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Example Questions
Example Question #44 : Nervous System
What kind of molecule can be used to inhibit the effects of a neurotransmitter?
Antagonistic molecules
Protagonistic molecules
None of these
Synergistic molecules
Agonistic molecules
Antagonistic molecules
Neurotransmitters in the human body are under tight control. Many drugs, such as anti-depressants or drugs for ADHD, limit neurotransmitter responses. Antagonistic molecules will inhibit neurotransmitters and are used in many drugs. These molecules structurally interact with receptor proteins, either blocking the active site or binding allosterically to alter the binding site shape. Antagonists can be competitive or uncompetitive.
In contrast, agonists are molecules that structurally resemble the ligand for a certain receptor and can bind to the active site to trigger a response. Nicotine, for example, is an agonist to certain acetylcholine receptors and can trigger these receptors.
Example Question #1 : Understanding Neurotransmitters
Which of the following is true regarding a synapse?
I. The neurotransmitter attaches to receptors on the presynaptic neuron
II. Propagation of the nerve signal is slowest at the synapse
III. Calcium ion channels located on the membrane of postsynaptic neuron facilitate the release of neurotransmitters
I and III
II only
II and III
I only
II only
Neurotransmitters, such as acetylcholine, are chemical signals that transmit action potentials from one neuron to another. This process occurs at the synapse, where a neurotransmitter is released from the presynaptic neuron. This neurotransmitter travels across the synaptic cleft and binds to a receptor on the postsynaptic neuron. Statement I is thus false.
The rate of propagation of a nerve signal is limited by the synapse because neurotransmitters must diffuse across the gap; statement II is true.
Calcium ions are very important in the release of neurotransmitters. Voltage-gated calcium channels are located on the axon of the presynaptic neuron. When an action potential reaches the synapse, calcium ions are allowed to enter into the presynaptic neuron. This influx of calcium ions interacts with vesicles containing neurotransmitters and causes them to release their contents into the synaptic cleft. Statement III is false because calcium ion channels are located on the membrane of presynaptic neuron, not postsynaptic neuron.
Example Question #2 : Understanding Neurotransmitters
A postsynaptic neuron has undergone a mutation that renders its SNARE proteins nonfunctional. What is the result of this mutation?
Neurons are unable to deliver neurotransmitter into the synaptic cleft
Action potentials are unable to propagate down the postsynaptic axon
None of the other answers
Neurons are unable to maintain resting membrane potential
Neurons are unable to synthesize neurotransmitter
Neurons are unable to deliver neurotransmitter into the synaptic cleft
The SNARE proteins are responsible for allowing vesicles filled with neurotransmitter to fuse with the cell membrane at the synaptic cleft, resulting in exocytosis. Without these proteins, the neurotransmitter cannot propagate the signal to any other cells.
Neurotransmitter synthesis occurs via translation or synthesis in the smooth endoplasmic reticulum, depending on the identity of teh molecule. Resting potential is determined by the sodium-potassium pump, and action potential propagation relies heavily on voltage-gated sodium channels and myelin.
Example Question #3 : Understanding Neurotransmitters
Which of the following types of molecules could potentially be a neurotransmitter?
I. Peptides
II. Gases
III. Monoamines
I and III
III only
I, II, and III
I and II
I, II, and III
All of the choices could potentially be neurotransmitters.
Peptide neurotransmitters are proteins. An example of a peptide neurotransmitter is somatostatin. Nitric oxide is the most well-known gaseous neurotransmitter. Monoamines are molecules that contain an amine group connected to an aromatic ring. These molecules are derived from aromatic amino acids. Dopamine, norepinephrine, and epinephrine are very well-known monoamine neurotransmitters.
Example Question #2 : Understanding Neurotransmitters
Which answer gives the two possible effects of a neurotransmitter on a postsynaptic neuron?
Apoptotic or no effect
Excitatory or no effect
Inhibitory or excitatory
Inhibitory or no effect
Inhibitory or excitatory
Receptors on postsynaptic neurons are connected to ion channels. When the neurotransmitter binds to the receptor, the channel opens, making that neuron more or less likely to have an action potential depending upon which type of ion the channel allows to enter or exit the neuron. The result is either an excitatory postsynaptic potential (EPSP) or an inhibitory postsynaptic potential (IPSP).
Example Question #3 : Understanding Neurotransmitters
Which of the following is true regarding the parasympathetic nervous system?
It is a part of the central nervous system
It works to elevate heart rate and blood pressure
It works to funnel blood to the muscles in preparation for a fight-or-flight response
It works to decrease heart rate and blood pressure
It is a part of the somatic nervous system
It works to decrease heart rate and blood pressure
The parasympathetic division of the autonomic nervous system promotes the "rest and digest mode." The somatic nervous system controls voluntary skeletal muscles, but the parasympathetic nervous system controls involuntary smooth & cardiac muscles. The neurons of the parasympathetic nervous system release acetylcholine, which is a neurotransmitter that leads to a decrease in heart rate and blood pressure. Results of increased parasympathetic activity include: decreasing blood flow to skeletal muscles, increasing blood flow to the gut, constricting pupils, and glycogenesis.
Example Question #1 : Understanding Neurotransmitters
Which neurotransmitter is involved in muscle movement?
Dopamine
Glutamate
GABA
Acetylcholine
Serotonin
Acetylcholine
The correct answer is ACh (acetylcholine) because it is involved with muscle contraction. It is released at the neuromuscular junction, the site where the neuron and muscle meet.
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