L7 Receptors As Drug Targets 4 – G Proteins PDF

Summary

This document provides an overview of L7 receptors as drug targets, focusing on G-proteins. It covers learning outcomes, different types of G-proteins, and their functions. The document also includes a summary and description of G-protein cycles.

Full Transcript

L7 Receptors As Drug Targets 4 – G Proteins

IOPPN/FOLSM
2023-24

Dr Jon Drug Design & Development
Robbins
5BBM2016

Pharmacology
Receptors as Drug Targets 4 –
G-Proteins

 Learning outcomes
1. Understand that heteromeric G-proteins are
intracellular proteins associated with the GPCR family

2. Describe in detail how G-proteins are activated and
deactivated in the G-protein cycle

3. Be able to describe which GPCRs activate which G-
protein subtypes

4. Be able to describe which G-protein subtypes can
activate a specific signalling pathway.

Overview

G-protein cycle

G-protein subtypes

G-protein mediated second messenger systems

Toxins

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 G-proteins
GTP binding proteins
– Heterotrimeric (α and βγ subunits)
– Homomonomeric (small single subunit)

ALL
– Replace GDP with GTP on activation
– Hydrolyse GTP to GDP + PO4 on deactivation
(GTPase activity)

Beta and gamma never separate from each other, but they do
separate from alpha

3
 G-protein: a multifunctional protein

Receptor binding

βγ subunit
C binding
GDP binding

α
GTP binding
N

Effector binding
GTPase activity & activating

Shown – alpha subunit
Receptor binding to C terminus
Effector binding to N terminus

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 G-proteins are activated by receptors
Rest state G-protein activation Subunit separation

N N N

βγ
CC C
C βγ
GTP α

C N
βγ C
GDP α GDP
GTP GTP α
N
N

More than one G-protein can be activated by a receptor

7 transmembrane domains.
At rest, receptor and G protein separate
Receptor activated when ligand binds and GPCR and G protein link at
C terminus

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 G-protein cycle
RGS = regulator of G-protein signalling
1) rest
C
4) GTPase βγ

+PO4
GDP α
2) binding
C N

GDP C
GTP α
3) activation
N GTP α

Effector
N
βγ

Effector βγ

G protein cycle – nothing used up
GTPase activity of alpha subunit converts GTP to GDP and alpha
subunit reassociates with beta gamma subunit.

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 Heteromeric G-proteins
16 different types of a-subunits in mammals
– Gs
αs, αolf
– Gi
αi1, αi2, αi3, αoA, αoB, αz, αt
– Gq
αq, α11, α14, α15, α16
– G12
α12, α13

Note there are different subtypes of β & γ subunits

Gq coupled to phospholipase C

Different G-proteins couple to different receptors
Receptor Subtype G-protein
opsin rhodopsin Gt (transducin)
muscarinic ACh M1, M3, M5 Gq & G11

muscarinic ACh M2, M4 Gi & Go

adrenoceptors α1 Gq & G11

adrenoceptors α2 Gi & Go
adrenoceptors β1, β2, β3 Gs
purinergic PTY12, P2Y13 Gi & Go
purinergic P2Y11 Gs & Gq & G11
purinergic P2Y1, 2, 4, 6, 14 Gq & G11

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 Same neurotransmitter can couple to different GPCRS and can
therefore have different physiological effects.

Different G-proteins couple to different effectors
G-protein Effector Second
messenger
Gs adenylyl cyclase cAMP ↑

Gi adenylyl cyclase cAMP ↑

Gt phosphodiesterase cGMP ↑

Go calcium channel Ca entry ↑

Gq/G11 phospholipase C IP3 ↑
DA G ↑
PIP2 ↑
G12/13 Rho-GEF Rho

Gq/G11 increases intracellular calcium
G12/G13 further signalling

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 Quiz 1
Which family of G-proteins couple to
GPCRs?

Describe the activation and deactivation of
a G-protein

What are the 4 subfamilies of G-proteins?

Which second messengers are altered by
Gq?

1. Heterotrimeric G proteins
2. Ligand binds to GPCR, G protein binds to GPCR at C terminus, alpha
subunit dissociates from beta gamma subunit, GDP converted to GTP
by addition of phosphate. Alpha subunit acts on effector. GTPase
activity hydrolyses GTP to GDP, inactivating the G protein. Alpha
subunit and beta gamma subunit reassociate.
3. The four subfamilies of G proteins are Gs, Gi, Gq and G12.
4. The second messengers that are altered by Gq are IP3, DAG and
PIP2.

