Session 2 The Role Of Neurones And Glia

Question 1

difference between the functions (general) of neurones and glia?

How many neurones are there and how many glia (estimate!)?

Answer 1

Neurones = sense changes and communicate with other neurones

Glia = support, nourish and insulate the neurones and also remove waste

Neurones 10[11]
Glia 10[12]

Question 2

What are the three types of glial cells (neuroglia)?

What are their main functions?

Answer 2

1. Astrocytes = most abundant and are supporters
2. Oligodendrocytes = insulators
3. Microglia (the smallest!) = immune response

Question 3

What are the 5 main roles of astrocytes?

Answer 3

1. Structural support
2. Help in providing nutrition for neurones
3. Remove neurotransmitters (take them up)
   - allow concentrations of the neurotransmitters to be controlled
4. Maintain an ionic environment (by buffering k+)
5. Help to form the blood brain barrier

Question 4

How do astrocytes help to provide energy for neurones?

What is this process called?

Answer 4

Neurones dont store or produce glycogen so astrocytes will produce lactate which can be transferred to the neurones which can be used for energy when neurones are very active

Glucose lactate shuttle
* astrocytic lactate (that was synthesised by glycolysis of glucose) is release to the extra cellular space and taken up by neurones through monocarboxylase transporters

Question 5

Why and how do astrocytes help to remove neurotransmitters?

Answer 5

astrocytes have transporters for transmitters (e.g. glutamate) which help to keep the extracellular concentration of these neurotransmitters low

Too much glutamate is toxic = excitotoxity

Question 6

What is the importance of astrocytes ability to help buffer k+ in the brain ECF?

Answer 6

High levels of neuronal activity have the potential to lead to a rise in K+ concentration in the brain ECF BUT astrocytes take up the k+ to prevent this

Astrocytes have a very negative resting membrane potential :)

Question 7

What is responsible for myelination of axons in;
A) CNS
B) PNS

Answer 7

A) oligodendrocytes (myelin wrapping)

B) schwann cells (layers of myelin sheath)

Question 8

What is the role of microglia?

Answer 8

They are immunocompetent cells
They recognise foreign material such as plaques and debris and are activated
They can perform phagocytosis to remove this foreign material

They are the brain’s main defence system!

Resting > Activated > phagocytic
(Thin and spindly) > large blob

Question 9

What does the blood brain barrier do?

What do brain capillaries have (as in what are they made up of)?

Answer 9

Limits diffusion of substances from the blood to the brain ECF

Maintains the correct environment for neurones

Brain capillaries have:

• tight junctions that are found between the endothelial cells
• a basement membrane that surrounds the capillary
• end feet of astrocyte processes

Question 10

What substances are transported across the BBB?

Answer 10

Glucose
Amino Acids
Potassium

• allow the concentration to be controlled

Question 11

The CNS is ‘immune privileged’ (immune specialised) what does this entail?

Answer 11

The brain doesn’t rapidly reject allografts (donor)

The skull is very rigid and so cant undergo a lot of volume expansion which would accompany inflammation = harmful

So

Microglia act as antigen presenting cells allowing T cells to enter the CNS

But the CNS inhibits the initiation of the pro-inflammatory T cell response

Question 12

What are the four main structures of a neuron?

Answer 12

Cell soma (the round bit)

Dendrites

Axon (with myelin sheath and nodes of ranvier)

Terminals (lots which synapse on dendrites of other neurons)

Question 13

What happens in the presynaptic terminal when depolarisation occurs?

Answer 13

Opening of voltage gated calcium ion channels

Calcium ions will enter the terminal

Vesicles fuse and release neurotransmitter

The neurotransmitter then will diffuse across the synaptic clef and bind to receptors on the post synaptic membrane (normally on dendrite)

Question 14

What does the postsynaptic response normally depend on?

Answer 14

The nature of the transmitter

The nature of the receptor

• ligand-gated ion channel
• G-protein coupled receptors

Question 15

What are the three chemical classes of neurotransmitters in the CNS?

Answer 15

1. Amino Acids
2. Biogenic amines
3. Peptides

Question 16

Name three neurotransmitters that are in the amino acid class

Answer 16

GABA

Glutamate

Glycine

Question 17

Name 5 neurotransmitter’s that are in the biogenic Amines class.

Answer 17

ACh 
Noradrenaline
Dopamine
Serotonin (5-HT) 
Histamine

Question 18

Name 6 neurotransmitters that are in the peptides class

Answer 18

Dynorphin
Enkephalins 
Substance P 
somatostatin 
Cholecystokinin
Neuropeptide Y

Question 19

What is the main excitatory (amino acids) neurotransmitter in the CNS?

Answer 19

Glutamate

Over 70% of all CNS synapses are glutamatergic

Question 20

What are the main inhibitory (amino acid) neurotransmitters?

Answer 20

GABA

Glycine

Question 21

What are the two main types of glutamate receptors? Plus subtypes!

Answer 21

Can be ionotropic or metabotropic

Ionotropic include:

• AMPA receptors
• Kainate receptors
• NMDA receptors

Metabotropic = mGluR1-7

Question 22

What type of receptors are ionotropic glutamate receptors?

What are they permeable to?

What does their activation cause?

Answer 22

Ion channels!

AMPA and Kainate receptors are permeable to;
Na+ and K+

NMDA are permeable to Na+, K+ AND Ca2+ !!!

activation causes depolarisation (increased excitability!)

Question 23

What type of receptors are metabotropic glutamate receptors?

