Deck 10: Properties and Functions of Neuroglial Cells

A) Certain glial cells grow too large.
B) Certain glial cells can migrate throughout the CNS.
C) Certain glial cells are not susceptible to programmed cell death.
D) Certain glial cells can divide.
E) Certain glial cells mutate more easily.

A) They produce astrocytes in the adult CNS.
B) They regulate cerebrospinal fluid.
C) They form the myelin sheath around axons within the central nervous system.
D) They move to sites of injury within the brain.
E) They form the myelin sheath around axons within the peripheral nervous system.

A) Glial cells have axons that are longer and wider than those of neurons.
B) Glial cells do not have axons.
C) Glial cells have axons that are longer and thinner than those of neurons.
D) Glial cells have axons, but not dendrites.
E) There are no "rule of thumb" ways to tell glial cells from neurons.

A) Oligodendrocytes
B) Astrocytes
C) Radial glial cells
D) Microglial cells
E) Schwann cells

A) They develop from the neural crest and are found in the central nervous system.
B) They develop from the neural crest and are found in the peripheral nervous system.
C) They develop from the mesoderm and are found in the central nervous system.
D) They develop from the mesoderm and are found in the peripheral nervous system.
E) They develop from the neural tube and are found in the central nervous system.

A) Long; short
B) Microglial; Schwann
C) Radial; fibrous
D) Fibrous; protoplasmic
E) Protoplasmic; radial

A) They are precursors to both astrocytes and radial glial cells.
B) They are precursors to both oligodendrocytes and astrocytes.
C) They cannot produce action potentials.
D) They are of mesodermal origin.
E) They are precursors to both oligodendrocytes and radial glial cells.

A) Radial glial cells
B) Schwann cells
C) Microglia
D) Astrocytes
E) NG2 cells

A) Glial cells aid in increasing capillary blood flow through their interaction with neurons and capillaries during periods of high activation.
B) There is an increase in the flow of oxygen ions along the axons of active neurons.
C) Glial cells allow more molecules into the intracellular space during periods of high activation.
D) Glial cells transport oxygen and other ions/molecules from blood capillaries directly to neurons during periods of high activation.
E) Oxygen ion channels in glial cells near blood capillaries become more permeable during periods of high activation, allowing more oxygen ions into glial networks.

A) Glial cells can increase the speed of transfer of neurotransmitters to neurons.
B) Capillaries can easily burst, which could damage neurons.
C) Glial cells can help regulate blood flow in relation to neural activity.
D) Neurons can send neurotransmitters through capillaries to other neurons.
E) Capillaries contain toxins that can kill neurons through direct contact.

A) faster transport of neurotransmitter molecules between glial cells.
B) lower intracellular concentrations of potassium, allowing for continuous reuptake of potassium.
C) higher intracellular concentrations of potassium, slowing down reuptake of potassium.
D) easier transfer of nutrients between glial cells.
E) higher concentration gradients between glial cells.

A) water from the extracellular space into the glial cells.
B) water from the glial cells into the extracellular space.
C) sodium between glial cells and the extracellular space.
D) water between glial cells and other glial cells.
E) sodium between glial cells.

A) "The organism likely has a mutation which causes their neurons to have lower resting potentials."
B) "You likely placed the electrode in an adjacent glial cell."
C) "The organism has improper myelination, resulting in a slower-than-normal response to light."
D) "Glial cells can cause neurons to have lower resting potentials; remove the glial cells and try again."
E) "You placed the electrode in the neuron's cell body instead of its axon."

A) depolarized, and more depolarized than the neurons.
B) depolarized, but less depolarized than the neurons.
C) completely unaffected by external potassium.
D) hyperpolarized, and more hyperpolarized than the neurons.
E) hyperpolarized, but less hyperpolarized than the neurons.

A) Glial cells and glial precursor cells cannot fire action potentials.
B) Only glial precursor cells can fire action potentials.
C) All glial cells and glial precursor cells can fire action potentials.
D) Only mature glial cells can fire action potentials.
E) Only astrocytes can fire action potentials.

A) calcium
B) sodium
C) potassium
D) oxygen
E) chlorine

A) Glial cells can continuously uptake potassium ions over a concentration gradient.
B) Glial cells can send faster signals to one another.
C) Glial cells can release more sodium ions to the extracellular space.
D) Glial cells can uptake more water from the extracellular space over a concentration gradient.
E) Glial cells can serve as effective insulators for axons.

A) AQP4 channels in the end foot.
B) of calcium channels in the end foot.
C) potassium ions in the end foot.
D) axons near the end foot.
E) potassium channels in the end foot.

