Synaptic Transmission

Question 1

It is the major process by which 💡electrical signals are 💡transferred between cells within the nervous system (or between neurons and muscle cells or sensory receptors).

Answer 1

Synaptic Transmission

Question 2

Within the nervous system, synaptic transmission is usually conceived of as an 💡interaction between two neurons that occurs in a 💡point-to-point manner at specialized junctions called __.

Answer 2

synapses

Question 3

Two main classes of synapses

Answer 3

1. electrical

2. chemical

Question 4

It is effectively a 💡low-resistance pathway between cells that allows current to flow directly from one cell to another and, more generally, allows the 💡exchange of small molecules between cells.

They are present between glial cells as well as between neurons.

LOW-PASS FILTERS

Simple and static

Answer 4

electrical synapses

Question 5

It is the 💡morphological correlate of an electrical synapse.

These junctions are 💡plaque-like structures in which the plasma membranes of the coupled cells become closely apposed and filled with electron-dense material.

Answer 5

gap junction

Question 6

Electrical synapses are __ (essentially no synaptic delay) and __ (i.e., current generated in either cell can f low across the gap junction to influence the other cell).

Answer 6

fast

bidirectional

Question 7

Slow electrical events are __ than are fast signals such as action potentials. “Low-pass filters”

Answer 7

much more readily transmitted

Question 8

One important role for neuronal gap junctions appears to be __.

Answer 8

synchronization of network activity

Question 9

It also appears that the patterns of electrical coupling by gap junctions may be __.

Answer 9

highly specific

Question 10

The properties of electrical synapses can be modulated by several factor:

Answer 10

voltage, intracellular pH, and [Ca++]

Question 11

Chemical synaptic transmission was first demonstrated between the __ and the __ by a simple experiment by Otto Loewi.

Answer 11

vagus nerve

heart

Question 12

What is the difference of the chemical synapses to electrical synapses?

Answer 12

There is no direct communication between the cytoplasm of the two cells.

Question 13

Chemical intermediaries that mediates the interaction between the cells

Answer 13

Neurotransmitters

Question 14

Chemical synapses are generally __, and thus one can refer to the presynaptic and postsynaptic elements.

Answer 14

unidirectional

Question 15

It is often the 💡terminal portion of an axon and is packed with 💡small vesicles whose exact shape and size vary with the neurotransmitter they contain.

It has regions, known as 💡active zones, of electron dense material that corresponds to the proteins involved in transmitter release.

It has 💡mitochondria and 💡rough endoplasmic reticulum.

Answer 15

presynaptic element

Question 16

It is also characterized by electron-dense material, which in this case corresponds to the 💡receptors for the neurotransmitter.

Answer 16

postsynaptic element

Question 17

Types of chemical synapses:

Answer 17

axodendritic
axosomatic
axoaxonic dendrodendritic dendrosomatic

Question 18

It is a complex  synaptic  arrangement   that  is  found  in the  inferior  olive  and  some  other  CNS  regions.

It involves both chemical and electrical synapses among the participating elements.

Two  dendritic  spines  are  coupled  by  a  gap  junction.

An  axon  terminal  packed  with  synaptic  vesicles  fills  the  upper  right  part  of  the  panel.

Answer 18

glomerulus

Question 19

It is a complex synaptic arrangement in which cells form both electrical and chemical synapses with each other.

Answer 19

mixed synapses

Question 20

It is a complex synaptic arrangement
in which an 💡axoaxonic synapse is made onto the 💡axon terminal and influences the efficacy of that terminal’s synapse with yet a 💡third element.

Answer 20

serial synapses

Question 21

It is a complex synaptic arrangement

in which 💡both cells can release transmitter to 💡influence the other.

Answer 21

reciprocal synapses

Question 22

Synaptic transmission is initiated by arrival of the (1)__ at the (2)__. The action potential (3__ the terminal, which causes (4)__. The subsequent rise in [Ca++] within the terminal triggers the (5)__. The transmitter is then expelled into the (6)__, diffuses across it, and binds to specific receptors on the (7)__. Binding of transmitter to receptors then causes the (8)__ in the postsynaptic membrane, which in turn results in changes in the potential and resistance of the postsynaptic membrane that alter the excitability of the cell.

