Chapter 45 Hormones
and the Endocrine System
Lecture Outline
Overview: The Body’s
Long-Distance Regulators
·
An
animal hormone is a chemical signal
that is secreted into the circulatory system that communicates regulatory
messages within the body.
°
A
hormone may reach all parts of the body, but only specific target cells respond
to specific hormones.
°
A
given hormone traveling in the bloodstream elicits specific responses from its
target cells, while other cell types ignore that particular hormone.
Concept 45.1 The endocrine system and the nervous
system act individually and together in regulating an animal’s physiology
·
Animals
have two systems of internal communication and regulation, the nervous system
and the endocrine system.
·
Collectively,
all of an animal’s hormone-secreting cells constitute its endocrine system.
°
Hormones
coordinate slow but long-acting responses to stimuli such as stress,
dehydration, and low blood glucose levels.
°
Hormones
also regulate long-term developmental processes such as growth and development
of primary and secondary sexual characteristics.
·
Hormone-secreting
organs called endocrine glands
secrete hormones directly into the extracellular fluid, where they diffuse into
the blood.
·
The
nervous and endocrine systems overlap to some extent.
°
Certain
specialized nerve cells known as neurosecretory
cells release hormones into the blood.
°
The
hormones produced by these cells are sometimes called neurohormones.
·
Chemicals
such as epinephrine serve as both hormones of the endocrine system and neurotransmitters
in the nervous system.
·
The
nervous system plays a role in certain sustained responses—controlling
day/night cycles and reproductive cycles in many animals, for example—often by
increasing or decreasing secretions from endocrine glands.
·
The
fundamental concepts of biological control systems are important in regulation
by hormones.
°
A
receptor, or sensor, detects a stimulus and sends information to a control center.
°
After
comparing the incoming information to a set point, the control center sends out
a signal that directs an effector to
respond.
°
In
endocrine and neuroendocrine pathways, this outgoing signal, called an efferent system, is a hormone or
neurohormone, which acts on particular effector tissues and elicits specific
physiological or developmental changes.
·
The
three types of simple hormonal pathways (simple endocrine pathway, simple
neurohormone pathway, and simple neuroendocrine pathway) include these basic
functional components.
·
A
common feature of control pathways is a feedback loop connecting the response
to the initial stimulus.
·
In
negative feedback, the effector
response reduces the initial stimulus, and eventually the response ceases.
°
This
prevents overreaction by the system.
°
Negative
feedback regulates many endocrine and nervous mechanisms.
·
Positive
feedback reinforces the stimulus and leads to an even greater response.
°
The
neurohormone pathway that regulates the release of milk by a nursing mother is
an example of positive feedback.
§
Suckling
stimulates sensory nerve cells in the nipples, which send nervous signals that
reach the hypothalamus, the control center.
§
The
hypothalamus triggers the release of the neurohormone oxytocin from the
posterior pituitary gland.
à
Oxytocin
causes the mammary glands to secrete milk.
§
The
release of milk in turn leads to more suckling and stimulation of the pathway,
until the baby is satisfied.
Concept 45.2 Hormones and other chemical signals
bind to target cell receptors, initiating pathways that culminate in specific
cell responses
·
Hormones
convey information via the bloodstream to target cells throughout the body.
°
Other
chemical signals—local regulators—transmit information to target cells near the
secreting cells.
°
Pheromones
carry messages to different individuals of a species.
·
Three
major classes of molecules function as hormones in vertebrates: proteins and
peptides, amines, and steroids.
°
Most
protein/peptides and amine hormones are water-soluble, unlike steroid hormones.
·
Signaling
by all hormones involves three key events: reception, signal transduction, and
response.
°
Reception of the signal occurs when
the signal molecule binds to a specific receptor protein in or on the target
cell.
°
Binding
of a signal molecule to a receptor protein triggers signal transduction within the target cell that results in a response, a change in the cell’s
behavior.
§
Cells
that lack receptors for a particular chemical signal are unresponsive to that
signal.
Water-soluble hormones have cell-surface
receptors.
·
The
receptors for water-soluble hormones are embedded in the plasma membrane.
