Endocrine System PDF

Summary

This document is an overview of the endocrine system and its characteristics, including the types of hormones, their mechanisms of action, and regulatory functions. It also covers different aspects of the system, such as the different types of hormone secretion patterns, the control of hormone secretion, hormone receptors and mechanisms of action, and intracellular receptors.

Full Transcript

ENDOCRINE SYSTEM
PREPARED BY: ALARZAR
CHARACTERISTICS OF THE
ENDOCRINE SYSTEM

¡ Composed of endocrine glands
and specialized endocrine cells
¡ Secrete small amounts of
chemical messengers called
hormones
¡ Hormones diffuse into the
bloodstream going to their effectors
or target tissues
NERVOUS SYSTEM ENDOCRINE SYSTEM
Short Duration responses Long duration responses
Uses neurotransmitters Uses hormones
Some neurons secrete hormones
called neuropeptides
Affect receptors through G proteins Affect receptors through G protein
Neurotransmitters are released Hormones circulate in the blood
directly on their target cell
Responds faster Responds fast
Response duration lasts for as long as Remains active for a substantial
action potentials are sent length of time
Frequency modulated signals Amplitude moderated signals
HORMONES: GENERAL
CHARACTERISTICS

1. Stability * concept
of half-life
2. Communication
3. Distribution
 HORMONES: CHEMICAL COMPOSITION

¡ LIPID SOLUBLE
¡ Nonpolar
¡ Includes steroid hormones, thyroid
hormones and fatty acid derivative
hormones
¡ Travel in the bloodstream bound to
proteins
¡ Removed from the circulation through
CONJUGATION
¡ Enzymes in the liver attach water-soluble
molecules (sulfate/ glucuronic acid) where
kidneys and liver can easily excrete them
HORMONES: CHEMICAL
COMPOSITION
¡ WATER SOLUBLE HORMONES
¡ Polar molecules
¡ Includes protein hormones, peptide
hormones, most amino acid derivative
hormones
¡ Circulate as free hormones
¡ Have short half-lives due to hydrolytic
enzymes called PROTEASES
¡ Some modifications are made to protect
them from being destroyed: 1)
glycoproteins, 2) modified terminal end 3)
binding proteins
HORMONE SECRETION
PATTERN DESCRIPTION
1. Chronic Results in relatively constant blood levels over long periods of time e.g.
Thyroid hormones
2. Acute Concentration changes suddenly and irregularly e.g. Epinephrine
3. Episodic Secreted at fairly predictable intervals and concentrations e.g.
reproductive hormones
 CONTROL OF SECRETION
HUMORAL STIMULI NEURAL STIMULI HORMONAL STIMULI
Stimulation by metabolites Following action potentials, Hormones stimulate the
and molecules in the neurotransmitters are secretion of other hormones
bloodstream released into synapses of
hormone-producing cells e.g. tropic hormones
e.g. Calcium, Sodium, Glucose e.g. releasing hormones (released by anterior pituitary
(neuropeptides released by hormones)
the hypothalamus)
Release of companion Use of inhibitory Inhibiting hormones prevent
hormone that opposes the neurotransmitter secretion of other hormones
effects of the secreted e.g. excitatory and inhibitory e.g. thyroid hormones
hormone neurotransmitters inhibiting their own tropic
e.g. glucagon and insulin hormones
REGULATION OF HORMONE LEVELS
HORMONE RECEPTORS AND
MECHANISMS OF ACTION

¡ Hormones exert their actions by binding
to target cell proteins called
RECEPTORS
¡ RECEPTOR SITE – specific portion of
each receptor molecule where a
hormone binds to
¡ SPECIFICITY – tendency for each type
of hormone to bind to one type of
receptor and not to others
AGONISTS
AND
ANTAGONISTS

E.G. MORPHINE
NALOXONE
DECREASE AND INCREASE IN
RECEPTOR NUMBER

¡ DECREASE
¡ Responses of target tissues rapidly
decrease over time through
DESENSITIZATION
¡ Occurs when the number of receptors
rapidly decreases after exposure to certain
hormones (DOWN REGULATION)
¡ INCREASE
¡ UP-REGULATION happens when a target
tissue periodically increase sensitivity and
increase the rate of receptor synthesis in
target cells
INTRACELLULAR RECEPTORS

