Endocrine System PDF

Summary

This document provides an overview of the endocrine system, covering its functions, major organs, types of hormones, and their actions on target cells. It introduces the basic principles behind hormone regulation and includes details of specific endocrine glands and hormones.

Full Transcript

The Endocrine System
Dr. Ali Ebneshahidi

© 2017 Ebneshahidi
Endocrine System
 The endocrine system interacts with the nervous
system to coordinate and integrate body activities
by means of hormones.
 Endocrine tissues and organs secrete hormone into
body fluids (mainly blood and lymph) directly
using diffusion.
 Exocrine tissues, such as salivary glands, and
sebaceous glands, secrete chemical substances
through ducts into an open space.

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 Five major functions of hormones
 a) Regulate metabolic processes (e.g. thyroid hormones).
 b) Control the rate of chemical reactions (e.g. growth
hormone).
 c) Aid in the transport of substances across the cell
membrane of target cells (e.g. insulin and glucagon).
 d) Regulate water and electrolyte balances (e.g.
antidiurectic hormone, calcitonin, and aldosterone).
 e) Play a vital role in reproduction, growth, and
development (e.g. estrogens, progesterone, and
testosterone).
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Major Endocrine Organs

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 Chemistry of Hormones
 Hormones are organic compounds secreted by endocrine glands, that
have a potent effect in target cells. There are two types of hormones.
 a) Protein hormones: made of amino acids joined by peptide bonds.
 fat – insoluble; as a result cannot diffuse across the membrane of target
cells.
 most hormones belong to this group except hormones secreted by the
gonads (testis and ovary) and the adrenal cortex.
 b) Steroid hormones: made of fatty acids using cholesterol as a
functional group.
 fat-soluble; as a result can diffuse into target cells.
 only hormones secreted by the gonads and adrenal cortex belong to this
group.
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Hormone Action
 1. Most hormones adhere to the following action
plan:
 a) endocrine gland synthesizes the hormone.
 c) Hormone diffuses into capillaries.
 d) Hormone is transported by blood or lymph toward
target cells.
 e) Hormone diffuses out of capillaries at target
tissue, and causes an effect in target cells.

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Thyroid Gland

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 2. Each step of this action plan is highly specific and
carefully controlled by the endocrine and circulatory
systems:
 synthesis of hormone using protein or lipid anabolism.
 secretion of hormone using exocytosis or diffusion.
 transport of hormone in the blood or lymph (i.e.
steroid hormones require a “protein transporter”
during the transport).
 interaction between the hormone and target cell (i.e.
protein hormones require receptors at the cell
membrane of target cells).
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 3. Effects in the target cells caused by hormone action:
 a. A change in cell membrane permeability (e.g. insulin
causes muscle cells to have a higher permeability for
glucose).
 b. A change in chemical reaction rate (e.g. growth
hormone stimulates higher chemical reaction rates in
muscle and bone cells).
 c. Enzyme activation (e.g. epinephrine increases enzyme
action in muscle cells).
 d. Activation of cell secretion (e.g. melanocyte -
stimulating hormone activates more melanin secretion
from the melanocytes).
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Actions of steroid hormones
 1. Steroid hormones bind to a protein transporter during the
transport in blood of lymph.
 2. When they have arrived at the target cells, the protein
transporter (being fat-insoluble) is repelled by the cell membrane,
while the steroid hormone (being fat-soluble) diffuses into the
cytoplasm of target cell.
 3. Steroid hormone also diffuses across the nuclear envelope and
enters into the nucleus of target cell.
 4. Steroid hormone binds to a specific receptor located on a
particular gene of target cell’s DNA.
 5. This binding alters the genetic information within that gene,
resulting in a new messenger RNA (mRNA) being produced after
transcription.
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 6. this new mRNA
will be translated
into a new protein
(or enzyme) in the
cytoplasm of
target cell.
 7. the new protein
or enzyme causes
a specific effect to
occur within the
target cells.