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 βγ subunits also produce effects

Activate kinases Inhibit calcium channels
(desensitisation) (inhibit NT release)

βγ

Activate potassium channels
Mop up other alpha subunits (regulate excitability)
(inhibit signalling)

Beta gamma subunits can produce effects including activation of
kinases, inhibition of calcium channels to inhibit neurotransmitter
release, activate potassium channels to regulate excitability and mop
up alpha subunits to inhibit signalling.

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 Toxins that act on G-proteins
Cholera toxin (CTX) – activates Gs & Gt
From bacteria
Pertussis toxin (PTX) – inhibits Gi & Go
From bacteria
Mastoparan – activates Gi
From wasp venom
Pasteurella multocida toxin (PMT) –activates
Gq,G11,G12,G13 & Gi
From bacteria

Pertussis toxin causes whooping cough

Some toxins act by ADP ribosylation
G-protein

C
C

N
toxin ADP
N
NAD+
R
ADP
R

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 ADP molecule alters function of G protein

This can activate or inhibit G-proteins
C
C βγ
βγ CTX GTP α activates
Gs GTP α
NAD
N
N ADP-R

ADP ribosylated at Arg 201 prevents GTPase activity

ADP-R
C C
βγ βγ
Go/Gi PTX
GDP α GDP α inhibits
NAD
N N

ADP ribosylated at Cys351 prevents receptor coupling

Cholera toxin causes constant activation of G protein, causing
abnormal excessive signalling
Below = pertussis toxin – stops binding of G protein to receptor.

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 Other compounds that act on G-proteins
GDP-β-S mimics GDP and prevents activation
of G-proteins

GTP-γ-S mimics GTP cannot be hydrolysed
by GTPase activity. G-protein permanently
activated

AlF4- similar to GTP-γ-S, activates G-proteins

YM-254890 from Chromobacterium Gq
inhibitor

YM-254890 is a drug synthesised from chromobacterium that inhibits
Gq proteins.

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 Comparison of G-protein families
Family Gs Gi/Go Gq/G11 G12/G13
Golf Gt, Ggust
Gz
members 2 5 5 2

receptors β-adrenoceptor M2 muscarinic M1 muscarinic chemokine

2nd mess Gs +AC Gi -AC + PLC Rho
Go -VOCC
Gt +PDE
Toxins cholera pertussis PMT PMT
PMT

What happens when G-proteins go wrong

Pseudohypoparathyroidism type 1a
(PHP1a) with precocious puberty

– Hypocalcemia
– Hyperposphatemia
– High parathyroid hormone (PTH) levels
– Mental retardation
– Signs of puberty at aged 4

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 Pseudohypoparathyroidism type 1a (PHP1a)
with precocious puberty

Broken down
C most tissues
Protein not stable
Low affinity at 37oC C
Arg366Ser αs
for GDP
GTP
N αs

C N
Constitutively active
In tissues lower GTP
αs Not functional
than 37oC

N
AC

ATP cAMP
Overactive

Mutation in alpha subunit Arg366Ser
G protein becomes unstable and does not function at normal body
temperature

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 Quiz 2
1. What effects can the beta-gamma
subunits have?

2. Which human diseases are caused by
toxins acting on G-proteins?

3. What is ADP ribosylation?

4. Give an example of a therapeutic drug
that acts on a G-protein

1. Beta gamma subunits can produce effects including activation of
kinases, inhibition of calcium channels to inhibit neurotransmitter
release, activate potassium channels to regulate excitability and mop
up alpha subunits to inhibit signalling.
2. Cholera and whooping cough (pertussis toxin) are human diseases
caused by toxins acting on G proteins.
3. ADP ribosylation is an effect produced by toxins against G proteins
where ADP molecules are added to G proteins, altering their structure
and thus their function.
YM-254890 is a drug synthesised from chromobacterium that inhibits
Gq proteins.

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 References

G-proteins
Neer (1995) Cell 80: 249-257.

PHP1a
Lania et al (2001) Eur. J. Endocrinol. 145: 543-559

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