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Example Questions
Example Question #1 : Action Potentials And Synapse Biology
Which of the following is false regarding synapses?
In a chemical synapse, there is an influx of calcium ions into the postsynaptic neuron upon neurotransmitter binding
The gap between a presynaptic and a postsynaptic neuron is called a synaptic cleft
The most common type of synapse found in cardiac cells are electrical synapses
In a chemical synapse, neurotransmitters bind to receptors on the postsynaptic neuron
In a chemical synapse, there is an influx of calcium ions into the postsynaptic neuron upon neurotransmitter binding
There are two types of synapses: the chemical synapse and the electrical synapse. Chemical synapses are more common than electrical synapses, and use neurotransmitters (chemicals) to propagate action potentials. Electrical synapses have tunnels between cells, called gap junctions, that quickly transmit signals from one cell to the other. Electrical synapses are found extensively in the heart, since it is essential to have quick signal transmission between cardiac cells.
In chemical synapses an action potential reaches the end of a presynaptic neuron, which causes neurotransmitters to be released from the presynaptic neuron. These neurotransmitters bind to receptors on the postsynaptic neuron and initiate a signal transduction pathway in the postsynaptic neuron. The space between the presynaptic and postsynaptic neuron is called the synaptic cleft. Synaptic clefts are important regions where neurotransmitters are released and regulated.
Calcium ions play an important role in chemical synapses. Once an action potential arrives at the presynaptic neuron terminal, calcium ion channels on the presynaptic neuron become permeable to calcium ions. This facilitates the movement of calcium ions into the presynaptic neuron. Influx of calcium ions signals the presynaptic neuron to release neurotransmitters into the synaptic cleft, which eventually bind to receptors on the postsynaptic neuron. The calcium ions do not enter the postsynaptic neuron at the synapse.
Example Question #82 : Biology
A/An __________ synapse uses gap junctions to transmit signals, and a/an __________ synapse transmits the signals the fastest.
chemical . . . chemical
electrical . . . chemical
chemical . . . electrical
electrical . . . electrical
electrical . . . electrical
Electrical synapses have two main characteristics. First, they transmit signals through specialized tunnels between cells called gap junctions. Gap junctions facilitate movement of molecules and ions between cells. This movement enables transmission of signals between adjacent cells. Second, electrical synapses have a much higher speed of signal transmission than chemical synapses. This occurs because the signals in electrical synapses are transmitted directly from one cell to the next via gap junctions. In chemical synapses, however, signals are transmitted indirectly via neurotransmitters, which decreases the speed of signal transmission.
Example Question #83 : Biology
Which of the following is characteristic of a chemical synapse?
I. Signal transmission involves neurotransmitters
II. They are bidirectional
III. They are more common than electrical synapses
I and III
II only
I, II, and III
I only
I and III
A chemical synapse is a type of synapse that uses neurotransmitters to transmit signals. A presynaptic neuron receives an action potential, which prompts neurotransmitters to be released into the synaptic cleft. These neurotransmitters traverse across the synaptic cleft and bind to receptors on the postsynaptic neuron. Binding of neurotransmitters initiates a signal pathway in the postsynaptic neuron.
One of the characteristics of a chemical synapse is that it is unidirectional. This means that the signal can only be propagated in one direction. The signal is always transmitted from the presynaptic to the postsynaptic neuron, never the other way around.
Chemical synapses are indeed more common than electrical synapses. Most nerves, neuromuscular junctions, and major organs in the body use chemical synapses to transmit action potentials. The only major exception is the heart; cardiac cells in the heart use electrical synapses to transmit signal from one cell to the other.
Example Question #84 : Biology
In a chemical synapse, which structure contains the neurotransmitter receptors?
Axon of the postsynaptic neuron
Dendrites of the postsynaptic neuron
Dendrites of the presynaptic neuron
Axon of the presynaptic neuron
Dendrites of the postsynaptic neuron
In a chemical synapse, the presynaptic neuron transmits a signal to the adjacent postsynaptic neuron. The postsynaptic neuron receives this signal via neurotransmitters. Recall that a neuron has directionality, with dendrites on one end and an axon on the other end. Dendrites receive an outside signal (signal enters neuron), whereas an axon transmits the signal to an adjacent neuron or muscle (signal exits neuron). This means that the axon end of the presynaptic neuron transmits the signal to the dendrite end of the postsynaptic neuron via a chemical synapse.
Example Question #91 : Biology
When a neuron is unable to produce another action potential no matter how much stimulation is provided, what period is the neuron said to be in?
The depolarization period
The hyperpolarization period
The impulse propagation period
The relative refractory period
The absolute refractory period
The absolute refractory period
During the absolute refractory period, no action potential can occur. In the relative refractory period, an action potential can occur with more stimulation than is normally required.