·
Binding
of a hormone to its receptor initiates a signal
transduction pathway, a series of changes in cellular proteins that
converts an extracellular chemical signal to a specific intracellular response.
°
The
response may be the activation of an enzyme, a change in uptake or secretion of
specific molecules, or rearrangement of the cytoskeleton.
°
Signal
transduction from some cell-surface receptors activates proteins in the
cytoplasm that move into the nucleus and directly or indirectly regulate gene
transcription.
·
An
example of the role of cell-surface receptors involves changes in a frog’s skin
color, an adaptation that helps camouflage the frog in changing light.
°
Skin
cells called melanocytes contain the dark pigment melanin in cytoplasmic organelles
called melanosomes.
§
The
frog’s skin appears light when melanosomes cluster tightly around the cell
nuclei and darker when they spread out in the cytoplasm.
°
A
peptide hormone called melanocyte-stimulating hormone controls the arrangement
of melanosomes and, thus, skin color.
°
Adding
melanocyte-stimulating hormone to the interstitial fluid containing the
pigment-containing cells causes the melanosomes to disperse.
§
However,
direct microinjection of melanocyte-stimulating hormone into individual melanocytes
has no effect.
°
This
provides evidence that interaction between the hormone and a surface receptor
is required for hormone action.
·
A
particular hormone may cause diverse responses in target cells having different
receptors for the hormone, different signal transduction pathways, and/or
different proteins for carrying out the response.
Lipid-soluble hormones have intracellular
receptors.
·
Evidence
for intracellular receptors for steroid hormones came in the 1960s.
°
Researchers
demonstrated that estrogen and progesterone accumulate within the nuclei of
cells in the reproductive tract of female rats but not in the nuclei of cells
in tissues that do not respond to estrogen.
°
These
observations led to the hypothesis that cells sensitive to steroid hormones
contain internal receptor molecules that bind the hormones.
·
Researchers
have since identified the intracellular protein receptors for steroid hormones,
thyroid hormones, and the hormonal form of vitamin D.
°
All
these hormones are small, nonpolar molecules that diffuse through the
phospholipid interior of cell membranes.
·
Intracellular
receptors usually perform the entire task of transducing the signal within the
target cell.
°
The
chemical signal activates the receptor, which directly triggers the cell’s
response.
°
In
almost every case, the intracellular receptor activated by a lipid-soluble
hormone is a transcription factor, and the response is a change in gene
expression.
·
Most
intracellular receptors are located in the nucleus.
°
The
hormone-receptor complexes bind to specific sites in the cell’s DNA and
stimulate the transcription of specific genes.
·
Some
steroid hormone receptors are trapped in the cytoplasm when no hormone is
present.
°
Binding
of a steroid hormone to its cytoplasmic receptor forms a hormone-receptor complex
that can move into the nucleus and stimulate transcription of specific genes.
·
In
both cases, mRNA produced in response to hormone stimulation is translated into
new protein in the cytoplasm.
°
For
example, estrogen induces cells in the reproductive system of a female bird to
synthesize large amount of ovalbumin, the main protein of egg white.
·
As
with hormones that bind to cell-surface receptors, hormones that bind to
intracellular receptors may exert different effects on different target cells.
A variety of local regulators affect
neighboring target cells.
·
Local
regulators convey messages between neighboring cells, a process referred to as
paracrine signaling.
°
Local
regulators can act on nearby target cells within seconds or milliseconds,
eliciting responses more quickly than hormones can.
°
Some
local regulators have cell-surface receptors; others have intracellular
receptors.
°
Binding
of local regulators to their receptors triggers events within target cells
similar to those elicited by hormones.
·
Several
types of chemical compounds function as local regulators.
°
Among
peptide/protein local regulators are cytokines,
which play a role in immune responses, and most growth factors, which stimulate cell proliferation and
differentiation.
°
Another
important local regulator is the gas nitric
oxide (NO).
§
When
blood oxygen level falls, endothelial cells synthesize and release NO.
§
NO
activates an enzyme that relaxes neighboring smooth muscle cells, dilating the
walls of blood vessels and improving blood flow to tissues.
§
Nitric
oxide also plays a role in male sexual function, increasing blood flow to the
penis to produce an erection.
