Deck 8: Transport Across Membranes: Overcoming the Permeability Barrier

A)acid solution.
B)hypotonic solution.
C)isotonic solution.
D)basic solution.
E)hypertonic solution.

A)any hydrophilic molecule regardless of size.
B)hydrophilic molecules smaller than 600 Da.
C)any hydrophobic molecule regardless of size.
D)hydrophobic molecules larger than 600 Da.
E)any molecule regardless of properties or size.

A)K_eq is always equal to 1.
B)ΔG depends on the concentration gradient.
C)inward movement is exergonic.
D)ΔG° is always equal to 0.
E)the rate of GLUT1 transport is faster than that of simple diffusion.

A)GLUT1
B)GLUT2
C)GLUT3
D)GLUT4
E)GLUT5

A)the E2 conformation is open to the outside of the cell and has high affinity for K⁺.
B)the E1 conformation is open to the inside of the cell and has high affinity for Na⁺.
C)Na⁺ triggered phosphorylation of the pump stabilizes the E2 conformation.
D)K⁺ triggered dephosphorylation of the pump stabilizes the E2 conformation.
E)Each E1-E2 cycle pumps 3 Na⁺ ions out and 2 K⁺ ions in.

A)binding of Cl⁻ on one side of the membrane.
B)binding of bicarbonate ion on one side of the membrane.
C)unidirectional transport of Cl⁻ only out of the cell.
D)two conformational states of the protein.
E)All are involved in the mechanism.

A)oxygen.
B)fatty acids.
C)water.
D)glucose.
E)carbon dioxide.

A)a Na⁺ electrochemical gradient across the membrane.
B)a H⁺ concentration gradient across the membrane.
C)a membrane potential of 100 mV across the membrane.
D)ATP hydrolysis by ATP synthase.
E)retinal absorption of light energy.

A)import is down a concentration gradient.
B)import is down an electrochemical concentration gradient.
C)import ΔG is positive.
D)import requires energy input.
E)All are true.

A)aquaporin
B)porin
C)class ATPase
D)anion exchange protein
E)GLUT

A)Cl^−.
B)amino acids.
C)vitamin B₁₂.
D)glucose.
E)a hydrophobic drug.

A)it is the ratio of solubility in an organic solvent to solubility in water.
B)it can be used to predict the probability that an amino acid is part of a transmembrane region of a protein.
C)it is high for a molecule that readily crosses membranes by simple diffusion.
D)it is the concentration at which the rate of transport is half maximal.
E)it depends on the polarity of the molecule.

A)glucose transport by GLUT1.
B)chloride-bicarbonate exchange.
C)aquaporin transport.
D)ion channel transport.
E)oxygen transport.

A)Its rate is higher than that of simple diffusion of the molecule.
B)It is highly specific for the molecule being transported.
C)The direction of transport is determined by concentration and/or electrochemical gradients.
D)The rate of transport is saturable.
E)All of the above are true.

A)gated channels.
B)simple diffusion.
C)carrier (permease)proteins.
D)uniport transporters.
E)ABC transporters.

A)the Faraday constant is 0.
B)ΔG is 1.
C)ΔG is 0.
D)the Vm is always -60 mV.
E)It is not possible to calculate Vm without also knowing the uncharged solute distribution across the membrane.

A)targets the glucose for transport back out of the cell.
B)decreases glucose transport into the cell by decreasing its concentration gradient across the plasma membrane.
C)increases glucose transport into the cell by increasing its concentration gradient across the plasma membrane.
D)converts glucose into a form that can more easily be exported from the cell.
E)maintains a higher level of glucose outside the cell.

A)O₂ and CO₂ passive diffusion
B)aquaporin water transport
C)Cl⁻ bicarbonate ion antiport
D)glucose uniport
E)All of the above are correct.

A)there is an equal solute concentration on both sides of the membrane.
B)water diffuses through a semipermeable membrane toward a higher solute concentration.
C)water diffuses through a semipermeable membrane toward a lower solute concentration.
D)a high solute concentration opens an aquaporin channel.
E)ATP hydrolysis drives aquaporin transport.

A)a glucose gradient.
B)light energy.
C)an H⁺ gradient.
D)a Ca²⁺ gradient.
E)osmosis.

