Deck 9: The Cytoskeleton and Cell Motility

A)chemically dissecting microtubules
B)focusing on a very thin plane just above the surface on which microtubules are lying
C)by preventing light rays emanating from individual motor proteins being monitored from being obscured by light rays from other areas
D)focusing on a very thin plane just above the surface on which microtubules are lying and by preventing light rays emanating from individual motor proteins being monitored from being obscured by light rays from other areas
E)denaturing the tubulin subunits of microtubules

A)nanodictation
B)nanomechanics
C)microscopotechnics
D)nanotechnology
E)picomechanics

A)strong interactions
B)noncovalent interactions
C)covalent interactions
D)magnetism
E)strong interactions and covalent interactions

A)intermediate filaments
B)microtubules
C)microfilaments
D)spindle fibers
E)microtubules and spindle fibers

A)microfilaments
B)protofilaments
C)prototubules
D)prototubulins
E)microtubular units

A)microfilaments
B)microtubules
C)intermediate filaments
E)macrofilaments

A)impressive
B)constant
C)ever-changing
D)energetic
E)forceful

A)injecting tubulin with a fluorescent dye
B)coupling tubulin to a fluorescent dye
C)coupling actin to a fluorescent dye
D)inducing a cell to express the gene for tubulin that has been fused to the gene for GFP
E)coupling tubulin to a fluorescent dye and inducing a cell to express the gene for tubulin that has been fused to the gene for GFP

A)TIRF
B)fluorescence recovery after photobleaching
C)total internal refraction microscopy
D)FRAP
E)fluorescence recovery after photobleaching and FRAP

A)the dynamics of the microtubules turning over in that bleached zone of the cell
B)the growth of new microtubules into the bleached zone
C)movement of microtubules through the bleached zone
D)all of these choices
E)the dynamics of the microtubules turning over in that bleached zone of the cell and the growth of new microtubules into the bleached zone

A)The cytoskeleton denatures in nonionic detergents.
B)The mRNA is solubilized by the nonionic detergents.
C)The mRNA is anchored to the cytoskeleton.
D)The cytoplasm is anchored to the mRNA.
E)The cytoskeleton is destabilized by the nonionic detergent.

A)tensile strength
B)solidity
C)brittleness
D)extensibility
E)tensile strength and extensibility

A)FRAP
B)TIRF
C)total internal reflection microscopy
D)atomic force microscopy
E)TIRF and total internal reflection microscopy

A)optical density
B)optical tweezer
C)confocal laser scanning
D)absorbance microscopy
E)laser pointer

A)above the limits of resolution
B)above the limits of magnification
C)below the limits of resolution
D)below the limits of magnification
E)at the limits of magnification

A)microfilaments
B)microtubules
C)intermediate filaments
D)all of these choices
E)minitubules

A)laser beams
B)atomic force microscopy
C)transmission electron microscopy
D)scanning electron microscopy
E)SDS-PAGE

A)compare the properties of different motor proteins
B)measure the properties of individual motors under different experimental conditions
C)ask how a specific mutation of a motor protein affects its motility properties
D)measure the interrelationships between molecular motor subunits
E)compare the properties of different motor proteins,measure the properties of individual motors under different experimental conditions and ask how a specific mutation of a motor protein affects its motility properties

A)1.5
B)2.5
C)3.5
D)10
E)35

A)kinesins
B)dyneins
C)myosins
D)kinesins and myosins
E)kinesins and dyneins

A)individually by diffusion
B)in groups of ten
C)inside transport vesicles
D)inside the Golgi complex
E)tied individually to microtubules

A)They preferentially kill tumor cells.
B)They preferentially stabilize tumor cells.
C)They disrupt tumor cell membranes.
D)They prevent entry of cells into the stage of meiosis.
E)They inhibit mitochondria.

A)Axons grow more rapidly.
B)Axonal outgrowth stops.
C)Axons grow more rapidly.
D)Axonal outgrowth stops.
E)There is no change in axonal outgrowth.