§
Highly
reactive and potentially toxic, NO usually triggers changes in the target cell
within a few seconds of contact and then breaks down.
à
Viagra
sustains an erection by interfering with the breakdown of NO.
§
When
secreted by neurons, NO acts as a neurotransmitter.
§
When
secreted by white blood cells, it kills bacteria and cancer cells.
·
Local
regulators called prostaglandins (PGs)
are modified fatty acids derived from lipids in the plasma membrane.
°
Released
by most types of cells into interstitial fluids, prostaglandins regulate nearby
cells in various ways, depending on the tissue.
°
In
semen that reaches the female reproductive tract, prostaglandins trigger the
contraction of the smooth muscles of the uterine wall, helping sperm to reach
the egg.
°
PGs
secreted by the placenta cause the uterine muscles to become more excitable,
helping to induce uterine contractions during childbirth.
°
Other
PGs help induce fever and inflammation, and intensify the sensation of pain.
§
These
responses contribute to the body’s defense.
§
The
anti-inflammatory effects of aspirin and ibuprofen are due to the drugs’
inhibition of prostaglandin synthesis.
°
Prostaglandins
also help regulate the aggregation of platelets, an early stage in the
formation of blood clots.
§
This
is why people at risk for a heart attack may take daily low doses of aspirin.
°
In
the respiratory system, two prostaglandins have opposite effects on the smooth
muscle cells in the walls of blood vessels serving the lungs.
§
Prostaglandin
E signals the muscle cells to relax, dilating the blood vessels and promoting
oxygenation of the blood.
§
Prostaglandin
F signals the muscle cells to contract, constricting the vessels and reducing
blood flow through the lungs.
Concept 45.3 The hypothalamus and pituitary
integrate many functions of the vertebrate endocrine system
·
The
hypothalamus integrates vertebrate
endocrine and nervous function.
·
This
region of the lower brain receives information from nerves throughout the body
and from other parts of the brain then initiates endocrine signals appropriate
to environmental conditions.
·
The
hypothalamus contains two sets of neurosecretory cells whose hormonal
secretions are stored in or regulate the activity of the pituitary gland, located at the base of the hypothalamus.
·
The
posterior pituitary (neurohypophysis)
stores and secretes two hormones produced by the hypothalamus.
°
The
long axons of these cells carry the hormones to the posterior pituitary.
·
The
anterior pituitary (adenohypophysis)
consists of endocrine cells that synthesize and secrete at least six different
hormones directly into the blood.
°
Several
of these hormones have other endocrine glands as their targets.
§
Hormones
that regulate the function of endocrine glands are called tropic hormones.
§
They
are particularly important in coordinating endocrine signaling throughout the
body.
·
The
anterior pituitary itself is regulated by tropic hormones produced by a set of
neurosecretory cells in the hypothalamus.
°
Some
hypothalamic tropic hormones (releasing hormones) stimulate the anterior
pituitary to release its hormones.
°
Others
(inhibiting hormones) inhibit hormone secretion.
·
Hypothalamic
releasing and inhibiting hormones are secreted into capillaries at the base of
the hypothalamus.
°
The
capillaries drain into portal vessels that subdivide into a second capillary
bed within the anterior pituitary.
·
Every
anterior pituitary hormone is controlled by at least one releasing hormone.
°
Some
have both a releasing hormone and an inhibiting hormone.
·
The
posterior pituitary releases two hormones, oxytocin and antidiuretic hormone.
°
Both
are peptides made by neurosecretory cells in the hypothalamus and, thus, are
neurohormones.
·
Oxytocin induces contraction of
the uterus during childbirth and causes mammary glands to eject milk during
nursing.
°
Oxytocin
signaling in both cases exhibits positive feedback.
·
Antidiuretic hormone (ADH) promotes retention of
water by the kidneys, decreasing urine volume.
°
ADH
helps regulate osmolarity of the blood via negative feedback.
§
Secretion
is regulated by water/salt balance.
·
The
anterior pituitary produces many different hormones.
°
Four
function as tropic hormones, stimulating the synthesis and release of hormones
from the thyroid gland, adrenal glands, and gonads.
