All MCAT Biology Resources
Example Questions
Example Question #1 : Neurotransmitters
Which of the following are major inhibitory neurotransmitters, causing inhibitory postsynaptic potentials (IPSPs)?
Glycine and epinephrine
Synaptobrevin and glutamate
GABA and glycine
Glycine and acetylcholine
Glycine and norepinephrine
GABA and glycine
GABA and glycine are the two major inhibitory neurotransmitters.
Norepinephrine, epinephrine, glutamate, and acetylcholine cause excitatory responses. Synaptobrevin is a snare protein involved in vesicle docking and fusion; it has no effect on whether or not a neurotransmitter is or is not inhibitory.
Example Question #1 : Neurotransmitters
The optic nerve is formed from the axons of all retinal ganglion cells. The optic nerves from each eye join at the optic chiasm and eventually enter either the left or right optic tract. The optic tract projects to three subcortical areas. One is the lateral geniculate nucleus, which is responsible for processing visual information. One is the pretectal area, which produces pupillary reflexes based on information from the retina. Finally, the superior colliculus uses the information from the retina to generate eye movement.
When light is shone upon one eye, it causes constriction of the pupil in both eyes. Constriction of the eye in which the light is shone is the direct response while constriction of the other is known as the consensual response. The pupillary reflexes are mediated through retinal ganglion neurons that project to the pretectal area which lies anterior to the superior colliculus. The cells in the pretectal area project bilaterally to preganglionic parasympathetic neurons in the Edinger-Westphal nucleus. This is also known as the accessory oculomotor nucleus. The preganglionic parasympathetic neurons in the Edinger-Westphal nucleus send axons through the oculomotor nerve to innervate the ciliary ganglion. The ciliary ganglion's postganglionic neuron innervates the smooth muscle of the pupillary sphincter.
The neurotransmitter released by the axons in the Edinger-Westphal neurons is most likely __________.
norepinephrine
acetylcholine
glutamine
dopamine
epinephrine
acetylcholine
Acetylcholine is correct. We are told from the passage that the neurons which make up the Edinger-Westphal nucleus are parasympathetic neurons. Therefore, this question is really testing one's knowledge of the neurotransmitter used by parasympathetic neurons. We cannot be expected to know from the question alone which neurotransmitter these neurons use. However, we are supposed to be aware that neurons that are parasympathetic use the neurotransmitter acetylcholine.
Example Question #114 : Systems Biology And Tissue Types
The central nervous system consists of the brain and the spinal cord. In general, tracts allow for the brain to communicate up and down with the spinal cord. The commissures allow for the two hemispheres of the brain to communicate with each other. One of the most important commissures is the corpus callosum. The association fibers allow for the anterior regions of the brain to communicate with the posterior regions. One of the evolved routes from the spinal cord to the brain is via the dorsal column pathway. This route allows for fine touch, vibration, proprioception and 2 points discrimination. This pathway is much faster than the pain route. From the lower limbs, the signal ascends to the brain via a region called the gracile fasciculus. From the upper limbs, the signal ascends via the cuneate fasciculus region in the spinal cord.
One of the most common neurotransmitters is acetylcholine. Which of the following methods will decrease the amount of the neurotransmitters in the synaptic cleft?
I. Increase the action potential frequency
II. Decrease the calcium concentration surrounding the neuron
III. Inhibit acetylcholine esterase
III only
II only
I and II only
I and III only
I only
II only
The presynaptic neuron require an action potential in order to open the calcium voltage channel. The opening of this calcium channel will allow the influx of calcium and trigger the release of vesicles with the neurotransmitter inside. The exocytosis of acetylcholine from the presynaptic cleft will then bind to the receptor on the postsynaptic cleft. Inhibiting acetylcholinesterase will prevent the breakdown of the neurotransmitter and allow for it to bind to the receptor longer. Decreasing the surrounding concentration of calcium will inhibit the release of the acetylcholine filled vesicles into the synaptic cleft.
Example Question #3 : Neurotransmitters
The cellular membrane is a very important structure. The lipid bilayer is both hydrophilic and hydrophobic. The hydrophilic layer faces the extracellular fluid and the cytosol of the cell. The hydrophobic portion of the lipid bilayer stays in between the hydrophobic regions like a sandwich. This bilayer separation allows for communication, protection, and homeostasis.
One of the most utilized signaling transduction pathways is the G protein-coupled receptor pathway. The hydrophobic and hydrophilic properties of the cellular membrane allows for the peptide and other hydrophilic hormones to bind to the receptor on the cellular surface but to not enter the cell. This regulation allows for activation despite the hormone’s short half-life. On the other hand, hydrophobic hormones must have longer half-lives to allow for these ligands to cross the lipid bilayer, travel through the cell’s cytosol and eventually reach the nucleus.
