Neuro: Neurotransmitter Systems II: GABA and Glycine

Question 1

Give a brief description of GABA.

Answer 1

• The major inhibitory neurotransmitter in the central nervous system (CNS)
• Approximately one third of synapses utilise GABA as their principle neurotransmitter
• Most commonly found as an inhibitory neurotransmitter in local circuit interneurons

Question 2

Describe GABA synthesis and storage.

Answer 2

• GABA is synthesised in the nerve terminals
• Predominant precursor for GABA synthesis is glucose - metabolised to glutamate.
• The enzyme glutamate decarboxylase (GAD) and the co-factor pyridoxal phosphate (derived from vitamin B6) catalyses the conversion of glutamate to GABA.
• Absence of Vitamin B6 can lead to diminished GABA synthesis. This can result in seizures due to a lack of neuroinhibitory drive.
• Synthesised GABA is transported into synaptic vesicles by vesicular inhibitory amino acid transporters (VIAAT)
• Glutamate stored in rounded vesicles and GABA stored in more oval shaped vesicles.

Question 3

Describe GABA uptake and degradation.

Answer 3

• GABA is released by exocytosis and binds to post synaptic receptors. GABA’s activity needs to eventually be terminated.
• In terms of GABA re-uptake, neurones and glial cells contain high-affinity sodium ion dependant GABA re-uptake transporters (GAT). Neurones predominantly express GAT-1 and glial predominantly express GAT-3. Transport GABA from the synaptic cleft back into the neurone or glial cell for subsequent degradation.
• Two key enzymes are required for degradation. GABA transaminase (GABA-T) catalyses the conversion of GABA into succinic semialdehyde dehydrogenase (SSADH). SSADH catalyses the conversion of succinic semialdehyde succinic acid which is then metabolised.

Question 4

What receptors does GABA bind to?

Answer 4

• GABA binds at both ionotropic and metabotropic GABA receptors
• The ionotropic receptor is termed the GABAA receptor.
• The metabotropic receptor is termed the GABAB receptor.
• There is also an ionotropic GABAC receptor - this is similar to the GABAA receptor in terms of structure, function and mechanism of action. However it is insensitive to a number of drugs that act on the GABAA receptor.

Question 5

Describe the GABAA receptor.

Answer 5

• Ligand-gated ion channel receptor
• When GABA binds, there is influx of negatively charged chloride ions which can lead to hyper-polarisation. This inhibits action potential firing by increasing the stimulus required to fire an action potential.
• Pentameric - comprised of five subunits which form the ion channel in various combinations
• There are 6 alpha subtypes, 3 beta subtypes, 3 gamma subtypes, as well as several other subunits.
• The most common configuration for a GABAA receptor is two alpha, two beta and a gamma subunit. GABA binds between the interface of the alpha and beta subunits of the receptor.
• Predominantly post-synaptic.
• Key drug target due to a number of different binding sites present on the receptor

Question 6

What are the key drug targets on the GABAA receptor?

Answer 6

• Agonists/antagonists e.g. GABA
• Benzodiazepine binding site
• Channel blockers e.g. picrotoxin
• Channel modulators e.g. GA
• Allosteric modulators e.g. barbiturates
• Benzodiazepines bind between the alpha and gamma subunits of the receptor
• Picrotoxin is a poisonous toxin that acts as a central nervous system stimulus. Non-competitive antagonist which functions to block the GABAA receptor ion pore and therefore GABA neurotransmission
• General anaesthetics (GA) can act as GABAA channel modulators and serve to increase GABAA receptor opening
• Barbiturates can also bind to the receptor - once used as drugs for anxiety and insomnia but are no longer recommended for this purpose and are used in epilepsy

Question 7

Describe the GABAB receptor.

Answer 7

• Metabotropic receptor
• Assemble as heteromers. Comprised of a GABAB1 and GABAB2 subunit.
• Neurotransmitter binding activates the G protein Gi/o which dissociates from the GABAB receptor. The G protein activates a secondary messenger pathway, inhibiting an enzyme called adenylyl cyclase which reduces levels of the secondary messenger cAMP. This leads to the activation of potassium channels. Activation of potassium channels leads to efflux of potassium ions out of the cell. Inhibitory effects are also mediated by blocking voltage gated calcium channels which is crucial for the action potential. This causes hyper-polarisation.

Question 8

How can inhibitory neurotransmitters e.g. GABA cause displacement of a membrane potential?

Answer 8

Inhibitory neurotransmitters (e.g. GABA) can cause neuronal membrane hyperpolarisation.

• This hyper-polarisation occurs via a influx of negatively charged chloride ions and via the efflux of positively charged potassium ions.

Question 9

What happens when there is stimulation of a GABAergic interneuron?

Answer 9

• Transient inhibition of action potential firing in its post synaptic target

Question 10

Describe the cerebellum.

Answer 10

• Prominent hindbrain structure and accounts for approximately 10% of the human brains volume.
• The cerebellum does not initiate movement but detects differences in “motor error” between an intended movement and the actual movement
• Aids the motor cortex to produces precise and co-ordinated movement
• Cerebellum is important in synchronisation of movement with musical rhythm

Question 11

Describe the GABA projections in the cerebellum.

Answer 11

• Called Purkinie cells (class of GABAergic neurons that comprise the principle projection neurons of the cerebellar cortex)
• Purkinjie cells have elaborate dendritic trees that receive convergent synaptic input from cells in the molecular layer.
• Purkinjie cells send GABAergic projections to deep cerebellar neurones.
• Purkinje cells output to the deep cerebellar neurons which generates an error connection signal that can modify movements
• This provides the basis for real-time control of both precise and synchronous movement

Question 12

Describe the balance of GABA and glutamate.