°
Several
others exert only direct, nontropic effects on nonendocrine organs.
°
One,
growth hormone, has both tropic and nontropic actions.
·
Three
of the tropic hormones secreted by the anterior pituitary are closely related
in their chemical structures.
°
Follicle-stimulating
hormone (FSH), luteinizing hormone (LH), and
thyroid-stimulating hormone (TSH) are similar glycoproteins.
§
FSH
and LH are also called gonadotropins
because they stimulate the activities of the gonads.
§
TSH
promotes normal development of the thyroid gland and the production of thyroid
hormones.
°
Adrenocorticotropic
hormone (ACTH)
is a peptide hormone that stimulates the production and secretion of steroid
hormones by the adrenal cortex.
·
All
four anterior pituitary tropic hormones participate in complex neuroendocrine
pathways.
°
In
each pathway, signals to the brain stimulate release of an anterior pituitary
tropic hormone.
°
The
tropic hormone then acts on its target endocrine tissue, stimulating secretion
of a hormone that exerts systemic metabolic or developmental effects.
·
Nontropic
hormones produced by the anterior pituitary include prolactin,
melanocyte-stimulating hormone (MSH), and ß-endorphin.
°
These
peptide/protein hormones, whose secretion is controlled by hypothalamic
hormones, function in simple neuroendocrine pathways.
°
Prolactin (PRL) stimulates mammary gland
growth and milk production and secretion in mammals.
§
It
regulates fat metabolism and reproduction in birds, delays metamorphosis in amphibians
(where it may also function as a larval growth hormone), and regulates salt and
water balance in freshwater fishes.
§
This
suggests that prolactin is an ancient hormone whose functions have diversified
during the evolution of various vertebrate groups.
§
Secretion
is regulated by hypothalamic hormones.
°
Melanocyte-stimulating
hormone (MSH)
regulates the activity of pigment-containing cells in the skin of some fishes,
amphibians, and reptiles.
§
In
mammals, MSH acts on neurons in the brain, inhibiting hunger.
°
ß-endorphin belongs to a class of
chemical signals called endorphins.
§
All
the endorphins bind to receptors in the brain and dull the perception of pain.
°
Both
MSH and ß-endorphin are formed by cleavage of the same precursor protein that
gives rise to ACTH.
·
Growth hormone (GH) is so similar
structurally to prolactin that scientists hypothesize the genes directing their
production evolved from the same ancestral gene.
°
GH
acts on a wide variety of target tissues with both tropic and nontropic
effects.
°
Its
major tropic action is to signal the liver to release insulin-like growth factors (IGFs), which circulate in the blood
and directly stimulate bone and cartilage growth.
§
In
the absence of GH, the skeleton of an immature animal stops growing.
°
GH
also exerts diverse metabolic effects that raise blood glucose, opposing the
effects of insulin.
°
Abnormal
production of GH can produce several disorders.
§
Gigantism
is caused by excessive GH production during development.
§
Acromegaly
is caused by excessive GH production during adulthood.
§
Pituitary
dwarfism is caused by childhood GH deficiency, and can be treated by therapy
with genetically engineered GH.
Concept 45.4 Nonpituitary hormones help
regulate metabolism, homeostasis, development, and behavior
Thyroid hormones function in development,
bioenergetics, and homeostasis.
·
The
thyroid gland of mammals consists of
two lobes located on the ventral surface of the trachea.
·
The
thyroid gland produces two very similar hormones derived from the amino acid
tyrosine: triiodothyronine (T3),
which contains three iodine atoms, and thyroxin
(T4), which contains four iodine atoms.
°
In
mammals, the thyroid secretes mainly T4, but target cells convert
most of it to T3 by removing one iodine atom.
§
Although
the same receptor molecule in the cell nucleus binds both hormones, the
receptor has greater affinity for T3 than for T4.
à
It
is primarily T3 that brings about responses in target cells.
°
This
process involves a complex neuroendocrine pathway with two negative feedback
loops.
·
The
thyroid plays a crucial role in vertebrate development and maturation.
°
Thyroid
controls metamorphosis of a tadpole into a frog, which involves massive
reorganization of many different tissues.
·
The
thyroid is equally important in human development.
