Receptor Pharmacology Lecture Notes PDF

Summary

These lecture notes cover Receptor Pharmacology, including the introduction to receptor pharmacology, ligand-receptor interactions, agonists, antagonists, and inverse agonists, and different types of receptors and signaling pathways. The notes also discuss the history of receptor theory and the different types of ligands.

Full Transcript

Receptor Pharmacology

1. Introduction to Receptor Pharmacology
2. Ligand-receptor interactions and Dose Response Relationships
3. Agonist, antagonist and Inverse Agonist
4. Cooperativity, allosteric interactions

Dr. Ly P. Vu
Assistant Professor, Faculty Pharmaceutical Sciences
Scientist, Terry Fox Laboratory, BC Cancer
Who is Dr. Ly Vu [email protected]
@Vuphuongly

Full name: Ly Phuong Vu or Vu Phuong Ly

Originally from Hanoi, Vietnam
U
Laboratory
BSc in Molecular Biology, Vietnam National University, Hanoi

PhD in Cancer Biology, Memorial Sloan Kettering Cancer Center, NY, NY, USA – thesis in transcriptional
control and histone modifying enzymes in blood stem cells and leukemia.

Post-doc in Molecular Pharmacology and Cancer Biology, Memorial Sloan Kettering Cancer Center, NY, NY,
USA

Joined Terry Fox Laboratory, BC Cancer July 2019

Joined Faculty of Pharmaceutical Sciences, UBC January 2022

Teach PHRM-100 (this lecture) and PHRM 333- Pharmacotherapy in Oncology
Introduction to Receptor Pharmacology
 What is receptor pharmacology –
why do we need to study this subject?
Ø Receptor pharmacology is the study of the interactions of receptors with drugs/pharmaceuticals
and other xenobiotics (substances that are foreign to the body).

Ø Majority of drugs target receptors act through their interaction with specific receptors.

Ø Understanding receptor pharmacology is fundamental for study of effects of drugs,

drug mechanisms of action and pharmacological features of drugs.
Learning Objectives

Define and describe different types of “receptors” and their “ligands”

Understand and describe the history of “Receptor Theory”

Name and describe examples of ligands/drugs that act on different types of
receptors
Definition of Receptors

! Receptor is the component of a cell that interacts with a specific ligand (e.g.
drug) and initiates the chain of events leading to the observed effect (adapted
from Katzung, 2011)

! Receptors are usually intracellular or membrane-bound proteins which produce a
pharmacological effect after binding with a specific ligand (e.g. drug)

! Macromolecules as receptors: protein; DNA and RNA
Why cells need Receptors ?
External Environment
DNA/gene

Genotype

A Cell mRNA

Phenotype
Protein
Why cells need Receptors ?

External Environment
DNA/gene
Interact with
neural system
Genotype
Interact with mRNA
other cells A Cell
within tissues

Phenotype
Interact with
Protein
Immune system
Why cells need Receptors ?

Signals External Environment
DNA/gene
Interact with Genotype
neural system

Interact with mRNA
other cells A Cell
Phenotype
within tissues
Receptors “receive” signals
for cell to ”know”:
Interact with ü what they are
Protein
Immune system ü where they are
ü what they do
Mode of delivering signals to receptors

5 types:
Ø Paracrine signaling molecules: target neighboring cells close to the release site.
Ø Endocrine (hormones): released by endocrine cells and reach target cells in one or more distant
body locations via blood circulation.
Ø Autocrine signaling molecules: target the same cell that secreted them.
Ø Neurotransmitters: are released by neurons and affect other neurons or effector cells near
the release site.
Ø Cell- cell interaction: between cells without chemical messengers
Why cells need Receptors ?

