The Mechanisms of Drug Actions in Pharmacology

THE MECHANISMS
OF
DRUG ACTIONS
SEDAT ALTUĞ MD PHD
FACULTY OF PHARMACY
DEPARTMENT of
PHARMACOLOGY
March 2017

PHARMACODYNAMICS
• The actions of a drug on the body and the influence of
drug concentrations on the magnitude of the response.
• Most drugs exert their effects, both beneficial and
harmful, by interacting with receptors present on the cell
surface or within the cell.
• The drug–receptor complex initiates alterations in
biochemical and/or molecular activity of a cell by a
process called signal transduction

PHARMACODYNAMICS
• Drugs act as signals, and their receptors act as signal
detectors.
• Receptors transduce their recognition of a bound agonist
by initiating a series of reactions that ultimately result in a
specific intracellular response.
• “Second messenger” or effector molecules are part of the
cascade of events that translates agonist binding into a
cellular response.

THE DRUG–RECEPTOR COMPLEX
• Cells have many different types of receptors, each of
which is specific for a particular agonist and produces a
unique response.
• Cardiac cell membranes, for example, contain β receptors
that bind and respond toepinephrine or norepinephrine,
as well as muscarinic receptors specific for acetylcholine.
• These different receptor populations dynamically interact
to control the heart’s vital functions.

The recognition of a drug by a receptor triggers a biologic response

RESPONSE
• The magnitude of the response is proportional to the number
of drug–receptor complexes.
• This concept is closely related to the formation of complexes
between enzyme and substrate.
• These interactions have many common features, perhaps the
most noteworthy being specificity of the receptor for a given
agonist.

RECEPTORS
• Most receptors are named for the type of agonist that
interacts best with it.
• For example, the receptor for histamine is called a histamine
receptor.
• it is important to know that not all drugs exert their effects by
interacting with a receptor.
• Antacids, for instance, chemically neutralize excess gastric
acid, thereby reducing the symptoms of “heartburn.”

RECEPTORS
• Specific molecules in a biologic system with which drugs
interact to produce changes in the function of the system.
• Selective in their ligand-binding characteristics (so as to
respond to the proper chemical signal and not to
meaningless ones).
• Modifiable when they bind a drug molecule (so as to bring
about the functional change).
• Proteins; a few are other macromolecules such as DNA.

RECEPTORS
• Once an agonist drug has bound to its receptor, some effector
mechanism is activated.
• The receptor-effector system may be an enzyme in the intracellular
space (eg, cyclooxygenase, a target of nonsteroidal anti-
inflammatory drugs) or in the membrane or extracellular space (eg,
acetylcholinesterase).
• Neurotransmitter reuptake transporters (eg, the norepinephrine
transporter, NET, and the dopamine transporter, DAT) are receptors
for many drugs, eg, antidepressants and cocaine. Most
antiarrhythmic drugs target voltage-activated ion channels in the
membrane for sodium, potassium, or calcium.
• For the largest group of drug-receptor interactions, the drug is
present in the extracellular space, whereas the effector mechanism
resides inside the cell and modifies some intracellular process.

RECEPTOR STATES
• Receptors exist in at least two states, inactive (R) and active
(R*), that are in reversible equilibrium with one another,
usually favoring the inactive state.
• Binding of agonists causes the equilibrium to shift from R to
R* to produce a biologic effect.
• Antagonists occupy the receptor but do not increase the
fraction of R* and may stabilize the receptor in the inactive
state.

RECEPTOR STATES
• Some drugs (partial agonists) cause similar shifts in
equilibrium from R to R*, but the fraction of R* is less than
that caused by an agonist (but still more than that caused
by an antagonist).
• The magnitude of biological effect is directly related to the
fraction of R*.
• Agonists, antagonists, and partial agonists are examples
of ligands, or molecules that bind to the activation site on
the receptor.

MAJOR RECEPTOR FAMILIES
• Pharmacology defines a receptor as any biologic molecule to
which a drug binds and produces a measurable response.
• Thus, enzymes, nucleic acids, and structural proteins can act
as receptors for drugs or endogenous agonists.
• However, the richest sources of therapeutically relevant
pharmacologic receptors are proteins that transduce
extracellular signals into intracellular responses.

FOUR FAMILIES
1) Ligand-gated Ion Channels,
2) G Protein–Coupled Receptors,
3) Enzyme-Linked Receptors
4) Intracellular Receptors.

