Neurotransmitter systems and neurochemistry (Prof. Sihra)

Question 1

What are the criteria for a molecule to be a neurotransmitter (NT) ?

Answer 1

• synthesis/presence in the nerve terminal
• storage in nerve terminal in secretory vesicles
• release (regulated by Ca2+)
• postsynaptic effect which is mimicked by exogenous ligands
• inactivation by specific mechanisms: reuptake + catabolism

Question 2

What are the classical NT types ?

Answer 2

• AAs: Glu, GABA, GLy
• derivative of AAs: dopamine (DA), noradrenaline (NA/NE), 5-hydroxytryptonamine (5-HT), histamine
• hetero-oligomers of AAs i.e. peptides: opioids peptides,, endomorphins, nociceptin, neurotrophin
• the “prototypic” NT = ACh

Question 3

What are the non-canonical NT types ?

Answer 3

• nucleotides and nucleosides (ATP, adenosine)
• lipid derivatives: endocannabinoids
• gases (NO, CO)

Question 4

What is the major excitatory NT in the CNS ?

How is this NT synthesized and taken up after release ?

Answer 4

Glutamate
Gln is converted to Glu by glutaminase. Part of it is taken up in the terminal by the EAAT1 (Excitatory AA Transporter 1) / Glu transporter, or taken up by astrocytes (glial cella) via GLAST (Glu Asp transporter) that converts it to Gln and delivers it to the terminal via SN1 (Gln transporter).

Question 5

What is EAAT1 ?

Answer 5

EAAT1 is a protein that mediates the transport of glutamic and aspartic acid back in the nerve terminal with the cotransport of three Na+ and one H+ cations and counter transport of one K+ cation. This co-transport coupling (or symport) allows the transport of glutamate into cells against a concentration gradient.

Question 6

What are GLAST and GLT-1 ?

Answer 6

GLT-1 and GLAST astroglial transporters are the glutamate transporters mainly involved in maintaining physiological extracellular glutamate concentrations. They use co-transport coupling like EAAT1.

Question 7

What is the major inhibitory NT in the CNS ?

Answer 7

Gamma-aminobutyric acid (GABA)

Question 8

How are Glu and GABA produced ?

Answer 8

Alpha-ketoglutarate leaves the Krebs cycle, can be converted to Glu by GABA-T (GABA transaminase), which can then be converted to GABA by GAD (Glutamate decarboxylase).

Question 9

Hiw is Glu stored in small synaptic vesicles (SSVs) ?

Answer 9

A proton pump created a electrical gradient py pumping protons H+ into the SSVs (hydrolysis of ATP). The negative charge of Glu drives it inside the positive vesicle.

Question 10

What is vGLUT1/2 ?

Answer 10

Vesicular glutamate transporter 1 (VGLUT1) is a vesicle-bound protein. It is a sodium-dependent phosphate transporter that is preferentially associated with the membranes of synaptic vesicles and functions in Glu uptake into vesicles.

Question 11

What is vGAT ?

Answer 11

The vesicular GABA transporter VGAT is responsible for uptake and storage of GABA and glycine by synaptic vesicles in the CNS. It is different from the plasma membrane transporters in that it is driven by a proton electrochemical gradient across the vesicle membrane.

Question 12

What is GLYT1-2 ?

Answer 12

Sodium- and chloride-dependent glycine transporter. It brings Gly back from the cleft into the nerve terminal.

Question 13

Can our body made ACh alone ?

Answer 13

No, choline is required in the diet.

Question 14

How is ACh made ?

Answer 14

An acetyl group associates w/ CoA to form Acetyl CoA. This associates w/ choline (form the diet) and is converted to ACh via choline acetyltransferase.

Question 15

How is ACh inactivated/broken down ?

Why is this break inactivation easy ?

Answer 15

By very active acetylcholinesterases (also plasma pseudocholinesterases).
As an ester, ACh is relatively labile and susceptible to esterase mediated hydrolysis.

Question 16

What part of ACh is recycled ?

Answer 16

Choline is recycled by reuptake.

Question 17

What is VAChT ?

Answer 17

The Vesicular acetylcholine transporter (VAChT) is a NT transporter which is responsible for loading ACh) into secretory organelles in neurons making ACh available for secretion.
It is co-packaged w/ ATP.

Question 18

What is the effect of He. (Hemicholinium) ?

Answer 18

He. is a drug which blocks the reuptake of choline by the high-affinity choline transporter (ChT) at the pre synapse –> rate limiting step in synthesis of ACh –> He. = indirect ACh antagonist

Question 19

What is the effect of Ve. (Vesamicol) ?

