Adrenal Gland Hormones PDF

Summary

This document describes the adrenal gland and adrenal hormones, including the regulation of aldosterone secretion and the mechanisms of action of aldosterone and catecholamines.It details the synthesis and function of these hormones, as well as how they are regulated. Information on Pheochromocytoma and associated symptoms is present.

Full Transcript

The Adrenal Gland and
Adrenal Hormones
After this lecture the students should
be able to:

State the class of hormones to which
aldosterone, epinephrine, and
norepinephrine belong and the location of
their synthesis;
Describe the regulation of aldosterone
secretion with particular emphasis on the
renin-angiotensin system;
Explain where and how aldosterone exerts
its effects;
Distinguish the 5 adrenoceptor subtypes
and explain the relative affinities of
adrenaline and noradrenaline for these;
zona glomerulosa
aldosterone:
function
Aldosterone governs the extracellular volume (ECV) due to its action on Na
retention/absorption by the kidney. Arginine vasopressin (AVP) - also known
as antidiuretic hormone (ADH) – regulates osmolality because of its effect on
free water balance (and indirectly affects Na concentration)

Osmolarity maintained at 300 mOs/L

28 L

3.5 L

10.5 L
Two integrated systems for regulating
salt/water balance
 Synthesis of aldosterone
As with cortisol, the adrenal cortex synthesizes aldosterone from cholesterol.
Because glomerulosa cells are the only ones that contain aldosterone
synthase, these cells are the exclusive site of aldosterone synthesis.

As with cortisol, no storage pool of presynthesized aldosterone so secretion of
aldosterone by the adrenal is limited by the rate at which the glomerulosa
cells can synthesize the hormone.

ACTH, extracellular [K+] [Na+], and the peptide hormone ANG II stimulate
the production of aldosterone in the glomerulosa cell.

They enhance secretion by increasing the activity of enzymes acting at rate-
limiting steps in aldosterone synthesis. These include the SCC enzyme
(common to all steroid-producing cells) and aldosterone synthase (unique to
glomerulosa cells and involved in the final steps of formation).

Once secreted, ∼37% of circulating aldosterone remains free in plasma. The
rest weakly binds to CBG (∼21%) and albumin (∼42%).
 Mechanism of action of aldosterone

The major action of aldosterone is to stimulate the kidney to reabsorb Na+
and water and to enhance K+ secretion. Aldosterone has similar actions in
the colon, salivary glands, and sweat glands. Mineralocorticoid receptors
(MRs) are also present in the myocardium, liver, brain, and other tissues, but
the physiological role in these tissues is unclear.
Like all the other steroid hormones, it acts by modulating gene transcription
after binding to the MR.

Some of the molecular consequences of aldosterone in the target cells of the
renal tubule are given in the next slide.

Aldosterone regulates only that small fraction of renal Na+ reabsorption that
occurs in the distal tubule and collecting duct. Most Na+ reabsorption occurs
in the proximal tubule by aldosterone-independent mechanisms, but loss of
aldosterone-mediated Na+ reabsorption can result in significant electrolyte
abnormalities, including life-threatening hyperkalemia and hypotension.
Conversely, excess aldosterone secretion produces hypokalemia and
hypertension.

2% change in excretion of Na 3 L change in ECV
 Mechanism of action of aldosterone
In the target cells of the renal tubule, aldosterone increases the activity of
several key proteins involved in Na+ transport.
transcription of the Na-K pump, so augmenting distal Na+
reabsorption.
expression of apical Na+ channels and an Na/K/Cl cotransporter so
increasing Na+ reabsorption and K+ secretion.
ROMK = renal outer
medullary
potassium channel

ENaC = epithelial
sodium channel

blood
urine

SGK =
Serine/threonine-
protein kinase
zona glomerulosa
aldosterone:
regulation
Regulation of aldosterone synthesis
Na and water levels feedback through the RAS
Ang II binds to receptor
Gaq to PLC to DAG and IP3
Ca increase, Ca-dependent enzymes increase
Depolarizes glomerulosa cells,
voltage-gated Ca channels open
Ca rises, stimulates
production of P450scc (desmolase, CYP11A1)
delivery of cholesterol
aldosterone synthase
High extracellular K
Depolarizes glomerulosa cells,
voltage-gated Ca channels open
Ca rises, stimulates
production of P450scc (desmolase, CYP11A1)
delivery of cholesterol
aldosterone synthase
ACTH
Binding to MC2R stimulates Ca influx
Regulation of aldosterone synthesis
eedback regulation of aldosterone synthesi

Also, adjustment of
circulating volume will
feedback on aldosterone
synthesis.

homeostasis
inhibition
The Adrenal Medulla:
Catecholamines
 Development of the AG

The adrenal cortex develops from mesodermal cells into steroidogenic cells
that produce mineralocorticoids, glucocorticoids, and adrenal androgens

but neural crest-derived chromaffin cells migrate into the cortical cells to
form the medulla

Influence of Cortisol: Chromaffin cells have the potential of developing into
postganglionic sympathetic neurons and synthesize the norepinephrine from
tyrosine, however, the cells of the adrenal medulla are exposed to high local
concentrations of cortisol (from the cortex) which inhibits neuronal
differentiation.

Additionally, cortisol induces the expression of phenylethanolamine-N-methyl
transferase (PNMT) in chromaffin cells, which converts norepinephrine to
epinephrine - the primary hormonal product of the adrenal medulla.
The Adrenal medulla (AM) bridges the endocrine and sympathetic NS; similar
to a sympathetic ganglion without postganglionic processes. Instead of being
secreted near a target organ, adrenomedullary catecholamines are secreted
into the blood and act as hormones.
 Synthesis of Catecholamines
epinephrine, some norepinephrine, are

ACTH + stored in the chromaffin granule
complexed with adenosine triphosphate
(ATP), Ca2+, and proteins called
chromogranins.