Lipid-soluble hormones bind with intracellular receptors
The receptor-hormone complex diffuses into the nucleus where it
activates genes
mRNA is produced
mRNA initiates the production of certain proteins (enzymes) that produce the
response of the target cell to the hormone
Intracellular receptor mechanisms are slow-acting because
time is required to produce the mRNA and the protein
CASCADE
EFFECT
ENDOCRINE GLANDS
MAIN REGULATORY FUNCTIONS OF THE ENDOCRINE SYSTEM

Control of food Modulation of
Regulation of Control of ion Control of water
intake and tissue
Metabolism levels balance
digestion development

Stimulation of
Control of blood Control of
Changes in heart uterine Modulation of
glucose and reproductive
rate and BP contractions and immune function
nutrients functions
milk
HYPOTHALAMUS

¡ ROSTRAL/ PREOPTIC AREA - Contains key
integrative circuitry for thermoregulation, fever,
electrolyte balance, wake-sleep circadian rhythms and
sexual behavior
¡ TUBERAL HYPOTHALAMUS (Middle) – contains
circuitry for feeding, sexual behavior, aggressiveness
and autonomic and endocrine responses
¡ POSTERIOR AREA – provides output to the arousal
system and hippocampus (role in regulating
wakefulness and stress response)

The hypothalamus. Saper, C. Lowell, B. Current Biology. Primer. Vol 24 Issue 23. December 2014.
https://www.cell.com/current-biology/fulltext/S0960-9822(14)01299-8?rss=yes&mobileUi=0
PITUITARY GLAND/
HYPOPHYSIS
¡ Rests at the sella turcica of the
sphenoid bone and roughly the
size of a pea
¡ Has 2 lobes: 1) POSTERIOR
PITUITARY GLAND
(neurohypophysis) and 2)
ANTERIOR PITUITARY GLAND
(adenohypophysis)
¡ INFUNDIBULIM – stalk of tissue
that connects the pituitary gland
and the hypothalamus
PITUITARY GLAND

¡ POSTERIOR PITUITARY GLAND
¡ Continuous with the hypothalamus in the brain
¡ Its hormones are called neuropeptides
¡ ANTERIOR PITUITATRY GLAND
¡ Develops from an out-pocketing of the roof of the
embryonic oral cavity
¡ Par intermedia – not functional in adults
¡ Produces traditional hormones
PITUITARY GLAND AND THE HYPOTHALAMUS

¡ The hypothalamus regulates the pituitary gland through:
¡ Anterior Pituitary - through specialized set of blood vessels called the
hypothalamohypophyseal portal system
¡ Releasing hormones – stimulate hormone secretion
¡ Inhibiting hormones – decrease hormone secretion
¡ Posterior Pituitary – through specialized neural pathway called the
hypothalamohypophyseal tract
HYPOTHALAMIC-
HYPOPHYSEAL
TRACT
HYPOPHYSEAL
PORTAL
SYSTEM
GIGANTISM
OXYTOCIN
ADH
SECRETION
GROWTH HORMONE

GH stimulates growth in most tissues and is a regulator of metabolism
GH stimulates
The uptake of amino acids and their conversion into proteins
The breakdown of fats and the synthesis of glucose
The production of somatomedins (with GH they promote bone and cartilage growth)
GH secretion increases in response to low blood glucose, stress, and an increase
in certain amino acids
GH is regulated by two hypothalamic hormones
Growth hormone-releasing hormone (GHRH)
Growth hormone-inhibiting hormone (GHIH)
THYROID GLAND
The largest endocrine gland
Located in the anterior neck
and consists of two lateral
lobes connected by a median
tissue mass called the
isthmus
Composed of follicles that
produce the glycoprotein
thyroglobulin
Other endocrine cells, the
parafollicular cells, produce
the hormone calcitonin
THYROID HORMONES

Consist of two related iodine-containing compounds
Triiodothyronine (T3): has two tyrosines with three bound iodine
atoms (90%)
Tetraiodothyronine (thyroxine or T4): has two tyrosine
molecules plus four bound iodine atoms (10%)
EFFECTS OF THYROID HORMONES