Answer 22

(1) action potential
(2) presynaptic terminal
(3) depolarizes
(4) Ca++ channels to open
(5) fusion of vesicles containing neurotransmitter with the plasma membrane
(6) synaptic cleft
(7) postsynaptic membrane
(8) opening (or less often, the closing) of ion channels

Question 23

The changes in membrane potential of the postsynaptic cell are termed __.

Answer 23

excitatory and inhibitory postsynaptic potentials (EPSPs and IPSPs)

Question 24

its probability of firing action potentials

Answer 24

cell’s excitability

Question 25

Why is the transmitter acts for only a very short time (milliseconds)?

Answer 25

because reuptake and degradation mechanisms rapidly clear the transmitter from the synaptic cleft

Question 26

See anki

Answer 26

See anki

Question 27

It is the signal for neurotransmitter release.

Answer 27

Calcium entry

Question 28

Ca++ will enter the terminal only if there is a favorable __ to do so.

Answer 28

Electrochemical gradient

Question 29

Extracellular [Ca++] is (1)__ relative to intracellular [Ca++], which favors entry into the terminal; however, during the peak of the action potential, the membrane potential is (2)__, and the (3)__ opposes the entry of Ca++ because of its (4)__. Thus, at the peak of the action potential, relatively little Ca++ enters the terminal because although the membrane is highly permeable to Ca++, the overall driving force is small.

Answer 29

(1) high (2) positive (3) voltage gradient (4) positive charge

Question 30

If the membrane potential is rapidly made (1)__ again (because of either the end of the action potential or by adjusting the voltage clamp), Ca++ rushes into the terminal as a result of the (2)__ (which arises instantaneously on repolarization) and the (3)__ (which remains high because it takes the Ca++ channels several milliseconds to close in response to the new membrane potential), thereby resulting in release of transmitter and a postsynaptic response

Answer 30

(1) negative (2) large driving force (3) high membrane permeability to Ca++

Question 31

It is small round or irregularly shaped organelles that stores the neurotransmitters.

Answer 31

Synaptic vesicles

Question 32

It is an action potential in a motor neuron causes a large depolarization in the postsynaptic muscle.

Answer 32

end plate potential (EPP) (equivalent to an EPSP in a neuron)

Question 33

Why is the EPP amplitude is reduced under conditions of low extracellular [Ca++]?

Answer 33

because the presynaptic Ca++ current is reduced, leading to a smaller rise in intracellular [Ca++], and transmitter release is proportional to [Ca++]

Question 34

It is a small spontaneous depolarizations of the postsynaptic membrane that is observed when EPP is flactuating.

Answer 34

miniature end plate potentials (mEPPs)

Question 35

It is a specific site where the small vesicles that contain nonpeptide neurotransmitters only can fuse with the presynaptic membrane

Answer 35

active zones

Question 36

As with other exocytotic processes, neurotransmitter release involves:

Answer 36

SM (sec1/Munc18-like) SNARE (soluble N-ethyl maleimide-sensitive factor attachment protein receptor) proteins v-SNARES in the vesicle membrane t-SNARES in the (target) presynaptic plasma membrane

Question 37

Example of v-SNARE

Answer 37

synaptobrevin

Question 38

Examples of t-SNARES;

Answer 38

syntaxin and SNAP-25

Question 39

Their 💡zipper-like interactions with the assistance of 💡SM proteins bring the vesicle membrane and the presynaptic plasma membrane close together before fusion.

Answer 39

synaptobrevin syntaxin SNAP-25

Question 40

It is a toxin produce by 💡Clostridium botulinum that targets SNARE proteins which disrupt synaptic transmission.

Answer 40

Botulinum toxins

Question 41

It is a SNARE protein that acts as the 💡Ca++ sensor and, even more specifically, that the second of its two cytoplasmic domains contains the Ca++ binding site. Its binding with calcium will trigger the 💡fusion of a docked vesicle and allowing release of its neurotransmitter. It is degraded by botulinum toxins.