Signals External Environment
DNA/gene
Interact with Ligands Genotype
neural system

Interact with mRNA
other cells A Cell
Phenotype
within tissues
Receptors “receive” signals
for cell to ”know”:
Interact with ü what they are
Protein
Immune system ü where they are
ü what they do
Definition of Ligands

! Ligand is a molecule that binds to a receptor to send signals leading to a
change in cell signaling/activities, and ultimately, cell behavior or structure.

! Ligands bind specific receptors

! Ligands can be classified by different criteria

! There are two main types of ligands based on their location:

Ø Intracellular ligands: ligands that bind to receptors inside the cell

Ø Extracellular ligands: ligands that bind to receptors outside the cell
Types of Ligands
Based on chemical properties of the ligands:
Ø water-soluble (hydrophilic) – e.g. peptide hormones; neurotransmitters; cytokines; nucleotides
and nucleosides
Ø lipid-soluble (hydrophobic) – e.g. steroid hormones (cortisol, testosterone, and estrogen etc);
thyroid hormones; eicosanoids; nitric oxide
Based on nature of the ligands:
Ø Gas
Ø Cholesterol
Ø Amino acids and Peptides
Ø Proteins
Ø Nucleotides and nucleosides
Types of Receptors

Based on their location in cell

Ø Cell surface receptors – typically trigger downstream cell signaling
pathways

Ø Intracellular receptors – cytoplasmic/nuclear receptors – typically
directly trigger downstream transcriptional activities of gene
activation/inhibition
 Cell surface receptors
3 types of cell surface receptors Ø Are transmembrane proteins
embedded in the plasma
membrane of target cells.
Ø Consist of : (i) an
extracellular domain
containing the ligand-binding
site, (ii) a transmembrane
domain and (iii) an
intracellular domain that
transmits the signal inside
G protein the cell.
Ø Receive a water-soluble
ligand and initiate a signal
transduction pathway that
alters cellular function.
Ø 3 main types based on
structural and functional
G protein–coupled receptors Enzyme-linked receptors Ion channel receptors similarities

https://theory.labster.com/signaling-receptor/
G protein coupled receptors
Ligand

Inactive
Active
Ø GPCRs consist of a single polypeptide embedded in a cell's plasma
membrane- seven-transmembrane receptors and the intervening
portions loop both inside and outside the cell.
Ø GPCRs interact with G proteins in the plasma membrane.
Ø An external signaling molecule binding to GPCR causes a conformational
change in the GPCR. This change then triggers the interaction between
the GPCR and a nearby G protein.
Ø G proteins are specialized proteins with the ability to bind the nucleotides
guanosine triphosphate (GTP) and guanosine diphosphate (GDP).
Ø Responses are fast – within seconds Adapted from https://www.nature.com/scitable/
G protein coupled receptors

Second
messenger

Muscle relaxation

Examples of GPCRs include adrenergic receptors, muscarinic
acetylcholine receptors, dopamine receptors, and opioid receptors.
Enzyme linked receptors

Ø Enzyme-linked receptors usually has only one transmembrane domain.
Ø Enzyme-linked receptors have cytosolic domain with either an intrinsic enzyme
activity or associated directly with an enzyme.
Ø Responses to signals are slow (minutes to hours) and require many intracellular
signaling steps that eventually lead to changes in gene expression.
Ø Enzyme-linked receptors response to extracellular signal proteins that promote the
growth, proliferation, differentiation, or survival of cells in animal tissues.
Adapted from https://www.nature.com/scitable/
Enzyme linked receptors

Ø 6 classes of of enzyme-linked receptors
Seven subfamilies of receptor tyrosine kinases
1. Receptor tyrosine kinases - Largest group
2. Tyrosine-kinase-associated receptors
3. Receptor like tyrosine phosphatases
4. Receptor serine/threonine kinases
5. Receptor guanylyl cyclases
6. Histidine-kinase-associated receptors

Adapted from https://www.nature.com/scitable/
 Enzyme linked receptors
Mechanisms – Oncology

f Major Classes of Cell Surface Receptors
Neighbor cell
Dimeric
Cytokine ligand
Ligands Delta
Hedgehog WNT Notch
r
n TGFβ LRP