°
Cretinism,
an inherited condition of thyroid deficiency, retards skeletal growth and
mental development.
·
The
thyroid gland has important homeostatic functions.
°
In
adult mammals, thyroid hormones help to maintain normal blood pressure, heart
rate, muscle tone, digestion, and reproductive functions.
·
Throughout
the body, T3 and T4 are important in bioenergetics,
increasing the rate of oxygen consumption and cellular metabolism.
·
Too
much or too little of these hormones can cause serious metabolic disorders.
°
Hyperthyroidism
is the excessive secretion of thyroid hormones, leading to high body
temperature, profuse sweating, weight loss, irritability, and high blood
pressure.
°
An
insufficient amount of thyroid hormones is known as hypothyroidism.
§
This
condition can cause cretinism in infants.
§
Adult
symptoms include weight gain, lethargy, and cold intolerance.
°
A
deficiency of iodine in the diet can result in goiter, an enlargement of the
thyroid gland.
§
Without
sufficient iodine, the thyroid gland cannot synthesize adequate amounts of T3
and T4.
à
The
resulting low blood levels of these hormones cannot exert negative feedback on
the hypothalamus and anterior pituitary.
à
The
pituitary continues to secrete TSH, elevating TSH levels and enlarging the
thyroid.
·
In
addition to cells that produce T3 and T4, the mammalian
thyroid gland produces calcitonin.
°
This
hormone acts in conjunction with parathyroid hormone to maintain calcium
homeostasis.
Parathyroid hormone and calcitonin balance
blood calcium.
·
Rigorous
homeostatic control of blood calcium level is critical because calcium ions (Ca2+)
are essential to the normal functioning of all cells.
°
If
blood Ca2+ falls substantially, skeletal muscles begin to
contract convulsively, a potentially fatal condition called tetany.
°
In
mammals, parathyroid hormone and calcitonin play a major role in maintaining
blood Ca2+ near a set point of about 10 mg/100 mL.
·
When
blood Ca2+ falls below the set point, parathyroid hormone (PTH) is released
from four small structures, the parathyroid
glands, embedded on the surface of the thyroid.
·
PTH
raises the level of blood Ca2+ by direct and indirect
effects.
°
In
bone, PTH induces specialized cells called osteoclasts to decompose the
mineralized matrix of bone and release Ca2+ into the
blood.
°
In
the kidneys, it promotes the conversion of vitamin D to its active hormonal
form.
§
An
inactive form of vitamin D is
obtained from food or synthesized in the skin.
°
The
active form of vitamin D acts directly on the intestines, stimulating the
uptake of Ca2+ from food.
°
A
rise in blood Ca2+ above the set point promotes release
of calcitonin from the thyroid
gland.
°
Calcitonin
exerts effects on bone and kidneys opposite those of PTH and thus lowers blood
Ca2+ levels.
·
The
regulation of blood Ca2+ levels illustrates how two
hormones with opposite effects (PTH and calcitonin) balance each other,
exerting tight regulation and maintaining homeostasis.
·
Each
hormone functions in a simple endocrine pathway in which the hormone-secreting
cells themselves monitor the variable being regulated.
°
In
classic feedback, the response to one hormone triggers release of the
antagonistic hormone, minimizing fluctuations in the concentration of Ca2+
levels in the blood.
Endocrine tissues of the pancreas secrete
insulin and glucagon, antagonistic hormones that regulate blood glucose.
·
The
pancreas has both endocrine and
exocrine functions.
°
Its
exocrine function is the secretion of bicarbonate ions and digestive enzymes,
which are released into small ducts and carried to the small intestine via the
pancreatic duct.
°
Tissues
and glands that discharge secretions into ducts are described as exocrine.
·
Clusters
of endocrine cells, the islets of
Langerhans, are scattered throughout the exocrine tissues of the pancreas.
°
Each
islet has a population of alpha cells,
which produce the hormone glucagon,
and a population of beta cells, which
produce the hormone insulin.
°
Both
hormones are secreted directly into the circulatory system.
·
Insulin
and glucagon are antagonistic hormones that regulate the concentration of
glucose in the blood.
