Deck 13: Synapses

A) neuron.
B) receptor-neurotransmitter complex.
C) membrane.
D) synapse.

A) Ionotropic EPSP
B) Metabotropic IPSP
C) Electrical synapse
D) Fast EPSP

A) any generic activating neurotransmitter.
B) acetylcholine.
C) the gap junction.
D) the cell membrane.

A) Postsynaptic densities
B) Synaptic vesicles
C) Neurotransmitters
D) Connexons

A) Neurotransmitter
B) Second messenger
C) Ligand-gated receptor
D) Voltage-gated receptor

A) facilitated diffusion.
B) calcium-dependent exocytosis.
C) active transport.
D) vesicular cycling.

A) amplifies the synaptic response
B) can be either excitatory or inhibitory
C) relatively slow
D) much more modifiable

A) Depolarization
B) Hyperpolarization
C) An action potential
D) Muscle contraction

A) Signaling cascade
B) Release of neurotransmitter into the synaptic cleft
C) Reuptake
D) Exocytosis

A) Small-molecule neurotransmitters are synthesized mainly in the nucleus.
B) Small-molecule neurotransmitters are contained in large dense-cored vesicles.
C) Neuropeptides are synthesized at the axon terminal.
D) The inactivation of small molecule neurotransmitters can occur via reuptake or via enzymes.

A) is actively pumped back into the presynaptic neuron.
B) crosses the postsynaptic membrane and then is broken down inside that cell.
C) is inactivated by calcium.
D) is broken down by acetylcholinesterase.

A) Acetylcholine
B) Dopamine
C) Glutamate
D) Both acetylcholine and glutamate

A) Acetylcholine
B) Serotonin
C) Dopamine
D) Norepinephrine

A) acetylcholine.
B) glutamate.
C) glycine.
D) GABA.

A) The movement of Na⁺ across the postsynaptic membrane
B) The diffusion of a neurotransmitter across the synapse
C) A depolarization caused by the release of a neurotransmitter from several synaptic vesicles
D) The postsynaptic response to the release of the contents of one synaptic vesicle

A) a count of the number of acetylcholine molecules in a vesicle.
B) a measure of the total amount of acetylcholine released into the synapse.
C) a measure of the stored acetylcholine in the presynaptic terminal.
D) the number of vesicles in the synapse.

A) Ca²⁺ was increased in the extracellular fluid so that action potentials would release many vesicles.
B) Ca²⁺ was absent in the extracellular fluid so that action potentials would release no vesicles.
C) Mg²⁺ replaced Ca²⁺ in the extracellular fluid so that action potentials would release few vesicles.
D) Mg²⁺ replaced Ca²⁺ in the extracellular fluid so that action potentials would release many vesicles.

A) There is more experimental support for the classical pathway of neurotransmitter release.
B) There was very little support for the classical pathway of neurotransmitter release, therefore the kiss-and-run pathway is currently the favored pathway.
C) Both pathways are portions of a larger pathway and therefore there should be one hypothesis.
D) The kiss-and-run pathway is likely used at lower rates of neurotransmitter release while the classical pathway predominates at higher rates of neurotransmitter release.

A) v-SNARE proteins attach to t-SNARE proteins.
B) Synapsin detaches the vesicle from the cytoskeleton.
C) Dynamin interacts with clathrin.
D) Calcium interacts with synaptotagmin.

A) Targeted vesicles move to active zones where they attach reversibly.
B) Docking is mediated by the formation of a SNARE complex.
C) The v-SNAREs and t-SNARES interact to hold the vesicle at the release site.
D) Fusion is triggered by the binding of Ca²⁺ to syntaxin.

A) Ca2⁺
B) Cl^-
C) Na⁺
D) K⁺

A) frequency of action potentials
B) movement of ions
C) neurotransmitter
D) receptor's affinity for the neurotransmitter

A) There will be a hyperpolarization.
B) There will be a depolarization.
C) An action potential will be produced.
D) The potentials created will cancel each other out.

A) I
B) II
C) III
D) IV

A) I
B) II
C) III
D) IV

A) postsynaptic potential
B) synaptic current
C) action potential
D) voltage

A) increases in permeability to K⁺.
B) increases in permeability to Na⁺.
C) decreases in permeability to Cl^-.
D) increases in permeability to Ca²⁺.

A) In a neuromuscular synapse, the main neurotransmitter is glutamate.
B) In a CNS neural synapse, serotonin produces an IPSP.
C) In a CNS neural synapse, K⁺ is the main ion producing the EPSP.
D) In a neuromuscular synapse, Na⁺ is the main ion producing the EPSP.

A) decrease; Na⁺
B) increase; Cl^-
C) increase; K⁺
D) increase; Na⁺

A) The receptor will flicker, and the rate of flickering will increase.
B) Acetylcholine will no longer be able to bind to the receptor.
C) Acetylcholine will remain bound to the receptor, and the channel will remain open indefinitely.
D) Acetylcholine will remain bound to the receptor, but the channel will close.

