Pituitary Adrenal Axis PDF

Summary

This document covers the pituitary-adrenal axis, including the hormones involved, their regulation, and the effects of hormone imbalances. It describes the processes and details the hormones, their synthesis, transport, and effects, especially regarding cortisol. Useful diagrams are included.

Full Transcript

The pituitary-adrenal axis
After this lecture the students should be able to:

State the class of hormone to which cortisol
belongs and identify where it is synthesized;
Describe signaling events associated with steroid-
based hormones
Understand how ACTH release is regulated and
discuss how it regulates cortisol release;
Identify the sites of action of cortisol and explain
how cortisol exerts its effects
Describe the consequences of cortisol excess and
its deficiency and discuss the phenotypes manifested
in Cushings syndrome and Addison’s disease
The adrenal gland is a hybrid gland consisting of a cortex and a medulla. The hormones of the adrenal gland are
important regulators of metabolism and serve an important role in adaptation to stress.
Cortisol is a glucocorticoid and increases plasma glucose levels; deficiency can result in hypoglycemia. Because of the anti-
inflammatory and immunosuppressive actions of adrenal corticosteroids, synthetic analogs are widely used in the
treatment of disorders ranging from skin rashes to arthritis.
Aldosterone is a mineralocorticoid, promotes salt and water retention by the kidney, critical for normal salt/water balance.
The adrenal cortex also synthesizes and secretes androgenic steroids, which may be converted by peripheral tissue to
testosterone.
Although the primary product of chromaffin cells in the medulla is epinephrine, it also produces variable amounts of the
epinephrine precursor norepinephrine. These catecholamines are distinct from the steroid hormones both structurally and
functionally.

capsule
Products and Zonation of the AG
The Adrenal Gland: Modulating our stress response
 Steroid Hormones

Ø All steroid hormones are derived from cholesterol and differ
only in the ring structure and side chains attached to it.

Ø All steroid hormones are lipid soluble thus are freely permeable
to membranes so are not stored in cells; they leave cells shortly
after synthesis.

Ø Steroid hormones are carried in the blood complexed to specific
binding globulins. e.g., Corticosteroid binding globulin
transports cortisol

Ø Enzymes which produce steroid hormones from cholesterol are
located in mitochondria and SmER

Ø In some cases a steroid is secreted by one cell and is converted
to the active steroid by the target cell; for example cortisol
 Sources of Cholesterol for Steroid Synthesis
The amount of free cholesterol in the cell is maintained
relatively constant: Complexed with
protein for exit
Stimulation

-
cellular synthesis
of cholesterol from free
acetate cholesterol steroid
level synthesis

esterified cholesterol level

The cholesterol precursor comes from cholesterol
LDL synthesized within the cell from acetate, from
Stimulation cholesterol ester stores in intracellular lipid
droplets or from uptake (cholesterol-containing
low density lipoproteins).
 Steroid Hormone Synthesis
A series of enzymatic steps in the mitochondria and ER of steroidogenic
tissues convert cholesterol into all of the other steroid hormones and
intermediates.
The rate-limiting step in this process is the transport of free cholesterol
from the cytoplasm into mitochondria. This step is carried out by the
Steroidogenic Acute Regulatory Protein (StAR), moving cholesterol from
the outer membrane to the inner membrane where cholesterol is
converted into pregnenolone
by the enzyme, cytochrome P450 side-chain
cleavage (P450scc; also called desmolase, or
CYP11A1).

This is a rate limiting, nonreversible step in the
initiation of steroid biosynthesis.

This step occurs in adrenal, ovary, and testis.
 Extracellular
lipoprotein

acetate Cholesterol
pool (CE)
L
HS T
A
AC ACAT = acyl CoA
Free cholesterol cholesterol transferase
HSL = hormone
sensitive lipase

Pregnenolone
In the adrenal gland, pregnenolone can
be converted into three different
pathways, depending upon whether
you want to make mineralcorticoids,
glucocorticoids, or androgens

Steroid
Hormone
 Adrenal Steroidogenesis
Zona glomerulosa zona fasciculata zona reticularis
(CYP17) (CYP17)
17a-hydroxylase lyase
pregnenolone 17a-hydroxypregnenolone dehydroepiandrosterone
3b-hydroxysteroid dehydrogenase
progesterone androstenedione
21-hydroxylase
11b-hydroxylase
(CYP11B2) 18 hydroxylase/oxidase glucocorticoids
mineralocorticoids (cortisol)
(aldosterone)

