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Foundations of Pharmacology PHAR2210

Receptors and other Drug Targets

A/Prof Lynette Fernandes

These lecture slides and associated unit materials are the intellectual property of
A/Prof Lynette Fernandes and should not be shared without her permission.
Sharing course materials without permission breaches UWA’s student conduct regulations
and may constitute a breach of the Copyright Act 1968.
 Learning outcomes
For each of the 4 receptor superfamilies, describe the following major
characteristic features
– mechanism of signal transduction
– receptor location
– effector protein(s)
– time scale of action
– agonists
Explain the role of ion channels, enzymes, and transporters as drug
targets
Identify examples of drugs used at various targets
 Resources
Pharmacology Education Project
https://www.pharmacologyeducation.org/pharmacology/pharmacodynamics
Selected figures on the LMS from Goodman and Gilman’s The
Pharmacological Basis of Therapeutics 13th edition 2017 McGraw-Hill
Education. Pharmacodynamics: Molecular Mechanisms of Drug Action.
Chapter 3
Rang and Dale’s Pharmacology, 10th edition 2024, London Elsevier. How
drugs act: Molecular aspects.
 “A drug will not work unless it is bound”
Paul Ehrlich (1854-1915)

Most drugs produce their effects by binding to protein targets
– receptors
– ion channels
– enzymes
– transporters or carrier molecules
 Receptor superfamilies

Receptors sub-divided into 4 major types or
superfamilies
1. ion channel receptors
2. G protein-coupled receptors
3. enzyme-linked receptors
4. nuclear receptors
 Receptor superfamilies

Superfamilies are distinguished
– based on how they transduce the signal
– NOT on which chemical signals stimulate them
– NOT on the nature of the change in cell function
Receptors within a particular superfamily use similar
transduction processes and so tend to have similar
general structures
 Ion channel receptors
drug

Principles of Pharmacology. D.E. Golan. Lippincott Williams & Wilkins. 2005
 Ion channel receptors
Located in the cell membrane
Collection of proteins form central pore / channel
No agonist, ion channel closed, no ion flow

nicotinic acetylcholine closed ion channel
receptor
Principles of Pharmacology. D.E. Golan. Lippincott Williams & Wilkins. 2005
 Ion channel receptors
Ions cannot cross the cell membrane
ACh binding alters ion channel structure and ions flow into
the cell
nicotinic acetylcholine receptor
ACh ACh Na+

Na+
closed ion channel open ion channel
Principles of Pharmacology. D.E. Golan. Lippincott Williams & Wilkins. 2005
 Ion channel receptors

subunit unfolded
protein structure
membrane

Rang and Dale’s Pharmacology, 2024

location of receptor: membrane
effector: channel
respond to: fast neurotransmitters
time scale of action: milliseconds, very fast
example: nicotinic acetylcholine receptor

Pancuronium, a nicotinic acetylcholine receptor antagonist, is used to produce paralysis
during anaesthesia
G protein-coupled receptors

drug

Principles of Pharmacology. D.E. Golan. Lippincott Williams & Wilkins. 2005
 G protein-coupled receptors

membrane

Rang and Dale’s Pharmacology, 2024

location of receptor: membrane
7 transmembrane domains
effector: enzyme or channel
respond to: hormones, slow neurotransmitters
time scale of action: seconds, fast
examples: adrenoceptors,
muscarinic acetylcholine receptors
Salbutamol, a b2-adrenoceptor agonist relieves bronchospasm in asthma
 G proteins
G proteins
– intracellular effector systems or 2nd messenger cascades
– guanosine nucleotide binding proteins, GTP and GDP
– comprise 3 subunits (a, b, g)
Main classes of Ga protein
1. Gas activates adenylate cyclase
2. Gai inhibits adenylate cyclase
3. Gaq activates phospholipase C
G proteins link GPCRs to effector proteins that generate intracellular
second messengers
– (Gas) adenylate cyclase generates cAMP
– (Gaq) phospholipase C generates inositol trisphosphate and diacylglycerol
GPCR activation: airway smooth muscle
RELAXATION (effect)

cyclic AMP (2nd messenger)

adenylate cyclase
(transduction/effector protein)
s

Gs (stimulatory G protein)

b2-adrenoceptor (receptor)

salbutamol (agonist)
Rang and Dale’s Pharmacology, 2024
Enzyme-linked receptors
drug