Answer 41

synaptotagmin

Question 42

During synaptic transmission, __ to release their contents into the synaptic cleft.

Answer 42

vesicles must fuse with the plasma membrane

Question 43

Two distinct mechanisms by which vesicles are retrieved after release of their neurotransmitter content:

Answer 43

endocytotic pathway “kiss and run.”

Question 44

It involves transient fusion of the vesicle to the synaptic membrane which will leads to the formation of a pore through which the transmitter is expelled, but there is no wholesale collapse of the vesicle into the membrane. More rapid recycling mechanism

Answer 44

Kiss and run

Question 45

Following vesicle fusion the neurotransmitter molecules are released and diffuse across the synaptic cleft (a very rapid process) and bind to receptors on the postsynaptic membrane which will lead to the opening of?

Answer 45

ion channels ligand gated (opening and closing are primarily controlled by the binding of neurotransmitter)

Question 46

It is a channel that are both ligand and voltage gated

Answer 46

NMDA (N-methyl-Daspartate) channels

Question 47

“fast” synaptic transmission

Answer 47

ionotropic receptors

Question 48

“slow” synaptic transmission

Answer 48

metabotropic receptors

Question 49

EPSPs are always __, and IPSPs are usually __.

Answer 49

depolarizing potentials hyperpolarizing

Question 50

If acetylcholine-gated channels open when the membrane is at its (1)__, a large inward (2)__ and a small outward (3) __ will flow through the (4)__ thereby resulting in a net inward current, which acts to (5)__ the membrane.

Answer 50

(1) resting potential (2) Na+ current (3) K+ current (4) acetylcholine channel, (5) depolarize

Question 51

The net inward current that results from opening such channels is called __. **refer to previous card

Answer 51

excitatory postsynaptic current (EPSC)

Question 52

It is the potential at which there is 💡no EPSP (or EPSC). ** if the membrane potential is depolarized enough, there will be a point at which the Na+ and K+ currents through the channel are equal and opposite, and thus there is no net current and no EPSP. Hyperpolarize

Answer 52

reversal potential

Question 53

It is a 💡key criterion for demonstrating the 💡chemical-gated as opposed to the voltage-gated nature of a synaptic response because currents through voltage-gated channels do not reverse, except at the Nernst potential of the ion for which they are selective (and then only if the channel is open at that potential).

Answer 53

Reversal potential

Question 54

What is the difference of IPSP to EPSP? This difference makes IPSPs to have a reversal potential equal to the Nernst potential of the ion carrying the underlying current.

Answer 54

IPSP channels are permeable to only a single ionic species, either Cl− or K+.

Question 55

The key distinction between inhibitory and excitatory synapses (and IPSPs and EPSPs) is (1)__: EPSPs (2)__ the probability, whereas IPSPs (3) the probability.

Answer 55

(1) how they affect the probability of the cell firing an action potential (2) increase (3) decrease

Question 56

It is the ratio of 💡EPSP amplitude to the amplitude needed to reach the 💡threshold to trigger an action potential. It quantifies the strength of the excitatory synapses.

Answer 56

Safety factor

Question 57

Most synapses have __, and thus it takes the summed EPSPs of multiple active synapses to trigger an action potential in the postsynaptic neuron.

Answer 57

low safety factors (<1)

Question 58

These are diseases of the neuromuscular junction where the EPPs are reduced such that the safety factor can fall below 1, and thus the EPPs sometimes fail to trigger action potentials in the muscle fibers, leading to weakness.

Answer 58

myasthenia gravis and Lambert-Eaton syndrome

Question 59

It refers to the fact that EPSPs that are separated by a latency less than their duration can 💡sum. EPSPs  in  response  to  two  spikes  in  the  same  axon  occurring  in rapid  succession

Answer 59

Temporal summation

Question 60

It refers to the fact that synaptic potentials generated by 💡different synapses can interact. Responses  evoked by  synapses  that  are  💡electrically  distant  from  each  other  (1  and  3). The combined EPSP amplitude may then reach threshold and lead to spiking of the cell.