What determines which pathway is taken?
Each step of the pathway is regulated by a specific enzyme.
Different zones of the adrenal cortex have different relative activities of enzymes, resulting in
different chemical reactions taking place.

e.g., CYP17 not expressed in glomerulosa
CYP11B2 (aldosterone synthase) only in glomerulosa
zona fasciculata glucocorticoid:
function
The largest and most actively steroidogenic zone is the middle zona fasciculata producing the
glucocorticoid hormone, cortisol….in the mitochondria and SmER

Lipid droplet
 Transport and Metabolism of Cortisol

Cortisol is transported in blood predominantly bound to corticosteroid-binding globulin (CBG)
(also called transcortin, binds 90%) , and albumin (binds 5% to 7%). The unbound (free; 3 – 5%)
form of the hormone exerts biologic effects within target cells and feeds back on the pituitary
and hypothalamus.

The liver is the predominant site of steroid inactivation and conjugates 95% of active and
inactive steroids with glucuronide or sulfate for excretion by the kidney. The circulating half-life
of cortisol is about 70 minutes.
 Mechanism of action

Cortisol acts primarily through the GR (glucocorticoid receptor), which binds to GRE
(glucocorticoid responsive element) and regulates gene transcription. In the absence of
hormone, the GR resides in the cytoplasm in a stable complex with several molecular
chaperones, including heat-shock protein 90 and cyclophilins. Cortisol-GR binding promotes
dissociation of the chaperone proteins, followed by the following:
 Rapid translocation of the cortisol-GR complex into the nucleus.
Dimerization and binding to GREs near the basal promoters of cortisol-regulated genes.
Recruitment of coactivator or co-repressor proteins, followed by covalent modification of
chromatin (e.g., histone acetylation for activation; histone deacetylation for inactivation).
A change (increase or decrease) in the assembly of the general transcription factors, leading
to changes in the transcription rate of the targeted genes.
Phosphorylation, followed by nuclear export and/or degradation of the GR, thereby
terminating the signal.
 Metabolic Effects of Cortisol
Glucocorticoids are essential for life. If the adrenal cortex is removed or is not functioning,
exogenous glucocorticoids must be administered or death will ensue. The actions of
glucocorticoids are essential for gluconeogenesis, for vascular responsiveness to
catecholamines, for suppression of inflammatory and immune responses, and for modulation of
CNS function; catabolic and diabetogenic qualities.

Glucocorticoids are essential for survival during fasting.
 Metabolic Effects of Cortisol
Glycogen Liver
Glucose
Glucose-P Glucose

Amino Glucose Free fatty
Protein acids precursors acids
+ Adipose
Glycerol
tissue
Stimulate Plasma
Muscle Inhibit Glucose
Free fatty acids
Amino acids

Stimulates protein and triglyceride catabolism
Stimulates “gluconeogenesis” in liver
Inhibition of glucose uptake by body (insulin antagonism) but not by brain. Elevates blood
glucose levels, “diabetogenic effect.” Nervous system becomes primary user of glucose
during stress.
Inhibits bone formation
Inhibition of non-essential functions (reproduction; growth)
Cortisol tames immune response
It is prescribed to suppress inflammation and the immune system. Analogs of glucocorticoid are
frequently used pharmacologically (e.g., as immunosuppressants in organ transplantations.
When cortisol levels are high, many of the body's defense mechanisms against infection are
inhibited.

However, disruption of physiologic homeostasis leads to side effects such as alterations in water
balance, weight gain, hypertension, muscle weakness, diabetes, and osteoporosis. These side
effects are mediated through the genomic function of GR (i.e. through the activation of
glucocorticoid response element [GRE]-mediated transcription).
 Regulating the mineralocorticoid action of cortisol
Cortisol can bind to the
mineralocorticoid receptor (MR) with
high affinity and activate the ‘incorrect’
set of genes….but it is transported in the
inactive form (reversibly inactivated by,
11β-hydroxysteroid dehydrogenase type
2 (11β-HSD2)); the enzyme that
converts it to the active form (11β-
HSD1) is only present in tissues that
express the GR, including liver, adipose,
skin, and CNS.
Thus, the mineralocorticoid receptor
(MR) is free and available in
aldosterone-responsive cells (e.g., distal
convoluted tubule cells of the kidney)

GC 11b-HSD2 MC
tissues tissues
11b-HSD1
Active Inactive
(cortisol, corticosterone) cortisone, 11-dehydrocorticopsterone