Note: synergy between
CRH/ACTH/cortisol and sympathetic
epinephrine axis i.e., stress resulting in
cortisol release
Aboutsustains
70-80%the epinephrine
of the cells of
Transported
response
chromaffin granule the adrenal medulla secrete
VMAT (secretory vesicle)
epinephrine, and the
ACTH + remaining 20-30% secrete
norepinephrine. Circulating
epinephrine is derived entirely
Diffuses out of granule
from the AM but only about
30% of the circulating
+ norepinephrine comes from it,
the rest from postganglionic
sympathetic nerve terminals.
Back to granule by vesicular Because the adrenal medulla
monoamine transporters (VMATs)is not the sole source of
 Regulation of catecholamines
Secretion of epinephrine and norepinephrine from the adrenal medulla is
regulated primarily by descending sympathetic signals in response to
various forms of stress, including exercise, hypoglycemia, and surgery.

The primary autonomic centers that initiate sympathetic responses
reside in the hypothalamus and brainstem, and they receive inputs from
the cerebral cortex, the limbic system, and other regions of the
hypothalamus and brainstem.

The chemical signal for catecholamine secretion from the adrenal medulla
is acetylcholine (ACh), which is secreted from preganglionic sympathetic
neurons and binds to nicotinic receptors on chromaffin cells.

ACh increases the activity of the rate-limiting enzyme, tyrosine
hydroxylase, and of dopamine β-hydroxylase and stimulates
exocytosis of the chromaffin granules.

Synthesis of epinephrine and norepinephrine is closely coupled to secretion
so that the levels of intracellular catecholamines do not change
significantly, even in the face of changing sympathetic activity.

Cortisol regulates epinephrine production by maintaining adequate
 Degradation of
catecholamines

The biological response of catecholamines is very brief ~ 10 sec, circulating
catecholamines are degraded

There are two primary enzymes involved in the degradation of
catecholamines:
monoamine oxidase (MAO) - the predominant enzyme in neuronal
mitochondria
catechol-O-methyltransferase (COMT)
 Mechanism of action of catecholmines

techolamines act through adrenergic GPCRs

RECEPTOR TYPE PRIMARY MECHANISM OF ACTION EXAMPLES, TISSUE DISTRIBUTION
AGONIST POTENCY
α1 ↑IP3, DAG (PLC, Gas) Vascular smooth muscle Epinephrine
< norepinephrine
α2 ↓cAMP (AC, Gai) Pancreatic β cells Epinephrine <
norepinephrine
β1 ↑cAMP (AC, Gas) Heart Epinephrine =
norepinephrine
β2 ↑cAMP (AC, Gas) Liver Epinephrine >>
norepinephrine
The
β3 α receptors andGas)
↑cAMP (AC, β3 receptors respond
Adipose better to norepinephrine
Norepinephrine >>than
epinephrine.
epinephrine The β1 receptor responds equally to the two catecholamines,
whereas epinephrine is more potent than norepinephrine for the β2 receptor.
A large number of synthetic selective and nonselective adrenergic agonists
and antagonists now exist.

A single catecholamine may thus evoke multiple different responses as a
consequence of circulating concentration e.g., epinephrine may evoke both
vasodilation and vasoconstriction
 Physiologic actions of
catecholamines
Because the adrenal medulla is directly innervated by the autonomic nervous
system, adrenomedullary responses are very rapid.

Because of the involvement of several centers in the CNS adrenomedullary
responses can precede onset of the actual stress (i.e., responses can be
anticipated).
For example, consider the sympathoadrenal response to exercise.
Exercise is similar to the fight-or-flight response, but without the subjective
element of fear.
It increases circulating levels of both norepinephrine and epinephrine. The
overall goal of the sympathoadrenal system during exercise is to meet the
increased energy demands of skeletal and cardiac muscle while maintaining
sufficient oxygen and glucose supply to the brain. The response to exercise
includes three of the following major physiologic actions of norepinephrine
and epinephrine
 Increased blood flow to the muscles
Norepinephrine and epinephrine (β1) act on the heart to increase the rate
(chronotropy) and strength (inotropy) of contractions, induce vasoconstriction
(α) of veins and lymphatics. All these effects increase cardiac output.

Increased glucose availability
Epinephrine promotes glycogenolysis in muscle (β2). Exercising muscle can
also use free fatty acids (FFAs), and epinephrine and norepinephrine (β2 and
β3) promote lipolysis in adipose tissue. This increases circulating levels of
lactate and glycerol, which can be used by the liver as gluconeogenic
substrates to increase glucose.
Epinephrine increases blood glucose by increasing hepatic glycogenolysis and
gluconeogenesis (β2).

decreased energy demand by visceral smooth muscle.
In general, a sympathoadrenal response decreases overall motility of the
smooth muscle in the GI tract and urinary tract, thereby conserving energy
where it is not needed.
 Pheochromocytoma

An uncommon tumor caused by hyperplasia of adrenal medulla or other
chromaffin tissue.

Excessive, unregulated production of catecholamines

Symptoms;
Sudden outburst of hypertension,
headaches,
episodes of sweating,
anxiousness,
tremor and
glucose intolerance

Laboratory detection of urinary catecholamines and their metabolites is
critical for diagnosis and treatment, adrenalectomy and subsequent
glucocorticoid and mineralocorticoid replacement therapy may be necessary