Answer 60

Spatial summation

Question 61

That is, when synapse 2 is active, channels are opened in the cell membrane, which means that it is more leaky. Therefore, when synapse 4 is also active, more of its EPSC will be lost (shunted) through the dendritic membrane, and less current will be left to travel down the dendrite to the initial segment. The result is that synapse 4 causes a smaller EPSP at the initial segment than it would have generated in isolation. Nevertheless, the combined EPSP is still larger than an EPSP caused by either synapse 2 or 4 alone.

Answer 61

Sublinear  summation

Question 62

Modulation of synaptic activity

Answer 62

Paired-pulse facilitation Posttetanic potentiation Synaptic depression

Question 63

When a presynaptic axon is stimulated twice in rapid succession, it is often found that the 💡postsynaptic potential evoked by the 💡second stimulus are 💡larger in amplitude than the one evoked by the first. Relatively rapid and short-lasting change in synaptic efficacy

Answer 63

paired-pulse facilitation (PPF)

Question 64

What is the difference if PPF and temporal summation?

Answer 64

Temporal summation, in which two EPSPs overlap and sum to a larger response; with PPF the second EPSP itself is greater in size.

Question 65

It is similar to PPF; however, in this case the 💡responses are compared before and after stimulation of the presynaptic neuron tetanically (tens to hundreds of stimuli at a high frequency). Such a tetanic stimulus train causes an increase in synaptic efficacy

Answer 65

Posttetanic potentiation (PTP)

Question 66

What is the similarity and difference of PTP and PPF?

Answer 66

PTP, like PPF, is an enhancement of the postsynaptic response, but it lasts longer

Question 67

It is thought to reflect 💡depletion of the number of releasable presynaptic vesicles.

Answer 67

Synaptic Depression

Question 68

A postsynaptically related cause of synaptic depression can be __ in the postsynaptic membrane.

Answer 68

desensitization of the receptors

Question 69

Both potentiation and depressive processes can occur at the same synapse.

Answer 69

True

Question 70

Presynaptic receptors can be either ionotropic or metabotropic.

Answer 70

True

Question 71

The activation of presynaptic (1) __ will (2)__ alter the electrical properties of the presynaptic terminal and cause rapid transient (millisecond time scale) changes in the probability of vesicle release (although they too can have much longer lasting effects).

Answer 71

(1) ionotropic receptors | (2) directly

Question 72

It refers to occasions when binding of presynaptic receptors leads to a 💡decrease in release of transmitter

Answer 72

Presynaptic inhibition

Question 73

Presynaptic inhibition mechanisms:

Answer 73

1. opening of channels decreases membrane resistance and creates a current shunt. 2. change in membrane potential caused by the opening of presynaptic ionotropic channels.

Question 74

Opening of channels decreases membrane resistance and creates a current shunt.

Answer 74

shunt acts to divert the current lessens the depolarization of the active zone less activation of Ca++ channels, less Ca++ entry, and less release of transmitter

Question 75

Change in membrane potential caused by the opening of presynaptic ionotropic channels.

Answer 75

small depolarization inactivation of voltage-gated Na+ channels lessening of the action potential–associated current and transmitter release

Question 76

It is a process where 💡repetitive stimulation of certain synapses in the brain can also produce more 💡persistent changes in the efficacy of transmission at these synapses.

Answer 76

long-term potentiation or long-term depression.

Question 77

T he increased synaptic efficacy that occurs in long-term potentiation probably involves both presynaptic (greater transmitter release) and postsynaptic (greater sensitivity to transmitter) changes, in contrast to the short-term changes that involve changes only in presynaptic function.

Answer 77

True

Question 78

It is an early step required for initiating the changes that result in long-term enhancement of the response of the postsynaptic cell to neurotransmitter.

Answer 78

Entry of calcium into the postsynaptic region

Question 79

Entry of calcium occurs at the post synaptic region is through:

Answer 79

NMDA receptors | AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid) receptors

Question 80

It is activated by 💡calcium entry at post synaptic region. It is a multifunctional 💡protein kinase that is present in very high concentrations in postsynaptic densities. It is believed to phosphorylate proteins that are essential for the induction of long-term potentia-tion.

Answer 80

Ca++-calmodulin kinase II

Question 81

These are the substances that 💡mediate chemical signaling between neurons.

