Neurotransmitter Receptors I: Ionotropic Receptors PDF

Summary

This document is a lecture outline on neurotransmitter receptors, specifically ionotropic receptors. It covers the life cycle of neurotransmission, including synthesis, storage, release, receptor binding, and inactivation. It also includes a section on the outcome of neurotransmitter release and various receptor families.

Full Transcript

2024-10-09

Neurotransmitter Receptors I:
Ionotropic Receptors

NROC36H3F

© Arruda Carvalho UTSC

The Life Cycle of Neurotransmission
I. Synthesis (1-2)
II. Storage (3) Lecture 3
III.Release
Lecture 4

From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc
IV. Receptor Binding (4-5)
V. Transmitter Inactivation (6-9)
Lecture 3
© Arruda Carvalho UTSC

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Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

What is the Outcome of Neurotransmitter Release?

?
Type of Response – Postsynaptic Receptor

Magnitude of Response – Receptor number, "state" of the receptors,
and amount of neurotransmitter released

© Arruda Carvalho UTSC

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Ionotropic and Metabotropic Receptors

Fast synaptic actions lasting
Slower synaptic actions lasting seconds to minutes
only milliseconds
Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

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Ionotropic Receptor Families

composed
of 3 to five
subunits

Each subunit has a membrane domain with four membrane-spanning -helices (M1– M4) and a short
extracellular c-terminus. The M2 helix lines the channel pore
Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

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nACh Receptor: an Iconic Ionotropic Receptor

Torpedo Ray

Panoramic view of the postsynaptic membrane of an electrocyte in the
Torpedo electric organ. The vase-like structure in the center of the field is
the external surface of the postsynaptic membrane. Clusters and linear
arrays of 8 to 9 nm protrusions represent the AChR oligomers.
© Arruda Carvalho UTSC

nACh Receptor: an Iconic Ionotropic Receptor
Two extracellular binding sites for Ach: In the clefts between
each α-subunit and its neighboring γ- or δ-subunit

The plant alkaloid nicotine can bind to the ACh binding site to activate the receptor

Principles of Neural Science ©McGraw Hill © Arruda Carvalho UTSC

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nACh Receptor: an Iconic Ionotropic Receptor

Each subunit contributes
one cylindrical
component to form
the ion channel through
the middle of the
complex

From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc
© Arruda Carvalho UTSC

nACh Receptor: an Iconic Ionotropic Receptor

Each subunit contains four
hydrophobic regions of
approximately 20 amino
acids called M1 to M4, each
of which is thought to form
an α-helix that spans the
membrane

Negatively charged amino
acids on each subunit repel
anions and establish cation
selectivity

Principles of Neural Science ©McGraw Hill © Arruda Carvalho UTSC

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nACh Receptor: an Iconic Ionotropic Receptor

The membrane-spanning segments that line
the pore are the five M2 regions, one
contributed by each subunit. The amino acids
that compose the M2 segment are arranged in
such a way that three rings of negatively
charged amino acids are oriented toward the
central pore of the channel – providing cation
selectivity

Modified from Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc
© Arruda Carvalho UTSC

nACh Receptor: an Iconic Ionotropic Receptor

or AcH

Some neuronal nicotinic ACh
receptors are composed of five
identical subunits and are
thought to bind five molecules
of Ach.

Each subunit binds one
molecule of Ach at the ACh
binding site, which is located
at the interface between
neighboring subunits

Principles of Neural Science ©McGraw Hill © Arruda Carvalho UTSC

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nACh Receptor: an Iconic Ionotropic Receptor
ACh gains access to its binding sites by entering the central pore of the receptor
where it then enters small channels that provide access to the binding sites.
Once the binding sites are occupied, the receptor rapidly opens to allow ion flow.

From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc
© Arruda Carvalho UTSC

nACh Receptor: an Iconic Ionotropic Receptor

The closed-to-open transition of the receptor is When the M2 segments
associated with a subtle rotation of its M2 segments. rotate because of ACh
binding, the kinks also rotate,
The M2 segments are helical and exhibit a mild kink in
relaxing the constriction
their structure that forces a leucine (L) residue from each
formed by the leucine ring,
segment into a tight ring that effectively blocks the flow
and ions can then flow
of ions through the central pore of the receptor.
From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc
© Arruda Carvalho UTSC

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nACh Receptor: Posttranslational Modification

nACh Receptor is phosphorylated by three kinases:

PKA phosphorylates the γ and δ subunits

PKC phosphorylates the δ subunit

Unidentified tyrosine kinase phosphorylates the β, γ,
and δ subunits

Phosphorylation sites are within the intracellular
loop between M3 and M4

Phosphorylation increases the rapid phase of
desensitization of the receptor, thereby limiting ion
flux through transitions into a closed state
TM = M

