Deck 9: Membrane Transport

A) 6.4 * 10⁶
B) 6.5
C) 1.5
D) 0.15
E) 1.6 * 10^-7

A) high; high
B) high; low
C) low; high
D) low; low
E) low; equal

A) phosphatidylethanolamine; palmitic acid
B) cholesterol; isoprene
C) phosphatidylcholine, phosphatidic acid
D) sphingomyelin; sphingosine
E) ganglioside G_M1; ceramide

A) K⁺ efflux
B) K⁺ influx
C) Na⁺ efflux
D) Na⁺ influx
E) Cl^- efflux

A) 11.7 kJ/mol
B) 0.145 kJ/mol
C) -0.145 kJ/mol
D) -11.7 kJ/mol
E) cannot be calculated from given information

A) monomeric; seven transmembrane $\alpha$ -helices
B) dimeric; $\beta$ -barrels
C) dimeric; three transmembrane $\alpha$ -helices
D) trimeric; $\beta$ -barrels
E) trimeric; four transmembrane $\alpha$ -helices

A) pH change
B) phosphorylation
C) voltage change
D) ligand binding
E) all of the above

A) a porin is always open but only transports solutes in one direction
B) an ion channel selective for K⁺ will also allow Na⁺ through since both are small enough to fit through the channel
C) amphotericin is able to assemble inside a membrane in such a manner to form a channel through which K⁺ and Na⁺ flow, thus disrupting the ion gradient
D) K⁺ channels can work in both directions, allowing the neuronal action potential to move in multiple directions
E) none of the above

A) Asn
B) Leu
C) Phe
D) Val
E) Ile

A) in addition to glucose, it will transport any other monosaccharide with six carbons
B) binding of glucose causes a conformational change so that the transporter is never open on both sides of the membrane
C) ATP hydrolysis prevents the transporter from working in reverse
D) it is able to transport glucose into a cell against a concentration gradient
E) none of the above

A) antiporter; inside to out; outside to in
B) antiporter; outside to in; inside to out
C) symporter; inside to out; inside to out
D) symporter; outside to in; outside to in
E) none of the above

A) ABC transporter; bacterial infections
B) ABC transporter; cancer
C) Na,K-ATPase; viral infections
D) Na,K-ATPase; parasitic infections
E) none of the above

A) uniporter; passive transport
B) uniporter; primary active transport
C) symporter; primary active transport
D) symporter; secondary active transport
E) antiporter; secondary active transport

A) binding of SNARE complex to synaptic vesicles and pre-synaptic membrane
B) binding of acetylcholine to muscle cell receptors
C) reuptake of acetylcholine by the nerve cell
D) hydrolysis of acetylcholine by acetylcholinesterase
E) release of acetylcholine by the nerve cell

A) K⁺
B) Na⁺
C) pre-synaptic Ca²⁺
D) post-synaptic Ca²⁺
E) none of the above

A) uniporter
B) antiporter using Na⁺
C) antiporter using Ca²⁺
D) symporter using Na⁺
E) symporter using Ca²⁺

A) prior to membrane association, SNARE proteins are in an unfolded state
B) two proteins of the SNARE complex come from the membrane and one from the synaptic vesicle
C) formation of a four-helix complex is critical for membrane association of the vesicle
D) formation of the SNARE complex is thermodynamically favorable, as is membrane fusion
E) all of the above

A) SNARE complexes dissociate to allow membrane fusion to occur
B) addition of triacylglycerols to the membrane allows the bilayer to bow inward
C) selective removal of acyl chains from membrane phospholipids allows the bilayer to bow outward
D) the composition of the two membranes has no effect upon the rate of fusion
E) none of the above

A) D-Glucose undergoes simple diffusion more rapidly than D-Mannitol because glucose is less polar.
B) D-Glucose and D-Mannitol enter the erythrocyte via an ion-gated channel.
C) D-Glucose and D-Mannitol are transported via a system that distinguishes the two sugars.
D) D-Glucose flux through the membrane is linear, whereas D-Mannitol flux is described by a hyperbolic curve.
E) None of the above provides the explanation.