Answer 81

Neurotransmitters

Question 82

For a substance to be considered a neurotransmitter, it must meet several generally recog-nized criteria;

Answer 82

1. the substance must be demonstrated to be present in the presynaptic terminal 2. the cell must be able to synthesize the substance 3. It should be released on depolarization of the terminal. 4. Finally, there should be specific receptors for it on the postsynaptic membrane

Question 83

It is a general term to describe 💡both synaptic and nonsynaptic signaling between cells.

Answer 83

Neurotransmission

Question 84

3 major categories of the neurotransmitters:

Answer 84

1. small-molecule transmitters 2. peptides 2. gaseous transmitters

Question 85

These are the small-molecule neurotransmitters

Answer 85

acetylcholine, amino acids, biogenic amines, and purines.

Question 86

PNS: neuromuscular junctions, at sympathetic and para-sympathetic ganglia, and of the postganglionic fibers from all parasympathetic ganglia and a few sympathetic ganglia. CNS: It is the trans-mitter at neurons in some brainstem nuclei, in several parts of the basal forebrain (septal nuclei and nucleus basalis) and basal ganglia, and in the spinal cord.

Answer 86

Acetylcholine

Question 87

It a form of dementia in which memory function is gradually and progressively lost due to degeneration of cholinergic neurons from the basal forebrain.

Answer 87

Alzheimer’s disease

Question 88

It is an enzyme that synthesizes acetylcholine.

Answer 88

choline acetyltransferase

Question 89

Two precursors of acetylcholine:

Answer 89

acetyl coenzyme A and choline

Question 90

It is an enzyme that terminates the action of acetylcholine.

Answer 90

acetylcholinesterase (highly concentrated in the synaptic cleft)

Question 91

It is the 💡product of acetylcholine hydrolysis that is taken up by an 💡Na+ symporter in the presynaptic membrane for the 💡resynthesis of acetylcholine.

Answer 91

Choline

Question 92

It is a drug that interfere with 💡acetylcholinesterase and thereby enhance the action of acetylcholine by prolonging its presence at its synapses. It is used to treat myasthenia gravis.

Answer 92

anticholinesterases

Question 93

It is an 💡autoimmune disease in which 💡antibodies bind to acetylcholine receptors at the neuromuscular junction, thereby disrupting their functionality and causing them to be more rapidly degraded. The eduction in receptors leads to severe weakness and ultimately paralysis.

Answer 93

Myasthenia gravis

Question 94

Three most important amino acids that acts as a neurotransmitter.

Answer 94

glutamate, glycine, and GABA

Question 95

It is the neurotransmitter at the overwhelming majority of 💡excitatory synapses throughout the CNS. It has a key role in multiple metabolic pathways, and it is a 💡precursor to GABA. It is the 💡major excitatory CNS neurotransmitter It is a potent 💡neurotoxin at high concentrations

Answer 95

Glutamate

Question 96

What is the action of glutamate to cells?

Answer 96

It causes depolarization

Question 97

It is the major inhibitory transmitter throughout the nervous system.

Answer 97

GABA

Question 98

It is an enzyme that catalyze the synthesis of GABA from glutamate.

Answer 98

glutamic acid decarboxylase

Question 99

Most notable brain regions that contain large numbers of 💡GABAergic projection neurons.

Answer 99

spiny neurons of the striatum | Purkinje cells of the cerebellar cortex

Question 100

It is a neurotransmitter that functions as an 💡inhibitory neurotransmitter in a much more 💡restricted territory (predominantly at spinal cord). It acts as a 💡co-transmitter at excitatory 💡NMDA-type glutamate receptors.

Answer 100

Glycine

Question 101

Fluctuations in glycine levels may also be an important modulator of NMDA-mediated synaptic transmission.

Answer 101

True

Question 102

After GABA and glycine are released from the presynaptic terminal, they are taken back up into the nerve terminal and neighboring glia by __.

Answer 102

high-affinity Na+-Cl−–coupled membrane transporters (solute carrier 6 (SLC6) family)

Question 103

Transport of the GABA and glycine into the cell is accomplished by (1)__ with (2)__ Na+ and (3)_ Cl− ion.