From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc
© Arruda Carvalho UTSC

nACh Receptor: Structural Variability

Functional neuronal nAChRs can be assembled from a single subunit (as in α7, α8, and α9), and
a single type of α subunit can be assembled with multiple types of β subunits (e.g., α3 with β2
or β4 or both) and vice versa, producing an array of receptors with distinct single channel
kinetics and rates of desensitization
Hendrickson et al., Frontiers in Psychiatry, 2013 © Arruda Carvalho UTSC

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nACh Receptor and the Rest of the Family

From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc
© Arruda Carvalho UTSC

Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

10
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5-HT3 Receptor

Homomeric complex composed of five copies of the same subunit (most related to α7
subtype of neuronal nAChRs),
Permeable to Na+ and K+ but not Ca2+
Sparsely distributed on peripheral primary sensory nerve endings and in the mammalian CNS
Antagonists used to treat vomiting, nausea, anxiety, psychosis
© Arruda Carvalho UTSC

Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

11
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GABAA and Glycine Receptors

GABAA

Jacob et al., Nat Rev Neuro, 2008

GABAA receptors are usually composed of two α-, two β-, and one γ- or δ-subunit.

The receptors are activated by the binding of two molecules of GABA in clefts formed
between the two α- and β-subunits, allowing the opening of the channel and influx of Cl-
Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

GABAA and Glycine Receptors

Glycine

Glycine receptors are composed of three α-
and two β-subunits and require the binding of
up to three molecules of ligand to open

Du, Lu et al., Nature, 2015
Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

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GABAA and Glycine Receptors
GABAA

TM = M

Jacob et al., Nat Rev Neuro, 2008 https://aopwiki.org/events/667

GABA and glycine receptor-channels contain either neutral or positively charged basic
residues flanking the M2 domain, which contributes to the selectivity of these channels for
anions

© Arruda Carvalho UTSC

GABAA and Glycine Receptors
GABAA

In Which Ways Could Modifications of
GABAARs or Glycine Receptors Interfere with
their Function? What could be the
Consequences for Behaviour?

© Arruda Carvalho UTSC

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GABAA Receptors and Disease

Underlying repetitive, non-abating seizures is a decrease in the phosphorylation of GABAAR
β3 subunits by PKC. This leads to an increased association with the clathrin-adaptor protein 2
(AP2) complex, followed by increased internalization through clathrin-mediated endocytosis.
Decreased numbers of synaptic GABAARs lead to reduced synaptic inhibition (= increased
excitatory drive and lower seizure threshold)

Jacob et al., Nat Rev Neuro, 2008 © Arruda Carvalho UTSC

Glycine Receptors and Disease

Strychnine, a GlyR antagonist
Pesticide, commonly used in rodents and small birds
Muscle spasms, followed by respiratory failure and brain death

Agatha Christie, in 1925.
Wikimedia Commons

© Arruda Carvalho UTSC

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Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

Purinergic Receptors

Ionotropic receptors for adenosine triphosphate (ATP), which serves as an excitatory
transmitter

Kaebisch et al., Comp Struct Biotech J, 2015

Smooth muscle cells innervated by sympathetic neurons of the autonomic ganglia as well as
on certain central and peripheral neurons

© Arruda Carvalho UTSC

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Purinergic Receptors

Comprised of only two transmembrane
domains, with some homology in its pore-
forming region with K+ channels. Each subunit
contributes two transmembrane (TM or M)
domains and three subunits congregate
together to form the native receptor

Permeable to both monovalent cations and Ca2+

Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

Purinergic Receptors

ATP binding causes the
expansion of the pore region
in an iris-like manner by
twisting of the transmembrane
(TM) helices to allow
permeation of cations

Browne et al., PNAS, 2014
© Arruda Carvalho UTSC

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Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

Glutamate Receptors

Development of agonists that could
pharmacologically distinguish
between different glutamate
receptor subtypes

N-methyl-D-aspartate (NMDA),
amino- 3-hydroxy-5-
methylisoxazoleproprionic acid
(AMPA), Kainate

© Arruda Carvalho UTSC

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Glutamate Receptors

(Non-NMDA)

Ionotropic
(NMDA or non-NMDA)

Metabotropic

Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

Ionotropic Glutamate Receptors

(Non-NMDA)

CNQX APV
(2-amino-5-phosphonovaleric acid)
(6-cyano-7-nitroquinoxaline-2,3-dione)

Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

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Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