A)Microtubules of the plant cell cortex are thought to affect the movement of cellulose-synthesizing enzymes in the cell membrane,which,in turn,affect cell wall growth and shape.
B)Microtubules of the plant cell vacuole are thought to affect the movement of cellulose-synthesizing enzymes in the cell membrane,which,in turn,affect cell wall growth and shape.
C)Microtubules of the plant cell cortex are thought to affect the movement of lipid-synthesizing enzymes in the cell membrane,which,in turn,affect cell wall growth and shape.
D)Microtubules of the plant cell wall are thought to affect the movement of cellulose-synthesizing enzymes in the cell membrane,which,in turn,affect cell wall growth and shape.

A)the motor domain
B)the neck
C)the rod-like stalk
D)the fan-shaped tail
E)the motor domain and the neck

A)identically to
B)perpendicular to
C)parallel to
D)diagonal to
E)horizontal to

A)retrograde
B)anterograde
C)astronomical
D)radial
E)intergrade

A)0
B)1
C)2
D)3
E)4

A)retrograde
B)anterograde
C)astronomical
D)radial
E)intergrade

A)phosphorylation,neurofibrillary tangles
B)phosphorylation,neurofibrillary anastomoses
C)dephosphorylation,neurofibrillary tangles
D)dephosphorylation,neurofibrillary anastomoses
E)amination,neurofibrillary tangles

A)kinesins
B)dyneins
C)myosins
D)kinesins and dyneins
E)kinesins and myosins

A)slightly elevated temperature
B)hydrostatic pressure
C)elevated calcium ion concentration
D)colchicine or vinblastine treatment
E)all of these choices disassemble microtubules in living cells

A)Only the alpha-tubulin of a heterodimer can bind to the ring of gamma-subunits.
B)Only the beta-tubulin of a heterodimer can bind to the ring of gamma-subunits.
C)The ring structure straightens out the microtubule.
D)The ring structure interacts with a homodimer instead of a heterodimer.
E)Only the alpha-tubulin of a heterodimer can bind to the ring of gamma-subunits.and the ring structure straightens out the microtubule.

A)Mg²⁺ ions
B)GTP
C)EGTA
D)a temperature of 37°C
E)a temperature of 4°C

A)kinesins
B)dyneins
C)kinesins and myosins
C)myosins
D)kinesins and dyneins

A)the minus end
B)the N-terminal end
C)the plus end
D)the C-terminal end
E)the 5'-end

A)It binds Ca²⁺ ions,which inhibit microtubule polymerization.
B)It binds Mg²⁺ ions,which inhibit microtubule polymerization.
C)It binds Ca²⁺ ions,which stabilize microtubule polymerization.
D)It destroys Ca²⁺ ions,which inhibit microtubule polymerization.
E)It destroys Mg²⁺ ions,which inhibit microtubule polymerization.

A)hydrolysis of GTP
B)hydrolysis of ATP
C)proton gradient
D)H⁺ gradient
E)condensation of ATP

A)single actin strand
B)triple helix
C)hyperpolar filament
D)double helix
E)supercoil

A)red blood cells
B)white blood cells
C)plant cells
D)neurons
E)muscle cells

A)highly ordered arrays
B)loose,ill-defined networks
C)tightly anchored bundles
D)cylindrical conglomerations
E)all of these choices describe types of microfilament organization

A)It removes both arms from the A microtubule.
B)It selectively removes the outer arms from the A microtubule.
C)It selectively removes the inner arms from the A microtubule.
D)It selectively removes the outer arms from the B microtubule.
E)It selectively removes the inner arms from the B microtubule.

A)alpha-tubulin
B)beta-tubulin
C)actin
D)keratin
E)myosin

A)troponeme
B)dynomeme
C)cilioneme
D)axoneme
E)flagelloneme

A)the nuclear envelope in the center of the cell
B)hemidesmosomes
C)desmosomes
D)the neurofilaments of neuron axons
E)all of these choices

A)denaturation
B)sulfation
C)phosphorylation and dephosphorylation
D)hydrolysis
E)hydroxylation

A)Plectin
B)Filamentin
C)Nexin
D)Vimentin
E)Myosin

A)alpha-helix
B)beta-pleated sheet
C)double helix
D)quaternary coil
E)coiled coil