Natural black licorice contains glycyrrhizic acid (GZA) which inhibits 11β-HSD2 and thereby increase the
mineralocorticoid activity of cortisol leading to Na retention, spikes in blood pressure, muscle spasms and a
disturbance of the acid-base balance
zona fasciculata glucocorticoid:
regulation
 Regulation of glucocorticoid secretion by HPA axis
centrally driven ACTH (Adrenocorticotropic hormone)
response e.g.
Rapid effects: StAR, HSL, SCC (desmolase)
Stress!
Longer-term effects: enzymes necessary
e.g. hypoglycemia for cholesterol synthesis and LDL receptor
Trophic effects: health of z. fasciculata and
normal daily reticularis
rhythm
The suprachiasmatic nucleus and retina impose a
circadian rhythm on CRH secretion, therefore ACTH
secretion, therefore cortisol.
Pulsatile release of CRH and ACTH, relative longer half
life of cortisol (70 vs 10 mins) is reflected in the traces
below.
Cortisol (mg/dL)
ACTH (pg/mL)
Glucocorticoid regulation and function: Summary

Inhibits
synthesis
transcription
of CRH
CRH release

Inhibits synthesis of
CRH receptor
ACTH
ACTH release

tissue

Consequence of action

Figure 23-3: The control pathway for cortisol
 Effects of altered glucocorticoid/steroid levels
In hypocortisolism (e.g., primary adrenal insufficiency, Addison's disease), there is hypoglycemia.
In hypercortisolism (e.g., Cushing's syndrome), there is hyperglycemia

If pituitary lesion If excess ACTH
or no ACTH (chronic stress, or pituitary tumor
(Cushing disease)), or deficiency in
cortisol feedback

fasciulata and
reticularis atrophy Enlarged adrenals
(ACTH acts as a trophic factor;
angiotensin II and high K
trophic for glomerulosa)
Excess steroids

No cortisol; dependency on
exogenous glucocorticoids
 Effects of altered glucocorticoid levels:
Adrenal Hyperplasia

impaired
feedback
Excess CRH
and ACTH

Hyperplastic Reduced
adrenal cortisol release

Excess secretion
and symptoms

21-hydroxylase deficiency symptoms: varying degree of virilism in females including
hirsutism and clitoral hyperplasia; precocious puberty in boys

Also, when the HPA axis is over-stimulated because of stress, and if the body cannot
keep up with the demand for cortisol, or if there is any other steroidogenic enzyme block,
excess ACTH might be shunted into the androgen production pathway.
Effects of altered glucocorticoid levels: Cushing syndrome
Cushing’s disease is hypercorticism (increased glucocorticoid production) caused by a pituitary basophilic adenoma.
Cushing’s syndrome refers to the consequences of increased plasma glucocorticoid concentration from any source.
ACTH and cortisol measurements discriminate between ACTH-dependent and independent causes.

Exogenous cause Endogenous causes
Overproduction of cortisol

Taking medicines Pituitary tumor Adrenal tumor Other unknown
containing (Cushing’s disease)
glucocorticoids

independent dependent independent

ACTH
Two primary consequences
1. Salt and water-retention with renal loss of K+ results in “moon face”. The fluid-retention
eventually leads to cardiac hypertrophy due to prolonged hypertension. There is often
peripheral oedema, due to the glucocorticoid-induced diabetes. This type of diabetes is typically
resistant even to large doses of insulin.
2. Catabolism causes muscle wasting, fat accumulation, osteoporosis with kyphosis, buffalo
hump, and fractures. The skin is thin with ulcers and red stirrer, and there is poor wound
healing. There is impaired fibrocyte formation and capillary resistance.
Effects of altered glucocorticoid levels: Cushing syndrome
Effects of altered glucocorticoid levels: Addison disease

a rare, chronic endocrine disorder in which the adrenal glands do not produce sufficient steroid
hormones (glucocorticoids and often mineralocorticoids).

Symptoms

Overproduction of ACTH due to decreased negative feedback by cortisol
Skin hyperpigmentation (excessive ACTH as well as other products of the parent precursor,
POMC, lead to increases in a and g forms of melanocyte-stimulating hormone, MSH)

Glucocorticoid deficiency symptoms: predisposition to hypoglycemia, hypotension, changes in
mood and personality, muscle weakness, anemia, decreased GI motility and appetite (weight
loss), decreased water clearance

Mineralocorticoid deficiency symptoms: loss of Na (craving for salt) and fluids and retention of K
(hyperkalemia), hypotension, muscle fatigue and pain ( due to increased extracellular K)