°
This
is a critical bioenergetic and homeostatic function, because glucose is a major
fuel for cellular respiration and a key source of carbon skeletons for the
synthesis of other organic compounds.
·
Metabolic
balance depends on maintaining blood glucose concentrations near a set point of
about 90 mg/100 mL in humans.
°
When
blood glucose exceeds this level, insulin is released and lowers blood glucose.
°
When
blood glucose falls below this level, glucagon is released and its effects
increase blood glucose concentration.
°
Each
hormone operates in a simple endocrine pathway regulated by negative feedback.
·
Insulin
lowers blood glucose levels by stimulating all body cells (except brain cells)
to take up glucose from the blood.
°
Brain
cells can take up glucose without insulin and, thus, have access to circulating
fuel at all times.
·
Insulin
also decreases blood glucose by slowing glycogen breakdown in the liver and
inhibiting the conversion of amino acids and glycerol to glucose.
·
The
liver, skeletal muscles, and adipose tissues store large amounts of fuel and
are especially important in bioenergetics.
°
The
liver and muscles store sugar as glycogen, whereas adipose tissue cells convert
sugars to fats.
°
The
liver is a key fuel-processing center because only liver cells are sensitive to
glucagon.
·
The
antagonistic effects of glucagon and insulin are vital to glucose homeostasis
and regulation of fuel storage and fuel consumption by body cells.
·
The
liver’s ability to perform its vital roles in glucose homeostasis results from
the metabolic versatility of its cells and its access to absorbed nutrients via
the hepatic portal vein.
·
Diabetes mellitus is perhaps the best-known
endocrine disorder.
°
It
is caused by a deficiency of insulin or a depressed response to insulin in
target tissues.
§
There
are two types of diabetes mellitus with very different causes, but each is
marked by high blood glucose.
°
In
people with diabetes, elevated blood glucose exceeds the reabsorption capacity
of the kidneys, causing them to excrete glucose.
§
As
glucose is concentrated in the urine, more water is excreted with it, resulting
in excessive volumes of water and persistent thirst.
°
Without
sufficient glucose to meet the needs of most body cells, fat becomes the main
substrate for cellular respiration.
°
In
severe cases of diabetes, acidic metabolites formed during fat breakdown
accumulate in the blood, threatening life by lowering blood pH.
·
Type I diabetes mellitus (insulin-dependent
diabetes) is an autoimmune disorder in which the immune system destroys the
beta cells of the pancreas.
°
Type
I diabetes usually appears in childhood and destroys the person’s ability to
produce insulin.
°
The
treatment is insulin injections, usually several times a day.
°
Human
insulin is available from genetically engineered bacteria.
·
Type II diabetes mellitus (non-insulin-dependent
diabetes) is characterized by deficiency of insulin or, more commonly, by a
decreased responsiveness to insulin in target cells, due to some change in
insulin receptors.
°
This
form of diabetes occurs after age 40, and the risk increases with age.
°
Although
heredity can play a role in type II diabetes, excess body weight and lack of
exercise significantly increase the risk.
°
Type
II diabetes accounts for more than 90% of diabetes cases.
§
Many
type II diabetics can manage their blood glucose with regular exercise and a
healthful diet, although some require insulin injections.
The adrenal medulla and adrenal cortex help
the body manage stress.
·
The
adrenal glands are located adjacent
to the kidneys.
·
In
mammals, each adrenal gland is actually made up of two glands with different
cell types, functions, and embryonic origins.
°
The
adrenal cortex is the outer portion,
and the adrenal medulla is the
central portion.
·
Like
the pituitary, the adrenal gland is a fused endocrine and neuroendocrine gland.
°
The
adrenal cortex consists of true endocrine cells, while the secretory cells of
the adrenal medulla derive from the neural crest during embryonic development.
·
The
adrenal medulla produces two hormones, epinephrine
(adrenaline) and norepinephrine
(noradrenaline).
°
These
hormones are members of a class of hormones, the catecholamines, amines that are synthesized from the amino acid
tyrosine.
§
Both
are also neurotransmitters in the nervous system.
°
Either
positive or negative stress stimulates secretion of epinephrine and
norepinephrine from the adrenal medulla.
