Chapter 10 - The Endocrine System PDF

Summary

Chapter 10 of the Essentials of Anatomy & Physiology textbook, 8th edition, discusses the endocrine system. The chapter covers fundamental concepts such as intercellular communication, the comparison of endocrine and nervous systems, different hormone types and their actions, and mechanisms of hormone action. The topics include hormone actions, types of receptors, and second messenger systems, and more.

Full Transcript

Chapter 10

The Endocrine
System

Copyright © 2020, 2017, and 2013 Pearson Education, Inc. All Rights Reserved
 Intercellular Communication

Maintains homeostasis
Mostly accomplished through chemical messages
Distant communication is coordinated by endocrine
and nervous systems
Nervous system is faster
Specific destination and short-lived effects

Endocrine system is slower
Releases hormones into bloodstream that bind to target
cells with longer-lasting effects
Nervous and Endocrine Systems Comparison

Both rely on release of chemicals that bind to
specific receptors on target cells
Both share chemical messengers
Epinephrine (E) and norepinephrine (NE)
Called hormones when released from adrenal medulla
Called neurotransmitters when released across synapses
Both are regulated by negative feedback
mechanisms
Both coordinate and regulate activities of other
cells, tissues, organs, and systems to maintain
homeostasis
 The Endocrine System

Includes all endocrine cells and tissues
Cells are glandular, secretory cells
Secretions enter the extracellular fluid
Local hormones, such as prostaglandins, affect adjacent
cells
Hormones are chemical messengers released in one
tissue and transported by the bloodstream to target cells
in other tissues
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 Three Groups of Hormones

Based on their chemical structure:
1. Amino acid derivatives
Structurally similar to amino acids
Include epinephrine, norepinephrine, thyroid hormones,
and melatonin

2. Peptide hormones
Consist of chains of amino acids
Largest class of hormones
Include ADH, oxytocin, hypothalamic, pituitary, and
pancreatic hormones
 Three Groups of Hormones Cont.

3. Lipid derivatives
Steroid hormones
Structurally similar to cholesterol
Bound to transport proteins in blood
Released by reproductive organs and adrenal glands

Eicosanoids
Fatty acid–based, derived from arachidonic acid
Coordinate local cellular functions and affect enzymatic
processes
Include prostaglandins
 Hormone Action
Hormones alter operations of the target cells
Change types, activities, locations, or quantities of
structural proteins and enzymes
Sensitivity of target
cell to hormone
depends on
presence or
absence of
receptors for that
hormone
Receptors are located either on
plasma membrane or inside the cell
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 Plasma Membrane Receptors
Required for hormones that are not lipid soluble
Examples: epinephrine, norepinephrine, peptide
hormones, and eicosanoids
Hormones cannot diffuse through the plasma
membrane
Must use receptors on outside of membrane
Effect is not direct
These hormones are first messengers that activate
second messengers in the cytoplasm
Action is linked by a G protein, an enzyme complex
 Second Messenger Systems
Small number of hormone molecules can activate
thousands of second messengers
Process called amplification
Magnifies effect of hormone on the cell

Examples of second messengers include:
Cyclic-AMP
Calcium ions
Cyclic-GMP
 Cyclic-AMP Second Messenger System
First messenger activates a G
protein
Which activates enzyme adenylate
cyclase
Which converts ATP to second
messenger, cAMP
Which activates kinase enzymes
inside cell
Which attaches a phosphate group
to another molecule in a process
called phosphorylation
Effect on target cell depends on
nature of protein affected
 Intracellular Receptors
Receptors inside cytoplasm or
nucleus
Used for lipid-soluble hormones
Examples: thyroid and steroid
hormones
Hormones cross plasma membrane
Form hormone-receptor complex
Activates or inactivates specific
genes
Alters rate of mRNA transcription
Changes structure or function of cell
 Hormone Secretion and Distribution
Rapidly enter blood and distributed throughout
body
Freely circulating hormones are short-lived and
inactivated when:
1. They diffuse to target cells and bind to receptors
2. They are absorbed and broken down in liver and kidney
3. They are broken down by enzymes in plasma or
interstitial fluid
Hormones bound to transport proteins stay in
circulation longer (steroid and thyroid hormones)
Each hormone has an equilibrium between bound
and free forms
 Control of Endocrine Activity

