Deck 15: The Plasma Membrane

A) phospholipids.
B) cholesterol.
C) proteins.
D) glycoproteins.

A) enough lipid to occupy a monolayer equal to
B) enough lipid to occupy a monolayer equal to twice
C) less lipid than would occupy a monolayer equal to
D) enough lipid to occupy a monolayer equal to one-half

A) located mostly in the outer leaflet of the bilayer.
B) located mostly in the inner leaflet of the bilayer.
C) symmetrically distributed between the two membrane halves.
D) asymmetrically distributed between the two membrane halves.

A) cells.
B) eukaryotic cells.
C) animal cells.
D) plant cells.

A) exclusively in the inner leaflet.
B) exclusively in the outer leaflet.
C) equally distributed between the inner and outer leaflets.
D) only on the basal surface of epithelia.

A) they have few peripheral proteins.
B) they have only one membrane, the plasma membrane.
C) their plasma membrane is not associated with a cytoskeleton.
D) their plasma membrane contains no cholesterol.

A) peripheral proteins.
B) transmembrane proteins.
C) cytoskeletal proteins.
D) $\beta$ -barrel proteins.

A) oligosaccharide side chains
B) lipid modifications
C) transmembrane α helices
D) phosphorylation motifs

A) C-terminal glycosylphosphatidyl inositol (GPI)
B) An N-terminal myristoyl group
C) Prenyl and palmitoyl group additions
D) Oligosaccharide side chains

A) from inner to outer surfaces of a membrane.
B) laterally in the plane of a membrane.
C) from apical to basal surfaces of intestinal epithelial cells.
D) only if attached to microtubules or microfilaments.

A) interaction of transmembrane proteins with the cytoskeleton.
B) restriction of glycolipids to the extracellular face of the plasma membrane.
C) presence of multiple pass transmembrane proteins.
D) presence of N-linked oligosaccharide side chains on glycoproteins at the cell surface.

A) boats.
B) barrels.
C) rafts.
D) barges.

A) between the cell surface and the outside solution.
B) between the membrane and the cytoplasm of the cells.
C) through the middle of the cytoplasm.
D) between the two leaflets of the cell membranes.

A) They open and allow glucose to pass between the epithelial cells.
B) They keep the Na⁺-K⁺ pumps in the apical membrane only.
C) They keep the Na⁺-glucose cotransporter in the apical membrane and the glucose-facilitated transporter in the basolateral membrane.
D) They keep the glucose-facilitated transporter in the apical membrane and the Na⁺-glucose cotransporter in the basolateral membrane.

A) small.
B) hydrophobic.
C) small and hydrophobic.
D) small and hydrophilic.

A) mediated only by a protein channel.
B) mediated only by a protein carrier.
C) mediated by a protein carrier or channel.
D) against the concentration gradient.

A) into the cell only.
B) out of the cell only.
C) into or out of the cell.
D) only in the presence of ATP.

A) glucose into cells.
B) ions into cells.
C) poisons and drugs out of cells.
D) amino acids across epithelia.

A) Channel-mediated diffusion
B) Facilitated diffusion
C) Active transport
D) All of the above are equally fast.

A) Na⁺ and Cl^-; K⁺
B) Na⁺; K⁺ and Cl^-
C) K⁺; Na⁺ and Cl^-
D) K⁺ and Cl^-; Na⁺

A) voltage-gated
B) ligand-gated
C) signal-gated
D) ion

A) 0
B) -60
C) +60
D) -100

A) resting membrane potential.
B) equilibrium potential for each ion.
C) membrane potential when all channels are closed.
D) membrane potential when all channels are open.

A) -60 mV
B) +60 mV
C) 0 mV
D) -1 mV

A) K⁺
B) Na⁺
C) H⁺
D) Ca²⁺

A) K⁺ ions are smaller than Na⁺ ions.
B) K⁺ ions have a lower charge density than Na⁺ ions.
C) a selectivity filter removes the water molecules from K⁺ ions but not from Na⁺ ions.
D) K⁺ ions are more concentrated inside the cell than outside the cell.

A) mucin.
B) chloride channel.
C) Na⁺-K⁺ pump.
D) Na⁺-Ca²⁺ transporter.

A) CFTR
B) mucin
C) Na⁺-K⁺ pump
D) MDR transporter

A) unfavorable direction, always driven by hydrolysis of ATP.
B) unfavorable direction, always coupled to another reaction or source of energy.
C) unfavorable direction, driven only by the flow of another molecule across a membrane.
D) favorable direction, coupled to the hydrolysis of ATP.

A) permeability of these ions across the lipid bilayer.
B) ratio of these ions in the blood.
C) action of the Na⁺-K⁺ pump.
D) flow of these ions through voltage-gated channels.

A) 1%
B) 10%
C) 25%
D) 66%

A) only to ensure that calcium does not precipitate inside the cells.
B) thus transient calcium increases can be used as intracellular signals.
C) so that calcium does not accumulate in mitochondria.
D) to allow extracellular calcium to drive import of other ions.

A) Na⁺
B) K⁺
C) H⁺
D) Ca²⁺

A) facilitated diffusion.
B) symport.
C) antiport.
D) endocytosis.

A) facilitated diffusion.
B) symport.
C) antiport.
D) endocytosis.

A) actin-based motility.
B) microtubule-based motility.
C) clathrin-based vesicle formation.
D) dynamin-based vesicle formation.

A) Macrophages and T lymphocytes
B) Platelets and neutrophils
C) Macrophages and neutrophils
D) Eosinophils and T lymphocytes

A) phagocytosis.
B) receptor-mediated endocytosis.
C) simple diffusion.
D) caveolae formation.

A) Chronic fatigue syndrome
B) Familial hypercholesterolemia
C) Lupus erythematosus
D) Cystic fibrosis

A) caveolin.
B) clathrin.
C) COPI.
D) dynamin.

A) There are a lot of them and they are easily obtained.
B) They contain larger plasma membranes than any other cell type.
C) They are of particular interest because they are made up of a lipid monolayer.
D) They lack nuclei and membrane-bounded organelles.

A) cholesterol and phosphatidylcholine.
B) glycolipids and phosphatidylinositol.
C) phosphatidylcholine and sphingomyelin.
D) phosphatidylethanolamine and phosphatidylserine.