A)the control oocytes lacking aquaporin swelled and burst as water was transported into the cells.
B)the oocytes expressing aquaporin swelled and burst as water was transported into the cells.
C)the oocytes expressing aquaporin collapsed as water was transported out of the cells.
D)the oocytes expressing aquaporin first swelled and then collapsed as water was transported into and then back out of the cells.
E)the oocytes expressing aquaporin first collapsed and then swelled as water was transported out and then back into the cells.

A)maximal rate of solute transport.
B)solute concentration at which the transport rate is half maximal.
C)initial rate of transport at any concentration.
D)constant rate of transport regardless of concentration gradient.
E)standard free energy change used to calculate the maximal rate of transport.

A)transporter proteins are required.
B)the direction of transport is [S]_high → [S]_low.
C)the direction of transport is [S]_low → [S]_high.
D)the S concentration gradient provides the energy necessary for S transport.
E)the mechanism is not saturable.

A)1-10-fold
B)10-100-fold
C)10-1000-fold
D)1-1000-fold
E)10-10,000-fold

A)P type
B)V type
C)F type
D)ABC type
E)All are inhibited by vanadate.

A)Binding of 2 Na⁺ to the symporter open to the outside of the cell allows a glucose molecule outside the cell to bind.
B)Binding of Na⁺ and glucose causes the symporter to open to the inside of the cell.
C)Release of 2 Na⁺ ions to the inside of the cells causes release of the glucose molecule.
D)Binding of 2 Na⁺ to the symporter on the inside of the cell causes the symporter to open to the outside of the cell and release of the Na⁺ ions.
E)All of the above are steps in the mechanism.

A)type 1
B)type 2
C)type 3
D)type 4
E)type 5

A)2 Na⁺ in,3 K⁺ out.
B)2 Na⁺ out,3 K⁺ in.
C)3 Na⁺ in 2 K⁺ out.
D)3 Na⁺ out,2 K⁺ in.
E)1 Na⁺ out,1 K⁺ in.

A)sensitivity to inhibitors such as proton pump inhibitors.
B)nondirectionality for moving a solute in either direction across a membrane depending on the solute concentration gradient.
C)coupling transport of a solute down its concentration with transport of another solute up its concentration gradient via a symport or antiport mechanism..
D)moving solutes away from equilibrium across a membrane.
E)coupling a thermodynamically unfavorable (endergonic)process with a favorable (exergonic)process.

A)active transport.
B)facilitated transport.
C)passive transport.
D)simple diffusion.
E)A,B,and C.

A)symporters.
B)P-class pumps.
C)permeases.
D)bacteriorhodopsin.
E)ABC transporters.

A)type 1
B)type 2
C)type 3
D)type 4
E)type 5

A)ions.
B)sugars.
C)amino acids and peptides.
D)polysaccharides.
E)All of the above are correct.

A)changing the orientation of the porin α-helical transmembrane segments to constrict the size of the channel.
B)changing the stereoisomer specificity of the porin transport.
C)blocking diffusion of the antibiotic through the porin channel.
D)disrupting the voltage difference across the porin channel.
E)reversing water transport through the channel.

A)structure
B)mechanism
C)localization in cells
D)physiological roles
E)All of the above are correct.

A)Na⁺/K⁺ ATPase
B)aquaporin water transport
C)CFTR Cl⁻ transport
D)Na⁺/glucose symport
E)glucose permease transport

A)take up nutrients from the environment against concentrations gradients.
B)transport out secretory products and waste material against concentration gradients.
C)maintain nonequilibrium intracellular concentrations of ions such as Na⁺,K⁺,Ca2⁺,and H⁺.
D)establish an electrical potential across the membrane.
E)All of the above are correct.

A)ABC type
B)type
C)P type
D)V type
E)All of the above are correct.

A)multidrug resistance (MDR)transporters.
B)Na⁺-drug antiporters.
C)the cystic fibrosis transmembrane conductance regulator (CFTR).
D)porins.
E)None of the above; no such transporter has been identified in eukaryotes.

A)they are large,easily injected cells.
B)they express all transporters known.
C)they express injected heterologous mRNAs.
D)they are relatively inexpensive and easy to obtain.
E)they can be maintained in little more than pure water.

A)voltage-gated channels.
B)ligand-gated channels.
C)mechanosensitive channels.
D)patch clamp-gated channels.
E)All of the above are types of gated channels.