§
These
hormones act directly on several target tissues to give the body a rapid
bioenergetic boost.
à
They
increase the rate of glycogen breakdown in the liver and skeletal muscles,
promote glucose release into the blood by liver cells, and stimulate the
release of fatty acids from fat cells.
à
The
released glucose and fatty acids circulate in the blood and can be used by the
body as fuel.
°
Epinephrine
and norepinephrine also exert profound effects on the cardiovascular and
respiratory systems.
§
They
increase heart rate and stroke volume of the heartbeat and dilate the
bronchioles in the lungs to increase the rate of oxygen delivery to body cells.
§
Catecholamines
also act to shunt blood away from skin, digestive organs, and kidneys, and
increase blood supply to the heart, brain, and skeletal muscles.
·
Epinephrine
generally has a greater effect on heart and metabolic rates, while the primary
role of norepinephrine is in sustaining blood pressure.
·
Secretion
of these hormones by the adrenal medulla is stimulated by nerve signals carried
from the brain via the sympathetic division of the autonomic nervous system.
·
In
response to a stressful situation, nerve impulses from the hypothalamus travel
to the adrenal medulla, where they trigger the release of epinephrine.
°
Norepinephrine
is released independently.
·
The
adrenal medulla hormones act in a simple neurohormone pathway.
°
The
neurosecretory cells are modified peripheral nerve cells.
·
Hormones
from the adrenal cortex also function in the body’s response to stress.
·
Stressful
stimuli cause the hypothalamus to secrete a releasing hormone that stimulates
the anterior pituitary to release the tropic hormone ACTH.
·
When
ACTH reaches the adrenal cortex via the bloodstream, it stimulates the
endocrine cells to synthesize and secrete a family of steroids called corticosteroids.
°
Elevated
levels of corticosteroids in the blood suppress the secretion of ACTH.
·
The
two main types of corticosteroids in humans are the glucocorticoids, such as cortisol, and the mineralocorticoids, such as aldosterone.
°
Both
hormones help maintain homeostasis when stress is experienced over a long
period of time.
·
The
primary effect of glucocorticoids is on bioenergetics, specifically on glucose
metabolism.
°
Glucocorticoids
make more glucose available as fuel.
°
They
act on skeletal muscle, causing a breakdown of muscle proteins.
°
The
synthesis of glucose from muscle proteins is a homeostatic mechanism providing
circulating fuel when body activities require more than the liver can
metabolize from its metabolic stores.
·
Cortisol
and other glucocorticoids also suppress certain components of the body’s immune
system.
°
Because
of their anti-inflammatory effect, glucocorticoids have been used to treat inflammatory
diseases such as arthritis.
°
However,
long-term use of these hormones can have serious side effects due to their
metabolic actions and can also increase susceptibility to infection.
·
Mineralocorticoids
act principally on salt and water balance.
°
Aldosterone
stimulates cells in the kidneys to reabsorb Na+ and water from
filtrate, raising blood pressure and volume.
°
Aldosterone
secretion is stimulated primarily by angiotensin II, as part of the regulatory
pathway that controls the kidney’s ability to maintain ion and water
homeostasis of the blood.
°
When
an individual is under severe stress, the resulting rise in blood ACTH levels
can increase the rate at which the adrenal cortex secretes aldosterone as well
as glucocorticoids.
·
A
third group of corticosteroids is composed of sex hormones.
·
All
the steroid hormones are secreted from cholesterol, and their structures differ
in minor ways.
°
However,
these differences are associated with major differences in their effects.
·
The
sex hormones produced by the adrenal cortex are mainly male hormones
(androgens) with small amounts of female hormones (estrogens and progestins)
°
Androgens
secreted by the adrenal cortex may account for the female sex drive.
Gonadal steroids regulate growth, development,
reproductive cycles, and sexual behavior.
·
The
gonads are the primary source of the sex hormones.
·
The
gonads produce and secrete three major categories of steroid hormones:
androgens, estrogens, and progestins.
·
All
three types are found in males and females but in different proportions.
·
Sex
hormones affect growth and development and regulate reproductive cycles and
sexual behavior.
·
The
testes primarily synthesize androgens,
the main one being testosterone.