P P
P P P P
PTCH SMO Frizzled
P P P P

Dishevelled

P P P

STAT Kinase Smads Signaling
TF TF

cascades
P
P

P P P P
TF

P
P P P P TF

P

Cytokine Receptor TGFβ Hedgehog Wnt Notch
s receptors tyrosine kinases receptors (Hh) receptors receptors receptors
Activate cytosolic Activate cytosolic Activate Smad Hh binding causes release Release an activated Cytosolic domain of Notch
STAT transcription kinases that translocate transcription factors in the of transcription factor transcription factor from a released by proteolysis
factors by to the nucleus and cytosol by phosphorylation (TF) from cytosolic multiprotein complex in acts in association with
phosphorylation activate transcription complex the cytosol nuclear transcription
factors by factors
phosphorylation

Adapted from https://www.nature.com/scitable/
Ion channel receptors

Ø Ion channel receptors are multimeric proteins located in the plasma membrane.
Ø Ion channel receptors forms a passageway or pore extending from one side of the membrane
to the other.
Ø Ion channels have the ability to open and close in response to chemical or mechanical signals.
Ø Responses are very fast - within few milliseconds
Ø Individual ion channels are specific to particular ions, meaning that they usually allow only a
single type of ion to pass through them.
Ø Most well characterized –Nicotinic receptor for neurotransmitters
Adapted from https://www.nature.com/scitable/
Ion channel receptors

Nicotinic receptor
Ø Consists of a pentamer of
protein subunits, with two
binding sites for acetylcholine
– when bound alter the
receptors’ configuration,
resulting in the open of the
internal pore
Ø The pore allows Na+ ions to
flow down their
electrochemical gradients
Intracellular receptors
Ø Intracellular receptors are typically globular proteins that
located in the cytoplasm or nucleus of target cells
Ø Intracellular receptors bind lipid-soluble chemical messengers
e.g. steroids (corticosteroids, vitamin D etc); Retinoic
acid (vitamin A); hormones
Ø Intracellular receptors once activated induce gene expression
changes by binding to “response elements” on DNA.
Ø The effects are slow (minutes to hours) and can be long-
lasting.
Ø The persistence of effect from enzymes/proteins can remain
active in cells for hours or days after they are synthesized.
Intracellular receptors

Adapted from https://www.open.edu/
Drugs as ligands for receptors to elicit responses

Receptors G Protein Enzyme Ion channel Intracellular
coupled linked receptors receptor
receptors receptors
Drug groups
Adrenergic receptor agonists or
antagonists
Insulin and
estrogen/progesterone agonists
Neuronal receptor modulators

Steroid drugs
The importance of Receptor Theory/Concept
“The receptor concept is to pharmacology as homeostasis is to physiology, or
metabolism to biochemistry. They provide the basic framework, and are the ‘Big
Ideas' without which it is impossible to understand what the subjects are about.”
The receptor concept: pharmacology's big idea by H P Rang1,2006

The concept of Receptor helps explain many aspects of drug actions. Receptors

Ø Largely determine the quantitative relations between dose or concentration of drug and

pharmacologic effects

Ø Are responsible for selectivity of drug action

Ø Mediate the actions of pharmacologic agents i.e. agonists and antagonists
Introduction of Receptor Concept

In mid-1870s, Langley proposed physiological action
of the drug alkaloid pilocarpine and atropine can
“form compounds” with physiological substances
similar to how two inorganic chemical substances
combine with each other.
1905- in his work on the effect of nicotine on muscles,
Langley described ” …nicotine (activates muscles)
John N. Langley- Professor of Physiology, and curare (induces muscle paralysis) act on the
University of Cambridge
“receptive substance” of muscle cells”
Introduction of Receptor Concept

