Neurotransmitters, Chemical Messengers, And Excitotoxicity

Question 1

Neurotransmitters are classified into what two categories?5

Answer 1

Small molecules: rapidly acting

Neuropeptides: slowly acting (need to bind to receptor); growth factors, receptor modulation, synaptic maturation

Question 2

What are the two categories of neurotransmitter receptors?

Answer 2

Ionotropic: increase conductance to certain ions by binding to ligand-activated channels; binding induces rapid conformational change -> increases the diameter of the pore -> allow ion influx; faster

Metabotropic: act to alter membrane properties via a second messenger; G-protein coupled receptors; slower

Question 3

How are neurotransmitter receptors classified?

Answer 3

GPCR: G-protein coupled receptor

RTK: receptor tyrosine kinase; activates tyrosine kinase activity in the cell; growth factor receptors

LGIC: ligand-gated ion channels; ionotropic

NTFR: nuclear transcription factor receptors; steroid receptors

Question 4

How are neurotransmitters inactivated or terminated?

Answer 4

Re-uptake into the presynaptic neuron by specific transporters

Accumulation in glial cells

Enzymatic degradation (ACh)

Diffusion away from synapse

Question 5

What is the fx of a synaptic transmitter after it is released?

What are the steps a neurotransmitter takes to have an effect?

Answer 5

Stimulate, inhibit, or modulate the postsynaptic neuron

AP opens Ca channels in the presynaptic neuron -> stimulates vesicle fusion to active zones -> vesicles release content into the synaptic cleft -> neurotransmitters induce receptor activation on the postsynaptic membrane -> depolarize the postsynaptic neuron

Question 6

What neurotransmitters are classified as biogenic amines/monoamines?

Answer 6

Catecholamines: epinephrine, norepinephrine, dopamine

Histamine

Serotonin

Question 7

Catecholamines are derived from _____.

What is the rate limiting step?

What is the sequence to get from tyrosine to epinephrine?

What converts norepinephrine to epinephrine?

Answer 7

Tyrosine

Tyrosine -> L-DOPA by tyrosine hydroxylase

Tyrosine -> L-DOPA -> dopamine -> norepinephrine -> epinephrine

Phenylethanolamine N-methyltransferase (PNMT)

Question 8

Dopamine is stored in vesicles in neurons; _____ are important in allowing the release of monoamines from vesicles into the synaptic cleft.

Answer 8

Vesicular monoamine transporters (VMAT)

Question 9

How are monoamines terminated?

Answer 9

COMT: mechanism for inactivation of epi released by the adrenal medulla and CNS

MAO: has two isoforms and is a target for neuropsychiatric disorders

Question 10

Where is norepinephrine located?

What is its fx?

What releases epinephrine?

Answer 10

Locus coeruleus

Waking up and awareness

Adrenal medulla

Question 11

Dopamine has neurons located in the ____ and the ____ of the midbrain; these project to the prefrontal cortex and parts of the limbic system.

Answer 11

Substantia nigra (project to the striatum); ventral tegmental area

Question 12

What four major systems use dopamine?

Answer 12

Substantia nigra: motor; damaged in Parkinson’s

Mesolimbic: VTA to nucleus accumbens; central to pleasure, reward, and addiction

Mesocortical: VTA to frontal cortex; attention, high level of consciousness

Tuberinfundibular: hypothalamus to anterior pituitary; suppresses the release of prolactin

*VTA = ventral tegmental area

Question 13

Histamine is found in the ____ of the posterior hypothalamus and projects throughout the brain.

Fx?

What are the two receptors?

What degrades histamine?

Answer 13

Tubomammillary nucleus (TMN)

Wakefulness

H1 and H2

Diamine oxidase

Question 14

Serotonin is located in the ____ and projects to many areas of the CNS.

Fx?

Derived from ____.

What is the rate limiting step?

5HTP -> serotonin uses what enzyme?

What metabolizes serotonin?