A) It binds acetylcholine.
B) K⁺ travels through this channel when it is open.
C) Two acetylcholine molecules need to bind to the intracellular side of the receptor.
D) When the channel opens, ions depolarize the membrane.

A) Voltage clamp
B) Ion flux
C) Stimulation
D) Patch clamp

A) Na⁺
B) K⁺
C) Ca²⁺
D) Cl^-

A) More electrical stimulation is occurring on the voltage-gated channels; therefore, they open with more frequency.
B) The increased concentration of acetylcholine eventually overwhelms the receptors, and the bottom panel represents what will happen just before they remain open permanently.
C) Because the channels are staying open longer due to increased acetylcholine concentration, K⁺ begins to move in significant quantities.
D) In this section of membrane, there are two acetylcholine channels that, in the presence of increasing neurotransmitter concentration, have an increasing probability of being open at the same time.

A) The sequence homology of the ligand-gated receptors is similar to that of voltage-gated receptors.
B) Ligand-gated channels have had a minimum of three independent appearances in evolutionary history.
C) Ligand-gated channels in the neuromuscular junction are evolutionarily distinct from ligand-gated channels in the brain.
D) Most kinds of ligand-gated channels appear to have evolved from a common ancestor.

A) ionotropic receptors open by voltage changes
B) ionotropic receptors are G proteins
C) ionotropic receptors use a second messenger system
D) ionotropic receptors function as ligand-gated channels

A) The G protein mediates the release of cAMP-dependent protein kinase, which activates adenylyl cyclase.
B) The G protein activates various second messengers, which all activate pathways that activate adenylyl cyclase.
C) The α subunit of the G protein, with GTP, diffuses laterally in the membrane and binds to and activates adenylyl cyclase.
D) The G protein causes a depolarization, which activates adenylyl cyclase.

A) Activating cAMP-dependent protein kinase
B) Opening of a K⁺ channel
C) Activating adenylyl cyclase
D) Activating phospholipase C

A) Diacylglycerol (DAG)
B) Inositol triphosphate (IP₃)
C) Calmodulin
D) Phospholipase C

A) upregulating the production of serotonin.
B) stimulating serotonin receptors.
C) inhibiting the reuptake of serotonin.
D) increasing the number of serotonin receptors.

A) head-to-motor neuron
B) sensory-to-motor neuron
C) skin-to-sensory neuron
D) motor neuron-to-gill

A) At the synapse, the neurotransmitter changes function.
B) The amount of neurotransmitter per presynaptic impulse changes.
C) Receptor density on the postsynaptic membrane changes.
D) The frequency of action potentials increases.

A) Panel 1 = Motor-neuron EPSP; Panel 2 = Gill withdrawal
B) Panel 1 = Skin PSP; Panel 2 = Gill contraction
C) Panel 1 = Synapse EPSP; Panel 2 = Head EPSP
D) Panel 1 = Synapse EPSP; Panel 2 = Gill contraction

A) Protein kinase dephosphorylates Ca²⁺ channels and decreases the Ca²⁺ current that normally terminates the action potential, which leads to a decrease in Ca²⁺ influx.
B) Protein kinase phosphorylates K⁺ channels and decreases the K⁺ current that normally terminates the action potential, which leads to an increase in Ca²⁺ influx.
C) Protein kinase dephosphorylates K⁺ channels and increases the K⁺ current that normally terminates the action potential, which leads to an increase in Ca²⁺ influx.
D) Protein kinase phosphorylates Na⁺ channels and decreases the Na⁺ current that normally activates the action potential, which leads to a decrease in Ca²⁺ influx.

A) Increase in AMPA receptors in the postsynaptic membrane
B) NMDA receptors mediate increases in intracellular Ca²⁺
C) Long-lasting neurotransmitter release
D) Lengthening of dendritic spines
E) Growth of new dendritic spines

A) Increased synaptic response occurs with increased numbers of AMPA receptors.
B) Increased synaptic response occurs with increased numbers of NMDA receptors.
C) A massive amount of glutamate releases Mg²⁺ from the NMDA receptor.
D) A massive amount of glutamate releases Mg²⁺ from the AMPA receptor.

A) They have longer-opening NMDA receptors compared to standard lab mice.
B) They produce more neurotransmitters than standard lab mice.
C) They produce more action potentials per second than standard lab mice.
D) They have a better long-term memory than standard lab mice.

A) Altering the amount of calcium entering the cell at the presynaptic terminus
B) Increasing the amount of neurotransmitter released from an action potential
C) Increasing the number of receptors on the postsynaptic membrane
D) Reducing voltage gated Na⁺ channels on the neuron