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 Sequence of steroid hormone action - Summary

 1. Endocrine glands secrete steroid hormone.
 2. Steroid hormone diffuses through target cell membrane.
 3. Hormone combines with a receptor molecule.
 4. Steroid hormone-receptor complex binds to DNA and promotes
synthesis of mRNA.
 5. mRNA enters the cytoplasm and directs protein synthesis.
 6. Newly synthesized protein produce hormone’s specific effects.
 7. The new protein causes a specific effect to occur within the target
cells.

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 Steroid Hormones

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Action of protein hormones
 1. A protein hormone is transported in the blood or lymph by
itself, without a transporter.
 2. When it has arrived at the target cell, the protein hormone binds
with a specific receptor embedded in the cell membrane of target
cell (The number of receptors changes in response to the amount
of hormone released -- “up-regulation” refers to the phenomenon
where more receptors will be produced to respond to a deficiency
of the hormone; while -- “down-regulation” refers to the process
of producing less receptors to respond to a large amount of
hormone).
 3. This binding activates a series of chemical reactions (“cascade
reactions”) in the cytoplasm of target cell.

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 4. The product of these reactions is a substance known as the
“secondary messenger” (usually cyclic adenosine monophosphate or
cAMP), which acts on behalf of the protein hormone, causes a potent
effect in the target cell (usually within the cytoplasm).
 5. Since protein hormones never diffuse to the DNA of target cells, no
new proteins or enzymes are made at the end.

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 Sequence of protein hormone action - summary
 1. Endocrine gland secretes nonsteroid hormone.
 2. Body fluid carries hormone to its target cell.
 3. Hormone combines with receptor site on membrane of its target cell,
activating G protein.
 4. G protein activates an enzyme called adenylate cyclase within target
cell’s membrane.
 5. Adenylate cyclase converts ATP into Cyclic AMP.
 6. Cyclic AMP activates protein kinases.
 7. These enzymes activate protein substrate in the cell that change
metabolic processes.
 8. Cellular changes produce the hormone’s effects.
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Protein Hormones

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 Control of hormone secretion
 I. Negative feedback mechanism
 a) most secretion of hormones is regulated by negative feedback where
once the desired effect is achieved in the target cell, an inhibitory
signal (hormone, nerve impulse, or enzyme) will be sent from the
target cells to the endocrine gland.
 b) hormones that are secreted by endocrine glands and travel to target
cells directly are called nontropic hormones.
 c) hormones that are secreted by an endocrine gland (e.g. pituitary
gland) and travels to another endocrine gland, causing the second gland
to secrete another hormone, are referred to as tropic hormones.
 d) most hormones travel a long distance and act on target cells, they are
called circulating (or endocrine) hormones; while other hormones
travel a short distance, they are called local (paracrine) hormones.
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 II. Nervous control
 a) Some hormone secretion is regulated by nerve
impulse where sympathetic and parasympathetic nerves
innervate the endocrine gland and control its secretion
(e.g. sympathetic nerves cause the adrenal medulla to
secrete epinephrine and nor epinephrine).
 b) Hormone release at the posterior pituitary gland is
controlled by nerve fibers from the hypothalamus. In
addition to transmitting nerve impulses, however, these
specialized nerve fibers seem to also transport “releasing
hormones” (e.g. gonadotropin releasing hormone or
GnRH) to the pituitary gland.
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 Relationship of pituitary gland & Hypothalamus

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 Major endocrine glands & hormones
 The pituitary gland is attached to the hypothalamus by infundibulum.
 Divided into anterior lobe (adenohypophysis) and posterior lobe
(neurohypophysis). Anterior lobe is about 3 times larger than
posterior lobe.
 1. Anterior pituitary is under hormonal control by the hypothalamus
where blood vessels transport “releasing hormones” to the anterior
lobe. Anterior pituitary contains 5 types of glandular cells.
 Somatotrophs produce GH.
 Lactotrophs produce PRL.
 Corticotrophs produce ACTH and MSH.
 Thyrotrophs produce TSH.
 Gonadotrophs produce FSH and LH.
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Relationship of the pituitary gland & Hypothalamus

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 2. Posterior pituitary is under nervous control by the hypothalamus
where nerve fibers innervate the posterior lobe for its release of
hormones [posterior pituitary does not produce hormones; it only
release hormones made by the hypothalamus (Oxytocin, ADH)].