Answer 103

(1) symport (2) two (3) one

Question 104

Biogenic amines

Answer 104

Cathecholamines: dopamine norepinephrine (noradrenaline) epinephrine (adrenaline) serotonin (5-hydroxytryptamine [5-HT]) histamine

Question 105

-

Answer 105

Dopamine

Question 106

-

Answer 106

Norepinephrine

Question 107

-

Answer 107

Epinephrine

Question 108

-

Answer 108

Serotonin

Question 109

-

Answer 109

Histamine

Question 110

``` Tyrosine (1) L-dopa (2) Dopamine (3) Norepinephrine (4) Epinephrine ```

Answer 110

1. tyrosine hydroxylase 2. dopa-decarboxylase 3. dopamine β-hydroxylase 4. phenylethanolamineN-methyl transferase

Question 111

``` Tryptophan (1) 5-hydroxytryptophan (2) Serotonin ```

Answer 111

1. tryptophan 5-hydroxylase | 2. aromatic L-amino acid decarboxylase

Question 112

It catalyze the conversion of histidine to histamine.

Answer 112

histidine decarboxylase

Question 113

Glutamate inside  the  presynaptic  terminal  is  packaged  into  synaptic vesicles  by  a  second  set  of  glutamate  transporters known as __.

Answer 113

vGLUTs  (vesicular glutamate transporters)

Question 114

Transport of  glutamate  into  synaptic  vesicles  by  vGLUT  is  driven  by the __,  the  electrochemical  gradient for  which  having  been  established  by  an  H+-ATPase  in  the vesicle  membrane.

Answer 114

countertransport  of  H+  ions

Question 115

Removal of synaptically released biogenic amines is generally accomplished by reuptake into glia and neurons via transporters belonging to the

Answer 115

Na+-Cl−–dependent transporter family

Question 116

These are enzymes that degrades catecholamines.

Answer 116

monoamine oxidase and catechol Omethyltransferase

Question 117

It has the potential to act as a transmitter or cotransmitter at synapses in the peripheral and central nervous systems. It is found in all synaptic vesicles and thus is co-released during synaptic transmission. It has its own receptors, which like standard neurotransmitters, are coupled to ion channels, but it can also modify the action of other neurotransmitters with which it is co-released, including norepinephrine, serotonin, glutamate, dopamine, and GABA.

Answer 117

ATP

Question 118

ATP is broken down by __ and __ to adenosine, which can be taken up again by the presynaptic terminal.

Answer 118

ATPases 5-nucleotidase

Question 119

It inhibit  💡dopamine  receptors  on postsynaptic  membranes  and  thus  diminish  the  effects of  dopamine  released  from  presynaptic  nerve  terminals.  Overdoses  of  such  antipsychotic  drugs  can  produce  a temporary  💡parkinsonian-like  state.

Answer 119

Chlorpromazine

Question 120

When neuropeptides are co-released with other transmitters, they may act synergistically or antagonistically.

Answer 120

True

Question 121

In the spinal cord, these neuropeptides act 💡synergistically with 💡glutamate and with 💡substance P 💡to enhance the action of serotonin and they 💡antagonize norepinephrine’s action at other synapses.

Answer 121

tachykinins and calcitonin gene–related peptide (CGRP)

Question 122

The slower release and lack of rapid reuptake mean that neuropeptides can act for long durations, diffuse over a region of brain tissue, and affect all cells in that region (that have the appropriate receptors) rather than just acting at the specific synapse at which it was released.

Answer 122

True

Question 123

These are drugs derived from the juice of the 💡opium poppy.

Answer 123

Opiates

Question 124

Compounds that are not derived from the opium poppy but that exert direct effects by binding to opiate receptors are called __. They inhibit neurons in the brain involved in the 💡perception of pain. They are the most potent 💡analgesic (pain-relieving)

Answer 124

opioids

Question 125

Opioids are defined as compounds whose effects are stereospecifically antagonized by a morphine derivative called __.

