Neurotransmitters lll: Monoamines (neuro)

Question 1

The diffuse modulatory systems of the brain (monoamines)

Answer 1

four systems with common principles:
- small set of neurons at core
- arise from brain stem
- one neuron influences many others
- synapses release transmitter molecules into extracellular fluid
four main systems:
- noradrenergic locus coeruleus
- serotonergic raphe nuclei
- dopaminergic substantia nigra and ventral tegmental area
- cholinergic basal forebrain and brain stem complexes

• can be point to point communication (fast, restricted) or diffuse modulatory systems (slower, widespread)
• behavioural effects: mood, memory, reward, movement, motivation

Question 2

Examples of metabotropic receptors

Answer 2

Stimulates AC - Dopamine D1, noradrenaline beta,
Stimulates PLC - 5-HT2, noradrenaline alpha1,
Inhibits AC - 5-HT1, Dopamine D2, noradrenaline alpha2,
(AC=adenylyl cyclase, PLC=phosplipase C)

Question 3

Effects of Noradrenaline

Answer 3

• arousal
• wakefullness
• exploration and mood (low NA in depressed)
• blood pressure regulation (antihypertensive eg clonidine alpha2)
• addiction/gambling

Question 4

Synthesis of catecholamines

Answer 4

• tyrosine -> DOPA, using tyrosine hydroxylase
• DOPA -> dopamine, using DOPA decarboxylase
• dopamine -> noradrenaline, using dopamine beta-hydroxylase
• noradrenaline -> adrenaline, using phenylethanolamine N-methyltransferase

Question 5

Regulation of NA

Answer 5

• post-synaptic - carry on the message
• pre-synaptic (autoreceptors) - usually inhibitory, negative feedback mechanism
• reserpine - depletes NA stores by inhibiting vesicular uptake
• amphetamine (indirect symphathomimetic) - enters vesicles displacing NA into cytoplasm, increased NA leakage out of neuron
• cocaine - blocks NA reuptake

Question 6

Function of noradrenaline

Answer 6

• NA alpha 1 -> phospholipase C -> PIP, IP3, DAG, Ca2+ -> smooth muscle contraction, glycogenolysis
• NA alpha 2 -> adenyl cyclase -> Ca2+ -> inhibition of NA release
• NA alpha 2 -> adenyl cyclase -> ATP, cAMP -> smooth muscle contraction
• NA beta -> ATP, cAMP -> contraction of cardiac muscle, smooth muscle relaxation, glycogenolysis

Question 7

Noradrenaline (NA)

Answer 7

• main action inhibitory (beta), also excitatory (alpha/beta)
• termination: neuronal uptake and MAO
• main cell body in locus coeruleus (NAergic neurons active when awake, amphetamine increases alertness and exploratory behaviour)
• high density in brainstem, hypothalamus and medial temporal lobe

Question 8

Dopamine (DA)

Answer 8

• involved in: movement, reward, inhibition of prolactin release, memory consolidation
• parkinsons disease, schizophrenia, addiction, emesis, ADHD
• inhibits central neurons (K+ channels)
• D1 (D1, D5) and D2 (D2, D3, D4) receptors
• D1 and D2 receptors in striatum, limbic system, thalamus and hypothalamus
• D3 receptors in limbic system, not striatum
• D4 receptors in cortex and limbic system
• termination: MAO, neuronal uptake
• main pathways: substantia nigra to basal ganglia (parkinsons disease), midbrain to limbic cortex (schizophrenia)
• functions/disorders: movement, addiction, stereotypy, hormone release and vomiting

Question 9

Seratonin (5-HT)

Answer 9

• 5-HT receptors (14 subtypes) all G-protein coupled except 5-HT3:
  • 5-HT1 inhibitory, limbic system – mood, migraine
  • 5-HT2 (5-HT2A), excitatory, hallucinogenic, limbic system & cortex
  • 5-HT3 excitatory, medulla – vomiting
  • 5-HT4 presynaptic facilitation (ACh) – cognitive enhancement
  • 5-HT6 and 5-HT7 – novel targets, cognition, sleep
  – Termination – MAO, neuronal uptake
  – Function / disorders
  • Mood (anxiety/depression)
  • Psychosis (5HT antagonism antipsychotic)
  • Sleep / wake (5-HT linked to sleep, 5-HT2 antagonists inhibit REM sleep)
  • Feeding behaviour (5HT2A antagonist increase apetite, weight gain; antidepressants decrease apetite
  • Pain, migraine (5-HT inhibits pain pathway, synergistic with opioids)
  • Vomiting

Question 10

Seratonin (5-HT) receptor subtypes

Answer 10

subtype -> signal transduction -> localisation -> function

• 5-HT(1A) -> inhibition of AC -> hippocampus -> autoreceptor
• 5-HT(1B) -> inhibition of AC -> substantia nigra -> auto receptor
• 5-HT(1D) -> inhibition of AC -> cranial blood vessels -> vasoconstriction
• 5-HT(1E) -> inhibition of AC -> cortex
• 5-HT(1F) -> inhibition of AC -> brain, periphery
• 5-HT(2A) -> activation of PLC -> platelet, smooth muscle, cerebral cortex -> platelet aggregation, contraction, neuronal excitation
• 5-HT(2B) -> activation of PLC -> stomach fundus -> contraction
• 5-HT(2C) -> activation of PLC -> choroid plexus
• 5-HT(3) -> ion channel -> PNS -> neuronal excitation
• 5-HT(4) -> activation of AC -> GI tract, hippocampus, neuronal excitation
• 5-HT(5A) -> inhibition of AC -> hippocampus -> unknown
• 5-HT(5B) -> unknown
• 5-HT(6) -> activation of AC -> striatum -> unknown
• 5-HT(7) -> activation of AC -> hypothalamus, intestine -> unknown