Ehrlich’s groundbreaking article “Aus Theorie und
Praxis der Chemotherapie”, was the basis for
histological staining techniques– using dyes to visualize
cellular structures.
1878- Ehrlich’s famous article on 'side-chain theory of
immunity” describing the binding of toxins to cells-
certain side-chains of the cells could bind certain toxins
with selectivity and specificity.
Paul Ehrlich_Nobel prize 1908
” …specific chemical characteristics of a cell
responsible for specific binding ….”
These receptors are either associated with cells or
distributed more abundantly in the blood stream in
response to antigen interaction.
Introduction of Receptor Concept
v In 1900, Ehrlich replaced the term 'side chain' with
'receptor’
v In 1907, Ehrlich proposed “chemoreceptors for
drugs”
v Ehrlich won the Nobel prize in 1908 for his landmark
immunological insights
v The receptor concept was extensively used in
Ehrlich’s chemotherapy work on “magic bullet
concept”: drugs that go straight to their intended cell-
structural targets.
History of Receptor Theory/Concept

The emergence of the drug receptor theory _Nature reviews 2002
Ligand/drug-receptor interactions and
Dose Response Relationships
Learning Objectives
Understand and describe drug-receptor interactions

Name and describe techniques to measure ligand-receptor interaction

Define dose–response relationship

Describe the use and implications of dose-response relationships

Define drug specificity versus selectivity

Describe the occupancy theory and its modifications

Understand the basis and use of dose-response curve

Define Efficacy versus Potency

List the definitions of ED50, TD50, therapeutic index

Describe and explain the different factors (Vmax/Emax, Km/Kd etc.) influencing the dose–response curves
 Recognition of the ligand at receptor site

Lock and Key model Lock and Key model for
Enzymes recognize their substrates
Ligand-Receptor interactions

as a lock receives a key.
Emil Fisher
Ligand/Drug Molecule

Ravel et al,. 2022
Recognition of the ligand at receptor site

Induced Fit theory
Substrate (for enzyme) or ligand (for receptor) binding causes a
subsequent conformational change in the complex

Daniel Koschland

Specificity and Flexibility

Boggula et al,. 2023
Drug-Receptor binding forces
Interaction between a drug and receptor is
formed via multiple bonds.
Four basic types of binding:
i. hydrophobic bond;
ii. Hydrogen bond
iii. Ionic bond
iv. Covalent bond
Drug-binding forces vary in strength.
Hydrophobic binding is weak, whereas
covalent binding can be strong.
Most drugs reversibly bind to their
receptors.
Duration of engagements vary from
minutes to hours.

Chapter1_2017_Pharmacology-and-Therapeutics-for-Dentistry
Drug specificity vs. selectivity

The strength and duration of the interaction between a drug and its target receptor and
the intended actions are characterized by the selectivity and specificity of the drug
Selectivity refers to a drug's strong preference for its intended target over other
targets.
i.e. a drug which is highly selective binds one/few receptors while a non-selective
drug binds many receptors
Specificity describes the extent to which a drug produces only the desired
therapeutic effect without causing any other physiological changes.
i.e. a drug with high specificity exhibits a strong drug–receptor interaction, ensuring
targeted action and minimal side effects while drugs with low specificity may
produce unintended consequences due to their weak drug-receptor interaction.
Drug specificity vs. selectivity

Factors influence selectivity and specificity:
Affinity of drug-receptor interaction
Uniqueness of interaction sites
Presence/absence of receptors in other tissues/cells
Ability of ligands/drugs to interact with other molecules/structures
*** No drug is entirely specific – NO 1 drug-1receptor
Measuring ligand-receptor interaction

Ligand binding assays directly capture the engagement and binding
of ligand-receptor – the first step of ligand-receptor interaction –,
measuring the physicochemical properties and kinetics of ligand-
receptor complex formation.