AMPA Receptors

Receptor assembly and trafficking

Three transmembrane α-helixes (M1, M3, and M4) and a
loop (M2) between the M1 and M3 helixes that dips into
Glutamate binding and out of the cytoplasmic side of the membrane. This M2
loop is thought to form the selectivity filter of the channel
Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

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AMPA Receptors: subunit composition

Sobolevsky et al., Nature, 2009
GluA4
Mod from Henley and Wilkinson, Dial Clin Neurosci, 2013

AMPARs are tetrameric structures, comprised of different combinations of the four types of
subunits, GluA1-4. Most AMPARs in the brain contain GluA2, a subunit that renders them
impermeable to Ca2+. Increasing amounts of evidence point towards an important role of
GluA2-lacking AMPARs, which are calcium permeable (cp-AMPARs), in synaptic plasticity
and learning
© Arruda Carvalho UTSC

AMPA Receptors: subunit composition

AMPARs containing the GluA2
subunit (light blue) in its unedited
(Q; pink) form also gate calcium.
However, the presence of a GluA2
subunit that has been RNA edited
to replace Q607 with an arginine
(R; dark blue) renders the AMPAR
impermeable to calcium

Henley and Wilkinson, Nat Rev Neuro 2016

© Arruda Carvalho UTSC

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AMPA Receptors: subunit composition

GluA2

After transcription the codon for glutamine in the M2 loop of the GluA2 mRNA is replaced
with one for arginine (a positively charged basic amino acid) because of a chemical
modification of a single nucleotide base through an enzymatic process termed RNA editing.

Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

AMPA Receptors: subunit composition

AMPA receptor-channels with this edited
GluA2 have a very low permeability to Ca2+,
most likely as a result of strong electrostatic
repulsion by the arginine

From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc
© Arruda Carvalho UTSC

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AMPA Receptors: subunit composition

RNA editing switches single amino acid in
GluA2 reducing Ca2+ permeability
GluA2

From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc

Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

AMPA Receptors: subunit composition

Deletion of the editing
site complementary
sequence (ECS) in the
intron impairs GluA2 Q/R
RNA editing. This resulted
in approximately 25%
unedited GluA2 mRNA at
the Q/R site compared to
age-matched wild-type
littermates

© Arruda Carvalho UTSC

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AMPA Receptors: Desensitization

Extended exposure to glutamate can lead to a change in the dimer bond at the ligand binding
domain which leads to closure of the channel. The rate and speed of desensitization will be
affected by composition of receptor subunits

From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc © Arruda Carvalho UTSC

Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

23
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NMDA Receptors

Critical role in development, learning and memory and brain injury

Unique properties:

Permeable to Ca2+

Glycine as a co-factor

Voltage-dependent

Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

NMDA Receptors
Membrane Depolarization Expels Mg2+ to Allow Ion Flux

Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

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NMDA Receptors: Structure

Paoletti et al., Nat Rev Neuro 2013

Karakas and Furukawa, Science 2014

Similar to AMPARs, NMDARs are tetrameric structures with four distinct domains: the
N-terminal domain (NTD), the agonist-binding domain (ABD), the transmembrane domain
(TMD) containing the ion channel, and an intracellular C-terminal domain (CTD)

© Arruda Carvalho UTSC

NMDA Receptors: Structure

Paoletti et al., Nat Rev Neuro 2013

Seven NMDAR subunits: GluN1, GluN2A– GluN2D and GluN3A and GluN3B.
NMDAR is composed of two GluN1 subunits and either two GluN2 subunits or a combination
of GluN2 and GluN3 subunits.
© Arruda Carvalho UTSC

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NMDA Receptors: Structure
Glutamate binding site

Glycine binding site Paoletti et al., Nat Rev Neuro 2013

GluN1 is essential for the formation of a functional pore to permit the flow of ions. The GluN1 or
GluN3 subunits provide the glycine-binding site for the receptor, while the GluN2 subunits
contain the glutamate binding sites.
© Arruda Carvalho UTSC

NMDA Receptor Subunit Diversity

Subunit composition
determines receptor
properties

Paoletti et al., Nat Rev Neuro 2013
© Arruda Carvalho UTSC

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NMDA Receptors: Function
The individual contributions of NMDA and AMPA receptors to the total excitatory postsynaptic
current (EPSC) can be dissected using pharmacological antagonists in voltage-clamp

The difference between the traces (blue
region) represents the contribution of the
NMDARs to the EPSC

The current that remains in the presence
of APV is the contribution of the AMPARs

Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

NMDA Receptors: Function

What Happens if NMDAR Function is
Disturbed?