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Anterior pituitary gland – 7 hormones
 Growth hormone (GH) -- for normal growth and

development of all body cells, especially muscle
and bone cells. [Hypersecretion of it during
childhood causes Gigantism, hypersecretion during
adulthood causes Acromegaly, and hyposecretion
causes Dwarfism].
 Thyroid-stimulating hormone (TSH) -- stimulates
the thyroid gland to secrete thyroid hormones.
[Hypersecretion causes Grave’s disease, and
hyposecretion causes cretinism in children and
myxedema in adults].
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a) Goiter b) Exophthalmos of graves disease

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 Adrenocorticotropic hormone (ACTH) – stimulates the
adrenal cortex to secrete mineralocorticoids, glucocorticoids,
or gonadocorticoids. [Hypersecretion causes Cushing’s
disease, while hyposecretion is rare].

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 Follicle-stimulating hormone (FSH) -- stimulates the production of
egg cells and sperm in the gonads. [Hypersecretion causes no known
effects, while hyposecretion can cause failure of sexual maturation].
 Luteinizing hormone (LH) -- triggers ovulation and stimulates the
production of estrogens and progesterone in female, and promotes
testosterone production in male. [Disorders are similar to those for
FSH].
 Prolactin (PRL) or Lactogenic hormone (LTH) -- stimulates milk
production in the mammary glands. [Hypersecretion can disrupt
normal menstrual cycles in female and causes impotence in male;
and hyposecretion causes poor milk production in female].
 Melanocyte-stimulating hormone (MSH) -- stimulates melanocytes
in the epidermis and hair follicles to release melanin pigment.
[Hypersecretion causes abnormally dark skin pigment, and
hyposecretion causes abnormally light skin pigment].
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Posterior pituitary gland
 Oxytocin (OT) -- stimulates uterine contraction
during the birth process, and activates milk
ejection from the mammary glands. [Disorders are
rare and have no known effects, except in some
hyposecretion cases, weak labor contraction is
reported].
 Antidiurectic hormone (ADH) -- stimulates water
reabsorption in kidney tubules. [Hypersecretion
has no know effects, and hyposecretion causes
frequent urination called diabetes insipidus].

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 Thyroid gland
 a) located inferior to the larynx (voice box) and attached to the trachea.
 b) divided into two lateral lobes.
 c) thyroid follicles utilize iodine and synthesize thyroglobulin (TGB) to
be stored in the colloids.
 d) upon stimulation of TSH, TGB is converted into two hormones --
Triiodothyronine (T3) and Thyroxine (T4) to promote normal
metabolism. [Hyposecretion causes hypothyroidism, similar to
cretinism and myxedema, and hypersecretion causes hyperthyroidism
that results in a goiter or in Grave’s disease].
 e) also secretes Calcitonin to lower blood calcium and phosphate
levels and regulate digestive hormones. [Both hyposecretion and
hypersecretion would affect normal balances of calcium and
phosphate].
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Regulation of thyroid hormone secretion

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 Parathyroid glands
 Four oval-shaped glands
embedded in the
posterior surface of the
thyroid gland.
 Secrete only 1 protein
hormone called
parathyroid hormone
(PTH) or parathormone
to raise blood calcium
level and lower blood
phosphate level.
[Hyposecretion causes
tetany, and
hypersecretion causes
osteitis fibrosa cystica].
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 Adrenal gland
 A. Adrenal Cortex: outer portion of the adrenal gland
which is attached to the superior surface of the kidney.
 Divided into 3 regions, from outside to inside: Zona
glomerulosa, Zona fasciculate, and Zona reticularis.
 Secretes over 30 steroid-based substances and several steroid
hormones, all crucial for normal homeostasis.
 Zona glomerulosa secretes mineralocorticoids which help
regulate the levels of minerals such as sodium, potassium,
and magnesium. Aldosterone is the most important hormone
in this group, where it raises blood levels of sodium and
water, and lowers blood potassium level.
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Adrenal gland

