Deck 5: Biological Membranes

A) hypertonic
B) hyperosmotic
C) hypotonic
D) hydrophilic
E) hydrophobic

A) ligand
B) clathrin
C) endosome
D) macrophage
E) low-density lipoprotein

A) It is slightly amphipathic because of the presence of one hydroxyl group.
B) It is slightly hydrophobic because of the presence of one hydroxyl group.
C) It is slightly hydrophobic because of the presence of one carboxyl group.
D) It is slightly amphipathic because of the presence of one carboxyl group.
E) It is slightly hydrophilic because of the presence of one hydrocarbon group.

A) covalent disulfide bonds.
B) associating with fatty acids through hydrophobic interactions.
C) associating with glycoproteins on the inner membrane surface.
D) bonding to integral proteins through noncovalent interactions.
E) embedding in only one side of the membrane.

A) Large, polar molecules
B) Small, polar molecules
C) Large, hydrophilic molecules
D) Small, hydrophilic molecules
E) Small, hydrophobic molecules

A) They divide the cell into compartments.
B) They transmit signals between the environment and the interior of the cell.
C) They serve as surfaces for chemical reactions.
D) They adhere to and communicate with other cells.
E) They inhibit the passage of materials.

A) symporter
B) macrophage
C) membrane potential
D) proton gradient
E) antiporter

A) The fatty acid tails bend.
B) The fatty acid tails lack double bonds.
C) The fatty acid tails are a chain of saturated fats.
D) The fatty acid tails solidify at room temperature.
E) The fatty acid tails interact via van der Waals forces.

A) Osmosis
B) Uniporters
C) Aquaporins
D) Channel proteins
E) ABC transporters

A) Plasma membrane
B) Biological membrane
C) Trans membrane
D) Peripheral membrane
E) Integral membrane

A) the solubility of water in the membrane.
B) the method of substance transport across the membrane.
C) the movement of surface proteins through the membrane.
D) the diffusion of lipid-soluble substances across the lipid bilayer.
E) the movement of lipids and integral proteins within the lipid bilayer.

A) They are amphipathic molecules.
B) They contain three fatty acids chains.
C) They contain a polar organic group attached to a phosphate group.
D) They have cylindrical shapes that allow them to associate with water most easily as a bilayer structure.
E) They have two distinct regions, one strongly hydrophobic and the other strongly hydrophilic.

A) Water
B) Oxygen
C) Nitrogen
D) Potassium ion
E) Carbon dioxide

A) Endocytosis
B) Phagocytosis
C) Pinocytosis
D) Exocytosis
E) Receptor-mediated endocytosis

A) Plasma membranes regulate the passage of materials.
B) Plasma membranes divide the cell into compartments.
C) Plasma membranes serve as surfaces for chemical reactions.
D) Plasma membranes prevent communication with other cells.
E) Plasma membranes transmit signals between the environment and the interior of the cell.

A) ATP
B) Water
C) Porins
D) Signals
E) Tunnels

A) it completely extends through the membrane.
B) it is a glycoprotein with carbohydrates attached.
C) it is completely embedded within the membrane.
D) it is attached to the inside of the membrane by an ionic bond.
E) it is covalently linked to the outer surface of the plasma membrane.

A) They have no hydrophobic portions.
B) They are weakly bound to the surface of the membrane.
C) They are only located on the inner side of a membrane.
D) They are firmly bound to the membrane.
E) They are completely embedded within the lipid bilayer.

A) Plasma membrane proteins
B) Biological membrane proteins
C) Transmembrane proteins
D) Peripheral membrane proteins
E) Integral membrane proteins

A) Plasmolysis
B) Turgor pressure
C) Osmotic pressure
D) Facilitated diffusion
E) Dynamic equilibrium

A) Ion pumps
B) Uniporters
C) Symporters
D) Antiporters
E) ABC transporter

A) hypotonic
B) hypertonic
C) turgor pressure
D) isotonic
E) plasmolysis

A) Dialysis
B) Osmosis
C) Simple diffusion
D) Active transport
E) Facilitated diffusion

A) It will have no unfavorable effect as long as the water is free from bacteria.
B) It will have serious, perhaps fatal consequences because there would be too much fluid to pump.
C) It will have serious, perhaps fatal consequences because the red blood cells could shrink.
D) It will have serious, perhaps fatal consequences because the red blood cells could swell and burst.
E) It will have no serious effect because the kidney could quickly eliminate excess water.

