Receptor Types PDF

Summary

This document provides a comprehensive overview of different receptor types, including intracellular and transmembrane receptors. It details various aspects of receptor interactions, such as ligand binding, affinity, and different types of signaling pathways. The document also explores concepts like agonist, antagonist, and inverse agonist relationships.

Full Transcript

180px-Transmembrane_receptor

Receptors

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 Outline
Definitions
(receptor, ligand, agonist, antagonist, efficacy, potency)

Receptor interactions

Receptor theories

Dose response relationship

Classification of receptors types

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Background
Receptor is a protein molecule, embedded in
either the plasma membrane or the cytoplasm
of a cell, to which a mobile signaling molecule
may attach.

Ligand is a molecule which binds to a receptor.
Ligand may be a peptide or other small
molecule, such as a neurotransmitter, a
hormone, a pharmaceutical drug, or a toxin.
When such binding occurs, the receptor
undergoes a conformational change, which
ordinarily initiates a cellular response.
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Background

Ligand binding is an equilibrium process.
Ligands bind to receptors and dissociate
from them according to the law of mass
action.

(the brackets stand for concentrations)

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 Binding affinity
Binding affinity is a measure of how well a
molecule fits a receptor is the.
Binding affinity is inversely related to the
dissociation constant Kd.
A good fit corresponds with high affinity and
low Kd.
The final biological response (e.g. second
messenger cascade or muscle contraction), is
only achieved after a significant number of
receptors are activated.

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DRUG RECEPTOR INTERACTIONS

Effect of drug attributed to two factors.

Affinity: tendency of the drug to bind to
receptor and form D-R complex.

Efficacy or intrinsic activity: ability of the
drug to trigger pharmacological responses
after forming D-R complex.

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Ligands
Not every ligand that binds to a receptor activates that
receptor. The following classes of ligands exist:

Full agonists are able to activate the receptor and result
in a maximal biological response. Most natural ligands are
full agonists.
Partial agonists do not activate receptors thoroughly,
causing responses which are partial compared to those of
full agonists.
Antagonists bind to receptors but do not activate them.
This results in receptor blockage, inhibiting the binding
of other agonists.
Inverse agonists reduce the activity of receptors by
inhibiting their constitutive activity.

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Constitutive activity
A receptor which is capable of producing its
biological response in the absence of a bound
ligand is said to display "constitutive activity.

The constitutive activity of receptors may be
blocked by inverse agonist binding.

Mutations in receptors that result in increased
constitutive activity underlie some inherited
diseases, such as hyperthyroidism (due to
mutations in thyroid-stimulating hormone
receptors).

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 Receptor Interactions

Lock and key mechanism

Agonist Receptor

Agonist-Receptor
Interaction
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 Receptor Interactions

Competitive
Inhibition

Antagonist Receptor

Antagonist-Receptor
DENIED!
Complex
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Receptor Interactions

Non-competitive Antagonist
Inhibition

Agonist Receptor

DENIED! 11
‘Inhibited’-Receptor
 Receptor Interactions

Induced Fit

Receptor

Perfect Fit!

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The occupancy theory:
The more receptors' sites occupied by ligand, the stronger response

The rate theory:
The more ligand-receptor interact / unit time, the stronger response

The induced-fit theory:
Agonist

Receptor + Agonist
Conformation A Responce
No ligand bound
Conformation B

+ Antagonist

Antagonist
Responce
ConformationA
or
Inactive conformation C

The macromolecular pertubation theory:
(induced fit + rate theory) 13
The activation -aggregation theory:
Always dynamic equilibr.
Agonist

+ Agonist
Responce Responce

Conformation B
(Active)

Antagonist
Responce
+ Antagonist

Inv. Agonist
Responce B Responce A
(opposite of responce A) + Inverse agonist

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Dose-Responce Relationships

A + B A-B [A] - equil. towards AB

L + R L-R [L] - equil. towards LR ??

L

L-R R locked in membrane (do not move freely)
L dissolved in extracellular fluid
R
Reaction on solid - liquid interface

Biological responce

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Efficacy vs. Potency

Efficacy:
The maximal effect (Emax) an agonist can produce
if the dose is taken to very high levels.

Potency:
The amount of a drug needed to produce a given
effect.

