Deck 17: Cell Organization and Movement II: Microtubules and Intermediate Filaments

A)loss of GTP cap
B)treatment with colchicine
C)binding of MAP2
D)binding of stathmin

A)centrioles.
B)γ-tubulin.
C)GDP-tubulin dimers.
D)basal bodies.

A)It promotes microtubule growth by enhancing polymerization at the (+)end.
B)Other microtubule plus-end tracking proteins use EB1 to "hitchhike" onto the growing microtubule.
C)It can bind further back from the blunt end of microtubules.
D)all of the above

A)lateral association of only γ-tubulin subunits.
B)head-to-tail association of only γ-tubulin subunits.
C)lateral association of tubulin dimers.
D)head-to-tail association of tubulin dimers.

A)axons of nerve cells
B)animal cells in interphase
C)animal cells in mitosis
D)dendrites of nerve cells

A)a GDP cap.
B)a GTP cap.
C)phosphorylation of tubulin subunits.
D)γ-tubulin.

A)head domain.
B)tail domain.
C)rod domain.
D)light chains.

A)γ-tubulin ring complex
B)pericentriolar material
C)centrosome
D)basal body

A)kinesin-I is a (−)end-directed motor.
B)kinesin-I transports vesicles along microtubules.
C)kinesin-I binds and hydrolyzes ATP to produce movement.
D)kinesin-I is composed of two heavy chains and two light chains.

A)microtubule-associated proteins.
B)incubation at 4°C.
C)ATP.
D)a tubulin concentration in excess of the Cc.

A)in the hollow core of the microtubule.
B)at the microtubule (−)end.
C)at the microtubule (+)end.
D)along the outer wall of the microtubule.

A)to ATP or ADP.
B)to GTP or GDP.
C)only to GDP.
D)none of the above

A)destabilizing proteins.
B)motor proteins.
C)nucleating proteins.
D)stabilizing proteins.

A)block microtubule assembly.
B)stabilize microtubules against depolymerization.
C)promote cell division.
D)sever microtubules.

A)motor (head)domain.
B)neck region.
C)stalk domain.
D)tail domain.

A)All cilia arise from nine sets of outer triplet microtubules (similar to centrioles).
B)Cilia contain the same transport system as flagella,called IFT.
C)All cells with cilia are motile because of the axonemal dynein motor.
D)Primary cilia contain receptors that increase the cell's responsiveness to its environment.

A)microtubule polymerization.
B)ATP.
C)kinetochore motor proteins.
D)BimC.

A)metaphase.
B)prometaphase.
C)anaphase.
D)telophase.

A)sliding movement of central pair microtubules.
B)contraction of central pair microtubules.
C)sliding movement of outer doublet microtubules.
D)contraction of outer doublet microtubules.

A)Dynactin is the protein that links dynein to microtubules.
B)Transport is toward the (+)end of the microtubules.
C)GTP binds to the head region of dynein.
D)LIS1 associates with the head region of dynein to facilitate transport.

A)(+)end-directed microtubule motors at the cell cortex
B)(+)end-directed microtubule motors at the kinetochore
C)(−)end-directed microtubule motors in the microtubule overlap zone
D)(+)end-directed microtubule motors in the microtubule overlap zone

A)centrosome.
B)spindle pole.
C)telomere.
D)centromere.

A)is nonmotile because it lacks the "central pair" of microtubules.
B)is relatively susceptible to microtubule destabilizing drugs like colchicine.
C)has no known role in humans.
D)none of the above

A)vimentin
B)keratin
C)laminin
D)desmin

A)simple fluorescence microscopy.
B)optical trap microscopy.
C)fluorescence speckle microscopy.
D)electron microscopy.

A)connect the spindle poles.
B)attach chromosomes to the spindle.
C)carry out cytokinesis.
D)anchor the spindle poles to the plasma membrane.

A)The spindle elongates.
B)Kinetochores remain attached to shortening kinetochore microtubules.
C)Chromosomes move to the spindle equator.
D)The spindle poles move closer together.

A)They are named based on their location in cells between actin microfilaments and microtubules.
B)All cells express the same class II cytoplasmic intermediate filament proteins.
C)Staggered,antiparallel tetramers give intermediate filaments strength.
D)Acidic and basic keratins provide dynamic paths on which organelles may travel.

A)Individual keratin filaments span the cell membrane and directly connect one cell to the next.
B)Knockout mice for a keratin gene like K14 exhibit stronger skin that can withstand abrasion.
C)The polarity of keratin filaments allows them to withstand shear stress.
D)Patients with mutations in keratin genes exhibit skin problems.