Deck 3: Chemical Signaling by Neurotransmitters and Hormones

A) the electron microscope.
B) the light microscope.
C) frog heart experiments first done by Loewi.
D) electrophysiological recordings.

A) mitochondria; neurotransmitter molecules
B) synaptic vesicles; mitochondria
C) synaptic vesicles; neurotransmitter molecules
D) mitochondria; ATP

A) axoaxonic
B) axodendritic
C) axosomatic
D) presynaptic inhibition

A) The presynaptic cell should contain the proposed substance and have a mechanism for synthesizing it.
B) Vesicles containing the substance move down the axon with the action potentials when the neuron is stimulated.
C) Receptors for the proposed substance should be present on the postsynaptic cell.
D) There is a means for inactivating the substance with an antagonist drug.

A) direct application of the proposed substance to the postsynaptic cell.
B) stimulation of the postsynaptic cell.
C) blocking receptors on the postsynaptic cell.
D) inactivating the substance.

A) acetylcholine.
B) amino acids.
C) neuropeptides.
D) monoamines.

A) all vesicles in the neuron will contain both substances.
B) stimulation of the neuron will result in release of only one of these.
C) some vesicles will contain only the neuropeptide and other vesicles will contain both substances.
D) some vesicles will contain only the classical neurotransmitter and other vesicles will contain both substances.

A) Neuropeptide replenishment after neural activity occurs more slowly than replenishment of classical neurotransmitters.
B) Neuropeptides are only synthesized in the cell body.
C) Necessary enzymes are packed into the vesicle with the protein precursor.
D) Transport of the vesicles down the axon depends on action potential propagation.

A) Synapses are uniform in size, transmitter release, and probability of action potential during an action potential.
B) Synapses vary widely in size, transmitter release, and probability of action potential during an action potential.
C) The most prevalent synapses in the brain are axoaxonic synapses.
D) In the rodent hippocampal synapses, a large amount of neurotransmitter is released when neurons fire.

A) preventing metabolism.
B) blocking transporters.
C) blocking autoreceptors.
D) increasing synthesis.

A) presynaptic inhibition.
B) neuromodulation.
C) axosomatic activation.
D) presynaptic facilitation.

A) docking of vesicles at the active zones.
B) opening of voltage-gated Ca²⁺ channels.
C) packaging of neurotransmitter into vesicles.
D) activation of autoreceptors.

A) exocytosis; Ca²⁺
B) endocytosis; Ca²⁺
C) exocytosis; Na⁺
D) docking; K⁺

A) priming; docking
B) active; docking
C) active; endocytosis
D) priming; exocytosis

A) It occurs through a process known as endocytosis.
B) Without it, the neuron would grow progressively larger as vesicular membrane is added to the terminal.
C) New vesicles for classical neurotransmitters are reformed and filled in the terminal.
D) The processes of endocytosis and exocytosis constitute vesicle recycling.

A) increase neurotransmitter release.
B) increase the rate of cell firing.
C) slow the rate of cell firing.
D) reduce neurotransmitter release.

A) increase in neurotransmitter release.
B) decrease in neurotransmitter release.
C) decrease in cell firing.
D) increase in cell firing.

A) enzymatic breakdown in the synaptic cleft.
B) transport back into the presynaptic cell.
C) transport into the postsynaptic cell.
D) transport into nearby glial cells.

A) Some neurotransmitters are synthesized by gut bacteria, and drugs can alter the gut bacteria populations, thereby influencing our health.
B) Gut bacteria species and diversity can have effects on the nervous system that are similar to drug effects.
C) Chronic stress can lead to higher populations of gut bacteria, thereby affecting health.
D) The nervous system responds to gut bacterial populations and helps to regulate their levels.

A) It diffuses out of the nerve cell through the cell membrane.
B) It is not released from synaptic vesicles via exocytosis.
C) It may be released from the postsynaptic cell.
D) It may be released from the presynaptic cell.

A) They rapidly cause intracellular effects.
B) G proteins are activated upon binding of neurotransmitter.
C) They are composed of only one subunit.
D) Binding of an agonist induces long-lasting responses in the cell.

