G Protein Coupled Receptors PDF

Summary

This document provides an overview of G protein-coupled receptors (GPCRs), focusing on their structure, function in signal transduction, and different pathways involving second messengers like cAMP.

Full Transcript

G-Protein-Linked Receptors

Session Learning Outcomes (SLOs)

SLO# 1 : List the pathways of signal transduction to generate different
physiological responses.

SLO# 2 : Describe the role of G proteins in the activation of specific
effector proteins.

SLO# 3 : Define primary and secondary messengers and give specific
examples of each.
G-Protein-Linked Receptors
G-protein-linked receptors form the largest family of cell-surface receptors, with hundreds of members
already identified in mammalian cells.

They mediate response to an enormous diversity of extracellular signal molecules, including hormones, local
mediators, and neurotransmitters.

These signal molecules are as varied in structure as they are in function.
Tthey can be proteins, small peptides, or derivatives of amino acids or fatty acids, and for each one of
them there is a different receptor. steroid dissolvedgasses
t

Despite the diversity of signal molecules that bind to them, all G-protein-linked receptors that have been
analyzed possess a similar structure: each made of a single polypeptide chain threads back and forth cross
the lipid bilayer seven times.

iiiiii
lipidbilayers
All G-protein-linked receptors possess a similar
structure
differ binding
site
insidethecell
G Protein
 Stimulation of G-Protein-linked Receptors Activates
G-Protein Subunits

1- Extracellular signal molecule binds to
a seven-pass transmembrane receptor Gprotein coupled receptor

2- The receptor protein undergoes
a conformational change
covalent
bonds
peripheralprotein
protein
complex 3- The receptor protein activates a G
subunits protein located on the underside of the
3
alphaBetaGama plasma membrane
G-Proteins
different subunits

G-proteins are heterotrimeric, with 3 subunits α, β, γ.
alpha alpha
The α subunit of a G-protein (Gα) binds GTP, & can
hydrolyze it to GDP + Pi.
alpha gamma

α & γ subunits have covalently attached lipid anchors that
bind a G-protein to the plasma membrane cytosolic surface.
G-Proteins
 All G-proteins – similar structure/activation

 G-protein is a switch turned on by the receptor

 There are several varieties of G proteins. Each is specific for a particular set of
receptors and particular set of downstream target proteins. intracellularproteinactivated
by GP jmes
 G-protein then activates an effector protein (usually an enzyme)

 There are TWO broad subclasses of trimeric G-protein-activated signal
transduction pathways depends on their target effector enzymes:
A. adenylyl cyclase
B. phospholipase C
 A: Some G-proteins Activate adenyl cylase
 The most frequent target enzymes for G proteins are adenyl cylase
II b
 Adenylate Cyclase (AC) is a transmembrane protein, with cytosolic domains
forming the catalytic site.
 Win
Adenylate Cyclase is responsible for production of the small intracellular signal
molecule cyclic AMP (cAMP). Enger
Smes's

 Phospholipase C, the enzyme responsible for production of the small intracellular
signaling molecules inositoltriphosphate and diacylglycerol.

XV
 enzyme

Signal Transduction Process
via GPCR GProtein coupledreceptor

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When there is no ligand, receptor is off;
Gα has bound GDP, and α, β, & γ subunits are complexed
together in an inactive state (GDP bound state)
 The sequence of events by which a hormone activates cAMP
signaling:
1-Ligand binds to the extracellular domain of a 7-helix
receptor (GPCR),
7helixpassthroughlipidbilayer

2- A conformational change in the
receptor

3- Activation of G-protein on the cytosolic inactive
side of the membrane

4- Gα releases GDP & binds GTP (GDP-GTP
exchange) and dissociates from βγ

Bycomplex inhibitory
inactive
in
5- Gα-GTP dissociates from the inhibitory active
βγ complex.
 Enzyme
Adenylyl cyclase

6- α subunit changes conformation
and binds to adenylate cyclase (AC).

7- Adenylate Cyclase is activated
by the stimulatory Gα-GTP.
 G-Protein-linked Receptors

Receptors have 7 transmembrane helices
Interact with heterotrimeric G-Proteins
for activation
– Gα binds GDP at rest inactive release GDP

Binding of
GTPto Ga
– Gβ and Gγ complete the hetero-trimer Dissociation of GBand Gy
Activation of receptor leads to:
– GDP release and GTP binding to Gα alpha
– Dissociation of Gβ and Gγ
tostop
intialstate
Slow hydrolysis of GTP to GDP returns the system to the resting state
Both the activated α subunit and the free big complex can regulate
target proteins. BandY
 charged
small
compounds

8- An activated Ga-protein-GTP can
trigger the formation of cAMP, which
then acts as a second messenger in
cellular pathways.

