Craviso: CNS Neurotransmission

Question 1

T/F: Average neuron forms ~ 1000 synaptic connections and receives even more

Answer 1

True

Question 2

What is the activity of a neuron dependent on?

Answer 2

the ratio of excitatory to inhibitory inputs to that neuron

Question 3

What are the small molecules involved in CNS functioning?

Answer 3

serotonin
norepi
dopamine
ACh
histamine

Question 4

neurotransmitter; sleep, arousal, mood, appetite

Answer 4

serotonin

Question 5

neurotransmitter; mood, arousal, appetite

Answer 5

norepi

Question 6

neurotransmitter; movement (motor control), behavior, mood, perception

Answer 6

dopamine

Question 7

neurotransmitter; arousal, cognition (memory and learning)

Answer 7

ACh

Question 8

neurotransmitter; wakefulness, equilibrium

Answer 8

histamine

Question 9

Excitatory amino acid neurotransmitter

Answer 9

glutamate (glutamic acid)

Question 10

Inhibitory amino acid neurotransmitters

Answer 10

GABA

glycine

Question 11

Neuropeptides involved in pain transmission

Answer 11

methionine
leucine enkephalin
substance P

Question 12

Endocannabinoids involved in memory, cognition, and pain perception

Answer 12

anandamide
2-arachidonylglycerol

**post-synaptic neurons make endocannabinoids and they are retrograde NTs

Question 13

Pattern of neuronal connectivity: Transmission is highly sequential and interconnected neurons are related to each other in a hierarchical fashion - e.g., primary sensory and motor pathways
Pain transmission!

Answer 13

long-hierarchical (relay)

Question 14

Pattern of neuronal connectivity:
Neurons from a single anatomical location extend multiple, divergent connections to target cells outside the region in which the neurons originate

Answer 14

non-hierarchical, projecting

ex: serotonin, norepi, dopamine, ACh, 5HT

Question 15

Where do serotonin neurons project from?

Answer 15

raphe nucleus

Question 16

Functions of 5HT (serotonin)

Answer 16

sleep, arousal, mood
behavioral changes
hallucinations
feeding behavior
vomiting

Question 17

Where do norepinephrine neurons project from?

Answer 17

locus coeruleus

Question 18

Functions of norepinephrine

Answer 18

arousal and mood (frontal cortex)
appetite (hypothalamus)
cardiovascular control

Question 19

Where do dopamine neurons project from?

Answer 19

midbrain
striatum
hypothalamus

Question 20

Functions of dopamine

Answer 20

mood
behavioral changes
motor control (nigrostriatal pathway)
neuroendocrine function
vomiting

Question 21

Where do ACh neurons project from?

Answer 21

forebrain and brainstem

Question 22

Functions of ACh

Answer 22

arousal
learning and memory (think of Alzheimer’s disease)
motor control (nigrostriatal pathway)

Question 23

The effects of cholinergic neurons can be via (blank) (GPCR) receptors or (blank) (ionotropic) receptors located presynaptically

Answer 23

muscarinic; nicotinic

Question 24

Where do histamine neurons project from?

Answer 24

hypothalamus

Question 25

Functions of histamine

Answer 25

arousal and wakefulness

equilibrium

Question 26

effects on synthesis, storage, release, reuptake and/or degradation of neurotransmitters; agonist or antagonist activity at nerve terminal autoreceptors

Answer 26

pre-synaptic mechanisms by which neurotransmitters are modulated

Question 27

receptor agonist, antagonist or modulatory activity; degradation of neurotransmitters

Answer 27

post-synaptic mechanisms by which neurotransmitters are modulated

**ACh is inactivated by degradation

Question 28

With these receptors, responses occur within several hundreds of milliseconds and last for seconds and even minutes

Answer 28

GPCRs (metabotropic receptors)

Question 29

Some metabotropic receptors (GPCRs)

Answer 29

all alpha and beta adrenergic receptors (norepi receptors)
dopamine
muscarinic ACh
histamine
neuropeptide and endocannabinoid receptors
most 5HT receptors (except those involved in vomiting)
metabotropic glutamate and GABA receptors

Question 30

How to GPCRs work?

Answer 30

1. neurotransmitter binds
2. activates G-protein
3. G-protein intracellular messengers modulate ion channels
4. ion channels open
5. ions flow across membrane

Question 31

Ionotropic receptors are also called (blank)

Answer 31

ligand-gated ion channels

Question 32

Where are most ionotropic receptors found?

Answer 32

at neuromuscular junctions

Question 33

With these receptors, responses occur within a few milliseconds and last for only MILLISECONDS

Answer 33

ionotropic receptors

Question 34

Which receptors DEPOLARIZE cells? What ion is involved?

Answer 34

AMPA *Na ion channel
kainate *Na ion channel
NMDA *Ca++ and Na
nicotinic ACh receptors
5HT3 receptors (vomiting) *Na

**Na+ or Ca++ are involved

Question 35

Which receptors HYPERPOLARIZE cells? What ion is involved?

Answer 35

GABA-A and glycine receptors

**Cl- ion channels

Question 36

How do ionotropic receptors work?

Answer 36

1. neurotransmitter binds directly to channel
2. channel opens
3. ions flow across membrane

Question 37

So, which occur more quickly, metabotropic or ionotropic receptor reactions? Which have longer lasting effects?