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% biolog. effect % biolog. effect

100 100

50 50

EC50 [Agonist ligand] EC50

log [Agonist ligand]

biolog. effect

X Y

Efficacy (how high activity is possible)

Efficacy X = Efficacy Y (both can give 100% responce)

Z Efficacy X> Efficacy Z (Z cam only give ca 30% responce)

EC50 X and Y
Potency (how easily is a given responce reached
(ex EC50)
EC50 Z
Potency X > Potency Y
Potency X = Potency Z
Potency Z > Potenzy Y

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log [Agonist ligand]
Classification of receptors
Depending on their functions and ligands, several types of
receptors may be identified:

Peripheral membrane proteins.
Transmembrane proteins.
Intracellular proteins

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 Receptors

Peripheral membrane Trans-membrane Intracellular

proteins proteins proteins

Metabotropic Ionotropic
receptors receptors

1. G protein-coupled receptors 1. Extracellular ligands
2. Receptor tyrosine kinases 2. Intracellular ligands
3. Guanylyl cyclase receptor
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 1.Peripheral membrane proteins
These receptors are relatively rare compared to the
much more common types of receptors that cross
the cell membrane.

Example: elastin receptor.

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 3. Intracellular proteins
They are located inside the cell rather than on its cell
membrane.
Examples:
1- the class of nuclear receptors located in the cell nucleus
These receptors often can enter the cell nucleus and modulate
gene expression in response to the activation by the ligand.

2- the IP3 receptor located on the endoplasmic reticulum.
The ligands that bind to them are intracellular 2nd
messengers like inositol triphosphate (IP3) upon
activation by extracellular hydrophilic hormones like
angiotensin, epinephrin.
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 File:Nuclear receptor action.png

This figure depicts the mechanism of a class I nuclear receptor (NR) which, in
the absence of ligand, is located in the cytosol. Hormone binding to the NR
triggers dissociation of heat shock proteins (HSP), dimerization, and
translocation to the nucleus where the NR binds to a specific sequence of DNA
known as a hormone response element (HRE). The nuclear receptor DNA
complex in turn recruits other proteins that are responsible for transcription
of downstream DNA into mRNA which is eventually translated into protein 22
which results in a change in cell function.
 File:Type ii nuclear receptor action.png

This figure depicts the mechanism of a class II nuclear receptor (NR) which,
regardless of ligand binding status is located in the nucleus bound to DNA. The
nuclear receptor shown here is the thyroid hormone receptor (TR)
heterodimerized to the retenoid X receptor (RXR). In the absence of ligand,
the TR is bound to corepressor protein. Ligand binding to TR causes a
dissociation of corepressor and recruitment of coactivator protein which in turn
recruit additional proteins such as RNA polymerase that are responsible for
transcription of downstream DNA into RNA and eventually protein which results
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in a change in cell function.
2. Trans-membrane proteins

Examples: Many hormone and neurotransmitter
receptors.
Trans-membrane receptors are embedded in the
phospholipid bilayer of cell membranes, that allow
the activation of signal transduction pathways in
response to the activation by the binding molecule
(ligand).
Metabotropic receptors are coupled to G proteins and
affect the cell indirectly through enzymes which control
ion channels.
Ionotropic receptors (also known as ligand-gated ion
channels) contain a central pore which opens in response
to the binding of ligand.
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Metabotropic vs. Ionotropic receptors
In contrast to ionotropic receptors, metabotropic
receptors do not form an ion channel pore; rather,
they are indirectly linked with ion-channels on the
plasma membrane of the cell through signal
transduction mechanisms (G proteins, tyrosine
kinases, or guanylyl cyclase).

Both receptor types are activated by specific
neurotransmitters.

When an ionotropic receptor is activated, it opens a
channel that allows ions such as Na+, K+, or Cl- to flow.

When a metabotropic receptor is activated, a series
of intracellular events are triggered that result in ion
channel opening but must involve a range of 2nd
messengers. 25
Metabotropic receptors
G protein-coupled receptors
Comprise a large protein family of trensmembrane receptors that
sense molecules outside the cell and activate inside signal
transduction pathways and, ultimately, cellular responses.
cAMP signal pathway
Phosphatidylinositol pathway

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 G-Protein coupled receptors G-protein: Guanine nucleotide binding protein
Ligand
(Agonist)
Extracellular fluid

Intracellular fluid Target Conform. change
Reseptor

 
 G-protein GTP

+P
GDP
GDP GDP
 

 

O

HN N GTP
H 2N N N GTP
Responce
O O
O P O P O n=1; GDP
O n=2; GTP
O O
n 27
HO OH
 Subtypes of G-proteins - Targets (Second messenger systems)

Ion chanels: G12 Na+ / H+ exchange

Enzyms: Gi Inhib. Adenylyl cyclase
Gs Stimul. Adenylyl cyclase
Gq Stimul. Phospholipase C

