Cell Communication 1: GPCRs 2024 Lecture Notes PDF

Summary

This document is a set of lecture notes on cell communication and G-protein-coupled receptors (GPCRs). It outlines different signal types, including light, small molecules, and proteins, and discusses signaling pathways involving receptor activation, transduction, and cellular responses

Full Transcript

In this lecture, we will investigate
cellular signal, concentrating on G-
Protein Coupled Receptors – their
activators, G-proteins, and
downstream effectors
Signals come in a variety of types.
A signal can range from light
(which activates the GPCR
receptors in the rods and cones in
your eye), to small molecules
(dopamine, morphine, etc.), to
proteins (Wnt signaling involved in
development), to mechanical
signals.
Signaling pathways can be divided
into three components
1.In order to detect a signal, cells
must have an appropriate
receptor that detects the stimulus
and converts it into a biological
signal the cell can use
2.Often, the signal is relayed within
the cell by a pathway of
sequentially acting proteins to
the appropriate intracellular
target in a process referred to as
 transduction
3.Finally, the cell responds by
mounting a response – the response
can be a change in the activities of
cellular proteins, a change in the
pattern of genes it expresses, or
both.
The textbook provides us with a
useful analogy for transduction
A cell phone receives radio
signals from the broadcast towers
and converts those signals into
sounds your ear can perceive and
vice versa when you speak. The
phone can also get signals from
your voice, from Bluetooth, wifi,
and it can detect light using its
camera, or vibrations/movement,
or mechanical action as you press
 the screen or buttons. All these
inputs illicit different responses.
Likewise, a signal received by a cell
(in this case a ligand binding to a
membrane receptor) must be
converted into an intracellular
biochemical pathway that does
something within the cell to change
its state
Eukaryotic cells depend on multiple
extracellular signals and there are
a few general principles that we
must consider as we discuss
signaling pathways
Individual cells respond only to
signals they can detect
Different cells may be primed to
respond differently to the same signal
by the expression of different/distinct
sets of receptors that can detect the
signal, and the expression/regulation of
distinct downstream effector
proteins/molecules in the pathway.
A single cell may have none, a few, or
thousands of receptors for a particular
signal
Combinations of signals acting together
can elicit distinct cellular responses
As shown in the figure, most cells
require signals to promote their survival –
if these are deprived then the cell will
activate programmed cell death and die
(cancer cells are a notable exception and
can survive independently of these
signals)
Some cells require signals to grow and
divide
Some cells respond to various signals by
changing their cell fate during
development – you’ll learn about these
pathways in the second half of the course
One signal molecule may induce
different response in different
target cells
Example: acetylcholine is a
neurotransmitter, its structure is
shown in (D)
Acetylcholine signals to
pacemaker cells in the heart to
decrease the rate of your
heartbeat
Acetylcholine signals to cells in
your salivary gland to trigger
 secretion of components of saliva by
regulated exocytosis
The acetylcholine receptor protein in
both cell types is identical, but the
cells have a completely different
physiological response
Acetylcholine binds to a different
receptor (a ligand-gated ion channel)
on skeletal muscle cells (a ligand-
gated ion channel) to trigger muscle
contraction
Therefore: the signal alone is not the
message; the information depends
on how the target cell receives and
interprets the signal
Another key concept is that signals
can act on different time scales
Some signals exert their effect
rapidly (on the order of
milliseconds to minutes)
These signaling pathways are fast
because they alter the activities of
proteins that are present within
the cell
Some signals exert their effects
slowly (minutes to hours)
These pathways involve changes
in gene expression; they are slower
because of the time required for
transcription of new mRNAs and the
time required for translation of these
new proteins
It’s also important to consider that
intercellular communication occurs
over varying distances depending
on the mechanism of the pathway
Contact-dependent signaling can
occur between two cells that are
in direct physical contact with one
another
In this case, the signaling cell
expresses a ligand molecule that
is bound to the extracellular
surface of its plasma membrane
 The target cell expresses a receptor
protein that is also bound to its
membrane
This ligand may only interact with its
receptor when the two cells are
adjacent to each other
Cell signaling also occurs on
distance scales of less than a cell
diameter to a few cell diameters
away
We’ve already seen an example of
this when neurons communicate
with each other by regulated
exocytosis of neurotransmitters at
synapses
Paracrine signals are released into
the extracellular fluid where they
act locally on neighboring cells
Cell-cell signaling may also act
over long distances
Endocrine signaling occurs when
endocrine glands secrete
hormones into the bloodstream
Hormones are distributed
throughout the body, target cells
with appropriate receptors can be
far-removed
Autocrine signaling is when a cell
secretes a signal that binds to a
receptor on the same cell and
activates a signaling pathway.