Cholesterol allows the lipid bilayer to maintain its fluidity despite the fluctuation in the body’s temperature due to events such as increasing metabolism. Cholesterol binds to the hydrophobic tails of the lipid bilayer. When the temperature is low, the cholesterol molecules prevent the hydrophobic tails from compacting and solidifying. When the temperature is high, the hydrophobic tails will be excited and will move excessively. This excess movement will bring instability to the bilayer. Cholesterol will prevent excessive movement.
Which of the following molecules can be found inside of a cell?
I. Cyclic adenosine monophosphate (cAMP)
II. Protein kinase A
III. Acetylcholine
I and II
II only
I only
I, II, and III
III only
I and II
Cyclic adenosine monophosphate and protein kinase A are both second messengers in the G protein-coupled receptor pathway. Since they are second messengers, they amplify and transmit the signal inside of the cell. Acetylcholine, however is a hydrophillic neurotransmitter and binds to the receptor located on the surface of the cell, thereby inducing intracellular signaling.
Example Question #51 : Neurons And Action Potential
The cellular membrane is a very important structure. The lipid bilayer is both hydrophilic and hydrophobic. The hydrophilic layer faces the extracellular fluid and the cytosol of the cell. The hydrophobic portion of the lipid bilayer stays in between the hydrophobic regions like a sandwich. This bilayer separation allows for communication, protection, and homeostasis.
One of the most utilized signaling transduction pathways is the G protein-coupled receptor pathway. The hydrophobic and hydrophilic properties of the cellular membrane allows for the peptide and other hydrophilic hormones to bind to the receptor on the cellular surface but to not enter the cell. This regulation allows for activation despite the hormone’s short half-life. On the other hand, hydrophobic hormones must have longer half-lives to allow for these ligands to cross the lipid bilayer, travel through the cell’s cytosol and eventually reach the nucleus.
Cholesterol allows the lipid bilayer to maintain its fluidity despite the fluctuation in the body’s temperature due to events such as increasing metabolism. Cholesterol binds to the hydrophobic tails of the lipid bilayer. When the temperature is low, the cholesterol molecules prevent the hydrophobic tails from compacting and solidifying. When the temperature is high, the hydrophobic tails will be excited and will move excessively. This excess movement will bring instability to the bilayer. Cholesterol will prevent excessive movement.
Which of the following molecules can be found inside of a cell?
I. Inositol trisphosphate
II. Protein kinase A
III. Epinephrine
I and II
I only
III only
II and III
II only
I and II
Inositol trisphosphate (IP3) and protein kinase A are both second messengers in the G protein-coupled receptor pathway. Since they are second messengers, they amplify and transmit the signal inside of the cell. Epinephrine, however is a hydrophilic (impermeable) neurotransmitter and hormone that binds to the receptor located on the surface of the cell.
Example Question #51 : Neurons And Action Potential
What side effect may occur after exposure to a chemical that inhibits the release of acetylcholinesterase?
An inability to stimulate neurons
An inability to release acetylcholine
Lack of receptors on the postsynaptic neuron
Repeated stimulation of postsynaptic neurons
Repeated stimulation of postsynaptic neurons
Acetylcholinesterase is the enzyme responsible for breaking down acetylcholine, an excitatory neurotransmitter released into the synaptic cleft. If acetylcholine cannot be broken down by this enzyme, the neurotransmitter will continue to attach to the receptors on the postsynaptic cell. This can result in continuous, uncontrolled stimulation of neurons.
Example Question #51 : Nervous System And Nervous Tissue
What is the normal resting potential of a neuron?
Resting potential is determined by evaluating the relative ion concentrations inside a cell in relation to the ion concentrations outside of the cell. For a resting neuron, the inside of the cell contains large amounts of potassium and the external environment contains large amounts of sodium. However, the resting potential is substantially negative due to the presence of negatively charged DNA and other molecules inside the cell. The normal resting potential of a neuron is .
Example Question #53 : Neurons And Action Potential
The parietal cells of the stomach are vital for both food digestion and as a defense mechanism against pathogens. When the parietal cells are not functioning properly, diseases such sepsis due to Clostridium difficile and malnutrition may occur. To keep the digestive system healthy, proper nutrition as well as a balanced diet is vital.