Transmembrane signaling mechanisms. A. Ligand binds to the extracellular
domain of a ligand-gated channel. B. Ligand binds to a domain of a
transmembrane receptor, which is coupled to a G protein. C. Ligand binds to the
extracellular domain of a receptor that activates a kinase enzyme. D. Lipid-soluble
ligand diffuses across the membrane to interact with its intracellular receptor. R =
inactive protein.

RECEPTOR
• The type of receptor a ligand interacts with depends on
the chemical nature of the ligand.
• Hydrophilic ligands interact with receptors that are found
on the cell surface.
• In contrast, hydrophobic ligands enter cells through the
lipid bilayers of the cell membrane to interact with
receptors found inside cells

TRANSMEMBRANE LIGAND-GATED ION CHANNELS:
• The extracellular portion of ligand-gated ion channels usually contains
the ligand binding site
• This site regulates the shape of the pore through which ions can flow
across cell membranes
• The channel is usually closed until the receptor is activated by an
agonist, which opens the channel briefly for a few milliseconds
• Depending on the ion conducted through these channels, these
receptors mediate diverse functions, including neurotransmission, and
cardiac or muscle contraction.

TRANSMEMBRANE LIGAND-GATED ION CHANNELS:
• For example, stimulation of the nicotinic receptor by
acetylcholine results in sodium influx and potassium outflux,
generating an action potential in a neuron or contraction in
skeletal muscle.
• On the other hand, agonist stimulation of the γ-aminobutyric
acid (GABA) receptor increases chloride influx and
hyperpolarization of neurons.
• Voltage-gated ion channels may also possess ligand-binding
sites that can regulate channel function.
• For example, local anesthetics bind to the voltage-gated sodium
channel, inhibiting sodium influx and decreasing neuronal
conduction

TRANSMEMBRANE G PROTEIN–COUPLED RECEPTORS
• The extracellular domain of this receptor contains the
ligand-binding area, and the intracellular domain interacts
(when activated) with a G protein or effector molecule.
• There are many kinds of G proteins (for example, Gs, Gi,
and Gq), but they all are composed of three protein
subunits.
• The α subunit binds guanosine triphosphate (GTP), and
the β and γ subunits anchor the G protein in the cell
membrane (Figure 2.3).

• Binding of an agonist to the receptor increases GTP binding to the
α subunit, causing dissociation of the α-GTP complex from the βγ
complex.
• These two complexes can then interact with other cellular effectors,
usually an enzyme, a protein, or an ion channel, that are
responsible for further actions within the cell.
• These responses usually last several seconds to minutes.
Sometimes, the activated effectors produce second messengers
that further activate other effectors in the cell, causing a signal
cascade effect.

• A common effector, activated by Gs and inhibited by Gi, is adenylyl
cyclase, which produces the second messenger cyclic adenosine
monophosphate (cAMP).
• Gq activates phospholipase C, generating two other second
messengers: inositol 1,4,5-trisphosphate (IP3) and diacylglycerol
(DAG).
• DAG and cAMP activate different protein kinases within the cell,
leading to a myriad of physiological effects. IP3 regulates
intracellular free calcium concentrations, as well as some protein
kinases.

The recognition of chemical signals
by G protein–coupled membrane
receptors affects the activity of
adenylyl cyclase. PPi = inorganic
pyrophosphate.

The Mechanisms of Drug Actions in Pharmacology

ENZYME-LINKED RECEPTORS:
• This family of receptors consists of a protein that may form
dimers or multi subunit complexes.
• When activated, these receptors undergo conformational
changes resulting in increased cytosolic enzyme activity,
depending on their structure and function (Figure 2.4).
• This response lasts on the order of minutes to hours.
• The most common enzyme linked receptors (epidermal growth
factor, platelet-derived growth factor, atrial natriuretic peptide,
insulin, and others) possess tyrosine kinase activity as part of
their structure.

ENZYME-LINKED RECEPTORS:
• The activated receptor phosphorylates tyrosine residues on
itself and then other specific proteins (Figure 2.4).
• Phosphorylation can substantially modify the structure of the
target protein, thereby acting as a molecular switch.
• For example, when the peptide hormone insulin binds to two
of its receptor subunits, their intrinsic tyrosine kinase activity
causes autophosphorylation of the receptor itself.
• In turn, the phosphorylated receptor phosphorylates other
peptides or proteins that subsequently activate other
important cellular signals.
• This cascade of activations results in a multiplication of the
initial signal, much like that with G protein–coupled
receptors.

