4. GABA & GLYCINE

Question 1

What is GABA?

Answer 1

• GABA is the major inhibitory neurotransmitter found in the CNS

Question 2

How is GABA synthesised?

Answer 2

• GABA is synthesized from Glutamate in the nerve terminals
• Glutamate can be metabolised from glucose
• Glutamate –> GABA by Glutamate decarboxylase

Question 3

What enzyme is involved in GABA synthesis & what co-factor is needed?

Answer 3

• Glutamate -> GABA by GLUTAMATE DECARBOXYLLASE

- Pyridoxal phosphate is the co-factor for Glutamate decarboxylase. The co-factor is derived from Vitamin B6

Question 4

What is the transporter involved in transporting GABA into vesicles?

Answer 4

• GABA is transported into vesicles by VIAAT (Vesicular inhibitory amino acid transporter)

Question 5

What’s the difference between GABA & Glutamate storage in vesicles?

Answer 5

• GLUTAMATE = VGLUT & round vesicles

- GABA = VIAAT & oval vesicles

Question 6

What transporters are involved in re-uptake of GABA & what are the two types?

Answer 6

• GAT (GABA re-uptake transporters) take up GABA from the synaptic cleft into the pre-synaptic neurone.
• GAT are located on neurones & glial cells
  1. GAT1 = neurones
  2. GAT3 = glial cells

Question 7

What two enzymes are involved in the degradation of GABA?

Answer 7

• GABA is degraded by being converted to Succinic acid in two steps (two enzymes):
  1. GABA-T (GABA Transaminase)
  2. SSADH (Succinic Semi-aldehyde dehydrogenase)
• GABA –> SUCCINIC SEMIALDEHYDE by GABA T
• SUCCINIC SEMIALDEHYDE –> SUCCINIC ACID by SSADH

Question 8

What are the two GABA receptors?

Answer 8

1. GABA-A (IONOTROPIC/LIGR)

2. GABA-B 9METABOTROPIC/G-PROTEIN COUPLED)

Question 9

What are the properties of GABA A receptors?

Answer 9

• GABA A receptors are ligand gated Cl- ion channels
• Binding of GABA to the GABA A receptor results in a chloride efflux, leading to hyperpolarisation
• The hyperpolarisation of the membrane decreases the likelihood of action potential firing, as it increases the threshold for action potential firing
• Therefore it has an inhibitory effect

Question 10

What are the sub-units for GABA A receptor & the most common configuration?

Answer 10

• The GABA A receptor has five sub-units
• Most common: 2 alpha, 2 beta & one gamma
• There are several sub-types: 6 alpha sub-types, 3 beta & 3 gamma sub-types
• GABA binds at the interface between alpha & beta

Question 11

Where does GABA & other drugs bind on the GABA A receptor?

Answer 11

• The GABA A receptor has multiple binding sites making it a key drug target
• GABA = binds between alpha & gamma
• BENZODIAZEPINES = binds between alpha & gamma
• PICROTOXIN - non-competitive antagonist that blocks the GABA A ion channel

Question 12

What are the properties of the GABA B receptor?

Answer 12

• The GABA B receptor is a G-protein coupled receptor
• It is coupled to Gi/o so it’s negatively linked to adenylate cyclase resulting in decreased cAMP & therefore decreased Ca2+.
• The GABA B receptor has an inhibitory effect

Question 13

What are the two effects of the GABA B receptor & the consequence?

Answer 13

1. Increase K+ efflux - G-protein signalling cascade activates potassium channels
2. Decrease Ca2+ influx
   - Both of these effects result in hyperpolarisation. reducing the likelihood of action potential firing
   - Therefore, GABA B receptor has an inhibitory effect once activated

Question 14

Define hyperpolarisation?

Answer 14

• Hyperpolarisation refers to the displacement of teh membrane potential towards a more negative value.
• This means that more stimulation is needed to reach the threshold for depolarisation

Question 15

What is the cerebellum?

Answer 15

• The cerebellum is a prominent hindbrain structure that is involved in detecting differences between the intended movement and the actual movement.
• Help the motor cortex produce precise & controlled movement

Question 16

What are the Purkinje cells of the cerebellum?

Answer 16

• The Purkinje cells are the GABAergic projection of the cerebellum into the deep cerebellar cortex, which generates an error signal allowing movements to be modified

Question 17

What’s the importance of the GABA & Glutamate balance?

Answer 17

• Glutamate is the major excitatory neurotransmitter
• GABA is the major inhibitory neurotransmitter
• Disruptions in the excitatory-inhibitory balance can lead to disorders or anxiety, migraines etc.

Question 18

What are two disorders that occur as a result of disrupted inhibitory & excitatory balance?

Answer 18

1. ANXIETY
2. EPILEPSY
   - A shift towards glutamatergic/excitatory neurotransmission can result in anxiety or epilepsy

Question 19

What is epilepsy?