T3 and T4
Increase the rate of glucose, fat, and protein metabolism in many
tissues
Increase body temperature
T3 and T4 play a role in
Maintaining blood pressure
Regulating tissue growth
Developing skeletal and nervous systems
Maturation and reproductive capabilities
REGULATION OF THYROID HORMONE
SECRETION
Thyrotropin-releasing hormone (TRH) and
thyroid-stimulating hormone (TSH) regulate
T3 and T4 secretion
TRH from the hypothalamus increases
TSH secretion
Increases as a result of chronic
exposure to cold
Decreases as a result of food
deprivation, injury, and infection
Increased TSH from the anterior pituitary
increases T3 and T4 secretion
T3 and T4 inhibit TSH and TRH secretion
(negative feedback)
 Parafollicular cells secrete calcitonin
Directly regulated by blood Ca2+ levels
Blood Ca2+ levels drop = calcitonin levels drop
Blood Ca2+ levels rise = calcitonin levels rise
Calcitonin targets the skeleton to
Inhibit osteoclast activity and the release of
calcium from the bone matrix
CALCITONIN Stimulate calcium uptake and incorporation
into the bone matrix
PARATHYROID GLANDS

Tiny glands embedded in the
posterior aspect of the thyroid
Secrete a polypeptide hormone
called parathyroid hormone (PTH)
PTH is essential in regulating
calcium balance in the blood (much
more important than calcitonin)
¡ PTH increases the release of Ca2+
from bones into blood by
increasing the number of
osteoclasts
PARATHYROID HORMONE

PTH also
Promotes Ca2+ reabsorption by the kidneys
and the formation of active vitamin D by the
kidneys
Active vitamin D increases calcium absorption
by the intestine
A decrease in blood Ca2+ levels stimulates
PTH secretion
ADRENAL GLANDS

Paired, pyramid-shaped organs that sit on top of the kidneys
Divided into two parts
Adrenal medulla (inner area)
Arises from the same cells that give rise to postganglionic sympathetic neurons
Adrenal cortex (outer area)
Glandular tissue derived from embryonic mesoderm
Composed of three layers
Zona glomerulosa
Zona fasciculata
Zona reticularis
Structurally and functionally, they are four glands in one
HORMONES OF THE ADRENAL MEDULLA

Approximately 80% of the hormones released is epinephrine (adrenaline) and
20% is norepinephrine
Secretion of these hormones prepares the body for physical activity by:
Increasing blood glucose levels
Increasing the use of glycogen and glucose by skeletal muscle
Increasing heart rate and force of contraction
Causes vasoconstriction in the skin and viscera
Causes vasodilation in skeletal and cardiac muscle
Released by the sympathetic division of the ANS in response to
Emotions
Injury
Stress
HORMONES OF THE ADRENAL CORTEX

Synthesizes and releases
steroid hormones called
corticosteroids
Different corticosteroids are
produced in each of the three
layers
Zona
glomerulosa: mineralocorticoids
(chiefly aldosterone)
Zona fasciculata: glucocorticoids
(chiefly cortisol)
Zona reticularis: gonadocorticoids
(chiefly androgens)
ZONE GLOMERULOSA

Mineralocorticoids
Regulate electrolytes in extracellular fluids
Aldosterone: most important mineralocorticoid
Maintains Na+ balance by reducing excretion of sodium from the body
Stimulates reabsorption of Na+ by the kidneys
Decreases K+ and H+ levels in the blood
Aldosterone secretion is stimulated by:
Rising blood levels of K+
Low blood Na+
Decreasing blood volume or pressure
ZONA FASCICULATA

Glucocorticoids (especially cortisol)
Help the body resist stress by
Keeping blood sugar levels relatively constant
Maintaining blood volume and preventing water shift into tissue
Cortisol provokes
Gluconeogenesis (formation of glucose from non-carbohydrates)
Rises in blood glucose, fatty acids, and amino acids
Excessive levels of glucocorticoids
Depress cartilage and bone formation
Inhibit inflammation
Depress the immune system
Promote changes in cardiovascular, neural, and gastrointestinal function
ZONA RETICULARIS

Gonadocorticoids (Sex Hormones)
Most gonadocorticoids secreted are androgens (male sex
hormones), and the most important one is testosterone
Androgens contribute to:
The onset of puberty
The appearance of secondary sex characteristics
Sex drive in females
Androgens can be converted into estrogens after menopause
ADRENAL
MEDULLA
STIMULATION
ADRENAL
CORTEX
STIMULATION
PANCREAS