 Signal transduction pathways have evolved to
perform multiple functions:
Transduce the signal into a molecular form that
can carry out the response
Relay the signal from point of reception to point
of action in the cell
Amplify the received signal
Integrate multiple signals that in combination
can cause distinct responses
Feedback from a pathway can regulate an
upstream component of that pathway
Distribute the signal to coordinate several
responses in parallel
Remember phosphorylation and
GTP-binding proteins (G-proteins)?
Amino acid residues that have a
hydroxyl (-OH) group are the
main targets for phosphorylation
by kinases
Proteins can be phosphorylated
on three different amino acid
residues: serines, threonines, and
tyrosines (one set of kinases
target serines and threonines,
another set targets tyrosines).
 G-proteins – cycle between active
and inactive conformations
depending on whether GTP or GDP is
bound, respectively. GTP binding is
controlled by GEFs (guanine
exchange factors), and the ability to
intrinsically hydrolyze GTP to GDP
leads to the G-protein to turn off.
The hydrolysis can be accelerated by
GTPase Activating Proteins (GAPs).
GTP-binding proteins are GTPases
that come in two prime varieties –
monomeric (small) GTPases, and
larger heterotrimeric GTPases.
The small GTPases (monomeric)
and the Galpha subunit have a
common GTPase domain, however
the Galpha subunit also has a
second domain called the “helical
domain”
G proteins have an endogenous
GTPase activity
GTP bound = ON, GDP bound =
OFF
The GTPase activity of G proteins
is usually regulated by accessory
factors
Guanine nucleotide exchange
factors (GEFs) induce G proteins
to release GDP and to bind to GTP
to become active
While many GTP-Binding proteins
 have intrinsic GTPase activity, GTPase
activating factors (GAPs) can bind a G
protein and enhance its rate of GTP
hydrolysis, thereby serving to
regulate the time a GTP-binding
protein is active.
These GTP and GDP-bound states
drive distinct structural
conformations of the G-protein
(allosteric changes) that regulate
what the G-protein can bind in its
“on’ and “off” states.
There are three main classes of
receptors we will discuss. For this
lesson, we will focus on GPCRs.
The second class of receptors are
G-protein coupled receptors
(GPCRs)
Largest family of cell surface
receptors in animals (>700 in
humans)
GPCRs detect odorants, light,
many other types of signals
These receptors have 7
transmembrane α-helices
Extracellular-facing N-terminus
and extracellular loops that may
 bind signals
Intracellular-facing C-terminus and
intracellular loops that interact with
downstream effectors
The second class of receptors are
G-protein coupled receptors
(GPCRs)
Largest family of cell surface
receptors in animals (>700 in
humans)
GPCRs detect odorants, light,
many other types of signals
These receptors have 7
transmembrane α-helices
Extracellular-facing N-terminus
and extracellular loops that may
 bind signals
Intracellular-facing C-terminus and
intracellular loops that interact with
downstream effectors
Ligand binding to the outside of
the receptor triggers a
conformational change on residues
on the cytosolic side. Different
GPCRs engage ligands in different
ways, but all transduce a
conformational change that to the
cytosolic side of the GPCR. This
enables the signal to be relayed to
the inside of the cell, across the
lipid bilayer.
Small molecules can be agonists,
which activate the GPCR and
transduce a signal to the cell
interior. Or they can be
antagonists, which compete for
agonists. Antogonists bind the
GPCR, but do not activate it – they
keep the GPCR in the off state.
They are effectively competitive
inhibitors. A specific GPCR can
have multiple agonists and
antagonists.
Harry Potter is neither an agonist
nor an antagonist. Or is he? Maybe
in some fan fiction.
The opiod receptor has a lot of
fame and press these days – as it is
the target for endogenous opiods
like beta-endorphin, but also the
target for exogenous or synthetic
opiods like morphine, opium,
oxycodone. Antagonists can be
life-saving. Like the use of
maloxone. It has high affinity for
opiod receptors and can compete
off opiates, but keep the receptor
inactive when naloxone is bound.
Be a protagonist and pick up some
antagonist at your pharmacy – you
might be able to save a life.