Answer 19

Vesamicol is an experimental drug, acting presynaptically by inhibiting acetylcholine (ACh) uptake into synaptic vesicles, thus reducing its release.

Question 20

What is the fct of ChT ?

Answer 20

The high-affinity choline transporter (ChT) (also known as solute carrier family 5 member 7) is a cell membrane transporter and carries choline into acetylcholine-synthesizing neurons (by using Na+ gradient).

Question 21

What is the characteristic of the synaptic vesicle ATP dependent proton pump ?

Answer 21

It is conserved in virtually all organisms.

Question 22

From which AAs are catecholamines derived ?

Answer 22

Tyrosine

Question 23

What are the steps leading from tyrosine to adrenaline (ADR) ?

Answer 23

Tyrosine –> L-DOPA (dihydroxyphenylalanine) by tyrosine hydroxylase (TH).
L-DOPA –> dopamine (DA) by L-aromatic AA decarboxylase (AADC)
DA –> noradrenaline (NA) by dopamine-beta-hydroxylase DBH)
NA –> ADR by phenylalanine-N-methyltransferase (PNMT)

Question 24

How are catecholamines stored into large dense core vesicles (LDCVs) ?

Answer 24

By the vesicular monoamine transporter 2 (VMAT2) (also known as solute carrier family 18 member 2 (SLC18A2)). This is an integral membrane protein that transports monoamines.

Question 25

Is it the electrical gradient or the pH gradient that allows VMAT2 to fct ?
Why ?

Answer 25

It is the pH gradient, because when protons are pumped into the LDCVs, Cl- ions often follow, rendering the H+ charge neutral. Instead, VMAT exchanges monoamines against protons.

Question 26

Are monoamines packaged in the LDCVs on their own ?

Answer 26

No, they are co-packaged w/ proteins.

Question 27

What drugs can act on VMAT2 ?

Answer 27

Methamphetamine, dextroamphetamine, methylphenidate, and lobeline block VMAT2, inducing monoamine release in the cytosol –> non exocytotic NT release

Question 28

How is DA recycled by the pre-synaptic neuron ?

Answer 28

The dopamine transporter (also dopamine active transporter, DAT, SLC6A3) is a membrane-spanning protein that pumps DA out of the synapse back into the cytosol.

Question 29

How is NA recycled by the pre-synaptic neuron ?

Answer 29

Via NET (Norepinephrine Transporter) = monoamine transporter, responsible for the sodium-chloride (Na+/Cl−)-dependent reuptake of extracellular NA/NE
NET can also reuptake extracellular DA

Question 30

Which drugs can act on DAT and NET ?

Answer 30

Dextroamphetamine, methylphenidate, reboxetine (NRI), venlafaxine (SNRI).

Question 31

Form which AA are indoleamines derived from ?

Answer 31

Tryptophan

Question 32

What are the steps between Trp and melatonin ?

Answer 32

Tryptophan –> 5-hydroxytryptophan by tryptophan hydroxylase (TPH) - blcoked irremissibly by parachlorophenyalanine
5-hydroxytrytophan –> 5-hydroxytryptamine (5-HT/serotonin) by L-aromatic AAD
In the PINEAL GLAND ONLY:
5-HT –> melatonin by 5-hydroxyindole-O-methyltransferase

Question 33

What is the only imidazole amine NT ?

From which AA is it derived ?

Answer 33

Imidazole amine NT = histamine, derived from hystidine via histidine decarboxylase

Question 34

What is pro-opimelanocortin (POMC) ?

Answer 34

• POMC = a precursor polypeptide w/ 241 AAs
• synthesized in the pituitary from the 285-amino-acid-long polypeptide precursor pre-POMC, by the removal of a 44-amino-acid-long signal peptide sequence during translation

Question 35

What is the function of POMC ?

Answer 35

POMC –> cleaved to give rise to multiple peptide hormones, packaged in LDCVs in response to appropriate stimulation:

• α-MSH produced by neurons in the arcuate nucleus has important roles in the regulation of appetite and sexual behavior, while α-MSH secreted from the intermediate lobe of the pituitary regulates the production of melanin
• ACTH = a peptide hormone that regulates the secretion of glucocorticoids from the adrenal cortex
• β-Endorphin and [Met]enkephalin are endogenous opioid peptides with widespread actions in the brain

Question 36

What do we mean when we talk about cotransmission ?

Answer 36

To the fact that, in various local sites around the body, small molecules are “cotransmitted” w/ a neuropeptide.

Question 37

Give a few examples of cotransmission.

