Lecture 12- Dopamine

Question 1

What is a neurotransmitter?

Answer 1

• A substance that is released by a neuron and that affects a specific target in a specific manner

Question 2

What is the time scale of neurotransmitter and receptor interaction and the resulting change?

Answer 2

• Interaction between neurotransmitter and receptor are transient (m/s to min), however the resultant action can result in long term changes in the target (hrs todays)

Question 3

What neurotransmitter family does dopamine belong to?

Answer 3

• Dopamine belongs to the monoamine family, which includes 3 catecholamines
• together with norepinephrine and epinephrine, histamine and serotonin (either depolarise or hyperpolarise the postsynaptic cell)

Question 4

What is dopamine biosynthesis like?

Answer 4

• starts with an amino acid Tyrosine that is readily available in the body and can cross the blood-brain barrier
• Tyrosine is made into L-dopa via Tyrosine hydroxylase
• L-dopa is made into dopamine within the nerve terminal via DOPA decarboxylase or Aromatic L-amino acid decarboxylase
• dopamine can be further utilised to make noradrenaline or adrenaline

Question 5

How is dopamine stored, released and re-uptaken into the nerve terminal?

Answer 5

• dopamine is packaged into vesicles by vesicular monoamine transporter
• vesicles fuse with the membrane upon calcium release (triggered by AP) -the vesicles release dopamine via exocytosis
• dopamine then interacts with the receptors on the postsynaptic membrane and is then taken back into the presynaptic terminal (via DAT, dopamine transporter) and is recycled can be used in vesicles again, or into an astrocyte where it can be degraded

Question 6

How can dopamine be degraded after release?

Answer 6

-

Question 7

What types of dopamine receptors are there?

Answer 7

• 7 transmembrane G-protein coupled receptors
• 5 main dopamine receptors
• 2 families
• within a nerve terminal all 5 may be present
• excitatory D1-like receptor family: D1, D5
• inhibitory D2-like receptor family: D2, D3, D4

Question 8

What do the D1 and D2 do?

Answer 8

• excitatory is the D1= coupled to excitatory G proteins= activation of adenylyl cyclase
• D2 etc. inactivates adenylyl cyclase via inhibitory G protein

Question 9

What are presynaptic dopamine receptors for?

Answer 9

• another isoform of two receptors= pre synaptic D2 and D3 they create a crtitical feedback loop telling the cell about the levels of dopamin (autoreceptors) influence the firing of APs and they inhibit calcium and potassium channels within the presynapatic terminal
• if too much dopamine can make the decision to retract the axonal arbor so less contact with the other neuron= so important regulatory function

Question 10

What is the dopamine receptor expression like across the brain?

Answer 10

• D1 and D2 in caudate nucleus and putamen a lot
• some also in the midbrain 400 000 dopamine neurons in the adult brain

Question 11

What are the 4 main populations of dopamine receptors separated into?

Answer 11

• 3 systems
  1. the ultrashort (within the retina the amacrine cells), amacrine cells and periglomural cells(olfactory)
  2. intermediate= regulate prolactin secretion and production, hypothalamus-> pituitary gland
  3. Long: ventral midbrain ->striatum, cortex, nigra-striatal pathway and the mesolimbic pathway, reward and motivation

Question 12

What are the two main dopamine midbrain pathways? (the motor plus reward dopamine aspects that we focus on)

Answer 12

1. The nigrostriatal pathway from the substantia nigra pars compacta to the dorsal striatum= motor function, originate in the midbrain, regulation of movement 4 cm long axons
2. The mesolimbic / mesocortical pathway from the ventral tegmental area to the limbic system via the nucleus accumbens (ventral striatum) and prefrontal cortex = reward, part of the limbic system, main role is reward and motivation, length up to 7 cm per axon

Question 13

What is the basal ganglia circuitry like and what is it important for?

Answer 13

• The basal ganglia provides refinement of information that is received by the cortex

– Direct pathway: D1R, initiating motor function (+)

– Indirect pathway: D2R, inhibiting unwanted movement (-)

• Interconnected subcortical nuclei - Striatum (caudate, putamen, nucleus accumbens), - Globus pallidus (GP) - Substantia Nigra (SN) - Subthalamic nuclei (STN) - (Thalamus)

Question 14

What is the direct pathway?

Answer 14

• start in the frontal lobe of the brain, decide to move and sends excitatory signal to the striatum
• at the same time the substantia nigra pars compacta is dopaminergic projection into the striatum, the dopamine on the D1R is to modulate the signal coming from the motor cortex
• striatum increases its inhibition of the globus pallidus GPi
• globus pallidus internal segment and subtantia nigra pars reticulata inhibit thalamus normally but now this is inhibited and so teh thalamus is more active so the excitatory input into the motor cortex

Question 15

What is the indirect pathway?

Answer 15

• motor cortex excites the striatum and in this case the Substantia nigra pars compacta is releasing the dopamine onto D2 so inhibitory
• striatum inhibits GPe and that usually inhibits the STN so now less inhibition and the STN is now more active
• STN excites GPi and SNpr increased stimulation which increases inhibition of the thalamus= reduces the thalamic input from the thalamus

Question 16

What is Parkinson’s disease?

