Hormonal Responses to Exercise PDF

Summary

These lecture notes detail hormonal responses to exercise. The document covers neuroendocrinology, hormone classes, mechanisms, and control. The notes also include discussion of specific hormones and their roles in exercise.

Full Transcript

HORMONAL RESPONSES
TO EXERCISE
Chapter 5
Lecture Outline

Neuroendocrinology.
Hormones: Regulation and Action.
Hormonal Control of Substrate Mobilization during Exercise.
 Neuroendocrinology
Branch of physiology focused on control systems
Nervous system releases neurotransmitters to
relay messages from nerve to nerve or from
nerve to tissues

Endocrine system releases hormones from
endocrine glands in the blood to reach target
tissues

Hormones (ligands) bind to specific proteins
(receptors) on target tissues and alter the
activity of those tissues

Ligand-receptor interaction causes a response
in the target cell called signal transduction
Classes of Hormones
Hormones can be divided based on chemical make up into
amino acid derivatives

peptides

proteins

steroids
Classes of Hormones
The structure of a hormone determines its mechanisms of

transport
signal transduction (how it exerts it effects)

The most important chemical characteristic is whether the hormone
can dissolve in water or cross the plasma membrane (lipid bilayer)

Lipophilic hormones – lipid-soluble

Cross membrane easily, don’t dissolve in water

Lipophobic hormones – water-soluble

Don’t cross membrane, do dissolve in water
 Hormone Effectiveness

Hormone effect on a tissue is influenced by:

Number of receptors available for binding

Plasma concentration of the hormone
 Blood hormone concentration
Plasma concentration of a hormone determined by:
Rate of secretion of hormone from the endocrine gland

Magnitude of input

Excitatory or inhibitory input

Rate of metabolism or excretion of hormone

Hormone inactivation at the receptor and/or removal by liver and kidneys

Quantity, capacity and affinity of transport proteins

Steroids and thyroid hormones are transported bound to a protein but to
exert their effects they need to be “free” to interact with the receptor

Changes in plasma volume

During exercise, plasma volume ↓ which causes a slight ↑ in hormone
concentration in plasma
Check your understanding
__________ release hormones directly into the blood to
alter the activity of tissues possessing receptors to which
that hormone can bind.
The ____________ and ___________ determine the
magnitude of the hormone effect at the tissue level.
The plasma hormone concentration can be changed by
altering the rate of ___________ or ___________ and
___________ of the hormone, the quantity, capacity and
affinity of ____________, and the plasma ________.
Hormone secretion can be controlled by several factors

EXAMPLE: Insulin secretion is determined by sum of inhibitory
vs. stimulatory input
Metabolism and Excretion of Hormones
Many hormones are altered or destroyed upon binding

Excess hormones are removed from the blood by:
Liver – metabolizes hormones (major site of hormone metabolism)
Kidneys – metabolize or excrete excess hormones into the urine

During exercise, what happens to blood flow to the liver and kidneys?
How might this impact the rate of hormone metabolism and
excretion during exercise?
How, then, would this impact blood hormone concentration levels
during exercise?
 Hormone-receptor interactions
Hormones are carried to all tissues but only affect those tissues with specific
receptors (proteins) capable of binding those hormones

Magnitude of effect dependents on:

Concentration of the hormone
Number of receptors on the cell
Affinity of the receptor for the hormone

Downregulation:↓ in receptor number in response to chronically high concentration
of hormone

Upregulation: ↑ in receptor number in response to chronically low concentration of
hormone

Chemicals with similar “shape” as a hormone will compete for the limited receptor
sites.

Receptors can be located in various parts of the cell:
Membrane
Cytoplasm
Nucleus
Mechanisms of Hormone Action
Altering activity of DNA to modify protein synthesis
Steroid hormones

Activating second messengers via G protein
Cyclic AMP
Ca++
Inositol triphosphate
Diacylglycerol

Altering membrane transport
Insulin via tyrosine kinase
Altering Activity of DNA in Nucleus
Lipophilic Hormones

Steroids and thyroid hormones

Receptor in the cytoplasm (translocation) or
in the nucleus

Slow-acting, longer lasting effects
Mechanism of Steroid Hormone Action
 Membrane Transport
Lipophobic Hormones

Hormones bind receptors located on the outer surface of the cell membrane
and activate carrier molecules in or near the membrane to increase movement
of some ion or substrate from outside to inside the cell
 Second Messengers
Some hormones cannot easily cross cell membranes because these hormones
are too large or highly charged

These hormones exert their effects by binding to a receptor on the membrane
surface and activating a G protein located in the membrane.

The G protein is the link between the hormone-receptor interaction and the
subsequent events inside the cell.

