Substitution therapy – wide array of side-effects, contraindication – cancer
Experimental indications:
- catabolic states (i.e. extensive burns)
- osteoporosis
- HIV/AIDS
- sport medicine
- aging
MSH – melanotropins
α-MSH: Ac-Ser-Tyr-Ser-Met-Glu-His-Phe-Arg-Trp-Gly-Lys-Pro-Val
β-MSH: Ala-Glu-Lys-Lys-Asp-Glu-Gly-Pro-Tyr-Arg-Met-Glu-His-Phe-Arg-Trp-Gly-Ser-Pro-Pro-Lys-
Asp
γ-MSH: Tyr-Val-Met-Gly-His-Phe-Arg-Trp-Asp-Arg-Phe-Gly
- Pregnancy (+)
- Adrenal glands (hypofunction)
Clinical significance
-Synthetic analogues
-Afamelanotide – photoprotection
-Melanotan II – increased libido
-Bremelanotide – aphrodisiac effect (MC3R and MC4R)