Hormonal secretion under negative feedback
control is based on three types of stimuli
1. Humoral (“liquid”) stimuli
Changes in composition of the extracellular fluid
Example: hormonal control of blood calcium levels

2. Hormonal stimuli
Changes in circulating hormone levels

3. Neural stimuli
Neural stimulation of a neuroglandular junction through
neurotransmitters
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 Hypothalamus and Endocrine Control
Hypothalamus provides highest level of endocrine
control
Coordinating centers in hypothalamus regulate
nervous and endocrine systems in three ways
 The Pituitary Gland
Also called the hypophysis

Protected by the sella
turcica
Hangs from hypothalamus
by infundibulum
Anterior and posterior
have very different structure
Secretes nine hormones
All are unique peptides or small proteins
All use cAMP second messenger mechanism
 The Anterior Lobe of the Pituitary Gland

Contains endocrine cells

Cells are surrounded by a complex capillary bed

The capillaries are part of the hypophyseal portal

system
Two capillary networks and the blood vessels that link
the networks are called a portal system

Named after their destinations (in this case the
hypophysis or pituitary gland)
The Hypophyseal
Portal System

Regulatory hormones diffuse onto target cells in
anterior lobe
Many of these hormones are tropic hormones meaning they
target other endocrine glands
 The Seven Anterior Lobe Hormones

1. Thyroid-stimulating hormone (TSH)
2. Adrenocorticotropic hormone (ACTH)
3. Follicle-stimulating hormone (FSH)
4. Luteinizing hormone (LH)
5. Prolactin (PRL)
6. Growth hormone (GH)
7. Melanocyte-stimulating hormone (MSH)
 Thyroid-stimulating Hormone
Also called thyrotropin
Released in response to
thyrotropin-releasing
hormone (TRH) from
hypothalamus
Targets thyroid gland
Triggers release of
thyroid hormones
Increases in thyroid
hormones cause
decrease in TRH and TSH secretion
 Adrenocorticotropic Hormone (ACTH)
Also called
corticotropin
Released in response
to corticotropin-
releasing hormone
(CRH) from the
hypothalamus
Targets adrenal cortex
Stimulates secretion of
glucocorticoids
Increases in glucocorticoids cause decrease in ACTH and
CRH secretion
 Gonadotropins

Released in response to gonadotropin-releasing
hormone (GnRH) from hypothalamus

Target the male and female gonads

Testes in males and ovaries in females

Include two hormones

Follicle-stimulating hormone (FSH)

Luteinizing hormone (LH)
 Follicle-stimulating Hormone (FSH)
Promotes follicle
development in
females
Promotes sperm
production in males
Cells of ovaries and
testes produce inhibin
Inhibits FSH production
through negative
feedback
 Luteinizing Hormone (LH)
Induces ovulation and
secretion of estrogens and
progesterone in females
In males, also called
interstitial cell-stimulating
hormone (ICSH)
Stimulates interstitial cells
endocrine cells of the testes
to produce androgens such
as testosterone
Estrogens, progesterone, and androgens inhibit
GnRH (which in turn decreases levels of LH)
 Prolactin (PRL)
Released in response to
prolactin-releasing factor
(PRF) from the hypothalamus
Targets mammary glands in
females
With other hormones,
stimulates mammary gland
development
In pregnancy and nursing,
stimulates production of milk
Circulating PRL stimulates
prolactin-inhibiting hormone
(PIH) and inhibits PRF
 Growth Hormone
Also called human growth hormone (hGH) and
somatotropin
Regulated by:
Growth hormone-releasing hormone (GH–RH) and growth
hormone-inhibiting hormone (GH–IH) from the
hypothalamus
Stimulates cell growth and replication of all cells, but
especially skeletal muscle and chondrocytes
Indirect action
Stimulates liver to release somatomedins or insulin-like
growth factors (IGFs), triggering an increase in amino acid
uptake and protein synthesis by cells following a meal
Somatomedins stimulate GH–IH and inhibit GH–RH
 Direct Actions of Growth Hormone
In epithelial and connective
tissues
Stimulates stem cell division and
differentiation
In adipose tissue
Stimulates breakdown of stored
fats and release of fatty acids, a
glucose-sparing effect
In the liver
Stimulates breakdown of
glycogen reserves and
release of glucose into
bloodstream
 Melanocyte-stimulating Hormone (MSH)