Another example of a GPCR: the
beta-adrenergic receptor. Agonists
include epinephrine. Antagonists
include propranolol.
This receptor, once activateD,
initiates the fight or flight response
(adrenaline)
GPCRs are major drug targets.
GPCRs signal through Gproteins.
Unlike small G-proteins like ran or
ras, these are heterotrimeric G-
proteins with an alpha, beta, and
gamma subunit. The G-alpha
protein is the GTP-binding protein,
which undergoes GTP-dependent
conformational changes. There are
a number of Galpha subunits – the
major classes of Galpha subunits
are shown above. The G-beta-
gamma subunits form an obligate
(always found together) heterodimer.
Together with the Galpha subunit,
they can form a heterotrimer. The
heterotrimer only forms when Galpha
is in the GDP state.
The GPCR binds the heterotrimeric
G-protein.
Once the GPCR is activated, it
induces guanine exchange on the
G-alpha subunit. GDP is released.
As the cytosolic concentration of
GTP is higher than GDP, GTP binds
the G-alpha subunit. This causes a
conformational change in the G-
alpha subunit, causing dissociation
of the Gbeta-gamma subunit.
Galpha-GTP and the free Gbeta-
gamma subunits are free to engage
and activate or inhibit downstream
effector molecules until the Galpha
subunit hydrolyzes GTP to GDP, and
the Galpha-beta-gamma heterotrimer
reforms.
GPCR GEF activity enables GDFP
dissociation and GTP binding to
the G-alpha subunit. The Galpha
then dissociates from the Gbeta-
gamma heterodimer, and each can
go on to activate downstream
effectors.
Signaling downstream of GPCRs
occurs through multiple molecules
GPCRs communicate directly with
heterotrimeric G-proteins
Heterotrimeric G proteins are
composed of α, β, and γ subunits
– only the α subunit binds to
GTP/GDP
In its GDP-bound state, all three
subunits associate in an inactive
conformation
When Gα binds to GTP, it
 dissociates from Gβγ and adopts an
active conformation
When a ligand binds to the
extracellular surface of the GPCR, the
cytosolic surface acts as a GEF for Gα
causing it to release GDP, bind to
GTP, and become activated
Gα and Gγ are covalently attached to
lipids in the membrane so they
diffuse within the bilayer
The active subunits diffuse within the
plane of the membrane to activate
downstream signaling molecules
(more about these in a bit)
There are many Galpha subunits –
each with specific downstream
effectors. Of note, a key
downstream effector is adenylyl
cyclase (AC). AC is activated by
Galpha-s (Stimulate) and inhibited
by Galpha-I (Inhibitory). There are
also many Gbeta and Ggamma
proteins – leading to a
combinatorial set of heterotrimeric
G-proteins that can be formed.
Galpha subunits have a catalytic
site – ie, they have all the residues
needed to hydrolyze GTP to GDP.
This is an intrinsic timer so that
downstream activation is limited by
the time the G-alpha subunit is in
the GTP state.
Give this some thought….
Other proteins, called GTPase
activating proteins (GAPs), can bind
and stimulate the Galpha subunit’s
intrinsic GTPase activity. They do
this by binding the Galpha subunit
in a state akin to its conformation
when GTP hydrolysis is in the
transition state. Ie, it lowers the
activation energy for the Galpha to
hydrolyze the GTP!
What are the signaling targets
downstream of heterotrimeric G-
proteins?
The Gβγ subunit can activate
ligand-gated ion channels
Acetylcholine slows the heart by
acting through pacemaker cells
Receptor activation ==>
dissociation of Gα and Gβγ
Gβγ opens K+ channels to make he
membrane harder to to activate
by depolarization and slows heart
rate
What are the signaling targets
downstream of heterotrimeric G-
proteins?
Many G proteins activate
membrane-bound enzymes that
produce small messenger
molecules
First messengers are
heterotrimeric G-proteins
Second messengers are these
molecules synthesized at the
membrane that diffuse into the
cytosol to act on other downstream
signaling proteins
cAMP and IP3 and DAG are second
messengers – ie. downstream
signaling molecules.