Answer 37

• norepinephrine cotransmitted w/ neuropeptide Y (NPY) in the locus ceruleus neurons + the sympathetic preganglionic neurons
• DA w/ neurotensin or cholecystokinin in substantia nigra neurons
• 5-HT w/ TRH, substance P or enkephalin in raphe nuclei neurons
• GABA w/ enkephalin in striatal neurons projecting to globus palllidus

Question 38

What is the particularity of small gas molecules and endocannabinoids when they act as NTs ?

Answer 38

They exert retrograde transmission.

Question 39

How many types of synaptic vesicles are there ?

How do they differ ?

Answer 39

• type 1: SSVs, 50nm diameter, GABA, Gly + Glu, recruitment + localisation to Active Zones, fast phasic release + recycling
• type 2: LDCVs, 250nm diameter for monoamines + SDVs (smaller diameter for 5-HT), delocalized organisation, slow tonic release, ER/Golgi replenishment
• type 3: LDCVs (250nm diameter), neuropeptides, otherwise same as type 2

Question 40

What are the 5 steps of neurotransmission ?

Answer 40

1. AP propagation down the axon (v-gated ion channels)
2. Ca2+ entry into synaptic knob
3. Release of NT by exocytosis
4. Binding of NT to postsynaptic receptors
5. Opening of specific ion channels in sub synaptic membrane

Question 41

What are P/Q type calcium channels ?

Answer 41

High-voltage-gated calcium channels contributing to vesicle fusion and NT release at synaptic terminals, present in Purkinje (P = Purkinje) neurons in the cerebellum and in cerebellar granule cells.

Question 42

What are N type calcium channels ?

Answer 42

High-voltage-gated calcium channels contributing to vesicle fusion and NT release at synaptic terminals, present throughout th brain and spinal chord (N =neural).

Question 43

What is the role of synaptotagmin ?

Answer 43

Synaptotagmin 1 (or synaptotagmin) = a Ca2+ sensor in the membrane of the pre-synaptic axon terminal.

Question 44

What is the role of dynamin ?

Answer 44

Dynamin = a GTPase responsible for endocytosis in the eukaryotic cell –> it is involved in the scission of newly formed vesicles from the membrane of one cellular compartment and their targeting to, and fusion with, another compartment, both at the cell surface (presynaptic membrane) as well as at the Golgi apparatus.

Question 45

How does dynamic work (theoretically) ?

Answer 45

Dynamin forms a helix around the neck of a nascent vesicle. Cooperative GTP hydrolysis results in the lengthwise extension of this helix, breaking the vesicle neck.

Question 46

What are the mane proteins that mediate vesicle fusion ?

Answer 46

The SNARE proteins.

Question 47

How was N-ethylmaleimide Sensitive Factor (NSF) discovered ?

Answer 47

NSF was discovered by James Rothman and colleagues in 1987 while at Stanford University; they identified NSF after observing that a cytoplasmic factor, required for membrane fusions, was inactivated by treatment with N-ethylmaleimide. This assay enabled them to purify NSF.

Question 48

What is SNAP 25 ?

Answer 48

Synaptosomal-associated protein 25 or Solube NSF Attachment Protein (SNAP-25) = a t-SNARE protein, a component of the trans-SNARE complex
SNAP25 is proposed to account for the specificity of membrane fusion

Question 49

What are SNAREs ?

Answer 49

SNARE proteins (“SNAP (Soluble NSF Attachment Protein) REceptor”) are a large protein superfamily consisting of at least 24 members in yeasts and more than 60 members in mammalian cells. Their primary role is to mediate vesicle fusion.

Question 50

What are syntaxins ?

Answer 50

Syntaxins are a family of membrane integrated Q-SNARE proteins participating in exocytosis.

Question 51

What are synaptobrevins ?

Answer 51

Synaptobrevins (synaptobrevin isotypes 1-2) are small integral membrane v-SNARE proteins with molecular weight of 18 kDa that are part of the vesicle-associated membrane protein (VAMP) family.

Question 52

How does G-alpha mediated signaling in 7TM receptors work ?

Answer 52

It involves the generation of “soluble” 2nd mesengers.

Question 53

What effects do G-alpha s/i and G-alpha q have ?

Answer 53

G-alpha s/i can stimulate or inhibit adenylate cyclase, thus leading to greater or lower levels of cAMP
G-alpha q stimulates PLC which leads to the production of IP3 and diacylglycerol
BOTH 2nd messengers lead to phosphorylation dependent (or independent) modulation of targets and ultimately to facilitation of synaptic transmission

Question 54

How does G-beta gamma signaling work for 7TM receptors ?

What effect does this have on synaptic transmission ?

Answer 54

It involves membrane delimited interaction w/ plasma membrane resident proteins i.e. ion channels and t-SNAREs.
This ultimately leads to inhibition of synaptic transmission.