The G protein may activate an enzyme in the membrane or open an ion channel
to allow Ca++ to enter the cell
Second Messengers

Glycogen Glucose

Caffeine phosphorylase

+

+
hormone sensitive lipase

Triglycerides FFAs
Second Messengers
Ca2+ Channel Activation
G-protein can activate
Ca2+ ion channels
Ca2+ enters the cell and
activates calmodulin

Activation of membrane-
* bound phospholipase C →
* Phosphotidylinositol (PIP2)
is hydrolyzed to:
Inositol triphosphate (IP3) →
intracellular Ca2+ release
Diacylglycerol → activates
* Protein Kinase C

These second messengers
are not independent because
changes in one can affect
* Second messengers action of the other.
Check your understanding
The hormone-_________ interaction triggers events at the cell

Changing the ___________ of the hormone, the _______ of receptors on the
cell, or the _________ of the receptor for the hormone will all influence the
magnitude of the effect.

Hormones bring about their effects by

activating/suppressing genes to alter _______________

activating ____________ messengers

modifying membrane ___________
Hormones: Regulation and Action
Hormones are secreted from endocrine glands
Major glands include:
Hypothalamus and pituitary glands

Thyroid and parathyroid glands

Adrenal glands

Pancreas

Testes and ovaries
Growth Hormone
Secreted by anterior pituitary gland

Stimulates release of insulin-like growth factors (IGFs)

IGF-1 responsible for muscle hypertrophy

Essential for normal growth of all tissues

Stimulates amino acid uptake and protein synthesis

Long bone growth

Growth hormone spares plasma glucose

Opposes insulin action, reduces the use of plasma glucose

Increases gluconeogenesis in liver

Mobilizes fatty acids from adipose tissue
Growth hormone and performance
A Closer Look 5.1

GH increases protein synthesis in muscle and long bone growth.
Used to treat childhood dwarfism.
Also used by athletes and elderly.

High doses of GH results in more adverse effects than benefits.

No evidence that GH promotes strength gains.
Minimal strength gains compared to resistance training alone.

Questionable benefits as anti-aging therapy.
 Antidiuretic hormone (ADH) or vasopressin
Secreted by hypothalamus and stored/released by posterior pituitary gland

Reduces water loss from the body to maintain plasma volume

Favors reabsorption of water from kidney tubules to capillaries.

Release stimulated by high plasma osmolality (low water concentration)
and low plasma volume

due to sweat loss without water replacement

Increases during exercise >60% VO2 max

to maintain plasma volume
Thyroid gland
Stimulated by TSH.

Triiodothyronine (T3) and thyroxine (T4).
Influences resting metabolic rate.
Permissive hormones.
Permit full effect of other hormones.

Calcitonin.
Involved in the regulation of plasma Ca++.
Blocks Ca++ release from bone, stimulates excretion by kidneys.
 The Adrenal Gland
Adrenal gland = two glands

Adrenal medulla secretes catecholamines:
epinephrine and norepinephrine
fast acting hormones
part of “fight or flight” response

Adrenal cortex secretes steroid hormones
derived from cholesterol:
Mineralocorticoids (aldosterone)
Glucocorticoids (cortisol)
Sex steroids (androgens & estrogens)
 Adrenal Medulla
Catecholamines:
Epinephrine (adrenaline) – 80% and norepinephrine – 20%
bind adrenergic receptors and change cellular activity via second messengers:
Alpha Receptors (α1, α2)
Beta Receptors (β1, β2, β3 )
Magnitude and direction (inhibitory vs. excitatory) of the response depends on
which ligand binds with which receptor
 Aldosterone
▪ Control Na+ and K+ concentration in plasma

▪ Stimulated by:

Increased K+ concentration

Decreased plasma volume

Increased SNS activity to kidney

▪ Regulation of Na+/H2O balance

▪ blood volume and blood pressure

Part of renin-angiotensin-aldosterone system

All three hormones increase during heavy exercise
Cortisol
Stimulated by:

Exercise

Stress

Makes amino acids available for tissue repair

Maintenance of plasma glucose during long-term fasting and exercise

Promotes protein breakdown for gluconeogenesis

Stimulates FFA mobilization from adipose tissue

Stimulates glucose synthesis

Blocks uptake of glucose into cells

forcing cells to use more free fatty acids as fuel
 Check your understanding
▪ The adrenal cortex secretes ____________ (mineralcorticoid), _________
(glucocorticoid), and ___________ (sex steroids).
▪ Aldosterone regulates __________ balance. Aldosterone secretion
_________ with strenuous exercise.
▪ ________ responds to a variety of stressors, including exercise, to ensure
that fuel (glucose and free fatty acids) is available, and to make amino
acids available for tissue repair.
 Adipose Tissue Is an Endocrine Organ
In addition to storing triglycerides, adipose tissue also secretes hormones