A
proteinkinase

9- cAMP activates the enzyme cyclic-
AMP-dependent protein kinase (PKA).
 The Cyclic AMP Pathway Can Activate Enzymes and
Turn On Genes

 The activated G-protein alpha subunit
switches on the adneylyl cyclase, causing a
dramatic and sudden increase in the
synthesis of cAMP from ATP (Gs).

of
Pasig gita's
a

 To help eliminate the signal, a second
enzyme called cAMP phosphodiesterase,
rapidly converts cAMP to ordinary AMP.
1
cAMP-dependent protein kinase (PKA) mediate
most of the effects of cyclic AMP

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ii n
11Imation

does

Role of cAMP, PKA in glycogen metabolism
 10- PKA catalyzes transfer of phosphate
from ATP to serine or threonine
residues of various cellular proteins,
altering their activity.

11- PKA phosphorylates. stimulaspecific
gene regulatory proteins te the
transcription of a whole set of target
genes.
This type of signaling pathway controls many processes in cells, ranging from hormone
synthesis in endocrine cells to the production of proteins involved in long-term memory
in the brain.
 The -adrenergic pathway
adrenaline

cadimation

La'snger
4p

kinase

nucles
expression
gene Activated PKA can also phosphorylate and thereby regulate
rigafeother other proteins and enzymes in the cytosol
proteins
 y
specifity

ACTH: Adrenocorticotropic hormone
 B: Some G-Proteins activates phospholipase C
Some extracellular signal molecules exert their effects via a type of G-
protein that activates the membrane-bound enzyme phospholipase C instead
of adenylyl cyclase.

cleavage

The Inositol Phospholipids Pathway Triggers
a Rise in Intracellular Ca2+

smooth
 target effector enzyme
is Phospholipase C

w̅
PLC cleaves a membrane
phospholipid (Phoshatidyl inositol)

Two 2nd Messengers

Inositol-1,4,5-Trisphosphate Diacylglycerol
(InsP3) (DAG)
o o
Release of Ca++ ions Activation of PKC
 Response:
Release of Ca++ ions Activated Protein Kinase C
Binds & activates Phosphorylates
Calmodulin-binding proteins
Activates seven ineroni

kinases & phosphatases Target proteins (ser & thr) physosin

Cell growth
Regulation of ion channels
cytoskeleton
increases cell pH
Transcription

Protein secretion factors
 A Ca2+ Triggers Many Biological Processes
 Ca 2+ has such an important and widespread role as an intracellular messenger.

 The effects of Ca 2+ in the cytosol are largely indirect; they are mediated through
the interaction of Ca2+ with various transducer proteins known as Ca2+ -binding
proteins.

 The most widespread and common of these is the
Ca2+ responsive protein called calmodulin.
G-protein-linked signaling :
Inositol phospholipid pathway:

A Ca2+ signal triggers many biological process
Example: the fertilization of an egg by a sperm triggers an increase
cytosolic Ca2+ in the egg.
C: Some G Proteins Regulate Ion Channels
 The target proteins for G-protein subunits are either ion channels or
membrane bound enzymes.

 Different targets are affected by different types of G proteins, and these
various G-proteins are themselves activated by different classes of cell
surface receptors.

 In this way, binding of an extracellular signal molecule to a G-protein-
linked receptor leads to effects on a particular subset of the possible
target proteins, eliciting a response that is appropriate for that signal and
that type of cell.
G proteins couple receptor activation to the opening of K+
channels in the plasma membrane of heart muscle cells.

1. Binding of the neurotransmitter acetylcholine to its
G- protein–linked receptor on heart muscle cells
results in the dissociation of the G protein into an
activated βγ complex and an activated α subunit.
G proteins couple receptor activation to the opening of K+
channels in the plasma membrane of heart muscle cells.

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phospholipase Ihappels

2- The activated γβ complex binds to and opens a K+
channel in the heart cell plasma membrane.
G proteins couple receptor activation to the opening of K+
channels in the plasma membrane of heart muscle cells.