INTRACELLULAR RECEPTORS
• The fourth family of receptors differs considerably from the
other three in that the receptor is entirely intracellular, and,
therefore, the ligand must diffuse into the cell to interact with
the receptor (Figure 2.5).
• In order to move across the target cell membrane, the ligand
must have sufficient lipid solubility. The primary targets of
these ligand– receptor complexes are transcription factors in
the cell nucleus.
• Binding of the ligand with its receptor generally activates the
receptor via dissociation from a variety of binding proteins.
• The activated ligand–receptor complex then translocates to
the nucleus, where it often dimerizes before binding to
transcription factors that regulate gene expression.

INTRACELLULAR RECEPTORS
• The activation or inactivation of these factors causes the
transcription of DNA into RNA and translation of RNA into an
array of proteins.
• The time course of activation and response of these receptors
is on the order of hours to days. For example, steroid
hormones exert their action on target cells via intracellular
receptors.
• Other targets of intracellular ligands are structural proteins,
enzymes, RNA, and ribosomes. For example, tubulin is the
target of antineoplastic agents such as paclitaxel (see
Chapter 46), the enzyme dihydrofolate reductase is the target
of antimicrobials such as trimethoprim (see Chapter 40), and
the 50S subunit of the bacterial ribosome is the target of
macrolide antibiotics such as erythromycin (see Chapter 39).

SIGNAL TRANSDUCTION
Signal transduction has two important features:
1) The ability to amplify small signals and
2) Mechanisms to protect the cell from excessive
stimulation.

SIGNAL AMPLIFICATION
• A characteristic of G protein–linked and enzyme-linked receptors
is their ability to amplify signal intensity and duration.
• For example, a single agonist–receptor complex can interact with
many G proteins, thereby multiplying the original signal manyfold.
• Additionally, activated G proteins persist for a longer duration than
does the original agonist–receptor complex.
• The binding of albuterol, for example, may only exist for a few
milliseconds, but the subsequent activated G proteins may last for
hundreds of milliseconds.
• Further prolongation and amplification of the initial signal are
mediated by the interaction between G proteins and their
respective intracellular targets.

SIGNAL AMPLIFICATION
• Because of this amplification, only a fraction of the total receptors
for a specific ligand may need to be occupied to elicit a maximal
response.
• Systems that exhibit this behavior are said to have spare receptors.
• Spare receptors are exhibited by insulin receptors, where it is
estimated that 99% of receptors are “spare.”
• This constitutes an immense functional reserve that ensures that
adequate amounts of glucose enter the cell.
• On the other hand, in the human heart, only about 5% to 10% of the
total β-adrenoceptors are spare.
• An important implication of this observation is that little functional
reserve exists in the failing heart, because most receptors must be
occupied to obtain maximum contractility.

DESENSITIZATION AND DOWN-
REGULATION OF RECEPTORS:
• Repeated or continuous administration of an agonist (or an
antagonist) may lead to changes in the responsiveness of the
receptor. To prevent potential damage to the cell (for example,
high concentrations of calcium, initiating cell death), several
mechanisms have evolved to protect a cell from excessive
stimulation.
• When a receptor is exposed to repeated administration of an
agonist, the receptor becomes desensitized (Figure 2.6)
resulting in a diminished effect. This phenomenon, called
tachyphylaxis, is due to either phosphorylation or a similar
chemical event that renders receptors on the cell surface
unresponsive to the ligand.

• In addition, receptors may be down-regulated such that they
are internalized and sequestered within the cell, unavailable
for further agonist interaction.
• These receptors may be recycled to the cell surface,
restoring sensitivity, or, alternatively, may be further
processed and degraded, decreasing the total number of
receptors available.
• Some receptors, particularly ion channels, require a finite
time following stimulation before they can be activated again.
During this recovery phase, unresponsive receptors are said
to be “refractory.”

• Similarly, repeated exposure of a receptor to an antagonist
may result in up-regulation of receptors, in which receptor
reserves are inserted into the membrane, increasing the
total number of receptors available.
• Up-regulation of receptors can make the cells more
sensitive to agonists and/or more resistant to the effect of
the antagonist.

ALLOSTERIC ANTAGONISTS
do not bind to the agonist receptor site; they bind to some
other region of the receptor molecule that results in
inhibition of the response to agonists
They do not prevent binding of the agonist. In contrast,
pharmacologic antagonists bind to the agonist site and
prevent access of the agonist.
The difference can be detected experimentally by evaluating
competition between the binding of radioisotopically labeled
antagonist and the agonist.
High concentrations of agonist displace or prevent the
binding of a pharmacologic antagonist but not an allosteric
antagonist.

The Mechanisms of Drug Actions in Pharmacology

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