Answer 16

• what happens when issue with the dopamine in the nigrostriatal pathway
• Progressive neurodegereration of DA neurons in the SNpc=nigrostriatal pathway
• 1% of population >65 yrs old
• 10% inherited, 90% idiopathic
• Symptoms only show when: >80% DA loss due to compensation
• second most common neurodegenerative disorder
• trauma can increase the susceptibility
• must have 80% of dopamine neurons lost until you show symptoms, before then all good due to compensatory mechanism (make more connections per neuron to compensate)

Question 17

What are Parkinson’s symptoms?

Answer 17

• Tremor
• Rigidity
• Akinesia
• Bradykinesia
• Postural changes
• Shuffling gait
• resting tremor (3 to 5 Hz) -lot of trouble initiating movement (akinesia)
• rigid due to lack of dopamine
• bradykinesia
• stout posture, fall into walking so helps them initiate movement
• shuffle

Question 18

What happens in Parkinson’s to the nigrostriatal pathway?

Answer 18

-loss in control of movement, and loss of control of unwanted movement too

Question 19

What are the available treatments for Parkinson’s disease?

Answer 19

• Pharmacological treatments
  1. Dopamine precursor (L-DOPA)
  2. DA agonists
  3. Inhibitors of DA degradation (MAO inhibitors)
• L dopa is the main treatment
• the dopamine pathways are activated by this but not only the motor one also the reward so exhibit some addictive behaviour
• also try to inhibit the degradation of the dopamine (via MAO inhibitors)
• or else Deep Brain Stimulation (STN or Gpi/SNpr) where the main focus is implanting stimulators in the basal ganglia circuitry trying to promote the feedback onto the motor cortex

Question 20

What is the relationship of dopamine and reward?

Answer 20

-this is all connected to the second midbrain dopamine pathway, the mesolimbic/mesocortical pathway

• Pleasurable and rewarding stimuli (food, sex etc) increase DA levels in the ventral dopamine system (nucleus accumbens and basal forebrain)

• DA tells the brain when a reward is salient

– noticeable, important i.e. better than expected

• tells you something is better than expected and also if something bad (when no dopamine)
• dopamine= the motivator behind reward

• Results in learning of behaviours that are important for survival *

• Addictive substances ‘hijack’ this reward system by inducing increased DA levels, particularly in the nucleus accumbens

Question 21

How does addiction work?

Answer 21

-cocaine: blocks the dopamine transporter, so the reuptake doesn’t occur and more dopamine in the cleft for longer and increase stimulation of postsynaptic neuron

-amphetamine: promotes, causes the fusion of vesicles and release of dopamine into the synaptic cleft and also inhibits the degradation of dopamine (inhibits MAO)

-withdrawal: largely driven by the D2 receptors,

Question 22

What is schizophrenia?

Answer 22

• Schizophrenia = split mind (not personality)
• The disconnection between experience and reality, or thoughts and feelings
• Onset typically 15-35yrs old
• 1-2% population experience a ‘psychotic episode’ in their life

Question 23

What is the relationship between schizophrenia and dopamine?

Answer 23

• Decreased brain volume (cortex, amygdala, hippocampus and thalamus)
• Increased ventricular volume (lateral and 3rd)
• Abnormal orientation of neurons in the hippocampus and entorhinal cortex
• Altered expression of neuropeptides
• The dopamine hypothesis of schizophrenia proposes increased levels of dopamine (or receptors) in the striatum.
• difference in orientation of the hippocampal neurons

Question 24

What is the salience hypothesis (schizophrenia)?

Answer 24

• Under normal conditions, a motivationally salient (or significant) stimulus is signaled by release of DA in the basal forebrain
• In psychosis, this process is disrupted so that increased DA coincides with events that have no intrinsic significance -> Leads to the formation of delusional beliefs to account for the subjective experiences of significance
• Similarly,hallucinations are internally generated representations (thoughts & mental images) that have been assigned inappropriate significance

Question 25

What are the symptoms of schizophrenia?

Answer 25

1.“Positive” symptoms are linked to “ DA in mesolimbic pathway

• presence of abnormal experiences/behaviours
• disordered thoughts & speech, hallucinations (often auditory), delusions (paranoid)
• (chronic addiction can shows similar positive symptoms)
• similarities to psychostimulants (age of onset)
• and PD (L-Dopa)= since the dopamine is not targeted with L Dopa

2.“Negative” symptoms are linked to DA dysfunction of the mesocortical pathway

- Absence of normal experiences/behaviours

• emotional blunting, apathy, social withdrawal

Question 26

What are some antipsychotic treatments?

Answer 26

• Treat the positive symptoms
• Block DA receptors (clozapine,haloperidol)
• Block DA and hence dampen the inappropriate experience of salience
• Side effects: reduced feelings of salience/motivation for stimuli & experiences in general
• ‘neuroleptic induced dysphoria’: emptiness, apathy, inability to feel pleasure (* reason patients stop medication)
• Problems with movement (‘PD-like’state)

Question 27

Learning outcomes?

Answer 27

• Understand DA synthesis,degradation,receptor stimulation
• Know the midbrain DA pathways (nigrostriatal and mesocorticolimbic) & basal ganglia circuitry/regulation
• Understand the role of DA in motor function and reward/ motivational behaviour
• Understand the cause, symptoms andtreatments of PD, addiction and schizophrenia