What are they linked to?

Answer 23

G protein coupled receptors

Linked to either..

Changes in IP3 and Ca2+ mobilisation

OR

Inhibition of adenylate cyclase and decreased cAMP levels

Question 24

How do excitatory neurotransmitters cause depolarisation of the postsynaptic cell?

Answer 24

By acting on ligand gated ion channels

• excitatory postsynaptic potential (EPSP)

Depolarisation causes more action potentials

Basically bring up potential towards threshold

Question 25

What is special about NMDA receptors?

Answer 25

As well as being permeable to sodium and potassium ions, they are also permeable to calcium ions

NMDA receptors need glutamate to bind AND the cell to be depolarised to allow ion flow through the channel

BOTH THINGS!!

Glycine can also act as a co-agonist

magnesium ions normally block the pores that glutamate need to bind to so they need a depolarisation to push out this magnesium ion which enables the channel to open

Question 26

What causes long term potentiation and was is important for the induction of long term potentiation?

(Once answered)
What happens if there is TOO much calcium ion entry through NMDA receptors?

Answer 26

Strong, high frequency stimulation causes long term potentiation

Calcium ions try though NMDA receptors is important for induction

Activation of NMDA receptors can up-regulate AMPA receptors

If there’s too much calcium ion entry through NMDA receptors it will cause excitotoxicity (too much glutamate)

Question 27

What is the main inhibitory transmitter in the brain?

Answer 27

GABA

Question 28

What mostly acts as a neurotransmitter in the brainstem and spinal cord?

Answer 28

Glycine

Question 29

GABAa and glycine receptors have integral Cl- channels. What happens when these open?

Answer 29

Hyperpolarisation!

Leads to inhibitory post-synaptic potential (IPSP)

Which will DECREASE action potential firing (hence inhibitory)

Question 30

What do barbiturates and benzodiazepines do in terms of receptors and transmitters?

What are these drugs used for?

Answer 30

They bind to GABAa receptors and both enhance the response to GABA

Barbiturates - have anxiolytic and sedative actions and are sometimes used as anti-epileptic drugs

Benzodiazepines - have sedative and anxiolytic effects
- these are used to treat anxiety, insomnia and epilepsy

Question 31

What do inhibitory interneurones in the spinal cord release?

Answer 31

Glycine!

Glycine is in high concentration in the spinal cord and brainstem

Question 32

Couple of key points about ACh?

Answer 32

• lots of it at the NMJ
• it’s a central neurotransmitter
• acts at nicotinic AND muscarinic receptors in the brain
• mainly excitatory

Question 33

Where do neurones containing ACh originate from?

Answer 33

Basal forebrain and brainstem

There are also local cholineric interneurones in the corpus striatum

Question 34

Degeneration of cholinergic neurones found WHERE is associated with Alzheimer’s disease?

What can you give to alleviate symptoms of Alzheimer’s?

Answer 34

Degeneration of cholinergic neurones in the NUCLEUS BASALIS

• give cholinesterase inhibitors to alleviate symptoms

As cholinesterase breaks down ACh normally

Inhibiting this enzyme will increase the amount of ACh around

Question 35

What are the cholinergic pathways in the CNS involved with?

Answer 35

Arousal, learning and memory

Motor control

Question 36

Which dopaminergic pathways in the CNS are involved with:

A) motor control

B) mood, arousal and reward

Answer 36

A) Nigrostriatal pathway

B) Mesocortical pathway + Mesolimbic pathway

Question 37

What are some conditions associated with dopamine dysfunction?

Treatment?

Answer 37

1. Parkinson’s disease
   This is associated with LOSS of dopaminergic neurones - substantia Nigeria input to corpus striatum

• can be treated with levodopa which is converted to dopamine by DOPA decarboxylase (AADC)

2. Schizophrenia
   This may be due to release of TOO MUCH dopamine
   - antipsychotic drugs are antagonists at dopamine D2 receptors

Question 38

How do we stop there being too much dopamine in the periphery but enough goes across the BBB to the brain?

Answer 38

Give L-DOPA which can readily cross BBB where it is converted to dopamine by AADC

Give Carbidopa which cant cross the BBB but will inhibit the AADC in the periphery, stoping L-DOPA being converted to dopamine here (as it inhibits AADC) but allowing it still to cross the BBB

(Ref to lecture if confused)

Question 39

What type of receptors does noradrenaline act through?

Answer 39

GPCR’s

Alpha and beta adrenoceptors

Receptors to noradrenaline in the brain are the same as in the periphery

Question 40

Where do you find the cell bodies of NA containing neurones?

Answer 40

In the brainstem (pons and medulla)

There is diffuse release of NA throughout cortex, hypothalamus, amygdala and cerebellum though!

Question 41

Where does most of the NA in the brain come from?

When are these neurones active/inactive?

Answer 41

A group of neurones in the LOCAL CERULEUS

• these are inactive during sleep
• activity increases during behavioural arousal
• amphetamines increases release of NA and dopamine and increases wakefulness

Question 42

There is a relationship between mood and the state of arousal. What may depression therefore be associated with?

Answer 42

Deficiency of NA

Question 43

Distribution of Serotonin? Where found in brain?

Functions?

Answer 43

Similar distribution to NA

Raphe Nuclei!

Functions: sleep/wakefulness and mood

Question 44

What are SSRI’s and what do they do?

Answer 44

Serotonin selective reputable inhibitors

Treat depression and anxiety