Functional assays measure the actual biological response (electrical
or biochemical or physical) evoked by the ligand via its receptor –
indirect readout of ligand-receptor engagements and its effectiveness
Dose-Response Relationship

A fundamental aspect of drug action is the relationship between the
dose administered and the effect/response obtained.
Ø Dose: amount of drug administrated in the patient
e.g. 500 mg of tylenol
Ø Response: effect shown by the body to a particular drug
e.g. reduced pain
Ø The relationship used to analyze a kind of response obtained
after administering specific dose of drug
Ø Dose vs. plasma concentration relationship
Ø Plasma concentration vs. response relationship
Dose-Response Relationship

A fundamental aspect of drug action is the relationship between
the dose administered and the effect obtained.
The dose–effect relationship of a drug is NOT a linear function
throughout the entire dose range.
Ø Below a minimum threshold, there will be no observable effect.
Ø Above a certain ceiling, even a large dose would exert no
additional effect - the maximal effect has already been reached.
 Occupancy Theory/ Occupation Concept
Ø 1926, A.J. Clark published his classical papers on the actions of
acetylcholine and atropine on the frog heart ….concluded: ‘‘The
hypothesis that the concentration-action curve of acetylcholine
expresses an adsorption process of the type described by
Langmuir appears to involve fewer improbable assumptions than any
alternative hypothesis’’ – ie, neurotransmitters, hormones and drugs
interact with receptors.

Ø Clark provided the first quantitative study of the antagonism of
acetylcholine by atropine and described the ‘parallel shift’ of the log
concentration-response curve produced by a competitive antagonist.
Alfred J. Clark, Chair of Pharmacology
University of Edinburgh (1926-1942) Ø It was from this point forward that the receptor concept began to take
hold quantitatively – generation of dose-response curve (Clark_
log concentration-effect curve)
What is dose response curve?

Relationship of dose (or concentration – in consideration of actual plasma
concentration vs. dose administrated) to response can be illustrated by a
graph which is called as dose response curve.

2 required components to build a dose response curve:

1. Doses of drug

2. Corresponding percentage of response groups to specific dosages
Occupancy Theory/ Occupation Concept

After binding (DR) has occurred, an effect (E) follows.
Drug effects (E) can be quantified:

Emax : Maximal Effect (response)
EC50 : Concentration yielding 50% of maximal response The effect of the drug is predictably and
Threshold: lowest concentration to elicit a measurable response quantitatively dependent on the drug
Kd : The dissociation constant concentration. A geometric relationship
Inverse of Kd The equilibrium association constant (Ka) (rectangular hyperbola) exists when
graphing E versus [D].
Chapter1_2017_Pharmacology-and-Therapeutics-for-Dentistry
Fractional occupancy
Assumption of the occupancy theory ~ law of mass action
All receptors are equally accessible to ligands.
Receptors are either free or bound to ligand. No more than one affinity state, or
states of partial binding.
Binding does not alter the ligand or receptor.
Binding is reversible.
Fractional occupancy: is the fraction of all receptors that are bound to ligand.

Practical equation
Fractional occupancy

Practical equation

When [Ligand]=Kd, fractional occupancy is 50%.
Utility of the [log] dose response curve

Saturation

Emax

Slope

Threshold
Utility of the [log] dose response curve

Saturation

Emax

Slope

Threshold

The range of concentration needed to fully depict the dose-response relationship (~3log units)
is too wide to visualize in linear format.
Utility of the [log] dose response curve

à Wide range of drug doses can be displayed on graph
à Comparison between different drugs is easier/clearer
Graded dose response curve

The dose-response relationship in which the magnitude of biological response is proportional
to the dose of drug i.e., as the concentration of a drug increases, its biologic effect gradually
increases until all the receptors are occupied (maximal response).
The pharmacological effect of drug is quantitatively measured and expressed in numeric units

A graded dose–response
curve has the general
shape of a rectangular
hyperbola (or transformed
to sigmoid-log curve).
Understanding Dose response curve

Graded dose response curve provides 4 important values:
1. Potency
2. Efficacy
3. Slope
4. Variability
Drug Potency and Efficacy

Potency is the concentration (EC50) or dose (ED50) of a drug required to
produce 50% of that drug’s maximal effect.