The parietal cells of the stomach secrete hydrochloric acid via the hormone gastrin. Gastrin is released when the stomach distends, via the presence of proteins and/or indirectly by the vagus nerve from the parasympathetic nervous system. Hydrochloric acid breaks down certain ingested food as well as activates certain zymogens for further digestion of macromolecules. The high acidity of the stomach due to the release of hydrochloric acid by parietal cells also destroys most pathogens. When the parietal cell is not functioning properly, opportunistic pathogens may create health problems.
Parietal cells also secrete intrinsic factor, a glycoprotein which binds to vitamin B12 to prevent destruction of the vitamin by the hydrochloric acid. Down the gastrointestinal tract, the vitamin is absorbed by the ileum of the small intestine. Vitamin B12 is essential for red blood cell production. A diet low in vitamin B12 may lead to anemia.
Even before the presence of food in the stomach, the parietal cells already began secreting hydrochloric acid during the cephalic phase of digestion. Which of the following best explains how this occur?
The activation of the parietal cells by somatostatin
The activation of the parietal cells by the migrating complex
The activation of the parietal cells by the sympathetic nervous system
The activation of the parietal cells by the vagus nerve from seeing the food
The distention of the stomach due to the presence of food in the stomach promotes the parietal cells to secrete hydrochloric acid
The activation of the parietal cells by the vagus nerve from seeing the food
During the cephalic phase of digestion, seeing the food will activate the cerebral cortex, which will then integrate the visual stimuli and trigger stimulation of the vagus nerve. The vagus nerve will then indirectly stimulate the G cells of the stomach to release gastrin. The release of gastrin will then promote the parietal cells to release hydrochloric acid.
Example Question #56 : Nervous System And Nervous Tissue
The central nervous system consists of the brain and the spinal cord. In general, tracts allow for the brain to communicate up and down with the spinal cord. The commissures allow for the two hemispheres of the brain to communicate with each other. One of the most important commissures is the corpus callosum. The association fibers allow for the anterior regions of the brain to communicate with the posterior regions. One of the evolved routes from the spinal cord to the brain is via the dorsal column pathway. This route allows for fine touch, vibration, proprioception and 2 points discrimination. This pathway is much faster than the pain route. From the lower limbs, the signal ascends to the brain via a region called the gracile fasciculus. From the upper limbs, the signal ascends via the cuneate fasciculus region in the spinal cord.
If the spinal cord was severed, which of the following functions will still be intact?
I. Fine touch
II. Pain
III. Knee-jerk reflex
III only
None of these
II only
I only
I and II
III only
According to the passage, both fine touch and pain require the signal to travel up to the brain in order to process the information. A severed spinal cord will interfere with both fine touch and pain. Reflex signals only travel at the level of the stimulus.
Example Question #1 : Glia
Prions are the suspected cause of a wide variety of neurodegenerative diseases in mammals. According to prevailing theory, prions are infectious particles made only of protein and found in high concentrations in the brains of infected animals. All mammals produce normal prion protein, PrPC, a transmembrane protein whose function remains unclear.
Infectious prions, PrPRes, induce conformational changes in the existing PrPC proteins according to the following reaction:
PrPC + PrPRes → PrPRes + PrPRes
The PrPRes is then suspected to accumulate in the nervous tissue of infected patients and cause disease. This model of transmission generates replicated proteins, but does so bypassing the standard model of the central dogma of molecular biology. Transcription and translation apparently do not play a role in this replication process.
This theory is a major departure from previously established biological dogma. A scientist decides to test the protein-only theory of prion propagation. He establishes his experiment as follows:
Homogenized brain matter of infected rabbits is injected into the brains of healthy rabbits, as per the following table:
Rabbit 1 and 2: injected with normal saline on days 1 and 2
The above trials serve as controls.
Rabbit 3 and 4: injected with homogenized brain matter on days 1 and 2
The above trials use unmodified brain matter.
Rabbit 5 and 6: injected with irradiated homogenized brain matter on days 1 and 2
The above trials use brain matter that has been irradiated to destroy nucleic acids in the homogenate.
Rabbit 7 and 8: injected with protein-free centrifuged homogenized brain matter on days 1 and 2
The above trials use brain matter that has been centrifuged to generate a protein-free homogenate and a protein-rich homogenate based on molecular weight.
Rabbit 9 and 10: injected with boiled homogenized brain matter on days 1 and 2
The above trials use brain matter that have been boiled to destroy any bacterial contaminants in the homogenate.
A scientist shows that PrPC in normal nervous cells helps speed nervous transmission. What other structures help speed nervous transmission?
Ependymal cells
Microglia
Astrocytes
All glial cells
Schwann cells
Schwann cells
Schwann cells act as insulators on nervous tissue to help propagate nervous transmission via saltatory conduction. This speeds transmission and makes axonal signal propagation much more rapid.
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