Leptin

Suppresses appetite through the hypothalamus

Enhances insulin sensitivity and fatty acid oxidation

Adiponectin

Increases insulin sensitivity and fatty acid oxidation

With increased fat mass (obesity)

Higher leptin levels and lower adiponectin

Leads to type 2 diabetes and low-grade inflammation

Exercise does not affect adiponectin or leptin concentration

These hormones are more responsive to changes in body weight
 The Pancreas – Insulin and Glucagon
Insulin ( cells)
Promotes the storage of
glucose, amino acids, and fats

Glucagon ( cells)
Promotes the mobilization of
FFAs and glucose

Somatostatin (from  cells)
Controls rate of entry of nutrients
into the circulation

Digestive enzymes and bicarbonate
Into the small intestine
The Gonads – Sex Hormones
Testosterone – anabolic, androgenic steroid hormone secreted by the testes

Promotes tissue (muscle) building

Anabolic steroids

Originally developed for medical uses

Chronic endurance exercise has been shown to decrease plasma
[testosterone]

Estrogen – steroid hormone secreted by the ovaries

Plays a significant role in bone health

Chronic endurance training can lead to decreased plasma [estrogen], which
can lead to osteoporosis
Anabolic Steroids and Performance
Initial studies showed no benefit for developing muscle mass

In contrast to real-world reports

“Subjects” used 10 to 100 times the recommended dosage

Also associated with negative side effects

Widespread use has led to testing of competitive athletes

Most users are not competitive athletes

Take more than one steroid in megadoses
 Check your understanding
Insulin is secreted by the ________ cells of the pancreas and promotes the
________ of glucose, amino acids, and fats.
Glucagon is secreted by the ______ cells of the pancreas and promotes the
_______ of glucose and fats.
Chronic endurance exercise (training) can __________ testosterone levels
in males and estrogen levels in females.
Muscle as an Endocrine Gland
▪ Skeletal muscle produces myokines when it contracts

Stimulate glucose uptake and fatty acid oxidation

Promote blood vessel growth in muscle

Promote liver glucose production and triglyceride breakdown

▪ Interleukin 6 (IL-6)

Both proinflammatory and anti-inflammatory effects

▪ IL-6 produced during exercise promotes anti-inflammatory effect

▪ Regular exercise promotes anti-inflammatory environment

Reduction in chronic inflammation and reduced risk of heart disease,
type 2 diabetes, and certain cancers
Hormonal Control of Substrate Utilization
Carbohydrate control is extremely important in the body, especially during
exercise

During prolonged exercise:

carbohydrates are necessary for fat oxidation

Greater reliance on blood-born substrates (glucose and FFA)

During intense exercise:

carbohydrates are the preferred substrate

Greater reliance on stored substrate (muscle glycogen)
Muscle glycogen breakdown under dual control
Plasma epinephrine is a powerful stimulator of glycogenolysis

Muscle
contraction

High-intensity exercise results in greater increases in plasma epinephrine
 Muscle Glycogen Utilization

Glycogenolysis is related to
exercise intensity

High-intensity exercise
results in greater and more
rapid glycogen depletion
Check your understanding
Glycogen breakdown to _______ in muscle is under the dual control of
epinephrine-cyclic AMP and Ca++-calmodulin.
The latter’s role is enhanced during exercise due to the increase in
________ from the sarcoplasmic reticulum. In this way, the delivery of
fuel (glucose) parallels the activation of contraction.
Blood Glucose Control During Exercise
The goal of hormones during exercise is to maintain plasma [glucose] during
times of increased rate of glucose removal from the circulation
Why is it necessary to make sure glucose is in the blood?…Don’t we want
it in the cells during exercise?!
BRAIN uses glucose!

Processes used to maintain plasma [glucose] during exercise:
Liver glycogenolysis
Liver gluconeogenesis from lactic acid, amino acids, glycerol
Mobilization of FFAs from adipose tissue
Spares glucose
Block glucose entry into cells
Forces FFA usage
Blood glucose homeostasis during exercise

Controlled by hormones.
Permissive or slow-acting.

Thyroxine, cortisol, and growth hormone.

Fast-acting.

Epinephrine, norepinephrine, insulin, and glucagon.
Thyroid Hormones
▪ Act in a permissive manner to allow other hormones to exert
their full effect

T3 enhances effect of epinephrine to mobilize free fatty acids
from adipose tissue

▪ No real change in T3 and T4 during exercise
 Cortisol
▪ Slow-acting hormone

▪ Effects:

Stimulates FFA mobilization from adipose tissue

Enhances gluconeogenesis in the liver

Decreases the rate of glucose utilization by cells

▪ Effect of exercise

Increases with exercise intensity

▪ Changes in cortisol may be related to repair of
exercise-induced tissue damage
 Growth Hormone
▪ Slow-acting hormone

▪ Effects:

Supports the action of cortisol

▪ Decreases glucose uptake by tissues

▪ Increases free fatty acid mobilization

▪ Enhances gluconeogenesis in the liver

▪ Exercise effect

Increase in plasma growth hormone with
increased intensity

Greater response in trained runners
Check your understanding
The hormones _________, __________ and __________ act in a permissive
manner to support the actions of other hormones during exercise.