Answer 125

naloxone

Question 126

These are three major classes of endogenous opioid peptides in mammals:

Answer 126

enkephalins, endorphins and dynorphins

Question 127

These are the simplest opioids; they are pentapeptides.

Answer 127

Enkephalins

Question 128

These are somewhat 💡longer peptides that contain one or the other of the 💡enkephalin sequences at their N-terminal ends.

Answer 128

Dynorphins and endorphins

Question 129

It is a peptide consisting of 11 amino acids. It is involved in 💡pain transmission and has a powerful effect on smooth muscle. it is the transmitter used at synapses made by 💡primary sensory neurons (their cell bodies are in the dorsal root ganglia) with spinal interneurons in the dorsal horn of the spinal column, and thus it is an example of a peptide acting as a 💡primary transmitter at a synapse.

Answer 129

Substance P

Question 130

These are opioids that act to decrease the release of 💡substance P at these synapses and thereby 💡inhibit the pathway for pain sensation at the first synapse in the pathway.

Answer 130

Enkephalins

Question 131

These are 💡neither packaged into synaptic vesicles nor released by exocytosis. Instead, these are 💡highly permeant and 💡simply diffuse from synaptic terminals to neighboring cells after synthesis, their synthesis being triggered by depolarization of the nerve terminal (the influx of Ca++ activates synthetic enzymes).

Answer 131

Gas neurotransmitters

Question 132

Examples of gaseous neurotransmitters.

Answer 132

nitric oxide (NO) and carbon monoxide (CO)

Question 133

It is a 💡transmitter at synapses between inhibitory motor neurons of the enteric nervous system and gastrointestinal smooth muscle cells It also functions as a neurotransmitter in the CNS. It functions as a 💡cellular signal transduction molecule (by regulating guanylyl cyclase) both in neurons and in nonneuronal cells

Answer 133

nitric oxide (NO)

Question 134

It is an enzyme that 💡catalyzes the production of NO as a product of the oxidation of 💡arginine to citrulline.

Answer 134

NO synthase

Question 135

NO synthase is stimulated by an increase in __.

Answer 135

cytosolic [Ca++]

Question 136

Neurotransmitter receptors are members of one of two large groups or families of proteins:

Answer 136

Ligand-gated ion channels (ionotropic receptors) and G protein-coupled receptors (metabotropic receptors )

Question 137

Almost all classic neurotransmitters and neuropeptides have at least one metabotropic-type receptor. Many of the classic neurotransmitters also have at least one ionotropic receptor.

Answer 137

True

Question 138

These are protein complexes that both have an extracellular binding site for the transmitter and form an 💡ion channel (pore) through the cell membrane.

Answer 138

Ionotropic receptors

Question 139

Binding of the neurotransmitter alters (usually increases) the probability of the ion channel being in the open state and thus typically results in postsynaptic events that are rapid in both onset and decay, with a duration of several milliseconds.

Answer 139

True

Question 140

See anki

Answer 140

See anki

Question 141

These receptors mediate postsynaptic phenomena that have a 💡slow onset and that may persist from hundreds of milliseconds to minutes.

Answer 141

metabotropic receptors

Question 142

Two major group of acetylcholine receptors:

Answer 142

Nicotinic receptors (ionotropic cys-loop family) muscarinic receptors (metabotropic family of receptor proteins)

Question 143

These are acetylcholine receptor that mediate 💡synaptic transmission at the neuromuscular junction. These receptor contains a relatively 💡nonselective cationic channel, so binding of acetylcholine produces an EPSP.

Answer 143

nicotinic receptors

Question 144

The junctional receptors (nicotinic) all use the __, whereas centrally located receptors (nicotinic) use one of the α subunits between __.

Answer 144

α1 subunit α2 and α10

Question 145

These five known muscarinic subtypes of acetylcholine receptors:

Answer 145

M1 to M5

Question 146

These are muscarinic subtypes of acetylcholine receptors that are coupled to 💡pertussis toxin–insensitive G proteins

Answer 146

M1, M3, and M5

Question 147

These are muscarinic subtypes of acetylcholine receptors that are coupled to 💡pertussis toxin–sensitive G proteins.