A)calcium
B)potassium
C)magnesium
D)manganese
E)sodium

A)intersheath bridge,nexin
B)peridoublet sheath,dynein
C)interdoublet bridge,nexin
D)interdoublet sheath,dynein
E)peridoublet sheath,nexin

A)filamentin
B)plectin
C)ascriptin
D)dynein
E)myosin

A)a 9 + 0 pattern
B)a 9 + 1 pattern
C)a 9 + 2 pattern
D)microtubules
E)none of these choices

A)elastic
B)highly resistant to shrinkage
C)springy
D)highly resistant to tensile forces
E)hyperflexible

A)kinesin-II
B)myosin
C)cytoplasmic dynein
D)kinesin
E)cytoplasmic kinesin

A)The keratin subunits remain in the cytoplasmic keratin subunit pool.
B)Filaments initially become labeled at scattered sites along their length.
C)Filaments become labeled at both ends simultaneously.
D)Filaments become labeled at one end exclusively.
E)The entire intermediate filament network is quickly labeled.

A)moving the cell from place to place
B)moving fluid and particulate material past the cell
C)a role in sensory function in monitoring the properties of extracellular fluids
D)moving vesicles down the nerve cell axon
E)all of these choices are functions of a cilium

A)centromeres
B)basal bodies
C)centrioles
D)spindle
E)MTOC

A)tubulin
B)actin
C)dynein
D)keratin
E)myosin

A)mitochondria
B)microtubules
C)microfilaments
D)intermediate filaments
E)lysosomes

A)bipolar
B)unipolar
C)tripolar
D)parallel
E)orthogonal

A)Sliding Lamina
B)Shortening Filaments
C)Sliding Filaments
D)And Then There Were Two
E)Filaments At Large

A)troponin
B)myosin
C)actinin
D)titin
E)tropomyosin

A)the combined decrease in sarcomere length
B)the combined shortening of actin filaments
C)the combined shortening myosin filaments
D)the combined shortening of thin filaments
E)the combined decrease in sarcomere length and the combined shortening of actin filaments

A)They undergo fission.
B)They become multinucleate via the embryonic fusion of large numbers of mononucleate myoblasts.
C)They become multinucleate via the embryonic fusion of large numbers of multinucleate myoblasts.
D)They become multinucleate via mitosis in myoblasts without cytokinesis.
E)They become multinucleate via the embryonic fusion of mononucleaate neuroblasts.

A)mitochondria
B)microtubules
C)microfilaments
D)intermediate filaments
E)lysosomes

A)sarcocytes
B)blastomeres
C)myomeres
D)sarcomeres
E)myotubules

A)The distance between the Z lines does not change.
B)The distance between the Z lines decreases.
C)The distance between the Z lines increases.
D)The Z lines disappear.
E)The Z lines become curved.

A)A bands
B)H zones
C)I bands
D)Z lines
E)M lines

A)A bands
B)the part of the A band on either side of the H zone
C)I bands
D)Z lines
E)the part of the H zone on either side of the A band

A)GTP
B)ATP
C)proton gradient
D)CTP
E)creatine phosphate

A)Its neck is twisted.
B)Its neck is relatively long.
C)Its neck is relatively short.
D)Its tail is very long.
E)Its tail is bipolar.

A)A bands
B)H zones
C)I bands
D)Z lines
E)M lines

A)myoglobin
B)kinesin
C)myosin
D)dynein
E)myometrium

A)All of the myosin heads beat synchronously.
B)All of the myosin heads beat out of synchrony with one another.
C)They use an enormous amount of ATP.
D)They use an enormous amount of GTP.
E)none of these choices

A)A bands
B)H zones
C)I bands
D)Z lines
E)M lines

A)separation of chromosomes during mitosis
B)cell elongation
C)cytokinesis
D)separation of chromosomes during mitosis and cell elongation
E)separation of chromosomes during mitosis and cytokinesis

A)cytochalasins
B)nocodazole
C)phalloidin
D)latrunculin
E)phalloidin and latrunculin

A)troponin
B)myosin
C)actinin
D)titin
E)tropomyosin