Intro Pharmacology 1 PDF

Summary

This document introduces pharmacology, focusing on receptors, transmitters, and drug actions. It includes diagrams and explanations of key concepts, making it suitable for introductory pharmacology courses.

Full Transcript

Principles of Pharmacology 1

Introduction to Pharmacology,
focusing on receptors, transmitters
and drug actions

Dr Vassilis Beglopoulos
Slides by Dr Chris Smith
 Signal molecule

The need for receptors
Signalling molecules or hormones in
G
the blood can reach a large no of
different cells
Receptor
Tea
– No specificity
Target
However - not all cells respond to proteins

circulating chemicals
– Specificity provided by only specific cells
o receptors for that chemical
having
Intracellular
s F signal
molecules
“a cell cannot respond to a chemical
signal if the cell lacks the appropriate
receptor proteins for that signal”
Silverthorn Response
 3 of 27

The receptor concept
– Langley and Ehrlich
Chemicals produce their
effects by combining with
specific receptor sites in cells
The response is a function of the number of
occupied receptors
The lock and key hypothesis
– chemical specificity

– Affinity – the “strength” of the drug receptor
interaction
Receptors
Proteins
Have binding site
– “Receptive to ligand”
– Has affinity to ligand
Receptor locations

Proneloveslipids

Hatelipid
Four types of receptors
ion channels enzyme

is be
ligand
Transmitters
Hormones

c
Neurotransmitters
Also
– Local signalling molecules
– Autocoids
– Neuropeptides
– Neuromodulators
– Cytokines
Hormones

Released from one cell into extracellular
space/circulation to travel to new site of
action where they provoke a specific
response
 Neurotransmitter From nervecell to musclecell

Synthesised in the presynaptic neurone and stored in vesicles

If
Exocytosis triggered upon Ca++ influx ci
Diffusion through synaptic cleft
e can
Bind to post-synaptic receptors triggering a response
Neurotransmitter uptake/break down to terminate transmission

IEI
Energy
nsmme.im

cleft
 The synapse

ATP

http://blog.nervousenc ounter.c om/?p=215
Neurotransmitter release
Exocytosis: Process by which vesicles release their contents

inertian
Axon
exocytosis Iiiii
neurotransmitter

receptor
y yy y
Diffusion

musclecell

Dendrite Bear et al., Neuroscience Exploring the Brain, 3rd ed
 Neurotransmitter release

on

Éiti

endrite

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 DrugsforAlzchiem.rs
Too
Neurotransmitter recovery and degradation
– Diffusion: Away from the synapse

– Reuptake: Neurotransmitter re-enters presynaptic axon terminal
Ree __

l – Enzymatic degradation: inside terminal cytosol or synaptic cleft
Neurotransmitters
Acetylecholine ACh
Monoamines
– Noradrenaline, dopamine, 5-HT
Amino acids
– Glutamate, GABA
Excitatorsneurotransmitter neurotransmitter
Inhibitors

Neuropeptides
– Endorphins
Purines
– ATP
Soluble gases
– Nitric oxide (not nitrous oxide!)
Amino acids
Certain amino acids are neuroactive and
function as neurotransmitters
– GABA
– Glutamate

The major inhibitory and excitatory
neurotransmitter respectively in the CNS
– GABA accounts for 40% of inhibitory transmission
– GLU accounts for 50% of excitatory transmission
Recall…
…the distinction the between a hormone and a
neurotransmitter

Neurotransmitter
– Synthesised and stored in nerve terminal and
released into the extracellular space to act on
adjacent neurones
Hormone
– Synthesised and stored in one organ and is
released into the blood to have an affect on another
organ I
 Hormone or neurotransmitter?

Adrenaline is important hormone
– Released into the blood
Increases heart rate, force of contraction
Dilates bronchi
Mobilises glucose (inhibit insulin release)
– Fight or flight

Noradrenaline is important neurotransmitter
Types of receptors based on ligand
Cholinoceptors (muscarinic and nicotinic)
Adrenoceptors (α and β)
Histamine (H1, H2 AND H3)
Dopamine (D1, D2 etc..)
Insulin
Steroids
Etc., etc. (100+ different types)
Types of receptors
Cholinoceptors (_______
Muscarinic and _______)
Nicotinic
____________
Adrenoceptors (α and β)
____________
Histamine
(H1, H2 and H3)
Dopamine (D1, D2 etc..)
5-HT (5-HT1, 5-HT2, 5-HT3…)
Insulin
Steroids
Etc. etc. (100+ different types)
Acetylecholine receptors Cholinoceptors