Increases activity of melanocytes in skin to
increase melanin production
Appears to be nonfunctional in adults
MSH is secreted
During fetal development
In very young children
In pregnant women
In certain diseases

Even in these situations, function unknown
 The Posterior Lobe of the Pituitary Gland

Contains axons from two groups of hypothalamic

neurons

The two hormones produced are:

1. Antidiuretic hormone (ADH)

2. Oxytocin (OXT)

Hormones transported within the axons and then

into capillaries of the posterior pituitary lobe
 Antidiuretic Hormone (ADH)

Also called vasopressin

Released when the body is low on water

Stimulated by increase in concentration of solutes in the
blood or decrease in blood volume and pressure

Primary target is kidney to decrease water loss

Triggers vasoconstriction to increase blood pressure
 Oxytocin (OXT)
In women, stimulates contraction of uterine
muscles during labor and delivery
Also stimulates contraction of cells surrounding
milk secretory cells in mammary glands
Plays an unclear role in sexual activity
In men, stimulates smooth muscle in walls of sperm duct,
potentially aiding in emission
In women, may stimulate smooth muscle contractions in
the uterus and vagina promoting sperm transport
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The Thyroid Gland
Found anterior to
trachea and inferior to
thyroid cartilage
Has two lobes
connected by narrow
isthmus
Contains many spherical
thyroid follicles
Lined by simple cuboidal
epithelium
Filled with viscous colloid
containing many proteins and
thyroid hormone molecules
 The Thyroid Follicles
Follicular cells make thyroid hormones that are
then stored in colloid
TSH causes release of thyroid hormones
Majority are transported bound to plasma proteins
Provides large reserves of thyroid hormones
Derived from amino acid tyrosine, and iodine
Thyroxine (T4) or tetraiodothyronine
has four atoms of iodine
Triiodothyronine (T3) has three iodine
atoms
More potent
than T4
 The Effects of Thyroid Hormones
Affect nearly every cell in body
Increase rate of ATP production in mitochondria
Activate genes coding for enzymes involved in glycolysis
and energy production
Enzymes increase rate of metabolism
Calorigenic effect is when cell uses more energy,
measured in calories, and heat is produced
Thyroid hormones essential to normal development
of skeletal, muscular, and nervous systems
 The C Cells of the Thyroid Gland
Also called parafollicular cells, are found between
follicles and produce calcitonin (CT)
Stimulated by increases in plasma Ca2+
Inhibits osteoclasts in bone
Stimulates calcium excretion by kidneys
Essential for normal bone growth in children and last
trimester of pregnancy
 Calcium Balance and Calcitonin

Hypercalcemia (high blood calcium level) causes:
Decreased sodium permeability of excitable membranes
Results in less responsive muscles and nerves
 The Parathyroid Glands

Two pairs of small glands embedded in posterior
surface of thyroid gland
 The Parathyroid Glands Cont.
Parathyroid principal or chief cells produce
parathyroid hormone (PTH)
Stimulated by decrease in plasma Ca2+
Activates osteoclasts and inhibits osteoblasts in bone
Reduces calcium excretion by kidney
Stimulates kidney to secrete calcitriol, which increases
Ca2+ and PO43- absorption in digestive tract
 Calcium Balance and PTH

Hypocalcemia (low blood calcium level) causes:
Increased sodium permeability of excitable membranes
Highly excitable, spasmodic muscles and neurons
Convulsions or muscular spasms
Parathyroid glands prevent hypocalcemia
The Adrenal Gland

Also called the suprarenal gland
Yellow, pyramid-shaped
Sits on superior border of each kidney
Two portions: adrenal cortex and
adrenal medulla
 The Adrenal Cortex
Contains high levels of cholesterol and fatty acids
Produces more than 24 steroid hormones
called corticosteroids
Are essential for metabolic
functions and vital to life
Transported in plasma bound to
proteins
Three zones of cortex produce
three types
1. Zona glomerulosa produces
mineralocorticoids
2. Zona fasciculata produces
glucocorticoids
3. Zona reticularis produces
androgens
 Mineralocorticoids
Also called MCs
Affect electrolyte balance in body fluids