Question 11

Autoreceptors

Answer 11

• inhibit cell firing and transmitter release at the terminal regions
• transmitter -> cell body -> terminal
• 5-HT -> 5-HT(1A) -> 5-HT(1D) (5-HT(1B))
• dopamine -> D2 or D3 -> D2 or D3
• noradrenaline -> alpha2 -> alpha2
• receptors can only be found post-synaptically

Question 12

Transporters

Answer 12

• transmitter - reuptake site
• dopamine - DAT (on dopamine neurons)
• 5-HT - SERT (on 5-HT neurons)
• NA - NET (on NA neurons)
• glutamate - EAAT1 (mostly on astrocytes)
• dopamine - vMAT2 (into vesicles)

Question 13

Monoamine transporters

Answer 13

• 12 TMDs
• both ends intracellular
• pump monamines in neuron
• DA, NA, 5HT transporters

Question 14

Acetylcholine (ACh)

Answer 14

– Abundant in basal forebrain, hippocampus
and striatum
– Termination – acetylcholinesterase (AChE)
– ACh excitatory neurotransmitter
• Nicotinic (ionotropic / fast)
• Muscarinic (G-protein coupled / slow)
– M1 excitatory (decreased M1 receptors in dementia)
– M2 presynaptic inhibition (inhibit Ach release)
– M3 excitatory glandular/smooth muscle effects (side effects)
– M4 and M5 function not well known
– Functions:
• Arousal
• Epilepsy (mutations of nAChR genes)
• Learning and memory (KO mice)
• Motor control (M receptors inhibit DA), pain, addiction
• Involved in schizophrenia, ADHD, depression, anxiety,
Alzheimers

Question 15

Other transmitter/ modulator substances

Answer 15

• Histamine
– H1 (arousal) and H3 (presynaptic / constitutively active)
– Functions: sleep / wake, vomiting
• Purines
– Adenosine (A1, A2A/2B) and ATP (P2X)
– Functions: sleep, pain, neuroprotection, addiction, seizures, ischaemia, anticonvulsant
• Neuropeptides
– Opioid peptides (mu, delta, kappa)
– Tachykinins (Substance P, neurokinin A & neurokinin B)
• NK1 (Substance P), NK2 (neurokinin A), NK3 (neurokinin B)
– Functions: pain
• Lipid mediators
-Products of conversion of eicosanoids to
endocanabinoids
-act on CB1 (inhibit GABA, glutamate release)
- involved in vomiting (CB1 agonist block it, MS, pain,
anxiety, weight loss/rimonabant CB1 antogonist)
• Melatonin
-MT1, MT2 receptors
- involved in sleep regulation, circadian rhythmicity,
agonists for jet lag and insomnia

Question 16

Opioid peptides and receptors

Answer 16

opioid peptide families -> opioid receptors

• proopioimelanocortin (beta-endorphin) -> MOP (mu) and DOP (delta)
• proenkephalin (enkephalins) -> DOP (delta)
• prodynorphin (dynorphins) -> KOP (kappa)
• pronociceptin (nociceptin/OFQ) -> NOP (ORL1)

Question 17

Drugs interacting with the diffuse system (psychostimulants: amphetamine)

Answer 17

• Amphetamine-like drugs (methylphenidate & MDMA)
• Release cytosolic monoamines (DA)
• Prolonged use neurotoxic
  • Degeneration of amine-containing nerve terminals, cell death
• Pharmacological effects:Pharmacological effects:
  • increased alertness and (increased aggression)
  • Euphoria / excitement
  • Stereotyped behaviour
  • Anorexia
  • decreased physical and mental fatigue (improves monotonous tasks)
  • Peripheral sympathomimetic actions (increased blood pressure & decreased gastric motility)
  • Confidence improves/lack of tiredness
• Therapeutic uses
  • ADHD (methylphenidate), appetite suppressants, narcolepsy

Question 18

Cocaine

Answer 18

• Blocks catecholamine reuptake (decreased DA, stimulant effect)
• Pharmacological effects:
  • Euphoria
  • Locomotor stimulation (Fewer stereotyped behaviours than amphetamine)
  • Heightened pleasure (Lower tendency for delusions, hallucinations and paranoia)
• Pharmacokinetics:
  • HCl salt, inhaled and i.v. administration (Nasal inhalation less intense, leads to necrosis of nasal mucosa)
  • Freebase form (‘crack’), smoked, as intense as i.v route

Question 19

Effects of drugs of abuse on other diffuse modulatory systems

Answer 19

MDMA (ecstasy):
- Inhibits monoamine transporters (mainly 5-HT)
• Large increased 5-HT (followed by depletion)
• increased 5-HT linked to psychotomimetic effects
• increased DA linked to euphoria (followed by rebound dysphoria)
LSD, Psylocybin:
• Hallucinogenic effect by acting on 5HT2 receptors
Psychostimulants:
• Also increase 5HT and NA
• Cocaine block DAT, NET, SER