Answer 14

Raphe nuclei

Controls attention and mood, involved in depression

Tryptophan

Tryptophan -> 5HTP using tryptophan hydroxylase

5-HT decarboxylase

MAO

Question 15

What are serotonin receptors and what is their fx?

Answer 15

5-HT2a: smooth m contraction

5-HT3: vomiting (ionotropic)

5-HT6: high affinity for several antidepressant

5-HT2c: role in controlling normal body weight and preventing seizures

Question 16

Where are cholinergic neurotransmitters located?

Answer 16

Pons, midbrain, motor cortex, autonomic, NMJ

Question 17

Ach has neurons located in the ____, which includes ____. The neurons project to _____.

Other Ach neurons originate in ____ and project to the dorsal thalamus and forebrain.

Fx?

Answer 17

Basal forebrain complex; septal nuclei and nucleus basalis; hippocampus and neocortex

Pontomesencephalotegmental cholinergic complex

Learning and memory

Question 18

What are the fx of Ach?

Where is it stored?

What moves it from cytosol into vesicles?

What inhibits Ach?

Answer 18

Producing consciousness but not awareness; voluntary motion; initiates REM sleep; excitatory

Stored in clear vesicles

Vesicular Ach transport protein (VAchT)

Acetylcholinesterase bound to post synaptic cell membranes

Question 19

What are two Ach receptors?

Answer 19

Nicotine receptors: ionotropic; allow for Na entrance and some allow Ca influx

Muscarinic receptors: metabotropic; 2nd messenger signaling systems

Question 20

What are the five types of Ach muscarinic receptors?

What are the Ach nicotinic receptors?

Answer 20

M1: neuronal; induce signaling of IP3/DAG and increases Ca
M3: smooth muscle; G-coupled
M5: G-coupled
M2: cardiac; inhibitory; decrease cAMP, stop Ca influx, increase K effluent and hyperpolarize the cell
M4: inhibitory

Located at NMJ, autonomic ganglia; has 5 subunits (alpha, beta, gamma, delta, epsilon)

Question 21

What are the excitatory AA neurotransmitters?

Inhibitory?

Answer 21

Glutamate, aspartame

GABA, glycine

Question 22

What is the location of GABA?

Fx?

Synthesis?

Termination/transmission?

Answer 22

Cortex, cerebellum

Inhibitory; released by interneurons; producing consciousness/awareness and controls voluntary motion

Synthesized from glutamate by glutamate decarboxylase and feeds into the Krebs cycle

Catabolized by GABA-transaminase to SSA

Question 23

What are the three GABA receptors?

Answer 23

GABAa: conducts Cl (ionotropic) -> depresses excitability -> inhibitory; benzodiazepine receptor; binding sites for barbiturates; ethanol augments GABA mediated Cl influx (sedative)

GABAb: metabotropic; mediates inhibitory NT release; increases K/decreases Ca to hyperpolarize the cell

GABAc

Question 24

What is the location of glycine?

Fx?

What is the effect of strychnine on glycine?

Answer 24

Spinal cord

Inhibitory NT

Loss of inhibitory regulation leads to death by respiratory failure following convulsions

Question 25

Opioids are ____ that influence neuronal activity.

Examples and what are they derived from?

Answer 25

Neuropeptides

Endorphins: POMC

Enkephalins: pro-enkephalins

Dynorphins: pro-dynorphin

Question 26

How do opioid receptors fx?

What are the four receptors that bind to opioids and how do they work?

Answer 26

Inhibitory (Gi) and inhibit adenylyl cyclase and indirectly alters ion flow

Mu: analgesia; respiration depression, constipation, euphoria, sedation, increases GH and prolactin and miosis; increases K efflux (hyperpolarization)

Kappa: analgesia; diuresis, sedation, miosis, dysphoria; decreases Ca influx (hyperpolarization)

Delta: analgesia; decreases Ca influx

Nociceptin: hyperalgesia; produces anxiety, depression, and tolerance to Mu opioid agonists

Question 27

What are the ligands of endocannabinoids?

Why are they atypical?

