Neurotransmitters Systems I: Glutamate

Question 1

What is neurotransmission?

Answer 1

Neurotransmission is the fundamental process that drives information transfer between neurons and their targets.

Question 2

Describe the structure of nerve cells and the functions of its organelles

Answer 2

Soma is the cell body

Axon is important in action potential propagation

Dendrites on the nerve cell body

Myelin sheath (insulating layer) speeds up nerve transmission

Nodes of ranvier are gaps between the myelin sheath - allows the action potential to jump
Synapse is the connection between two neurons

Question 3

Where are neurotransmitters found in nerve cells?

Answer 3

Neurotransmitters in synaptic vesicles which fuse with the axon terminal membrane by endocytosis

Question 4

What does the fusion of vesicles with the axon membrane cause?

Answer 4

Causes release of neurotransmitter across the synaptic cleft to bind to receptors on the dendrite on postsynaptic cells

Question 5

What are neurotransmitters?

Answer 5

Neurotransmitters are chemical messengers that transmit signals from a neuron → target cell across a synapse (neurotransmission)

Question 6

What are 3 criteria required for a molecule to be classed as a neurotransmitter?

Answer 6

1. The molecule must be synthesised and stored in the presynaptic neuron
2. The molecule must be released by the presynaptic axon terminal
3. The molecule must produce a response in the postsynaptic cell

Question 7

When are neurotransmitters released from the presynaptic terminal?

Answer 7

The molecule is released by the presynaptic axon terminal upon stimulation by an action potential

Question 8

Why are neurotransmitters stored within the presynaptic neurons?

Answer 8

Neurotransmission is a rapid process so readily available store of neurotransmitter must be available at all times

Question 9

How do neurotransmitters produce a response at the postsynaptic membrane?

Answer 9

Neurotransmitters are released from the presynaptic vesicles and diffuse across the synaptic cleft to bind to postsynaptic membrane receptors

Question 10

How is an action potential is propagated

Answer 10

1. Resting potential -70mV
2. Depolarisation increased positivity of membrane
   potential due to influx of Na+
3. Action potential due to accelerated Na+ depolarisation
   +30mV
4. Repolarisation due to Na+ VGCs close and K+ channels
   open causing efflux occurs => -ve membrane potential
5. Hyperpolarisation dips below -70mV to allow the
   membrane potential to be reset for another action
   potential to occur

Question 11

Explain how an action potential travels along the axon

Answer 11

Action potential is all or nothing mechanism propagated along the entire length of the axon plasma membrane in one direction

Question 12

How does an action potential activate VGCCs?

Answer 12

Action potential arrives at presynaptic bouton opening VGCCs causing Ca2+ influx

Question 13

What is the effect of Ca2+ release in neurotransmission?

Answer 13

Ca2+ causes the vesicles to fuse with the presynaptic membrane causing neurotransmitter release via exocytosis

Question 14

What are the major central neurotransmitters?

Answer 14

Acetylcholine
Glutamate 
GABA
Glycine 
Monoamines

Question 15

Describe the effects of Ach

Answer 15

Ach acts on ligand gated ion channels (nicotinic AchR) and metabotropic channels (muscarinic AchR)

Question 16

What is glutamate?

Answer 16

This is the major excitatory neurotransmitter in the central nervous system (CNS)

Question 17

Why did it take so long to determine glutamate as a neurotransmitter?

Answer 17

It took a long time to realise glutamate was a neurotransmitter as it is at a crossroad of multiple metabolic pathways

Question 18

Are glutamate responses inhibitory or excitatory?

Answer 18

Nearly all excitatory neurons in the CNS are glutamatergic and it has been estimated that over half of all brain synapses release glutamate

Question 19

Where is glutamate synthesised?

Answer 19

Synthesised in the nerve terminals

Question 20

Outline glutamate synthesis

Answer 20

Glutamate synthesis occurs via the conversion of glutamine → glutamate via the phosphate-activated glutaminase enzyme

NH₂ group converted to OH group via glutaminase

Question 21

How is glutamate transported to vesicles?

Answer 21

Transported into vesicles by vesicular glutamate transporters (VGLUT)
Counter transport with H+ to drive glutamate entry into vesicles

Question 22

Describe the varying concentration of glutamate in the cytosol and vesicles

Answer 22

Estimated ~10⁴ increase in [glutamate] in the synaptic vesicles compared to the cytosol - mediated by VGLUT

Question 23

What type of receptors elicit glutamate responses?

Answer 23

Ionotropic receptors
AMPA, NMDA and Kainate

> AMPA and NMDA make up the majority of excitatory neurotransmission in the brain

Question 24

What are the ionotropic glutamate receptors named after?

Answer 24

They are named after the agonists that activate them

Question 25

Summarise the ionotropic effects of glutamate receptors

Answer 25

Influx Efflux
AMPA Na+ K+
NMDA Na+ Ca2+ K+
Kainate Na+ K+

Question 26

Describe the composition of AMPA receptors

Answer 26

Four subunits (plus alternative splice variants)
GluA1, GluA2, GluA3, GluA4

Question 27

Describe the structure of the AMPA receptor?

Answer 27

Hetero-tetrameric - ‘dimer of dimers’
2GluA2 subunits
Plus 2 GluA1, 3 or 4 subunits

Question 28

What causes the AMPA receptors to open?

Answer 28

Four orthosteric binding sites

Two sites must be occupied for channel opening

Question 29

What is the effect of increased binding to AMPA receptors?

Answer 29

Current increases as more binding sites are occupied

As more binding sites are occupied current and influx of Na+ will increase

Question 30

How does the GluA2 subunit prevent excitotoxicity?

