Deck 16: Cell Organization and Movement I: Microfilaments

A)ATP-actin can assemble into filaments.
B)actin subunits can treadmill through an actin filament.
C)actin assembly can produce force for movement.
D)actin (−)ends assemble more rapidly than actin (+)ends.

A)myosin
B)profilin
C)thymosin β₄
D)filamin

A)one
B)two
C)four
D)eight

A)an ATP-binding cleft.
B)a head domain.
C)a CH domain.
D)only one actin-binding site.

A)thymosin β₄
B)FH2 domain of formin
C)profilin
D)cofilin

A)a decrease in cell locomotion because less actin would be recruited to the leading edge.
B)an increase in cell locomotion because there would be a higher concentration of actin available.
C)no change in cell locomotion because thymosin β4 doesn't interact with Rho,Rac,or Cdc42.
D)none of the above

A)growth;lower
B)shrinking,higher
C)treadmilling,lower
D)none of the above

A)ATP binding.
B)phosphorylation.
C)Ca²⁺ binding.
D)dephosphorylation.

A)attach actin filaments to cell membranes.
B)disassemble actin filaments.
C)reveal the polarity of actin filaments.
D)reveal the polarity of myosin filaments.

A)actin filaments.
B)microtubules.
C)lamins.
D)intermediate filaments.

A)microtubules,microfilaments,intermediate filaments
B)intermediate filaments,microtubules,microfilaments,
C)microfilaments,microtubules,intermediate filaments
D)none of the above

A)Listeria ActA protein binds and inactivates the Arp2/3 complex.
B)Listeria ActA binds VASP,which enhances ATP-actin assembly.
C)Cofilin is necessary to accelerate the assembly of the (−)end of the filament.
D)CapZ promotes the elongation of the filament.

A)cleaves actin by binding the ATP-actin in the filament.
B)cleaves actin by twisting adjacent F-actin monomers in the filament.
C)recruits G-actin monomers to the elongating F-actin microfilament.
D)promotes exchange of ADP for ATP on G actin.

A)predominantly to filament (+)ends.
B)predominantly to filament (−)ends.
C)equally to both filament ends.
D)along the length of filaments.

A)at a moving cell's trailing edge.
B)at a moving cell's leading edge.
C)around the entire periphery of a nonmotile cell.
D)throughout the cytosol of a moving cell.

A)binding of ATP.
B)hydrolysis of ATP.
C)release of phosphate (Pi).
D)release of ADP.

A)myosin II.
B)actin depolymerization.
C)contraction.
D)actin polymerization.

A)skeletal muscle contraction
B)cytoplasmic streaming
C)cytokinesis
D)flagellum-mediated cell motility

A)increased organization of actin in stereocilia due to stabilized actin dynamics
B)increased rates of polymerization due to reduced availability for ADP-G-actin
C)increased steady-state treadmilling of F-actin
D)faster movement of cells toward a chemical signal

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

A)peroxisome
B)vacuole
C)mRNA
D)nucleus

A)active Cdc42 at the leading edge of the cell and active Rho at the back of the cell
B)active Rac at the back of the cell and active Cdc42 at the front of the cell
C)active Cdc42 at the back of the cell and active Rac at the leading edge of the cell
D)active Rac at the leading edge of the cell and active Rho at the back of the cell

A)membrane extension.
B)focal adhesion formation.
C)cell-body translocation.
D)gel-sol transitions.

A)α actinin
B)cofilin
C)fimbrin
D)profilin

A)to center myosin thick filaments
B)to attach actin thin filaments to the Z disk
C)to maintain a constant actin thin filament length
D)to make contraction sensitive to Ca²⁺

A)Proteins promoting bundle formation have one actin-binding site,whereas proteins promoting network formation have two actin-binding sites.
B)Different types of actin bind different actin-binding proteins to form bundles or networks.
C)Proteins that promote bundle formation bind ADP-actin,whereas proteins that promote network formation bind ATP-actin.
D)Proteins promoting bundle formation tend to be short and inflexible,whereas proteins that promote network formation tend to be longer and more flexible.

A)thymosin β4 and cofilin.
B)cofilin and profilin.
C)profilin and thymosin β4.
D)CapZ and cofilin.

A)myosin V.
B)myosin I.
C)stress fiber formation.
D)myosin II.

A)myosin I.
B)myosin II.
C)myosin V.
D)myosin VI.

A)the ability to bind ATP
B)the ability to form dimers
C)the ability to bind actin
D)the presence of a head domain

A)rear focal adhesion,membrane protrusion,front focal adhesion,cell body translocation,de-adhesion.
B)membrane protrusion,front focal adhesion,cell body translocation,de-adhesion,rear focal adhesion.
C)front focal adhesion,cell body translocation,de-adhesion,rear focal adhesion,membrane protrusion.
D)cell body translocation,de-adhesion,rear focal adhesion,membrane protrusion,front focal adhesion.

A)Arp 2/3;Rho
B)Arp 2/3;Cdc42
C)WASP;Rho
D)Rho kinase;Cdc42

A)The cells completely close the scratch,and only lamellipodia and filapodia are seen with actin staining.
B)The distance the cells migrate into the scratch is small,and actin staining reveals stress fibers,lamellipodia,and filapodia.
C)The cells are stimulated to undergo mitosis.
D)The cells migrate into the scratch,but no stress fibers can be observed with actin staining.