Answer 147

M2 and M4

Question 148

Glycine-mediated inhibitory synapses are common in the __, whereas GABAergic synapses make up the majority of inhibitory synapses in the __.

Answer 148

spinal cord brain

Question 149

Both glycine and GABA have ionotropic receptors that are members of the cys-loop family, each of these receptors has a Cl− channel.

Answer 149

True

Question 150

Glycine receptors are pentamers and may be heteromers of α and β subunits (3 : 2 ratio) or homomers. The β subunit seems to bind to an intracellular scaffold protein called that appears to help localize receptors to the postsynaptic site.

Answer 150

gephyrin

Question 151

T he α subunit contains the glycine binding site, and there are four genes coding for distinct α subunits (and splice variants of each).

Answer 151

True

Question 152

GABA has two separate ionotropic receptors coded for by distinct sets of genes.

Answer 152

GABA(A) and GABA(C)

Question 153

These are GABA ionotropic receptors that is being targeted by the drugs: 💡benzodiazepines and barbiturates which enhance opening of the receptors’ Cl− channels in response to GABA.

Answer 153

GABA(A) receptors

Question 154

These are GABA ionotropic receptors that are structurally similar to GABA(A) receptors but have a distinct pharmacological profile (e.g., they are 💡not affected by benzodiazepines) and are coded for by a separate set of genes (ρ1, ρ2, and ρ3).

Answer 154

GABA(C) receptors

Question 155

These are GABA 💡metabotropic receptors where binding of GABA to this receptor activates a heterotrimeric GTPbinding protein which leads to 💡activation of K+ channels and hence 💡hyperpolarization of the postsynaptic cell, as well as 💡inhibition of Ca++ channels (when located presynaptically) and thus a reduction in release of transmitter.

Answer 155

GABA(B) receptor

Question 156

Glutamate has both ionotropic and metabotropic receptors.

Answer 156

True

Question 157

These are ionotropic receptor subtypes of glutamate: These are excitatory and contain a cationic-selective channel and are permeable to 💡Na+ and K+, but 💡only a subset allow Ca++ to pass.

Answer 157

AMPA, kainate, and NMDA

Question 158

These are formed from GluR1 to GluR4 subunits.

Answer 158

AMPA receptors

Question 159

These require either KA1 or KA2 and GluR5 to GluR7 subunits.

Answer 159

kainate receptors

Question 160

These all have NR1 subunits plus some combination of NR2 and NR3 subunits.

Answer 160

NMDA receptors

Question 161

AMPA and kainate receptors behave as classic ligand-gated channels

Answer 161

True

Question 162

NMDA channels are different. First, they require 💡binding of both glutamate and glycine to open. Second, they display 💡voltage sensitivity as a result of Mg++ blockade of the channel. That is, at resting (or more negative) membrane potentials, a 💡Mg++ ion blocks the entrance to the channel so that even when glutamate and glycine are bound, no current flows through the channel. If the cell is depolarized the Mg++ block is relieved and current can flow through the channel.

Answer 162

True

Question 163

Purines have two receptor families: These receptors form a cationic channel that is permeable to Na+, K+, and Ca++.

Answer 163

an ionotropic (P2X) and a metabotropic (P2Y) family

Question 164

These are coded for by 10 genes, but only 6 are expressed in the human CNS. They have the typical features of G protein–coupled receptors and are known to 💡activate K+ currents and 💡modulate both NMDA and voltage-gated Ca++ currents. They predominate on astrocytes.

Answer 164

Metabotropic purine receptors (P2Y receptors)

Question 165

Receptors for the various biogenic amines [except one class of serotonin receptors (5-HT3)] are all 💡metabotropic-type receptors. Thus, these neurotransmitters tend to act on relatively long time scales by generating slow synaptic potentials and by initiating second messenger cascades.

Answer 165

Biogenic Amine Receptors: Serotonin, Dopamine, Noradrenaline, Adrenaline, Histamine Neuropeptide Receptors

Question 166

NO and CO do not bind to receptors. One way they do affect cell activity is to activate enzymes involved in second messenger cascades, such as guanylyl cyclase.

Answer 166

Gas Neurotransmitter Receptors