Answer 30

Presence of GluA2 subunits prevents Ca2+ flow into the cell

Protective against excitotoxicity

Question 31

How many subunits is the NMDA receptor composed of?

Answer 31

3 subunits (plus alternative splice variants)
GluN1 (or NR1), GluN2 (or NR2), GluN3 (or NR3)

Question 32

Describe the structure formed by the 3 NMDA receptor sunbinit

Answer 32

Hetero-tetrameric - ‘dimer of dimers’
2 GluN1 subunits
Plus 2 GluN2 (or GluN3)
→ GluN3 subunits are inhibitory to NMDA receptor function (reason unknown)

Question 33

What mechanisms are in place to mediate NMDA receptor activation?

Answer 33

NMDA receptors are ligand and voltage gated

Question 34

What ligands are required to bind to NMDA for channel opening?

Answer 34

Glutamate (GluN2) and Glycine or D-serine (GluN1)

All sites must be occupied for channel opening

Question 35

Why is NMDA voltage gated?

Answer 35

Mg2+ block present at resting membrane potential

Question 36

What is synaptic plasiticity?

Answer 36

The ability of synapses to modify their strength

Question 37

Outline how glutamate release activates its receptors

Answer 37

1. Release of glutamate
2. Glutamate binds to AMPA + NMDA receptors
3. Influx of Na+ into the postsynaptic cell
4. Removes Mg2+ block allowing Na+ and Ca2+ to enter
   the cell
5. Leads to receptor trafficking→ increased AMPA
   increases Na+ influx
6. Activates CamKII enzyme increasing ionic conductance
   of the receptors
7. => increased Na+/Ca2+ entry

Question 38

What is receptor trafficking?

Answer 38

New AMPA receptors are made and inserted at the postsynaptic membrane

Question 39

What is the significance of receptor trafficking?

Answer 39

Receptor trafficking underlies a process called Long Term Potentiation (LTP)
Causes synaptic strengthening (inc. AMPA & ionic conductance)
Important in learning + memory

Question 40

What are LTPs?

Answer 40

Underlying Long term potentiation (LTP) are increased excitatory postsynaptic potentials (EPPs)
These events can trigger action potentials

Question 41

What are the 5 subunits of kainate receptors?

Answer 41

Five subunits (plus alternate splice variants)
GluR5  (GluK1)
GluR6  (GluK2)
GluR7  (GluK3)
KA1     (GluK4)
KA2     (GluK5)

Question 42

Describe the structure formed by kainate subunits

Answer 42

Tetrameric

GluK1-3 can form homomers or heteromers
GluK4 & 5 are only form heteromers with GluK1-3 subunits

Question 43

How is kainate binding mediated?

Answer 43

Ligand gated ion channel

Glutamate binding required for channel opening not well understood

Question 44

How many kainate receptors are in the brain?

Answer 44

Limited distribution in the brain - function less well understood

Question 45

Describe the structure of metabotropic receptors

Answer 45

GPCRs with extracellular venus fly trap domain for ligand binding
Have 7 transmembrane domains
Intracellular C terminal domain
All coupled to G proteins linked to several signalling pathways

Question 46

How many metabotropic glutamate receptors are there?

Answer 46

8 subtypes of metabotropic receptors mGlu1-8

Question 47

What are the 3 groups metabotropic glutamate receptors are categorised into?

Answer 47

Group 1

• (mGlu1 & 5)
• coupled to Gq
• predominantly postsynaptic

Group 2

• (mGlu2 & 3)
• Gi and Go - inhibit AC decreasing cAMP
• presynaptic

Group 3

• (mGlu4,6,7 & 8)
• Gi and Go - inhibit AC decreasing cAMP
• presynaptic

Question 48

What are the glutamate reuptake receptors?

Answer 48

Excitatory amino acid transporters (EAAT)

Once glutamate is bound to its receptor; some transporters reuptake glutamate - EAAT

Question 49

What is excitotoxicity?

Answer 49

This is the pathological process by which excessive excitatory stimulation can lead to neuronal damage and death

Question 50

What is one of the most common cause of excitotoxicity?

Answer 50

Non functional vesicular glutamate receptors (VGLUT) causes spontaneous activation

Question 51

Explain how nonfunctional VGLUTs cause excitotoxicity

Answer 51

Glutamate can’t enter synaptic vesicles so accumulates in the cytosol
=> inc. [glutamate] in cytosol = EAAT reverse their functions

Normally glutamate moves from a [high] → [low] from the synaptic cleft back into the cell
If there’s high [glutamate] in the cell it will move back into the cleft
=> glutamate binds to its receptors when re entering cleft
=> binds to NMDA and AMPA receptors removing Mg2+
block
=> Ca2+ influx via NMDA receptors

Question 52

What are the effects of increased Ca2+?

Answer 52

Excessive Ca2+:
Mitochondrial damage
Oxidative stress
Apoptosis

Question 53

What other disorders has excitotoxicity been associated with?

Answer 53

Excitotoxicity has been linked to:
Stroke
Autism
Alzheimer’s Disease

Question 54

Explain the role of excitotoxicity in Alzheimer’s disease

Answer 54

In alzheimrs we have glutamate mediated excitotoxicity - excessive glutamate can lead to cell death which causes shrinkage in the Alzheimer’s disease brain

Question 55

What drug can be given to alleviate some of the excitotoxic effects in alzheimers?

Answer 55

Memantine is a NMDA receptor antagonist - blocking NMDA receptor preventing excessive glutamate release

Question 56

What makes a neurotransmitter a neurotransmitter?

Answer 56

Synthesised and stored in the pre-synaptic terminal
Released upon stimulation
Mediates a synaptic response