Excitatory neurotransmission

Question 1

How can ionotropic glutamate receptors be studied

Answer 1

• transfecting in the cDNAs encoding for their subunits into host epithelial cells, maintained in a cell culture
• function of receptors can be investigated after 1-2 days by transiently applying agonist by breif pressure ejection from nearby pipette
• whole-cell recording mode (clamped at -60mV)
• inward flow of cations

Question 2

Primary cation for AMPA and Kainate receptors

Answer 2

Na

Question 3

What are the three main types of ionotriopic glutamate receptor and how are these defined

Answer 3

• defined by selective agonist
• AMPA, Kainate, NMDA

Question 4

How to activate NMDA

Answer 4

requires both glutamate and co-agonist glycine, or D-serine

Question 5

Effects of cell depolarisation

Answer 5

NMDARs become unblocked

Question 6

Net flow of current at +20mV

Answer 6

• mainly carried by K+ ions leaving the cell
• Mg does not enter or block the cell

Question 7

Net flow of current at -60mV

Answer 7

• inward mainly carried by Na and Ca ions entering cell
• Mg enters and blocks open channel

Question 8

Impact that glycine has on current

Answer 8

• in absence of glycine, glutamate does not induce a current due to activation of AMPARs
• in presence of glycine, current is greatly increased as now glutamate additionally activates NMDARs

Question 9

Where does glutamate bind

Answer 9

GluN2 subunit

Question 10

Where does glycine bind

Answer 10

GluN1 subunit

Question 11

How can the effect of magnesium on single NMDA receptors be studied using the outside-out patch technique

Answer 11

• the traces show single channel events recorded at a negative holding potential of -60mV
• at this potential magnesium causes rapid transitions in a concentration-dependent manner from the open state to the open but blocked state

Question 12

What is APV

Answer 12

NMDR selective competitive antagonist

Question 13

What is CNQX

Answer 13

AMPAR antagonist

Question 14

Synergistic interplay of synaptic AMPA receptors and NMDA receptors at an excitatory synapse

Answer 14

• neurally released glutamate activates AMPA receptors,
• associated ion channel does not conduct due to magnesium blocking it
• Na influx causes depolarisation of neuronal spine
• if depolarisation is sufficient, it causes magnesium unblocking of NMDA receptor
• appearance of a slow synaptic depolarisation

Question 15

How does repetitive stimulation of multiple glutamatergic inputs increase the postsynaptic depolarisation

Answer 15

glutamate activation of synaptic AMPARs which unblock magnesium inhibition of NMDAR, reveals slow component of excitatory postsynaptic potential (EPSP)

Question 16

Define temporal summation

Answer 16

the same presynaptic fibre fires action potential in quick succession, causing individual EPSPs to summate

Question 17

Define spatial summation

Answer 17

two or more presynaptic inputs are simultaneously active causing their individual EPSPs to summate

Question 18

What are ionotropic AMPARs

Answer 18

• tetramer
• GluA1-4 subunits
• majority are heteromers
• calcium permeable
• blocked by endogenous polyamines
• critical in determining receptor function

Question 19

Incorporation of GluA2 subunit in ionotropic AMPARs

Answer 19

impairs Ca permeability and prevents polyamine block

Question 20

How is AMPAR permeability to calcium dictated

Answer 20

by the nature of a single amino acid located in the ion conducting pore

Question 21

RNA editing is responsible for

Answer 21

determining whether GluA2 subunit contains A or R residue at this key ion channel location

Question 22

GluA2Q

Answer 22

calcium permeable, blocked by polyamines

Question 23

GluA2R

Answer 23

calcium impermeable, not blocked by polyamines

Question 24

Which site regulates calcium permeability

Answer 24

M2 Q/R site

Question 25

What does spermine do

Answer 25

• acts as intracellular AMPAR ion channel antagonist to block outward current carried by cations
• only blocks GluA2-subunit lacking AMPARs and non-edited GluA2 AMPARs

Question 26

Evidence that S1 and S2 form ligand binding domain

Answer 26

• show sequence homology to bacterial amino acid binding proteins
• bacterial proteins bind amino acids between 2 lobes of a clam shell that are in a dynamic equilibrium between open and closed states - ligand binding stabilises the closed state
• swapping S1 and S2 fomains between GluA3 and GluK2 causes appropriate changes to the agonist pharmacology -> forming agonist binding site

Question 27

Structure of the NMDA receptor

Answer 27

• composed of GluN1 and GluN2 subunits
• NMDAR subunits have similar topology to the AMPA and kainate subunits
• GluN1 subunit binds Glycine/D-serine and the GluN2 subunit binds Glutamate
• NMDARs have an asparagine residue (site of magnesium block)

Question 28

How can we monitor movement of AMPARs in neurons

Answer 28

using fluorescent quantum dots and high resolution microscopy

Question 29

What are quantum dots (QD)

Answer 29

tiny semiconductor particles

Question 30

What factors dictate the number of synaptic receptors

Answer 30

• reversible receptor stabilisation
• a dynamic equilibrium between pools of receptors in synaptic extrasynaptic and intracellular compartments

Question 31

For effective synaptic transmission, postsynaptic receptors must…

Answer 31

cluster opposite presynaptic release sites

Question 32

How are newly synthesized receptors transported in AMPA receptor trafficking

Answer 32

intracellularly in vesicles by molecular motors on microtubules

Question 33

Steps of AMPA receptor trafficking

Answer 33

1) transport of newly synthesised receptors
2) vesicle exocytosis in dendritic shaft
3) random movement of receptors on cell surface
4) diffusion trapping stabilises receptors
5) diffusing receptors internalised
6) endocytosed receptors can be recycled by exocytosis

Question 34

What can influence the expression and location of AMPARs

Answer 34

1) neuronal activity
2) exposure to acute and chronic stress
3) neurodegenerative disorders
4) by various drugs

Question 35

Describe Long Term Potentiation (LTP)

Answer 35

• an electrophysiological correlate of learning and memory
• involved “activity-dependent” changes in synaptic excitatory transmission mediatede by glutamate receptors
• focus for research on improving synaptic plasticity and pathophysiology of neurodegenerative diseases
• development of congitive-enhancing drugs

Question 36

How is LTP induced

Answer 36

• high frequency theta burst stimulation (HFS) of the Schaffer collateral input from CA3 to the CA1 region
• release lesion block, allowing calcium to enter
• calcium binds to enzyme calmodulin kinase II, causing it to migrate

Question 37

Postsynaptic AMPA receptor trafficking and LTP

Question 38

How to assess learning and memory in rodents

Answer 38

• role of GluA1-AMPARs in spatial memory
• morris water maze
• GluA1 mutant mice are imapired in this task and exhibit impaired hippocampal LTP

Question 39

AMPA receptors as therapeutic targets

Answer 39

• cogntive disorders
• development of novel “paid acting” antidepressants

Question 40

Huntington’s Disease

Answer 40

• incurable neurodegenerative disease
• caused by CAG repeats of the huntingtin gene, leading to a polyQ region in the huntingtin protein
• characterised by motor dysfunction
• mouse model exhibits impaired hippocampal LTP
• AMPAkine CX929 improves impaired LTP and cognitive performance