3- Inactivation of the α subunit by hydrolysis of bound GTP
causes it to re-associate with the βγ complex to form an
inactive G protein, allowing the K+ channel to close
 Fine-Tuning of the Response

There are four aspects of fine-tuning to consider
1- Amplifying the signal (and thus the response).
inthereceptor
2- Specificity of the response. celltype
3,5
3- Overall efficiency of response, enhanced by scaffolding
proteins.
4- Termination of the signal
 1- Signal Amplification
Enzyme cascades amplify the cell’s response
At each step, the number of activated products is much
greater than in the preceding step
 Reception
Binding of epinephrine to G protein-coupled receptor (1 molecule)

What do we have/need 2nd messengers
and G proteins? Transduction
Inactive G protein

For amplification 2
Active G protein (10 molecules)

1. Single hormone binds to a single Inactive adenylyl cyclase increase ofthe
receptor molecule -> activates multiple G Active adenylyl cyclase (10 ) 2
number of
activatedmolecules
proteins (10x) -> each G protein activates a ATP

single adenylate cyclase (AC) -> each Cyclic AMP (10 ) 4

adenylate cyclase makes multiple cAMP Inactive protein kinase A

(100-1000x) -> 104 amplification with a Active protein kinase A (10 ) 4

single hormone molecule. Inactive phosphorylase kinase
Active phosphorylase kinase (105)

2. Each cAMP binds to a single PKA -> Inactive glycogen phosphorylase
Active glycogen phosphorylase (106)
each PKA can phosphorylate multiple
targets. Amplifies signal from 104 to 106 Response
Glycogen
Glucose 1-phosphate
(108 molecules)
 2- The Specificity of Cell Signaling

Different kinds of cells have different collections of proteins
which allow cells to detect and respond to different signals.
o
Even the same signal can have different effects in cells with
different proteins and pathways
– Pathway branching and “cross-talk” further help the cell coordinate
incoming signals
 3- Signaling Efficiency: Scaffolding Proteins and Signaling
Complexes
Scaffolding proteins are large relay proteins to which other relay proteins are
attached
Scaffolding proteins can increase the signal transduction efficiency by grouping
together different proteins involved in the same pathway

Signaling Plasma
molecule membrane

Receptor

Three
different
protein
kinases
Scaffolding
protein
 4- Termination of the Signal
Inactivation mechanisms are an essential aspect of cell signaling
When signal molecules leave the receptor, the receptor reverts
to its inactive state
for homeostasis
How to shut it off?

1-Within seconds, the GTP
on the a subunit is
hydrolyzed to GDP by the Gα
(GTPase activity). Alpha
subunit dissociates from AC,
turning it off –alpha binds to
βγ complex to reform an
inactive G protein -> signal is
off. Self-Inactivation in G-protein
Signaling
 How to shut it off?
2-. Hydrolysis of cAMP  AMP by Phosphodiesterases -> signal is
off.
- cAMP phosphodiesterase is inhibited by caffeine, theophylline (tea), and
theobromine (chocolate)
- cAMP helps improve memory

soshort live

signor
e cAMP-
phosphodiesterase
rapidly cleaves
cAMP
(so short lived) 35
 How to shut it off?
3- In some cases the activated receptor is phosphorylated via a G-
protein Receptor Kinase.
The phosphorylated receptor then may
bind to a protein
β-arrestin, preventing interaction with
G proteins -> signal is off.

β-Arrestin promotes removal of the
receptor from the membrane by
clathrin-mediated endocytosis -> signal
is off.

β-Arrestin may also bind a cytosolic phosphodiesterase, bringing this
enzyme close to where cAMP is being produced, converting cAMP to AMP.
Therefore, contributing to signal turn off
 How to shut it off?
4- cAMP activates PKA phosphorylates target proteins
protein phosphatase dephosphorylates proteins target
proteins converted back to original form, reversing the
signal -> signal is off
The G protein is now ready to
couple to another receptor.

kinases – phosphatases
What if you can’t turn off cascade?
Vibrio cholera - causes cholera

Normal gut: H20, NaCl, NaHCO3 secretion controlled by
hormones via Gs/cAMP signal pathways
bacteria

 V. cholera – secretes enterotoxin, chemically modifies
Gs – no GTPase activity - stays ON

The stimulatory G-protein is permanently activated.

Severe watery diarrhea – dehydration, death
 Summary: G-PROTEIN–COUPLED RECEPTORS

Stimulation of GPCRs Activates G-Protein Subunits
Some G Proteins Directly Regulate Ion Channels
Some G Proteins Activate Membrane-bound Enzymes
The Cyclic AMP Pathway Can Activate Enzymes and Turn On Genes
The Inositol Phospholipid Pathway Triggers a Rise in Intracellular
Ca2+
A Ca2+ Signal Triggers Many Biological Processes
Intracellular Signaling Cascades Can Achieve Astonishing Speed,
Sensitivity, and Adaptability