One ligand can bind to more than one type of G-prot. coupled reseptors

second messenger pathways

NH2
NH2
Adenylyl cyclase N N
N N

N N Activate c-AMP dependent protein kinases
O O O N N
O P O P O P O O (Phosphoryl. of proteins, i.e. enzymes)
O
O O O O
P O P O P O
OH
HO OH O Various responces
(ex. metabolism, cell division)
ATP c-ATP

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 Subtypes of G-proteins - Targets (Second messenger systems)

Ion chanels: G12 Na+ / H+ exchange

Enzyms: Gi Inhib. Adenylyl cyclase
Gs Stimul. Adenylyl cyclase
Gq Stimul. Phospholipase C

Various processes in cell Various processes in cell
second messenger pathways
Activate protein kinases Release Ca2+

R'
O
O O R'
O O P O
Phopholipase C O O OH
R O O
O +
O R HO
O O HO O
P O P
OH O
OH
O P
HO
O
DAG
HO IP3
P Diacylglycerol
O Inositol-1,4,5-triphosphate
P
PIP2
Phosphatidylinositol besphophate

Several steps Li (Treatmen manic depression)
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 Gs cAMP Dependent Pathway
hormon Inhibit
EXTRACELLUL
e or
A R

RS Ri

A
GTDPP
 C
 GDP
CYTOSOL

GTP ATP

ATP
Inactive
Protein protei
cAM kinas n
P e
ADP Active
Adenylate cyclase protein
Signaling
System Cell response30
Gi cAMP Dependent Pathway

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Gq Protein Coupled Receptor
EXTRACELLUL
A R

CYTOSOL

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Metabotropic receptors
Receptor tyrosine kinases
Receptor tyrosine kinases (RTK)s are the high
affinity cell surface receptors for many
polypeptide growth factors, cytokines and
hormones.
Receptor tyrosine kinases have been shown to be
not only key regulators of normal cellular
processes but also to have a critical role in the
development and progression of many types of
cancer.
Examples: VEGFR, FGFR

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Enzyme coupled receptors - Catalytic receptors

Ligands: Peptide hormones

1) Binding of Ligand
2) Dimerisation
of reseptor Phosphoryl of Tyr

Tyr kinase -OH -OH -OH
domain
(Janus kinase)
(JAKs)

STATS
protein

O P O P STATS
O P O P 1) Phosphoryl. of STAT
protein
2) Release of STAT in cytoplasma
3) STATto cell nucleus
4) Intitation of transcription

STAT: Signal transducers and activators of transcription 34
Metabotropic receptors
Guanylyl cyclase receptor
Is another enzyme-linked receptor.
Same principle of receptor tyrosine kinases.

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Ionotropic receptors

Ion channel-linked receptors are involved in rapid
signaling events most generally found in
electrically excitable cells such as neurons and
are also called ligand-gated ion channels.
Opening and closing of Ion channels are
controlled by neurotransmitters.
Example: nicotinic receptor of Acetylcholine.

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Ligand-gated ion channels
Ligands
Ligand binding sites Fast neurotransmitters
ex. Acetylcholine (nicotinic receptors)
Membrane
(Phospholipides)

Ion chanel
Fastest intracellular response, ms

Binding of ligand - opening of channel - ion (K+, Na+) in or out of cell - response

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 Summary

Endogenous ligands General structures

Fast neurotransmitters Ligand gated ion channels
ex. Acetylcholine

Slow neurotransmitters G-Protein coupled receptor
ex. noradrenaline

Insulin Enzyme coupled receptors
Growth factors Catalytic receptors

Steroid hormones Cytoplasmic receptors
Thyroid hormones
Vitamin A, D
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Receptor subtypes Somatic nervous system Autonomic nervous system
Most receptor classes - several sub-types
Each subtype - different A(nta)gonists sympathetic parasympathetic

Det somatiske nervesystem Det autonome nervesystem

Det sympatiske Det parasympatis ke
nerves ystem nerves ystem
Sub types cholinergic receptors CNS CNS CNS

Acetylcholine ganglion
Acetylkolin
Noradrenalin

Synapse

Muscarinic Reseptor
receptors Nicotinic Effektor celle

M1: G-Protein coupled receptors receptors
4.3 Å
Stimulate phopholipase A
Nmuscle: Ligand gated ion chanels
5.9 Å
HO M2: G-Protein coupled receptors Incr. Na+/Ca2+
O
N
Inhib. adenylyl cyclase
N
Nneuro: Ligand gated ion chanels
O
H
N
H
Incr. Na+/Ca2+
H
O

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Any Questions??

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