A) It allows the glial cell to travel throughout the CNS.
B) It allows the glial cell to send signals to damaged neurons.
C) It allows the glial cell to replicate.
D) It allows the glial cell to engage in phagocytosis, clearing debris.
E) It allows the glial cell to form new myelin around damaged neurons.

A) glutamate
B) potassium
C) ATP
D) calcium
E) adenosine

A) the nodes contain higher concentrations of potassium pumps.
B) ions can only flow into the axon via these nodes.
C) the nodes are impermeable to ions.
D) microglial cells make contact with the axon at the nodes in the CNS.
E) water can flow into the axon via these nodes.

A) one; one
B) several; several
C) several; one
D) one; several
E) no; several f. several; no

A) glial cells can myelinate any cell.
B) myelination must be inhibited to avoid over-myelination.
C) myelination is an efficient process.
D) glial cells must undergo cell death to avoid over-myelination.
E) new axons cannot be myelinated.

A) ATP
B) connexon
C) AQP4
D) PMP22
E) ACh

A) neurotransmitters.
B) potassium channels.
C) ankyrins.
D) neurotrophins.
E) connexons.

A) The trembling mice have fewer neurons than the normal mice.
B) The trembling mice have improper myelination compared to the normal mice.
C) The trembling mice have glial cells that are less connected to one another than the normal mice.
D) The trembling mice have more potassium channels in their glial cells than the normal mice.
E) The trembling mice have less microglial cells than the normal mice.

A) uptake of potassium from clefts.
B) movement of calcium through glial cell networks.
C) hyperpolarization of nearby neurons.
D) uptake of sodium from clefts.
E) release of potassium from the glial cell.

A) Glial cells are smaller than neurons and have fewer ion channels.
B) Glial cells have lower resting potentials than neurons.
C) Neurons are myelinated, which contributes to the speed of their return to resting potential.
D) Potassium spreads through networks of glial cells, which slows the return to resting potential.
E) Calcium waves through glial networks prevent potassium from reentering the glial cells.

A) sodium; potassium
B) calcium; potassium
C) ATP; sodium
D) calcium; ATP
E) sodium; ATP

A) are able to change structure to become more like oligodendrocytes.
B) extend fine processes throughout the environment and contact surrounding cells.
C) transport calcium ions to neurons.
D) are unchanging from the time an organism reaches adulthood.
E) are responsible for blood clotting in injured adult brains.

A) also release glutamate, exacerbating the effect of brain injury.
B) release calcium, exacerbating the effect of the brain injury.
C) release debris, increasing immune response in the brain.
D) fire action potentials, causing deleterious signaling through the brain region.
E) die, increasing the volume of the extracellular space.

A) Oligodendrocytes; potassium
B) Microglia; glutamate
C) Astrocytes; ATP
D) NG2 cells; calcium
E) Schwann cells; ACh

A) They contribute to action potentials.
B) They contribute to neuroplasticity.
C) They contribute to CNS immune responses.
D) They contribute to synaptic pruning.
E) They contribute to clearing of debris.

A) over-myelination.
B) increased conduction velocity.
C) release of other neurotransmitters.
D) lower resting potential.
E) cell death.

A) increasing the rate of neurotransmitter release.
B) bridging activity of neurons with other neurons.
C) decreasing the reuptake of certain neurotransmitters.
D) reducing the resting potential of neurons.
E) increasing flow of cerebrospinal fluid throughout the CNS.

A) cerebrospinal fluid.
B) select neurotransmitters.
C) microglia cells.
D) myelin sheaths.
E) potassium pumps.

A) stop the movement of certain molecules from the bloodstream into the brain.
B) protect the bloodstream from neuronal debris.
C) stop neurotransmitters from passing into the bloodstream.
D) prohibit the movement of any molecules from the bloodstream into the brain.
E) protect endothelial cells from damage caused by neuronal activity.

A) astrocytes; cytokines
B) oligodendrocytes; adenosine
C) microglia; cytokines
D) astrocytes; glutamate
E) microglia; adenosine

A) hyperpolarize other glial cells.
B) send action potentials.
C) release ATP.
D) communicate with other glial cells, neurons, and immune cells.
E) myelinate axons.

A) attack T lymphocytes.
B) both stimulate and suppress activity of T lymphocytes.
C) only suppress activity of T lymphocytes.
D) only stimulate activity of T lymphocytes.
E) myelinate T lymphocytes.

A) Astrocytes
B) Microglia
C) Oligodendrocytes
D) Schwann cells
E) Radial glial cells