A triangular gland, which has both exocrine and
endocrine cells, located behind the stomach
Acinar cells produce an enzyme-rich juice used
for digestion (exocrine product)
Pancreatic islets (islets of Langerhans) produce
hormones (endocrine products)
The islets contain two major cell types:
Alpha (α) cells that produce glucagon
Beta (β) cells that produce insulin
INSULIN

Target tissues
Liver
Adipose tissue
Muscle
Satiety center in the hypothalamus
Nervous system relys on blood glucose levels maintained by
insulin
Increases the uptake of glucose and amino acids by cells
Glucose
Is used for energy
Stored as glycogen
Converted into fats
Amino acids are used to synthesize proteins
Low levels of insulin promote the formation of ketone bodies
by the liver
GLUCAGON

Target tissue is mainly the liver
Causes the breakdown of glycogen
to glucose
Stimulates the synthesis of glucose
from amino acids
Liver releases glucose into the
blood
THE PANCREATIC
TISSUE
REGULATION OF INSULIN
AND GLUCAGON
REGULATION OF
INSULIN SECRETION
HORMONAL REGULATION OF NUTRIENTS

After a meal, the following events take place
High glucose levels stimulate insulin secretion but inhibit glucagon, cortisol, GH, and
epinephrine secretion
Insulin increases the uptake of glucose, amino acids, and fats, which are used for energy
or are stored
Sometime after the meal, blood glucose levels drop
Insulin levels decrease and glucagon, GH, cortisol, and epinephrine levels increase
Glucose is released from tissues
The liver releases glucose into the blood, and the use of glucose by most tissues, other
than nervous tissue, decreases
Adipose tissue releases fatty acids and ketones, which most tissues use for energy
HORMONE REGULATION OF NUTRIENTS

During exercise, the following events occur
Sympathetic activity increases epinephrine and glucagon secretion,
causing a release of glucose from the liver into the blood
Low blood sugar levels, caused by the uptake of glucose by skeletal
muscles, stimulate epinephrine, glucagon, GH, and cortisol secretion
Causes an increase in fatty acids and ketones in the blood, all of which are
used for energy
TESTES AND OVARIES

Testes
Secrete testosterone
Initiates maturation of male reproductive organs
Causes appearance of secondary sexual
characteristics and sex drive
Is necessary for sperm production
Maintains sex organs in their functional state

Ovaries
Secrete estrogens and progesterone
Maturation of the reproductive organs
Appearance of secondary sexual characteristics
Breast development and cyclic changes in the uterine
mucosa
PINEAL BODY

Small, pinecone-shaped
structure located superior and
posterior to the thalamus
Secretory product is
melatonin
Melatonin
Can inhibit reproductive
maturation
May regulate sleep-wake cycles
THYMUS

Lobulated gland located deep
to the sternum
Major hormonal products are
thymopoietins and thymosins
These hormones are
essential for the development
of the T lymphocytes (T cells)
of the immune system
OTHER ENDOCRINE GLANDS

Gastrointestinal tract
Produces gastrin, secretin, and cholecystokinin, which regulate
digestive functions
Kidneys
Produce erythropoietin, which stimulates red blood cell production
Placenta
Secretes human chronic gonadotropin, which is essential for the
maintenance of pregnancy
HORMONE-LIKE SUBSTANCES

Autocrine agents
Chemical signals that locally affect cells of the same type as the cell producing the autocrine
agent
Prostaglandins, thromboxanes, prostacyclins, and leukotrienes
Paracrine agents
Chemical signals that locally affect cells of a different type than the cell producing the
paracrine agent
Growth factors, clotting factors, and histamine
Autocrine and paracrine chemical signals differ from hormones in that
They are not secreted from discrete endocrine glands
They have local effects rather than systemic effects
They have functions that are not understood in all cases
DEVELOPMENTAL ASPECTS

¡ Endocrine glands derive from all three germ layers.
Those derived from mesoderm produce steroid
hormones; the others produce the amino acid–based
hormones.
¡ The natural decrease in function of the female’s
ovaries during late middle age results in menopause.
¡ All endocrine glands gradually become less efficient
as aging occurs. This change leads to a generalized
increase in the incidence of diabetes mellitus and a
lower metabolic rate.