°
Androgens
promote development and maintenance of male sex characteristics.
°
Androgens
produced early in development determine whether a fetus develops as a male or a
female.
°
At
puberty, high levels of androgens are responsible for the development of male
secondary sex characteristics, including male patterns of hair growth, a low
voice, and increased muscle mass and bone mass typical of males.
°
The
muscle-building action of testosterone and other anabolic steroids has led some
athletes to take them as supplements.
§
Abuse
of these hormones carries many health risks, and they are banned in most
competitive sports.
·
Estrogens, the most important of
which is estradiol, are responsible for the development and maintenance of the
female reproductive system and the development of female secondary sex
characteristics.
·
In
mammals, progestins, which include
progesterone, are involved in promoting uterine lining growth to support the
growth and development of an embryo.
·
Both
estrogens and androgens are components of complex neuroendocrine pathways.
°
Their
secretion is controlled by gonadotropins (FSH and LH) from the anterior
pituitary gland.
°
FSH
and LH production is controlled by a releasing hormone from the hypothalamus,
GnRH (gonadotropin-releasing hormone).
The pineal gland is involved in biorhythms.
·
The
pineal gland is a small mass of tissue
near the center of the mammalian brain.
°
The
pineal gland synthesizes and secretes the hormone melatonin, an amine.
°
Depending
on the species, the pineal gland contains light-sensitive cells or has nervous
connections from the eyes that control its secretory activity.
°
Melatonin
regulates functions related to light and to seasons marked by changes in day
length.
°
Its
primary functions are related to biological rhythms associated with
reproduction.
§
Melatonin
secretion is regulated by light/dark cycles.
§
Melatonin
is secreted at night, and the amount secreted depends on the length of the
night.
§
Thus,
melatonin production is a link between a biological clock and daily or seasonal
activities such as reproduction.
°
Recent
evidence suggests that the main target cells of melatonin are the part of the
brain called the suprachiasmatic nucleus (SCN), which functions as a biological
clock.
§
Melatonin
seems to decrease the activity of neurons in the SCN, and this may be related
to its role in mediating rhythms.
°
Much
remains to be learned about the precise role of melatonin and about biological
clocks in general.
Concept 45.5 Invertebrate regulatory systems also
involve endocrine and nervous system interactions
·
Invertebrates
produce a variety of hormones in endocrine and neurosecretory cells.
·
Some
invertebrate hormones have homeostatic functions, such as regulation of water
balance.
·
Others
function in reproduction and development.
°
In
hydras, one hormone functions in growth and budding (asexual reproduction) but
prevents sexual reproduction.
°
In
the mollusc Aplysia, specialized
nerve cells secrete a neurohormone that stimulates the laying of thousands of
eggs and inhibits feeding and locomotion, activities that interfere with
reproduction.
·
All
groups of arthropods have extensive endocrine systems.
°
Crustaceans
have hormones for growth and reproduction, water balance, movement of pigments
in the integument and eyes, and regulation of metabolism.
·
Crustaceans
and insects grow in spurts, shedding the old exoskeleton and secreting a new
one with each molt.
°
Insects
acquire their adult characteristics in a single terminal molt.
°
In
all arthropods with exoskeletons, molting is triggered by a hormone.
·
The
hormonal control of insect development is well understood.
·
Brain hormone, produced by neurosecretory
cells in the brain, stimulates the release of ecdysone from the prothoracic
glands, a pair of endocrine glands behind the head.
·
Ecdysone promotes molting and the
development of adult characteristics.
·
Brain
hormone and ecdysone are balanced by juvenile
hormone, secreted by the corpora allata, a pair of small endocrine glands
that are somewhat analogous to the anterior pituitary of vertebrates.
°
As
the name suggests, juvenile hormone promotes the retention of larval (juvenile)
characteristics.
·
In
the presence of a high concentration of juvenile hormone, ecdysone still
stimulates molting, but the product is simply a larger larva.
·
Only
when the level of juvenile hormone declines can ecdysone-induced molting
produce a pupa.
°
Within
the pupa, metamorphosis produces the adult form.
·
Synthetic
juvenile hormone is used as insecticide to prevent insects from maturing to
reproductive adults.