Answer 12

• GABA is the major inhibitory neurotransmitter and glutamate is the major excitatory neurotransmitter in the brain - both work together to control the brain’s overall level of excitation.
• Precursor for GABA synthesis is glutamate. Glutamate converted to GABA via the action of glutamate decarboxylase (GAD)
• Balance between GABA and glutamate needs to be tightly regulated for normal brain function.

Question 13

What can happen if this excitatory-inhibitory balance of GABA and glutamate is disrupted?

Answer 13

• Epilepsy - seizures mediated by rhythmic firing of large groups of neurons. Too much glutamatergic excitation.
• Anxiety

Question 14

How can you restore the excitatory-inhibitory balance of GABA and glutamate if it is disrupted (epilepsy)?

Answer 14

• If there is too much glutamatergic excitation, you need increased GABAergic inhibition
• GABAA receptor enhancers such as the barbiturates and benzodiazepines increase GABAergic neurotransmission by acting as positive allosteric
  modulators at the GABAA receptor.
• GABA re-uptake transporters (GAT blockers) blockers block re-uptake of GABA into presynaptic neurone so increase availability of GABA in the synaptic cleft
• GABA-transaminase inhibitors. This inhibition will increase the availability of GABA since this is the enzyme that catalyses the breakdown of GABA
• Glutamate decarboxylase (GAD) modulators such as gabapentin and valproate increase the activity of the enzyme GAD in order to increase the conversion of glutamate to GABA.
• Prodrugs which are inactive precursors such as progabide can be metabolised by the body into GABA
• Also other anti-epileptic drugs which can directly decrease excitation as opposed to ones that target GABA neurotransmission.

Question 15

How can you restore the excitatory-inhibitory balance of GABA and glutamate if it is disrupted (anxiety)?

Answer 15

There are anxiolytics such as the benzodiazepines - these act as positive allosteric modulators at the GABAA receptor in order to increase GABAergic neurotransmission

Question 16

Describe glycine.

Answer 16

• Second major inhibitory neurotransmitter in the central nervous system (CNS)
• Glycine most commonly found as an inhibitory neurotransmitter in the ventral horn (which is comprised of grey matter - neuronal cell bodies), the location for spinal interneuron terminals
• Compared to GABA, the distribution of glycine in the CNS is much more localised
• Limited understanding of glycine receptors due to limited allosteric modulators

Question 17

Describe glycine synthesis and storage.

Answer 17

Glycine is synthesised in the nerve terminals.

• Mitochondrial isoform of the enzyme serine hydroxymethyl-transferase converts serine into glycine.
• Glycine is transported into vesicles by vesicular inhibitory amino acid transporters (VIAAT)

Question 18

Describe glycine reuptake and degradation.

Answer 18

• After exocytosis glycine activity needs to eventually be terminated

Glycine re-uptake:
Neurones and glial cells contain high affinity sodium ion dependant glycine re-uptake transporters (GlyT). Glial cells predominantly express GlyT-1 and neurones predominantly express GlyT-2. Both transport glycine from the synaptic cleft back into the glial cell or neurone for its subsequent degradation.

Degradation:
Various enzymes are responsible for degradation. There are different by products as a result of different enzymatic reactions. This includes the reversal of glycine biosynthesis through the action of serine hydroxymethyl-transferase.

Question 19

What happens if there is mutations in the genes encoding glycine re-uptake transporters?

Answer 19

Mutations in the genes encoding for some of these transporters can result in hypoglycinemia - this is a neonatal disease characterised by symptoms including lethargy and seizures.

Question 20

Describe the glycine receptor.

Answer 20

• Ligand gated ion channel.
• When there is glycine binding, there is influx of negatively charged chloride ions. This can lead to hyper-polarisation which inhibits action potential firing by increasing the stimulus required to fire an action potential.
• Pentameric and is comprised of 5 subunits which conform the ion channel pore in various combinations
• There are four alpha subtypes and one beta subtype. The most common configuration for the glycine receptor is 3alpha1 2beta or 4alpha1 1beta.
• A plant alkaloid called strychnine is a potent blocker of the glycine receptor.
• Unlike the GABAA receptor which is predominantly post-synaptic, the glycine receptor is both presynaptic and postsynaptic.

Question 21

Describe glycine and NMDA interaction.

Answer 21

• Glycine can act as a co-agonist at the glutamate NMDA receptor
• Ligands for the NMDA receptor is glutamate and glycine or D-serine.
• Glutamate binds to the GluN2 subunits of the NMDA receptor whilst glycine/D-serine binds to the GluN1 subunits.
• All binding sites need to be occupied - 2 GluN2 subunits and 2 GluN1 subunits in order for ion channel opening to occur.

Question 22

What is Hyperekplexia?

Answer 22

• Rare disorder characterised by hypertonia (increased muscle tone) and an exaggerated startle response.
• Can occur due to unexpected stimuli e.g. loud noises
• Deficiencies in glycine neurotransmission due to gene mutations with glycine receptors/transporters can lead to neuronal hyperexcitability

Question 23

What happens in fainting goats?

Answer 23

• In juvenile startle goats, there is a decreased muscle chloride conductance - can be caused by glycine receptor mutations (since the glycine receptor allows the influx of chloride ions and can cause hyper-polarisation)
• As the goats mature, GABAA receptors are upregulated to compensate