____________ and ____________ also provide a “slow acting” effect on
carbohydrate and fat metabolism during exercise.
Epinephrine and Norepinephrine
▪ Fast-acting hormones

▪ Maintain blood glucose during exercise by

increasing muscle and liver glycogen
breakdown

increasing FFA mobilization and oxidation

blocking glucose uptake by the tissues

▪ Plasma Epinephrine and Norepinephrine increase
during exercise

Also related to increased heart rate and blood
pressure during exercise
Epinephrine and Norepinephrine
Submaximal intensity exercise

▪ Decreased plasma Epinephrine and Norepinephrine responses to a
fixed submaximal workload following endurance training
Epinephrine and Norepinephrine
Supramaximal intensity exercise

▪ Increased plasma Epinephrine and Norepinephrine in
trained individuals
 Fast-Acting Hormones Controlling Blood Glucose
Insulin vs. Glucagon

Insulin Glucagon
Uptake and storage of glucose and FFA Mobilization of glucose and FFA fuels
↓ during exercise ↑ during exercise
Effects of insulin and glucagon

Figure 5.26
 Effect On Blood
Hormone
[Glucose]
Epinephrine 
Norepinephrine 
Growth Hormone 
Cortisol 
Glucagon 
Insulin 
Check your understanding
Plasma glucose is maintained during exercise by ________ liver glycogen
mobilization, using ________ plasma FFA, __________ gluconeogenesis, and
____________ glucose uptake by tissues.

The _________ in plasma insulin and the __________ in plasma E, NE, GH,
glucagon, and cortisol during exercise control the above mechanisms to maintain
glucose concentration.

Glucose is taken up by muscle 7-20 times faster during exercise than at rest even
though plasma insulin ________. This is due to increases in the number of glucose
transporters due to high intracellular ________ and _______ insulin sensitivity.
Increased blood ______ also increases the delivery of __________ and __________
which facilitates glucose uptake. An ________ glucose uptake also increases
facilitated diffusion of glucose.

Training causes ___________ circulating levels of E and NE responses to fixed
submaximal exercise and ___________ circulating levels of E and NE responses to
supramaximal exercise.
Table 5.2: Summary of Hormonal Responses That Serve to Mobilize Fuels
and Preserve Blood Glucose During Exercise

Hormone Gland Exercise Action Effect on Fuel
Response Utilization
Glucagon Pancreas ↑ ↑ FFA mobilization Mobilizes fat fuels
(alpha-cells) ↑ Glycogenolysis Preserves blood
↓ Glucose uptake glucose
Insulin Pancreas ↓ ↑ Glucose, amino Stores fuels
(beta-cells) acid, and FFA Lowers blood
uptake into tissues glucose
 Table 5.2: Summary of Hormonal Responses That Serve to Mobilize Fuels
and Preserve Blood Glucose During Exercise

Hormone Gland Exercise Action Effect on Fuel
Response Utilization
Epinephrine Adrenal ↑ ↑ Muscle and liver Mobilizes both fat and
Norepinephrine medulla glycogenolysis carbohydrate fuels

Cortisol Adrenal ↑ ↑ FFA mobilization Mobilizes fat fuels
cortex ↑ Gluconeogenesis Preserves blood
↓ Glucose uptake glucose
Growth hormone Anterior ↑ ↑ FFA mobilization Mobilizes fat fuels
pituitary ↑ Gluconeogenesis Preserves blood
↓ Glucose uptake glucose
FFA mobilization decreases during heavy exercise
This occurs in spite of persisting hormonal stimulation for FFA mobilization

Possible Reasons Why:
1. High levels of lactic acid
promotes re-synthesis of
2 triglycerides
2. Elevated [H+] due to
increased lactate inhibits
hormone sensitive lipase
3. Inadequate blood flow to
adipose
4. Insufficient albumin to
1 transport FFA in plasma
Check your understanding
The plasma FFA concentration ___________ during heavy exercise even though the
adipose cell is stimulated by a variety of hormones to increase triglyceride breakdown
to _____________ and _______. This may be due to:

(1) the higher H+ concentration, which may inhibit _________

(2) the high levels of lactate during heavy exercise promoting the resynthesis of
_______________

(3) an inadequate ___________ to adipose tissue, or

(4) insufficient ________ needed to transport the FFA in the plasma.