NS2_G-protein coupled receptors_notes_2pg.pdf

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NS2. G-protein coupled receptors

Physiology IIB
Andrea Yool
[email protected]

Objectives

General principles of G-protein-coupled
receptor (GPCR) signaling mechanisms

Examples of G-protein coupled receptor
signaling:
-direct (G protein binding)
-second messenger binding
-kinase-mediated phosphorylation
Responses are defined by the ion channels
that are activated or inhibited
Ligand gated channels
produce responses that
are fast and localized.
G protein coupled
receptors produce
responses that are
relatively slower,
smaller, longer in
duration, and
widespread within the
cell.

Cell-cell communication

Cell surface receptors include:
-Directly-gated ion channel (“ligand-gated”)
-G-protein coupled receptor

Other mechanisms include:
– Tyrosine-kinase-linked receptors
– Other enzymatic activity-linked receptors
– Intracellular receptors (steroid hormones)
 Mechanism of G-protein coupled
receptor signaling
Receptor-stimulated
G proteins bind GTP,
dissociate into active
subunits that interact
with downstream
targets (effectors),

and return to the
resting state when
GTP is hydrolysed
into GDP (and
Hawes et al., 2000. Peptides 21:961
phosphate, Pi).

Mechanism of G-protein
coupled receptor signaling
G proteins have 3
subunits a and bg

The a subunit binds
GTP
Separated subunits
regulate signaling
cascades

Image from Sigma Aldrich
Good details to know

G-proteins, classified by functions
Gs stimulates adenylyl cyclase
Gi inhibits adenylyl cyclase
Gt transducin (retina) activates
phosphodiesterase
Go regulates ion channels
Gq couples to phospholipase

Diversity of G-proteins

There are multiple
isoforms for each subunit,
creating a vast array of
combinatorial possi-
bilities, and thus
selectivity of signaling
mechanisms.

For your interest
 GPCR diversity
GPCRs (“metabotropic receptors”) are a
superfamily of related genes.
There are >1000 different genes for GPCRs.
Needed to respond to diverse small molecules
and neuropeptide hormones and transmitters.
A subset use the same native transmitters
(GABA, ACh); however, these
GPCR and ligand-
gated receptors differ in
gene sequence, protein
structure, function,
pharmacology.

Responses are defined by the ion channels that
are activated (or inhibited)
Different responses to the same transmitter depend
on the type of receptor activated. selective
pharmacological
agents
DIRECT GPCR

cation or second messenger regulation of
anion current an ion channel (K or Ca, typically)
 Responses are defined by the ion channels that
are activated (or inhibited)
Example: Acetylcholine
nicotine
nAChR mAChR
muscarine
(nicotinic) (muscarinic)

cation second messenger regulation of
current an ion channel (K or Ca, typically)

Responses are defined by the ion channels that
are activated (or inhibited)
Example: Acetylcholine

GPCR typical effects

increase Kir: inhibit
mAChR
decrease Kir: excite
increase CaV: excite
decrease CaV: inhibit
Multiple levels of regulation by G proteins

1. Direct modulation of channel
function by binding of a G protein

2. Modulation by synthesis of a second
messenger that binds to the channel

3. Modulation by second-messenger-
mediated activation of a kinase that
phosphorylates the channel

Direct modulation of ion
channel function by G proteins
Example: The M channel of
cardiac atrium is regulated by the
mAChR (muscarinic ACh
receptor).
Functional significance:
Parasympathetic stimulation of the
heart slows the rate (supporting
the “rest and digest” goal of the
autonomic nervous system).
 Functional roles of K channels
Kir channels are open
at negative potentials
and set the resting
membrane potential.

KV channels open at
positive potentials, and
repolarise cells after a
stimulus.

K channels restore and
maintain the resting
state.

Parasympathetic fibers (vagus nerve) release
ACh onto the cardiac atrial muscle cells.

Go --> increased activity
of Kir channels

slower depolarisation yields
a slower heart rate
Modulation of ion channel function by binding of
an intracellular second messenger ligand

Signal transduction
in the retina

Functional significance: The mechanism for
the detection of light in the vertebrate visual
system.

How does light change membrane potential?

Photoreceptors at the back of the retina detect light
 Seeing light

“Dark current”: A continuous depolarising
current flows through cGMP-gated cation
channels in membranes of photoreceptors
in the dark.
In response to light, decreased cGMP and
closure of the channels causes hyper-
polarisation of the photoreceptor cell.
The decrease in transmitter release is
interpreted by the CNS as the detection of
light.

Photoreceptor signaling
A photon (hv) is absorbed by a
rhodopsin GPCR, thus activating
the G-protein transducin. The GT
subunit activates phosphodi-
esterase (PDE), to breakdown
cGMP into inactive GMP. cGMP-
gated cation channels close.

modified from Leskov et al., 2000
 Modulation of channel function by kinase-
mediated phosphorylation

Increase in the rate and
force of contraction in the heart
Functional significance: The
sympathetic nervous system
prepares the body for a “fight or
flight” response, which includes an
increase in cardiac output.

Sympathetic signaling in cardiac muscle

Adrenaline binds to an
adrenergic GPCR,
– activates a G protein,
which
– regulates adenylate
cyclase (an enzyme)
which
– increases the
GS synthesis of cAMP.
Sympathetic signaling in cardiac muscle
cAMP activates PKA,
a protein kinase
that phosphorylates
voltage-gated Ca
channels,
increasing their open
probability,
and thus increasing
the intracellular Ca,
promoting cardiac
muscle contraction.

Sympathetic signaling in cardiac muscle

Enhanced Ca channel
activity is seen as an
increase in the
duration of the
plateau,
corresponding to an
increase in Ca influx
and increased tension
generation (strength
of contraction).
 Revision questions

True or false? Ion channels are not influenced
by intracellular second messenger signals.

List three levels of control of channels by G-
protein signaling cascades.

What functions do GPCRs enable for
determining neuronal patterns of activity?