Efficacy (Emax) is the maximum effect which can be expected from this drug
(i.e. when this magnitude of effect is reached, increasing the dose will not
produce a greater magnitude of effect).
Drug Potency and Efficacy

https://derangedphysiology.com/
Drug Potency and Efficacy

Drug A and Drug B achieve the same Drug A achieves a higher maximum effect
maximum effect, i.e. they have equal than Drug B. Drug A is therefore said to be
efficacy. However, Drug A achieves this more efficacious (higher efficacy).
effect at a lower dose (i.e Drug A has
higher potency than Drug B).
https://derangedphysiology.com/
Slope and Variability

Slope reflects the effect of incremental Variability reflects reproducibility/consistency
increase in doses vs. response of data – which can be variable between
different testing subjects
Slope and Variability

(A) Steep – small window of response (Left) Variable: highly dependent on subjects –
(B) Wide - large window of response e.g. individual responses to drugs differ
(Right) Consistent
Reading the curves

https://derangedphysiology.com/
Reading the curves

Both Drug A and Drug B achieve the same
maximum effect, i.e. they have equal efficacy.
At EC50, Drug B is more potent than drug A.
Both Drug A and Drug B achieve the maximum
effect (Emax) at the same dose (i.e. they have
equal maximum potency).
Drug B achieves EC50 effect with a lower dose.
Drug A has a steeper dose-response curve than
Drug B - a rise from EC50 to Emax is
accomplished with a relatively small increase in
dose.

https://derangedphysiology.com/
Modifications of the Occupancy Theory

1954, Ariens’ modification: the maximal drug response is not equal to the maximal
occupancy à modifier α: intrinsic activity where response = α x [R]
1956, Stephensen's modification: the concepts of stimulus and efficacy. non-linear
relationship between receptor activation vs. response
à modifier ε: intrinsic efficacy where efficacy = ε × [R]
Quantal dose response curve
Birkett (1995) wrote:
"An alternative way of constructing a concentration effect curve is
to determine the percentage of a population of patients showing
a defined response at various drug concentrations... These are
called quantal (population) concentration response curves and
have the same shape and parameters as the
graded concentration response curves"

The quantal dose response is the dose-response
relationship in which a defined drug effect which is either
present or absent.
In a population, there is usually some variation of doses
required to achieve the defined drug effect
The distribution of these dose tends to be a normal
Gaussian distribution (i.e a bell curve)
Quantal dose response curve
The cumulative percentage of the population responses to increasing doses can be plotted as a
curve (which assumes a sigmoid shape)

Median effective dose
(ED50)
ED50 and LD50

The median effective dose (ED50) is the
dose at which 50% of individuals exhibit
the specified quantal effect
The median lethal dose (LD50) is the
dose required to kill 50% of subjects
TD50 and Therapeutic index

The median toxic dose (TD50) is the dose
Toxic effect
required to produce a defined toxic effect in
50% of subjects
The therapeutic index (TI) is a numeric
measure of the selectivity of the drug for its
desired effect

* TD50 can be LD50 TD50
Implications and Caveats of Therapeutic index
Implications:
TI guides the need for therapeutic level monitoring. Drugs with a narrow therapeutic
index should be monitored more closely.
IT guides the dosing interval. The drug with a narrow index would need to be given
more frequently and in smaller doses.
Caveats:
Difficulties to determine LD50
or toxic effects for TD50
Misinterpretation of risk
Therapeutic range/window

Therapeutic range/window
The therapeutic window is the range
between the minimum toxic dose and
the minimum therapeutic dose, or the
range of doses over which the drug is
effective for most of the population and
the toxicity is acceptable.

Q: For drugs, do we aim for small or large therapeutic window?