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  Zona fasciculata secretes glucocorticoids which affect glucose
or carbohydrate metabolism. Cortisol is the most important
hormone in this group, where it is involved in carbohydrate,
lipid and protein metabolism, and also helps fight stress and
inflammation. [Hyposecretion causes Addison’s disease, and
hypersecretion causes Cushing’s syndrome].
 Zona reticularis secretes gonadocorticoids which supplement
sex hormones from the testes and ovaries and stimulate early
development of reproductive organs. These hormones are male
types (adrenal androgens), namely testosterone, but can be
converted into female types, such as estrogens, by the skin,
liver, and adipose tissues. [Hyposecretion causes congenital
adrenal hyperplasia, and hypersecretion causes gynecomastia
in male].

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Adrenal gland
 B. Adrenal Medulla: inner portion of the adrenal gland.
 Made of modified nerve tissue that is under direct regulation of
sympathetic nerves of the autonomic nervous system.
 Contains glandular cells called chromaffin cells which secrete 2
closely related hormones -- Epinephrine (or adrenaline), and
Norepinephrine (or noradrenaline).
 Effects of these hormones resemble sympathetic stimulation,
where body activities such as cardiac actions, blood pressure,
and breathing rate are increased, while digestive processes are
decreased. [No known effects are due to hyposecretion of these
hormones, but hypersecretion can caused hypertension,
increased blood glucose level, and high heart rate].

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 Pancreas
 The only gland that is both exocrine and endocrine in physiology.
 In its exocrine aspect, 99% of its mass is composed of cells called
acini which secrete digestive enzymes and fluids into the small
intestine through the pancreatic ducts.
 In its endocrine aspect, 1% of its mass is little groups of cells called
islets of langerhans (or pancreatic islets) which secrete hormones to
regulate blood glucose level.
 in each pancreatic islet, alpha cells (α cells) secrete glucagons to raise
blood glucose level.
 beta cells (β cells) secrete insulin to lower blood glucose level.
[Hyposecretion causes diabetes mellitus where excessive glucose is
present in urine, and hypersecretion causes hyperinsulinism].

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 Regulation of blood glucose

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 delta cells (δ cells) secrete somatostation or growth hormone
inhibiting hormone (GHIH) which helps regulate
carbohydrate metabolism by inhibiting the secretion of
glucagons.

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Diabetes mellitus

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 Ovary
 The female sex organ that also serves as an endocrine gland.

 Contains follicular cells in its secondary and mature follicles,
where they secrete Estrogen to develop and maintain female
sexual characteristics, to regulate ovarian and menstrual cycles, to
maintain pregnancy, and to develop secondary sexual
characteristics. [Both hyposecretion and hypersecretion will have
broad effects in female reproduction].