A) Na⁺; second messenger
B) Ca²⁺; kinase
C) Ca²⁺; second messenger
D) Cl^-; effector enzyme

A) slow/ionotropic; fast/metabotropic
B) fast/ionotropic; slow/metabotropic
C) slow/metabotropic; fast/ionotropic
D) fast/metabotropic; slow/ionotropic

A) The receptor itself is an ion channel that opens upon ligand binding.
B) The receptor has one subunit with seven transmembrane domains.
C) They are coupled to intracellular G proteins.
D) When activated they can stimulate effector enzymes.

A) Na⁺
B) Cl^-
C) K⁺
D) Ca²⁺

A) opening of a G protein-gated ion channel.
B) changes in the levels of a second messenger.
C) fast excitatory transmission.
D) changes in gene expression.

A) Activation of G protein $\rightarrow$ change in activity of effector enzyme $\rightarrow$ activation of protein kinase $\rightarrow$ change in second messenger levels
B) Activation of G protein $\rightarrow$ change in second messenger levels $\rightarrow$ change in activity of effector enzyme $\rightarrow$ activation of protein kinase
C) Change in second messenger levels $\rightarrow$ change in activity of effector enzyme $\rightarrow$ activation of protein kinase $\rightarrow$ activation of G protein
D) Activation of G protein $\rightarrow$ change in activity of effector enzyme $\rightarrow$ change in second messenger levels $\rightarrow$ activation of protein kinase

A) stimulates the release of dopamine.
B) inhibits the synthesis of dopamine.
C) directly stimulates postsynaptic dopamine receptors.
D) is the synthetic precursor to dopamine (DA).

A) Allosteric modulators often have fewer side effects because they show greater receptor subtype selectivity.
B) Allosteric modulators have reduced receptor subtype selectivity, so they treat a wider range of disorders.
C) Allosteric modulators are readily available; agonists and antagonists are more difficult to synthesize.
D) Allosteric modulators consistently lead to release of more transmitter, thereby more effectively treating a disorder.

A) Calcium/calmodulin kinase
B) Tyrosine kinase
C) Protein kinase A
D) Protein kinase C

A) protein kinase G; cGMP
B) protein kinase A; cAMP
C) nitric oxide; cGMP
D) nitric oxide; calcium

A) long-term changes in gene expression.
B) the rate of cell firing.
C) rapid synaptic events.
D) opening of ion channels.

A) G proteins are activated.
B) the two trk receptors phosphorylate each other on tyrosine residues.
C) ion channels open.
D) second messenger systems are activated.

A) these are the primary sites of synaptic input.
B) these areas are easily viewed in human subjects.
C) dendrites are not affected by drugs.
D) the size and location of dendrites are fixed through the human life span.

A) synaptic cleft; brain
B) bloodstream; synaptic cleft
C) synaptic cleft; bloodstream
D) vesicles; bloodstream

A) Acetylcholine
B) Norepinephrine
C) Nitric oxide
D) Cortisol

A) epinephrine; norepinephrine
B) epinephrine; glucocorticoids
C) glucocorticoids; chromaffin cells
D) glucocorticoids; epinephrine

A) microcellular; prolactin; vasopressin
B) magnocellular; vasopressin; oxytocin
C) target; oxytocin; prolactin
D) Langerhans; releasing hormones; tropic

A) anterior pituitary; thyroid
B) posterior pituitary; hypothalamus
C) hypothalamus; anterior pituitary
D) hypothalamus; posterior pituitary

A) Hormones can alter behavioral responses to drugs.
B) Hormone secretion can be altered by psychoactive drugs.
C) Some hormones have psychoactive effects on their own.
D) The effects of hormones on the brain are simple and easy to measure.

A) metabotropic; G proteins
B) intracellular; transcription factors
C) tyrosine kinase; transcription factors
D) membrane-bound; G proteins

A) cortisol; corticosterone
B) corticosterone; cortisol
C) estradiol; melatonin
D) melatonin; estradiol

A) is the same in males and females because they are subject to the same hormones during early development.
B) differs in males and females because the social behaviors it regulates differ between males and females.
C) is the same in both males and females because both all social behaviors are the same in males and females.
D) differs in males and females because brain size differs in males and females.

A) antidepressants; Parkinson's disease
B) epinephrine; autism spectrum disorder
C) oxytocin; Parkinson disease
D) oxytocin; autism spectrum disorder