Aldosterone – major MC
Secreted in response to low plasma Na+, low BP, high
plasma K+, or presence of angiotensin II
Triggers reabsorption of sodium ions and elimination of
potassium ions
Prevents loss of sodium in urine, sweat, saliva, and
digestive secretions
Secondarily triggers water reabsorption through osmosis
 Glucocorticoids
Also called GCs
Affect glucose metabolism

Most important are cortisol (hydrocortisone),
corticosterone, and cortisone
Secreted in response to ACTH
Increase rates of glucose synthesis and glycogen
formation, resulting in increase in blood glucose levels
Also act as anti-inflammatory
 The Androgens

Small quantities produced in both males and
females
Some converted to estrogens in plasma
Stimulate development of pubic hair in boys and
girls before puberty
Not important in adult men
In adult women, produce muscle mass, blood cell
formation, and support sex drive
 The Adrenal Medulla
Highly vascular
Contains cells similar to sympathetic ganglia
Innervated by preganglionic sympathetic fibers
Two groups of secretory cells produce:
Epinephrine (E, or adrenaline); 75–80 percent of
secretions
Norepinephrine (NE, or noradrenaline); 20–25 percent
Hormones trigger metabolic changes to increase
availability of energy molecules
Support and prolong overall sympathetic response
 The Pineal Gland
Located on posterior portion of roof of third
ventricle
Contains neurons, glial cells, and secretory cells
that produce melatonin
Rate of secretion affected by light and day–night cycles
May influence timing of sexual maturation
May protect CNS neurons with antioxidant activity
Plays role in maintaining circadian rhythms (day–night
cycles)
 The Endocrine Pancreas
Pancreas lies between stomach and proximal
small intestine
Contains both exocrine and endocrine cells
 The Endocrine Pancreas Cont.

Endocrine cells located in pancreatic islets, or
islets of Langerhans
Account for only 1 percent
of all pancreatic cells
Alpha cells secrete the
hormone glucagon
Beta cells secrete the
hormone insulin
 Blood Glucose and Insulin
Increases in blood glucose levels activate beta cells
to release more insulin
Stimulates glucose uptake by cells that have insulin
receptors, all cells except:
Neurons and red blood cells, epithelial cells of kidney
tubules, epithelial cells of intestinal lining
Increases rates
of protein synthesis
and fat storage
Result is lower
blood glucose
level
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 Blood Glucose and Glucagon
Decreases in blood glucose levels activate alpha
cells to release more glucagon
Mobilizes energy reserves
Glycogen in liver and muscles broken down to glucose
Adipose tissue releases fatty acids
Result is

higher
blood
glucose level
 Pancreatic Regulation of Blood Glucose
Secretion of insulin and glucagon is independent of
direct neural stimulus
Indirectly affected by any hormone that also
influences blood glucose levels
Examples: cortisol and thyroid hormones

Also affected by ANS activity
Parasympathetic stimulation enhances insulin release
Sympathetic stimulation inhibits insulin release
 Diabetes Mellitus
Faulty glucose metabolism causing buildup of
glucose in the blood and urine
Type 1 diabetes (juvenile diabetes)
Inadequate insulin production

Type 2 diabetes
Display insulin resistance where tissues do not respond
properly to insulin
Symptoms: hyperglycemia, glycosuria, polyuria
Diabetes Mellitus Cont.
 Secondary Endocrine Organs

Many organs
release hormones,
but their primary
function is in
another system
Examples:
intestines, kidneys,
heart, thymus,
gonads, and
adipose tissue
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 The Intestines