Answer 37

ionotropic are faster; metabotropic last longer

Question 38

Amino acid neurotransmitters mediate major excitatory inputs via (blank) and inhibitory inputs via (blank)

Answer 38

glutamate; GABA

Question 39

Excitatory transmission is balanced by feed-forward and recurrent inhibitory actions of (blank) released from interneurons

Answer 39

GABA

Question 40

Inputs to neurons are paired to achieve a coordinated balance between excitatory and inhibitory events, but (blank) neuro-transmission predominates

Answer 40

inhibitory

Question 41

T/F: Interference of the relationship b/w excitatory and inhibitory neuro-transmission is highly disruptive

Answer 41

True

**can cause two extremes - comatose or seizures

Question 42

synthesized from glutamate, by glutamic acid decarboxylase that requires pyridoxal phosphate

Answer 42

GABA

Question 43

What is GABA metabolized by in the mitochondria of neurons and glial cells?

Answer 43

GABA-amino transferase

Question 44

What is unique about endocannabinoid transmission?

Answer 44

retrograde transmission - synthesized in post synaptic neuron

Question 45

What does GABA bind to?

Answer 45

metabotropic receptors in nerve terminal which can modulate GABA release

ionotropic GABA receptors postsynaptically, they will enhance the actions of GABA

Question 46

There is a high conc of these receptors in the spinal cord

Answer 46

GABA-B receptors

Question 47

an agonist at GABAB receptors, is used for treating spasticity (involuntary and abnormal muscle contractions) in individuals with amyotrophic lateral sclerosis (ALS) and multiple sclerosis (MS)

Answer 47

Baclofen (Lioresal)

Question 48

When GABA binds, you are conducting (blank)

Answer 48

Cl-

Question 49

What does GABA do to cells?

Answer 49

hyperpolarizes

Question 50

The majority of GABAs effects are mediated by (blank) receptors

Answer 50

GABA-A

Question 51

Contrast phasic and tonic neurotransmission

Answer 51

tonic - continuous activation of extra-synaptic receptors

phasic - rapid, synchronous opening of channels in synaptic cleft; resolves in time and space

Question 52

What is this?

GABA gets released, and diffuses outside the synaptic cleft - binds to high affinity receptors and causes continuous activation of extra-synaptic receptors

Answer 52

tonic inhibition

Question 53

Glycine are (blank) conducting ion channels

Answer 53

Cl-

Question 54

occurs in nature in certain seeds; an ingredient in rat poison; an antagonist of glycine neurotransmission and a powerful convulsant!

Answer 54

strychnine

**causes seizures when you block inhibitory neurotransmitters

Question 55

What happens to glutamate after its release?

Answer 55

reuptake occurs via transporters present on nerve terminals and astrocytes (mostly astrocytes) - glutamate is converted to glutamine

Question 56

These cells are responsible for much of the uptake and regulation of glutamate

Answer 56

glial cells

Question 57

2 types of non-NMDA glutamate receptors

Answer 57

AMPA receptors

Kainate receptors

Question 58

primarily Na+ - conducting ion channels; some receptors also permeable to Ca2+
mediate the majority of excitatory synapses
play a major role in neural plasticity

Answer 58

AMPA receptors

Question 59

primarily Na+ - conducting ion channels; some receptors also permeable to Ca2+
Located both pre- and post-synaptically
physiologic role not known but play a role in neural plasticity

Answer 59

Kainate receptors

Question 60

Ionophores that conduct primarily Ca2+; also conduct Na+
Are essential mediators of neural plasticity and are capable of converting specific patterns of neuronal activity into long-term changes in synapse structure and function (e.g., play a role in learning and memory)

Answer 60

NMDA glutamate receptors

Question 61

What is an essential co-agonist necessary for NMDA receptors to be activated by glutamate?

Answer 61

glycine!!!

Question 62

What blocks the NMDA channels and must be overcome with a strong depolarizing stimulus to activate the NMDA receptors?

Answer 62

magnesium

Question 63

What two things must happen for NMDA receptors to be activated?

Answer 63

1. simultaneous binding of two agonists (glutamate and glycine)
2. strong enough depolarization to overcome Mg2+ block

Question 64

What is neural plasticity?

Answer 64

the constant pruning and altering of neuronal dendritic connections; mostly due to the actions of glutamate

Question 65

Increases sensitivity of post-synaptic neurons to glutamate

Answer 65

long-term potentiation

Question 66

Decreases sensitivity of post-synaptic neurons to glutamate

Answer 66

long-term depression

Question 67

How do NMDA receptors mediate neural plasticity?

Answer 67

If NMDA receptors are being activated more frequently, the number of AMPA receptors will increase and will cause a stronger, quicker response. Also, with increasing Ca++ due to activation of NMDA receptors, genes will be turned on that can change the synapse structure and make for stronger synaptic connections

If NMDA receptors are not being activated frequently, AMPA receptors will be internalized and there will be weaker synaptic connections

Question 68

Excessive activation of NMDA glutamate receptors causes (blank)

Answer 68

excitotoxicity

Question 69

What is excitotoxicity?

Answer 69

too much activation of NMDA –> too much Ca++ coming in –> activates a lot of cellular processes –> NO and other free radicals build up –> leads to death of neurons