Principles of Pharmacology. D.E. Golan. Lippincott Williams & Wilkins. 2005
 Enzyme-linked receptors

membrane
enzyme (e.g., kinase which
phosphorylates proteins)
Rang and Dale’s Pharmacology, 2024

location of receptor: membrane
effector: enzyme
respond to: metabolism, growth, differentiation
time scale of action: minutes, slow
examples: insulin receptor, receptors for cytokines, growth
factors
In diabetes, insulin is used to activate the insulin receptor, reducing blood glucose levels
 Insulin receptor

tyrosine kinase

intracellular proteins

Principles of Pharmacology. D.E. Golan. Lippincott Williams & Wilkins. 2005
 Nuclear receptors
drug

Principles of Pharmacology. D.E. Golan. Lippincott Williams & Wilkins. 2005
 Nuclear receptors

Rang and Dale’s Pharmacology, 2024

location of receptor: intracellular
effector: gene transcription
respond to: steroid hormones, other factors
time scale of action: hours, very slow
examples: glucocorticoid, other steroid hormones

Glucocorticoid drugs such as prednisolone are effective anti-inflammatory agents
 Glucocorticoid receptor

(cortisol)

Principles of Pharmacology. D.E. Golan. Lippincott Williams & Wilkins. 2005
 Protein targets for drug action

Receptors
Ion channels
– effect of drugs?
Enzymes
– effect of drugs?
Transporters
– effect of drugs?
 Receptors as drug targets
Agonists bind to and activate receptors
Antagonists bind to, but do not activate receptors

Agonist

Antagonist

Rang and Dale’s Pharmacology, 2024
 Ion channels as drug targets
Blockers physically plug the ion channel
– nifedipine is a Ca2+ channel blocker used to treat hypertension
Modulators bind to accessory sites and modulate channel activity
– benzodiazepines enhance GABA-activated Cl- channel opening,
used to treat anxiety

Blocker

Modulator

Rang and Dale’s Pharmacology, 2024
 Enzymes as drug targets
Substrate analogues competitively inhibit the enzyme
– analgesics like paracetamol inhibit cyclooxygenase

Inhibitor

False
substrate

Pro-drug

Rang and Dale’s Pharmacology, 2024
 Enzymes as drug targets
Some drugs act as false substrates for enzymes
– anti-cancer drug fluorouracil replaces uracil in purine biosynthesis,
blocking DNA synthesis

Inhibitor

False
substrate

Pro-drug

Rang and Dale’s Pharmacology, 2024
 Enzymes as drug targets
Pro-drugs must be enzymatically converted to become active
– ciclesonide is converted to the active metabolite in the lung, resulting
in fewer adverse effects in non-airways

Inhibitor

False
substrate

Pro-drug

Rang and Dale’s Pharmacology, 2024
 Transporters as drug targets
Specific carrier proteins transport ions and small organic molecules
across cell membranes
– glucose, amino acids, neurotransmitters, Na+, Ca2+ etc.
Some drugs inhibit transporters
– anti-depressant drug fluoxetine inhibits the re-uptake of the neurotransmitter
serotonin into neurones

Normal
transport

Inhibitor
Rang and Dale’s Pharmacology, 2024
 Transporters as drug targets
False substrates
– CNS stimulant amphetamine uses the noradrenaline transporter to enter nerve
terminals and replace/release the neurotransmitters noradrenaline and serotonin

Normal
transport

False
substrate
Rang and Dale’s Pharmacology, 2024