Release local
hormones that
coordinate
digestive activities
Major control over
rate of digestive
processes
Can be influenced
by ANS
 Hormones Released by the Kidneys
Calcitriol
Stimulated by PTH, derived from vitamin D3, increases
absorption of calcium and phosphate ions from digestive
tract
Erythropoietin, or EPO
Stimulated by low oxygen levels in kidney tissues,
causes increase in RBC production
Renin
An enzyme that triggers hormonal chain reaction (renin-
angiotensin-aldosterone system) to increase blood
pressure and blood volume
 The Heart
Endocrine cells in right atrium of heart
Respond to increased blood volume entering
chamber
Excessive stretch causes them to release atrial
natriuretic peptide (ANP)
Promotes loss of sodium, and therefore water
Inhibits release of renin, ADH, and aldosterone
Results in decrease in blood pressure and blood volume
 The Thymus

Located deep to sternum in mediastinum
Very active in early childhood, atrophies in adults
Releases thymosins
Aid in development and maintenance of immune
defenses
 The Gonads: The Testes
In males, interstitial endocrine cells of testes
produce androgens
Most important is testosterone
Promotes sperm production
Maintains secretory glands of male reproductive tract
Determines secondary sex characteristics
Stimulates protein synthesis in skeletal muscles
Sperm production balance maintained by inhibin
Secreted by nurse cells in the testes
 The Gonads: The Ovaries

In ovaries, the female sex cells (oocytes) are
surrounded by follicles
FSH triggers follicular cells to produce:
Estrogens
Support maturation of egg cell and growth of uterine lining

Inhibin
Provides negative feedback to FSH
 The Gonads: The Ovaries cont.
Once follicle releases an oocyte (ovulation) the
corpus luteum is formed from remaining follicular
cells
Releases mixture of estrogens and progesterone
Accelerates fertilized egg movement through uterine tube
Prepares uterus for arrival of developing embryo
Contributes to mammary gland enlargement

All gonadal hormones regulated by hormones of
the anterior pituitary gland
 Adipose Tissue

Produces peptide hormone leptin
Provides negative feedback control of appetite
Binds to neurons in hypothalamus to trigger satiation
(fullness) and suppression of appetite
Must be present for normal levels of GnRH and
gonadotropin synthesis
Low body fat can result in late puberty and cessation of
menstrual cycles
Increase in body fat can increase fertility
 Hormonal Interactions
Extracellular fluid contains mixture of hormones
that may have the same target, resulting in four
possibilities:
1. Antagonistic (opposing) effects
Example: parathyroid hormone and calcitonin
2. Synergistic effects
Net result of two is greater than the sum of their individual
effects
3. Permissive effects
Need for one hormone to be present for another to work
4. Integrative effects
Hormones may have different but complementary effects
Important in coordinating diverse physiological activities
 Hormones and Growth
Six key hormones required for normal growth
1. Growth hormone (GH)
Supports muscular and skeletal development
Undersecretion causes dwarfism
Oversecretion causes gigantism

2. Thyroid hormones
Required for normal nervous system development

3. Insulin
Required for energy supply to growing cells
 Hormones and Growth cont.

4. Parathyroid hormone (PTH)
Promotes calcium availability for normal bone growth

5. Calcitriol
Promotes absorption of calcium for building bone
Lack of PTH and calcitriol can result in rickets

6. Reproductive hormones
Can affect activity of osteoblasts and influence secondary
sex characteristic development
 Hormones and Stress
Stress is triggered by:
Physical injury or disease
Emotional responses: anxiety or depression
Environmental conditions: extreme cold or heat
Metabolic conditions: acute starvation

Stress triggers:
The general adaptation syndrome (GAS)
Also called the stress response
Three phases: alarm, resistance, exhaustion
 Hormones and Behavior
Hypothalamus is key hormone regulator and
monitor
Behavior is also affected by hormonal
abnormalities
Precocious puberty can occur when sex hormones are
released at an earlier than normal age
Results in more aggressive and assertive behavior

CNS intellectual functions like learning, memory, and
emotions can be altered in the adult due to hormone
imbalances
 Hormones and Aging

Usually most hormones remain the same
throughout adulthood
Exceptions are the reproductive hormones
Changes to target organ receptors more likely to
occur through reduced sensitivity
 Endocrine System Integration with Other
Systems
Endocrine system
provides long-term
regulation and
adjustment of
homeostatic
processes
Adjusts metabolic
rates of all systems
Regulates growth
and development
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