© Arruda Carvalho UTSC

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NMDA Receptors, Hallucinations and Schizophrenia

Hallucinogenic
compounds Phencyclidine
(PCP), Ketamine, and
dizocilpine (MK-801) are
NMDAR pore-blockers

From Molecules to Networks, © 2014, 2009, 2004 Elsevier Inc
© Arruda Carvalho UTSC

NMDA Receptors, Hallucinations and Schizophrenia

Glutamate hypothesis of Schizophrenia

Glutamatergic projection neuron
Ketamine

Interneuron

Mod from Stone et al., Ther Adv Psychopharm, 2011

© Arruda Carvalho UTSC

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NMDA Receptors and Glutamate Excitotoxicity

Kritis et al., Front Cell Neurosci 2015

© Arruda Carvalho UTSC

Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

29
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Distribution of Ionotropic Glutamate Receptors: Postsynaptic
Density (PSD)

View of PSD from outside of the cell View of PSD from inside of the cell

A typical PSD is around 350nm long, with approximately 20 NMDARs (located by the
center of the PSD), and 10 to 50 AMPARs (less centrally localized). mGluRs are located
on the periphery, outside the main PSD

Principles of Neural Science 5th edition © The McGraw-Hill Companies © Arruda Carvalho UTSC

Distribution of Ionotropic Glutamate Receptors: Postsynaptic
Density (PSD)

PSD-95: Binds to the NMDAR, AMPAR and other proteins, localizing and concentrating
them at postsynaptic sites

Transmembrane AMPA receptor regulatory proteins (TARPs): Strongly regulates the trafficking,
synaptic localization, and gating of AMPARs. E.g. Stargazin

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AMPAR Trafficking is Complex and Tightly Controlled

Jacobi and von Engelhardt, Curr Op Neurobiol, 2017 © Arruda Carvalho UTSC

TARP Composition Differs Across the Brain

Jacobi and von Engelhardt, Curr Op Neurobiol, 2017

© Arruda Carvalho UTSC

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TARPs: Stargazin

stg mice lack Stargazin
© Arruda Carvalho UTSC

TARPs: Stargazin

stg WT

GluA1

GluA2

GluA

GluA

stg mice show lack of functional AMPARs in cerebellum despite normal expression of GluA
© Arruda Carvalho UTSC

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TARPs: Stargazin

Increasing expression of Stargazin increases the presence of
AMPAR in the membrane
Exogenous glutamate (whole neuron)

Bath application

Evoked response
Neurotransmitter release in the synapse Control = normal levels of stargazin
Stg = overexpression of stargazin
Schnell et al., PNAS, 2002
© Arruda Carvalho UTSC

TARPs: Stargazin

Increasing expression of Stargazin increases the presence of
AMPAR in the membrane

Bath application

Evoked response
Increased presence of AMPARs in the membrane leads to an increase in response to bath application of
glutamate (H), but no change in the evoked response (E), as these receptors are not in the synapse

Schnell et al., PNAS, 2002 © Arruda Carvalho UTSC

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TARPs: Stargazin

Increasing expression of PSD-95 increases the presence of
AMPAR in the synapse

Bath application

Evoked response

Schnell et al., PNAS, 2002
© Arruda Carvalho UTSC

(1)
(2)

Stargazin guides AMPARs to membrane (1) and anchors them to the synapse via its PDZ
domain-mediated interaction with PSD95 (2)

Tomita et al., J. Cell Biol 2001 © Arruda Carvalho UTSC

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synaptic

Bath application (exogenous glutamate) Spontaneous Transmission

stg/stg = stargazin knockout
Stargazin C = Removal of C terminal PDZ binding domain (disrupts binding to PSD-95)

© Arruda Carvalho UTSC

Tomita et al., J. Cell Biol 2001
“The interaction of stargazin with AMPA receptor subunits is essential for delivering functional
receptors to the surface membrane of granule cells, whereas its binding with PSD-95 and
related PDZ proteins is required for targeting the AMPA receptor to synapses”
© Arruda Carvalho UTSC

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AMPAR Auxiliary Subunits: Stargazin

Stargazin Kato et al., TINS, 2010

Stargazin increases GluA surface expression, glutamate affinity, and attenuates the rate and
extent of desensitization

The stargazin-mediated enhancement of glutamate evoked currents reflects both an
increase in GluA surface expression and an augmentation of ion flow

© Arruda Carvalho UTSC

Lecture Outline
Overview
Ionotropic Receptor Families
nACh receptor
5-HT3 Receptor
GABAA and Glycine Receptors
Purinergic Receptors
Glutamatergic Ionotropic Receptors
AMPA/Kainate
NMDA
Receptor Localization in the PSD
© Arruda
© 2018 Arruda Carvalho Carvalho
UTSC winterUTSC
term

36