Answer 27

Anandamide, 2-arachidonylglycerol (2-AG) = lipid molecules

Not stored in vesicles, not released from pre-synaptic terminals, are released from post-synaptic locus and have retrograde actions

Question 28

How does the CB1 receptor for endocannabinoids fx?

What does SC CB1 affect?

What does neocortical CB1?

What does hippocampus and basal ganglia CB1 affect?

Answer 28

Uses Gi signaling to reduces adenylyl cyclase activity

Localized on axons and pre-synaptic terminals to decreases NT release

**Interacts with EAA and GABA, inhibiting them in the pre-synaptic terminal

SC SB1 receptors are associated with modulation of nociception

Neocortical CB1 receptors are associated with protecting against excitotoxicity

Hippocampus and basal ganglia CB1 receptors are associated with changes in affect and motor effects

Question 29

How do CB2 receptors for endocannabinoids fx in the brain, immune system, and viscera?

Answer 29

Brain: found on microglia; target of interest in Alzheimer’s

Immune system: lymphocytes, thymus, spleen, tonsils; modifies cytokine release; ant-inflammatory

Viscera: wide-spread in gut and other viscera; CB2 agonists used to treat inflammatory bowl disease and prevent inflammatory cystitis in bladder pain syndromes

Question 30

Glutamate is derived from ___.

Aspartate is derived from ____ and located in ____.

They are classified as ____.

Answer 30

Alpha-ketoglutarate

Oxaloacetate; visual cortex and pyramidal cells

Excitatory amino acids (EAA)

Question 31

What are the two types of glutamate receptors?

Answer 31

Metabotropic: modulates synaptic signaling of receptors and transmitter release; located on pre and post synaptic locations

Ionotropic: NMDA and non-NMDA receptors (kainate and AMPA)

Question 32

Glutamate AMPA receptors are ___ and NMDA is ____.

NMDA receptor is blocked by ____ on the postsynaptic terminal. How is this blockage removed?

Answer 32

Fast conducting/depolarization, voltage independent, little impact on Ca

Slow conducting, determines the duration of depolarization, voltage dependent, strong influence on Ca

Mg; AMPA receptor receives the NT, allows the influx of Na, and depolarizes the cell -> once the cell is depolarizes to >60mV, the Mg is displaced, opening the NMDA receptor -> NMDA receptor bound to glycine allows the influx of Ca, further depolarizing the cell, and generating an AP

Question 33

Describe the excitatory glutamate synapse.

Answer 33

Glutamine inside cell -> glutamate by glutaminase -> glutamate is packaged into vesicles inside the cell -> released into the synaptic cleft -> binds to receptors (AMPA, NMDA, kainate, metabotropic GPCR) on the postsynaptic membrane -> ions flow into the cell and depolarizes the cell -> glutamate reuptake back into the cell -> catabolized by glutamine synthase back into glutamine

Question 34

What happens if there is excess glutamate being produced during the excitatory glutamate synapse?

Answer 34

Too much glutamate prevents it from being inactivated and reuptake back into the cell -> floods the synaptic cleft -> activates extra synaptic glutamate receptors -> excitotoxicity and cell death

Question 35

What activates the glutamate receptor NMDA?

Fx?

What are its other binding sites?

Answer 35

N-methyl-D-aspartate, glutamate, aspartate

Allows Ca influx to depolarizes the cell; slow onset

Glutamate: EPSP
Glycine: co-agonist; has to be present for EAA to work but can’t open the channel
Mg: blocks the channel; depolarization kicks out Mg to open channel
PCP: blocks the channel

Question 36

Non-NMDA allow for ____.

What are its two types?

Activation of these leads to ____.

What are AMPA binding sites?

Answer 36

Na influx

AMPA, kainate

Excitatory post-synaptic potential (EPSP)

Glutamate, benzodiazepine (inhibit NT)

Question 37

What are the fx of the EAA receptors in the CNS?

Answer 37

Non-NMDA: primary afferents, premotor (UMN)

NMDA: long-term changes in synaptic strength, learning, memory

Metabotropic: learning, memory, motor system

Question 38

What are uptake systems for getting rid of EAA?