 Also contains degenerating scar tissue called corpus luteum which
contain lutein cells that secrete Progesterone to help maintain
ovarian and menstrual cycles, and pregnancy. [Discorders are
similar to those for estrogens].
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 Testis:
 The male sex organ that also serves as an endocrine gland.
 Contains interstital cells (or leydig’s cells) that secrete
testosterone to develop secondary sexual characteristics.
[Both hyposecretion and hypersecretion and will have broad
effects in male reproduction].
 Pineal gland:
 Pine cone shaped located deep in the cerebrum.
 Secrets melatonin to regulate circadian rhythms which are
necessary to keep track of day/night cycles, sleep/wake
rhythm, menstrual and ovarian cycles.
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 Thymus gland: A diminishing gland (over time) located
between the lungs. secretes a group of hormones, such as
thymosin, to affect the production and maturation of
lymphocytes in body defenses.
 Heart: The organ for pumping blood in the cardiovascular
system. Contains 2 small chambers called atrium which
secrete atrial natriuretic factor (ANF) which helps regulate
blood pressure.
 Digestive organs: stomach secretes hormones such as
gastrin to stimulate stomach activities. Small intestine
secretes hormones such as cholecystokinin (CCK) to
stimulate gallbladder activities, and intestinal gastrin to
regulate stomach activities.
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 Kidneys:
 organs for filtering and cleansing our blood and
tissue fluids.
 secrete a hormone called Erythropoietin to
stimulate red blood cell production in the red bone
marrow.
 Placenta:
 protective sac around the fetus during pregnancy.
 secretes estrogen and progesterone to maintain
normal pregnancy.
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 Major events in the general stress syndrome
 1. As a result of stress, nerve impulses are transmitted to the
hypothalamus.
 2. Sympathetic impulses arising from the hypothalamus
increases blood glucose conc., blood glycerol conc., blood
fatty acid conc., heart rate, blood pressure, and breathing
rate. They dilate air passages, shunt blood into skeletal
muscles, and increase secretion of epinephrine from the
adrenal medulla.
 3. Epinephrine intensifies and prolongs sympathetic actions.
 4. The hypothalamus secretes CRH, which stimulates
secretion of ACTH by the anterior pituitary gland.
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 5. ACTH stimulates release of Cortisol by the adrenal cortex.
 6. Cortisol increases the conc. of blood amino acids, releases fatty
acids, and forms glucose from noncarbohydrate sources.
 7. Secretion of glucagons from the pancreas and growth hormone from
the anterior pituitary increase.
 8. Glucagons and growth hormone aid mobilization of energy sources
and stimulate uptake of amino acids by cells.
 9. Secretion of ADH from post. Pituitary increases.
 10. ADH promotes the retention of H2O by the kidneys, which
increases blood volume.
 11. Renin increases blood level of angiotnsin II, which acts as a
vasoconstrictor and also stimulates Aldosterone secretion by the
adrenal cortex. Aldosteron increase Na+ retention by the kidneys.
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 Stress and the adrenal gland

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 The control pathway of Cortisol

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Disorders of the thyroid gland
 Hyperthyroid:
 Grave’s disease: Auto antibodies (against self)
bind TSH receptors on thyroid cell membranes,
mimicking action of TSH, over stimulating gland
(hyperthyroidism); This is an exothalmic goiter.

 Hyperthyroidism: High metabolic rate, sensitivity
to heat, rest lessness, hyperactivity, weight loss,
protruding eyes, goiter.

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 Hypothyroid:
 Hashimoto’s disease: Auto antibodies (against self) attack
thyroid cells, producing hypothyroidism.
 Hypothyroidism (infantile): Cretinism - shunted growth,
abnormal bone formation, mental retardation, low body
temperature, sluggishness.
 Hypothyroidism (adult): Myxedema - low metabolic rate,
sensitivity to cold, sluggishness, poor appetite, swollen tissue,
mental dullness.
 Simple goiter: Deficiency of thyroid hormone due to iodine
deficiency; because no thyroid hormones inhibit pituitary
release of TSH, thyroid is over stimulated and enlarges, but
functions below normal (hypothyroidism).

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Goiter and Myxedema

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Disorders of the parathyroid glands
 I. Hyperparathyroidism: fatigue, muscular weakness, painful
joints, altered mental functions, depression, weight loss, bone
weakening, increased PTH secretion over stimulates osteoclasts.
 Cause: Tumor.
 Treatment: Remove Tumor, correct bone deformities.
 II. Hypoparathyroidism: muscle cramps and seizures. Decreased
PTH secretion reduces osteoclast activity, diminishing blood
calcium ion concentration.
 Cause: inadvertent surgical removal; injury.
 Treatment: calcium salt injections, massive doses of vitamin D.

© 2017 Ebneshahidi