A) Osmosis
B) Cotransport
C) Plasmolysis
D) Simple diffusion
E) Facilitated diffusion

A) stable.
B) isotonic.
C) hypotonic.
D) hypertonic.
E) amphipathic.

A) hypotonic
B) hypertonic
C) turgor pressure
D) isotonic
E) plasmolysis

A) coating detaches from vesicle.
B) coated vesicle forms by endocytosis.
C) ligands separate from receptors, which are recycled.
D) contents of secondary lysosome are digested and released into the cytosol.
E) endosome fuses with primary lysosome, forming secondary lysosome.

A) Glucose is transported against a concentration gradient.
B) Glucose moves readily across the membrane by simple diffusion.
C) Glucose phosphates move readily across the membrane by simple diffusion.
D) The binding of glucose triggers a conformational change in the carrier protein.
E) The transport of solutes via carrier proteins is faster than via channel proteins.

A) Pinocytosis has occurred.
B) Plasmolysis has occurred.
C) There has been no net water movement.
D) There has been a net flow of water out of the cell.
E) There has been a net flow of water into the cell.

A) These red blood cells have been placed in an isotonic solution.
B) These red blood cells have swollen in response to a hypertonic external solution.
C) These red blood cells have swollen in response to a hypotonic external solution.
D) These red blood cells have shrunk in response to a hypertonic external solution.
E) These red blood cells have shrunk in response to a hypotonic external solution.

A) The cell surface would shrivel.
B) The cell surface will keep expanding.
C) The surface area would remain constant.
D) The number of membrane receptor proteins would decrease.
E) The ratio of cell surface would decrease, compared to cell volume.

A) osmotic.
B) isotonic.
C) hypotonic.
D) hypertonic.
E) pressurized.

A) hypotonic
B) hypertonic
C) turgor pressure
D) isotonic
E) plasmolysis

A) to transfer Na⁺ to the inside of a cell.
B) to assist a Na⁺ to bind to a carbohydrate.
C) to transfer Na⁺ to the outside of a cell.
D) to assist a cell to release Na⁺ by exocytosis.
E) to assist a cell to take up Na⁺ by endocytosis.

A) The transport of glucose powers the transport of sodium.
B) ATP causes a conformational change in the carrier protein.
C) Both D and E
D) Glucose molecules are transported against their concentration gradient.
E) Sodium ions are transported down their concentration gradient.

A) Energy from ATP
B) A transmembrane protein
C) The transport of large food particles
D) The transport of small nonpolar molecules
E) Movement down a concentration gradient

A) polar
B) nonpolar
C) phosphorous
D) concentration
E) electrochemical

A) The active transport of glucose
B) The very fast turnover rate of glucose metabolism
C) The ability of the cell to engulf glucose by pinocytosis
D) The continuous excretion of glucose from other parts of the cell
E) The rapid addition of a phosphate to the glucose molecules

A) vesicles
B) gap junctions
C) tight junctions
D) anchoring junctions
E) cell surface receptors

A) A gap junction bridges the space between cells.
B) A gap junction is a much larger space between cells.
C) A gap junction provides communication between cells.
D) A gap junction can control the passage of materials between cells.
E) A gap junction requires the use of ATP to open and close its channels.

A) Endocytosis would not occur.
B) Lysosomes would not be formed.
C) Facilitated diffusion would not occur.
D) Lysosomes would be formed lacking hydrolytic enzymes.
E) The phagocytic vacuole would not fuse with the lysosome.

A) Lysis
B) Exocytosis
C) Cotransport
D) Pinocytosis
E) Facilitated diffusion

A) Desmosomes
B) Gap junctions
C) Tight junctions
D) Plasmodesmata
E) Adhering junctions

A) Glucose
B) Bacteria
C) Hormones
D) Potassium ions
E) Carbon dioxide

A) Desmosomes
B) Gap junctions
C) Tight junctions
D) Plasmodesmata
E) Adhering junctions

A) They provide structure to plant cells.
B) They provide anchorage points between adjacent cells.
C) They allow passage of materials through intercellular spaces.
D) They prevent the passage of materials through intercellular spaces.
E) They allow the transport of small molecules and ions between adjacent cells.

A) Osmosis
B) Exocytosis
C) Pinocytosis
D) Phagocytosis
E) Facilitated diffusion

A) passive transport
B) active transport
C) aquaporins
D) pores
E) transporters