Answer 38

Adjacent neurons and glia: Na dependent secondary to active transport; have a high affinity

Glia: converts glutamate -> glutamine and release it into the ECF; neurons take the glutamine and covert it back to glutamate

Question 39

Nitric oxide acts as a ____ in the CNS.

What are the characteristics of NO?

Answer 39

Gasotransmitter

Independent of intracellular Ca release, release upon nerve stimulation, diffuses through membrane, acts on pre and post synaptic membranes, can be a retrograde messenger, not found in synaptic vesicles, not release from nerve terminals, not stored

Question 40

When Mg is removed from NMDA, there is an influx of Ca. The Ca binds with ____ and activates ____.

NOS catalyze the reaction that converts arginine to _____.

Answer 40

Calcineurin; NOS (nitric oxide synthase)

NO

Question 41

What are the fx of NO?

What is the negative effect of NO?

Answer 41

Relaxes smooth m, involved in memory, enhances NT release in the CNS, cardio and respiratory control

Leads to the production of free radicals

Question 42

____ is the mechanism to explain why there is continual neuron death after an ischemic event.

It is based on the idea that overstimulation of the ____ can cause cell death even in neurons not directly involved in the ischemic event.

Examples?

What area is most affected?

Answer 42

Excitotoxicity

EAA system

Cerebral ischemia/stoke, hypoxia, anoxia, mechanical trauma to CNS, hypoglycemia, epilepsy

Anoxic core (area of the ischemic event) -> leads to O2 deprivation, cells unable to meet metabolic needs, depolarization of membrane

Question 43

What happens within mixtures of the event initiating excitotoxic pathways?

Answer 43

Neurons get depolarized and flood the synaptic cleft with glutamate -> post synaptic cell is activated but can only handle so much -> ATP levels fall to 0 inside the neurons -> Na/K ATPase ceases to fx -> cell depolarizes -> AP and release of more NT including EAA -> less Na in synaptic cleft therefore no AMPA so no reuptake of EAA -> less Ca in synaptic cleft so no NMDA activation -> soooo much glutamate

Question 44

Excess glutamate can stimulate receptors outside of the post-synaptic membrane. These stimulate the axon and allow for ___ flooding into the cytosol of the cell.

What does this cause?

Answer 44

Ca

Activation of phospholipase A2

Activation of calcineurin (phosphatase)

Activation of Mu-calpain (protease)

Activation of apoptotic pathway

Question 45

Excess Ca causing the activation of phospholipase A2 cause the release of ____ from the membrane and damages the cell membrane.

Arachidonate binds to the _____ on the ER. Causes the release of more ____ from intracellular stores.

Increase Ca activates a kinase that phosphorylates _____ causing ____. Also impairs ____.

Answer 45

Arachidonate

Ryanodine receptor

Ca

eIF2alpha: fx in transcription/translation of protein; when phosphorylated it stops making protein

Impairs mitochondria fx

Question 46

Excess Ca causes activation of Mu-calpain (protease). What is its fx?

Answer 46

Cleaves spectrin and eIF4G which are involved in protein synthesis and maintaining structure of cell membrane -> cleavage causes lack of protein formation and cell damage

Question 47

Excess Ca causes the activation of calcineurin. What is the fx?

Answer 47

Activates phosphatase -> activates NOS -> increases NO synthesis -> cause vasodilation and contributes to edema

Question 48

As mitochondrial membranes are disrupted from the high Ca influx, ____ are activated.

Examples?

Excitotoxicity will also suppress ____ that will normally inhibit cytochrome C and caspase 9.

Answer 48

Apoptotic pathways

Cytochrome C, caspase 9 -> caspase 3 -> proteolytic enzyme -> apoptosis

Bcl2 enzymes

Question 49

In an ischemic event, with a pt in a hypoxia state, what happens if the pt is flooded with O2 too fast?

Answer 49

This will cause a reperfusion injury: neurons can no longer process the O2 -> O2 will end up as a free radical

Normally mitochondria will take the O2 and generate ATP