Example Question #92 : Biology
What is the process by which action potentials are able to "jump" from one node of Ranvier to the next?
Depolarization
Saltatory conduction
Repolarization
Relative refractory period
Saltatory conduction
Saltatory conduction is the property that allows an action potential to jump from one node to the next along a neural axon. This is accomplished by the presence of myelin, a non-conducting sheath around the axon. Myelin interrupts the flow of current down the membrane, forcing it to skip from one region of membrane to the next, rather than fluidly traveling down the entire axon length.
Depolarization is the stage of action potential transmission in which sodium channels are opened, and sodium rushes into the cell down its concentration gradient. The resting potential of the neural membrane is roughly . The rapid influx of positive sodium ions causes this potential in increase to at the action potential peak.
Repolarization is the stage of action potential transmission in which potassium channels of a cell are opened, and potassium moves out of the cell. This event re-establishes the negative resting membrane potential.
The refractory period is the obligatory temporal gap between action potentials. After an action potential, the primary gating mechanism of the voltage-gated sodium channels causes the channels to close and deactivate. This constitutes the absolute refractory period, during which no stimulus is capable of producing an action potential. The relative refractory period follows, during the cell repolarization, when potassium efflux causes the membrane potential to drop below the resting potential. This state of hyperpolarization means that a greater stimulus is required to reach threshold, and constitutes the relative refractory period.
Example Question #93 : Biology
In humans, nerve impulses are transmitted with the coordinated action of sodium and potassium ion channels. These channels open in a specific sequence, to allow for membrane potential changes to take place in a directional manner along the length of an axon.
Figure 1 depicts a single phospholipid layer of a cell membrane, and three transmembrane channels important to action potential propagation.
A scientist is studying the nerve cell depicted in the above figure. He notices that proteins like 1, 2, and 3 are only located a certain regions along the length of the axon. What are these regions most likely to be called?
Synaptic clefts
Dendrites
Nissl bodies
Axon hillocks
Nodes of Ranvier
Nodes of Ranvier
The proteins responsible for allowing ionic flow into and out of axons are most likely to be found at Nodes of Ranvier, where there is no myelin and ions can move freely. Action potentials travel via saltatory conduction, meaning that the ion channels are only stimulated a certain points on the membrane. The majority of the impulse is conducted through the interior of the axon without further external stimulation.
Example Question #92 : Biology
In saltatory conduction displayed by neurons containing myelinated axons, ion flow takes place at which region of the axon?
Schwann cells
Myelinated portion of the axon
Nodes of Ranvier
Ion flow does not take place during saltatory conduction
Nodes of Ranvier
Saltatory conduction is defined as the method by which action potentials are propagated along axons in myelinated neurons. The method by which they do this is by the generation of action potentials at each node of Ranvier. The only places along the myelinated axon that display ion flow are the nodes of Ranvier. The myelinated portions do not display ion flow, allowing the electrical stimulus to rapidly jump down the axon from one node to the next rather than slowly flow down the full axon length.
Schwann cells are types of cell that make up the myelin coated sheath for select neurons.
Example Question #93 : Biology
In humans, nerve impulses are transmitted with the coordinated action of sodium and potassium ion channels. These channels open in a specific sequence, to allow for membrane potential changes to take place in a directional manner along the length of an axon.
Figure 1 depicts a single phospholipid layer of a cell membrane, and three transmembrane channels important to action potential propagation.
A scientist shows that the protein labeled "1" has a voltage gate, as well as an inactivation gate, while proteins 2 and 3 lack this dual gate architecture. What ion is most likely to be controlled by protein 1?
Potassium
Sodium
Magnesium
Calcium
Chloride
Sodium
Sodium channels have an inactivation gate, as well as a voltage gate. This allows the sodium channels to be turned off, even while voltage changes persist, thereby facilitating repolarization. This dual gate structure also causes the refractory period.
Example Question #11 : Action Potentials And Synapse Biology
In humans, nerve impulses are transmitted with the coordinated action of sodium and potassium ion channels. These channels open in a specific sequence, to allow for membrane potential changes to take place in a directional manner along the length of an axon.
Figure 1 depicts a single phospholipid layer of a cell membrane, and three transmembrane channels important to action potential propagation.
The protein labeled "2" in the diagram facilitates repolarization following the peak of an action potential. What ion is most likely to be controlled by this protein channel?
Magnesium
Sodium
Potassium
Chloride
Calcium
Potassium
Potassium is the major species that repolarizes a neuron following depolarization. After sodium has entered the cell to create depolarization, repolarization is driven by potassium ion efflux.
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