The first second messenger
molecule we’ll discuss is cAMP
cAMP is generated from ATP by
adenylyl cyclase and degraded to
AMP by cAMP phosphodiesterase
Caffeine inhibits
phosphodiesterase – your cup of
morning coffee is partially
stimulating your brain by keeping
cAMP around in your neurons for
longer
cAMP mediates its downstream
effects by activating cAMP-
dependent protein kinase (PKA) for
fast AND slow signaling
Example of signaling by cAMP and
PKA: glycogen utilization by
skeletal muscles
Muscles and liver store glucose as
a polysaccharide called glycogen
(polymer of glucose) that’s
broken down rapidly to provide
glucose as a short-term energy
supply
The hormone epinephrine is
secreted by the adrenal gland in
response to stress or physical
 exertion
Epinephrine binds to a GPCR on
muscles to activate heterotrimeric G-
proteins that, in turn, activate
adenylyl cyclase
Adenylyl cyclase converts ATP to
cAMP
cAMP activates PKA which goes on to
phosphorylate another kinase called
phosphorylase kinase
Phosphorylase kinase phosphorylates
a THIRD enzyme named glycogen
phosphorylase
Glycogen phosphorylase causes
glycogen breakdown into glucose
that the muscle will use to power
contraction
Multi-step signal transduction
cascade, but FAST because no new
gene expression is required
cAMP will then be broken down to
AMP by cAMP phosphodiesterase (not
shown) to terminate the signal
Another example of signaling by
cAMP and PKA: changes in gene
expression
In many cell types, a rise in cAMP
responses involve changes in
gene expression that occur over
minutes to hours
In this case, once activated by
binding to cAMP, PKA enters the
nucleus to phosphorylate
transcription factors
This activation leads to
 expression of sets of genes
This mechanism is important for
many different processes including
hormone production in endocrine
cells and the formation of long-term
memories in certain neurons in the
brain
Thus, cAMP acts as a second
messenger in both short- and long-
term signaling pathways
Another example of signaling by
cAMP and PKA: changes in gene
expression
In many cell types, a rise in cAMP
responses involve changes in
gene expression that occur over
minutes to hours
In this case, once activated by
binding to cAMP, PKA enters the
nucleus to phosphorylate
transcription factors
This activation leads to
 expression of sets of genes
This mechanism is important for
many different processes including
hormone production in endocrine
cells and the formation of long-term
memories in certain neurons in the
brain
Thus, cAMP acts as a second
messenger in both short- and long-
term signaling pathways
Remember: Ca+2 concentration is
low in the cytosol
Pumps in the plasma membrane
pump some calcium out of the
cell
BUT pumps in the ER and in
mitochondria also transport Ca+2
into the ER lumen and into the
matrix, respectively
ER calcium is used as an internal
“reservoir” to be used in specific
signaling pathways
The other most common enzyme
activated by heterotrimeric G-
proteins is phospholipase C (PLC)
PLC signals through the
production of TWO downstream
second messengers
GPCR is activated by ligand è
heterotrimeric G-proteins
activated by GPCR è PLC is
activated by Gβγ
PLC binds to a membrane lipid –
inositol phospholipid and cleaves
 it into:
1.Diacylglycerol which stays
associated with the membrane, and
2.Inositol 1,4,5-trisphosphate (IP3)
which is release from the membrane
and diffuses into the cytosol
Diacylglycerol recruits a kinase
named protein kinase C (PKC) to bind
to the cytosolic face of the plasma
membrane
IP3 binds to a ligand-activated Ca+
ion channel in the ER membrane
causing it to open and release Ca+2
into the cytosol
Ca+2 binds to PKC on the membrane
and ACTIVATES it to phosphorylate
its own set of downstream targets to
propagate the signal
The targets of PKC vary depending
on the type of cell
The other most common enzyme
activated by heterotrimeric G-
proteins is phospholipase C (PLC)
PLC signals through the
production of TWO downstream
second messengers
GPCR is activated by ligand è
heterotrimeric G-proteins
activated by GPCR è PLC is
activated by Gβγ
PLC binds to a membrane lipid –
inositol phospholipid and cleaves
 it into:
1.Diacylglycerol which stays
associated with the membrane, and
2.Inositol 1,4,5-trisphosphate (IP3)
which is release from the membrane
and diffuses into the cytosol
Diacylglycerol recruits a kinase
named protein kinase C (PKC) to bind
to the cytosolic face of the plasma
membrane
IP3 binds to a ligand-activated Ca+
ion channel in the ER membrane
causing it to open and release Ca+2
into the cytosol
Ca+2 binds to PKC on the membrane
and ACTIVATES it to phosphorylate
its own set of downstream targets to
propagate the signal
The targets of PKC vary depending
on the type of cell
In the next lecture, we’ll talk about
enzyme coupled receptors.