Answer 19

• Epilepsy is a brain disorder characterized by periodic & unpredictable seizures. It involves rhythmic firing of large groups of neurones
• There’s too much glutamatergic neurotransmission, so it can be treated by increasing inhibitory neurotransmission or decreasing excitatory neurotransmission

Question 20

Give GABA-mediated treatments for epilepsy?

Answer 20

1. GABA A enhancers - increase inhibitory neurotransmission
2. GAT blockers - prevent re-uptake of GABA
3. GAD MODULATORS - Increase activity of glutamate carboxylase which produces GABA from Glutamate
4. GABA -T INHIBITORS - Prevent degradation of GABA
5. PRODRUG - Administer a precursor of GABA which can be metabolised into GABA

Question 21

Give examples of GABA A receptor enhancers

Answer 21

GABA A enhancers - increase inhibitory neurotransmission, by increasing receptor activity to increase hyperpolarisation
E.g benzodiazepines & barbituates

Question 22

Give an example of GAT blockers?

Answer 22

• prevent re-uptake of GABA, to increase circulating GABA

- E.g Tiagabine

Question 23

Give an example of GAD Modulators

Answer 23

• E.g Gabapentin,Valproate

- Increase activity of glutamate carboxylase which produces GABA from Glutamate

Question 24

Give an example of a prodrug for GABA

Answer 24

• E.g Progabide

- Can be metabolised into GABA

Question 25

Give an example of GABA-T inhibitors

Answer 25

• E.g Vigabatrine

- Prevent degradation of GABA

Question 26

Describe the basis by which anxiolytic treat anxiety

Answer 26

• Anxiety is caused by too much glutamatergic transmission, so it can be treated by increasing inhibitory neurotransmission
• GABA A receptor enhancers such benzodiazepines & barbituates are used

Question 27

What is glycine?

Answer 27

• Glycine is the second major inhibitory neurotransmitter after GABA
• It is found mainly in the ventral horn

Question 28

How is glycine synthesised?

Answer 28

• Glycine is synthesized from serine
• But serine is metabolised from 3 -phosphoglycerate from glycolysis
• Serine –> Glycine by SERINE HYDROXYMETHYTRANSFERASE

Question 29

What enzyme is responsible for glycine synthesis?

Answer 29

• SERINE HYDROXYMETHYTRANSFERASE

- It is involved in both the synthesis & degradation of glycine

Question 30

Which transporters are involved in transporting glycine into vesicles?

Answer 30

• Glycine is stored in oval vesicles

- It is packaged into vesicles by VIAAT (Vesicular Amino-acid transferase)

Question 31

Which transporters are involved in the re-uptake of Glycine?

Answer 31

• Glycine is taken up from the synaptic cleft into teh pre-synaptic neurone by GlyT (Glycine re-uptake transporters)
• The GlyT are found on neurones & glial cells
• GlyT1 = glial cells
• GlyT2 = neurones
• Mutations in these transporters can lead to hypoglycaemia

Question 32

How is glycine degraded?

Answer 32

• Glycine is converted to serine by SERINE HYDROXYMETHYLTRANSFERASE

Question 33

What enzyme is involved in the synthesis & degradation of glycine?

Answer 33

• SERINE HYDROXYMETHYLTRANSFERASE

Question 34

Describe the structure of the glycine receptor & the most common configuration

Answer 34

• The glycine receptor is a LIGR Cl- ion channel
• the glycine receptor is located on the post-synaptic & pre-synaptic membrane
• Glycine receptor has a pentameric structure
• It consists of 5 sub-units
• Most common: 3 alpha, 2 beta or 4 alpha, 1 beta

Question 35

What’s the effect of the glycine receptor?

Answer 35

• Glycine binding to the glycine receptor leads to an influx of chloride resulting in hyperpolarization
• The hyperpolaristaion decreases the likelihood of an action potential firing, resulting in an inhibitory effect

Question 36

What other receptor can glycine bind to?

Answer 36

• Glycine can also bind to the NMDA receptor

- Glycine can bind to the GLuN1 whilst glutamate binds to the GLuN2 subunit of the NMDA receptor

Question 37

What is hyperekplexia & how does it occur?

Answer 37

• HYPEREKPLEXIA is characterised by hypermyotonia which is increased muscle tone leading to an exaggerated startled response
• Mutations can disrupt normal glycinergic neurotransmission. This leads to hyperexcitability due to the impaired glycinergic inhibition

Question 38

What happens in myotonic goats?

Answer 38

• In myotonic goats there’s decreased muscle chloride conductance. Normally a chloride influx causes hyperpolarisation, but glycine receptor mutation can affect whether this occur
• As the goats get older, their GABA A receptors will be upregulated to increase inhibition & to replace the impaired chloride conductance