Divided into nicotinic (nAChR) and muscarinic (mAChR)
subtypes depending on activity to selective drug

mAChr
nAChR
G-protein coupled receptor
Ligand gated ion channel
permeable to Na+ ions 5 subtypes (M1 – M5)
Excitatory M1, M3 and M5 excitatory
M2 and M4 inhibitory
Nicotinic ACh receptors
nAChR = pentameric
quate anerotien
– 5 subunits
Each subunit termed either α,
β, γ, δ or ε
Each subunit spans the
membrane four times
Variations in subunits
confers
Provides
specificity between
neuronal and muscle
nAChRs
 neurotransmitterinbrain
Primary Excitatory

Glutamate receptors
Both ionotropic and metabotropic GLU
receptors exist
Ionotropic named after selective ligands
(like ACh receptors)
– AMPA
– NMDA
– Kainate
Ionotropic receptors open cation channel
 neurotransmitters
1211
GABA receptors

GABAA
– Ionotropic – ligand gated ion channel
– Chloride channel
GABAB
– Metabotropic – GPCR
– Ultimately inhibit voltage gated Ca++ channels and
open K+ channels
 G protein coupled receptors Metabotropic
An extremely large group of receptors
– visual pigments, odorant receptors, monoamine
receptors, peptide receptors etc etc
– Specific examples are muscarinic, alpha/beta
convertsProtiensfromoneformplaceto
Via activation of transducer proteins:
any guanine
pf
nucleotide binding proteins (G proteins)
Common structural motifs
Single polypeptide chain linear
7 hydrophobic (transmembrane) regions
so_
Extracellular N-terminus
Intracellular C-terminus
– Size of the N- and C-termini and the various loops
differ enormously
– Confers site specificity, different subtypes and
involvement of varied second messenger systems
to be possible
G protein coupled receptors

0000000
G protein coupled receptors

Excitatory Inhibitory
Signal Transduction Mechanism
Receptor activated G protein
– A family of proteins that bind guanosine triphosphate - G T P

G Protein-GDP + GTP osmotic G Protein-GTP + GDP

o o
Inactive Active
Receptor
 TO
G Protein-dependent signal transduction
OTP
Active G Protein interacts with yet another protein: Ion Channel or
Enzyme.

Ion Channel

00
– Mechanism is the influx of an ion eg Na +, Ca++
Enzyme
– Produces a substance that serves as a relay in the
signal transduction mechanism called: C
co
Second Messenger or Intracellular Messenger
By far the largest category
Ligands acting on receptors

Agonist Cellular response

Both willbind to samesiteonreceptor
buteachhavedifferentresponse

Antagonist No effect
FEE
Agonists / Antagonists
Pharmacological agonist
Combines with a receptor and produces a
response
must
– has affinity and efficacy
HiFominy

Pharmacological antagonist
1C
Combines with a receptor, does not produce a
response, but prevents
6 the action of an agonist
– has affinity but no efficacy
I
 Acting on ion channels

Permeation blocked
blockers
eg local anaesthetics
block Na+ channels

Increased/decreased
Allosteric
modulators
opening probability
eg barbiturates and
benzodiazepines
 Acting on enzymes
Substrate
1
catalyzereaction
Normal reaction, normal
metabolite produced

Inhibitor Normal reaction inhibited
2 prevetingenzymes
storing

G
eg aspirin inhibits COX

False Abnormal metabolite
3substrate produced

Prodrug Active drug produced
4
Acting on transporters
c
Normal
transport

Transport
Inhibitor or blocked
c
Eg prozac
seamanage
o
Abnormal
False Unnatural compound
substrate accumulated
Types of drug action
Transport systems (5%)
Enzymes (15%)
Microbes (40%)
Cellular Receptors (40%)
Others (less than 1%)
Genetic transplants (0.00000000001%)
Recap
Drugs acting on specific proteins on cell
e

membranes called receptors
Drugs that block the action of specific
enzymes
08
Drugs that inhibit cell transport
mechanisms
Drugs that act on ion channels
Drugs that act on invading organisms
Drugs with a non-specific action