Deck 5: Cell Membrane Structure and Function

A) hydrophobic and nonpolar.
B) hydrophobic only.
C) nonpolar only.
D) hydrophilic only.
E) polar only.

A) double layer of phospholipids with hydrophobic tails facing toward one another.
B) single layer of phospholipids with water molecules attached along one side.
C) double layer of phospholipids with hydrophilic heads facing away from one another.
D) double layer of phospholipids with hydrophobic tails facing away from each other (toward the cytoplasm of the cell and the extracellular solution).
E) single layer of phospholipids with tails pointed toward the inside of the cell.

A) carbohydrate; lipid
B) lipid; protein
C) cholesterol; lipid
D) nucleic acid; lipid
E) protein; cholesterol

A) Receptor proteins
B) Fever
C) Cholesterol
D) Recognition proteins
E) Inadequate enzymes

A) Cholesterol
B) Unsaturated fatty acid tails
C) Nonpolar heads of the phospholipids
D) Saturated fatty acid tails
E) Channel proteins

A) Simple diffusion and osmosis would continue to occur.
B) The movement of molecules across the membrane would not be affected.
C) All movement of molecules across the membrane would cease.
D) Immune reactions would not be affected.
E) Only water would be able to pass through the membrane.

A) Cytoskeleton
B) Proteins
C) Nucleic acids
D) Carbohydrates
E) Phospholipids

A) nucleic acids.
B) external proteins.
C) carbohydrates.
D) internal proteins.
E) lipids.

A) They are cell-surface connection sites.
B) They identify the cell.
C) They prevent the passage of amino acids.
D) They permit ions and water molecules to move through the plasma membrane.
E) They may set off cellular changes such as cell division or hormone secretion.

A) all proteins in the plasma membrane come from a membrane other than the human or the mouse.
B) all proteins are anchored within the membrane.
C) proteins are asymmetrically distributed within the membrane.
D) many proteins can move around within the bilayer.
E) different membranes contain different proteins.

A) glycerol.
B) phospholipids.
C) triglycerides.
D) waxes.
E) steroids.

A) only in muscle cell membranes.
B) exposed on the surface of the cell membrane.
C) attached to carbohydrates and facing the interior of a cell.
D) associated with the fatty acid region of the lipids.
E) in the interior of the membrane.

A) Transport proteins
B) Receptor proteins
C) Connection proteins
D) Recognition proteins

A) They occur in an uninterrupted bilayer, with membrane proteins strictly anchored to the surface of the membrane.
B) They have hydrophilic tails in the interior of the membrane.
C) They form a viscous fluid through which proteins shift and flow.
D) They are free to depart from the membrane and are dissolved in the surrounding solution.
E) They frequently flip-flop from one side of the membrane to the other.

A) head-tail-tail-head.
B) tail-head-tail-head.
C) head-tail-head-tail.
D) tail-head-head-tail.
E) head-head-tail-tail.

A) both the extracellular fluid and cytoplasm.
B) interstitial fluid.
C) cytoplasm of the cell.
D) interior of the plasma membrane (i.e., toward one another).
E) extracellular fluid surrounding the cell.

A) One of the components of the membrane is water.
B) The bilayer permits diffusion of certain lipid-soluble substances.
C) The membrane is water soluble.
D) The plasma membrane is ʺfluidʺ because of the movement of substances across the membrane.
E) The individual phospholipid molecules are not bonded to one another, so the movement of certain proteins and lipids is possible within and through the bilayer.

A) maintaining membrane integrity.
B) facilitated diffusion of molecules.
C) active transport of molecules.
D) distinguishing foreign cells from ʺselfʺ cells.
E) maintaining membrane fluidity.

A) single layer, with the phosphorus-containing region facing the interior of the cell.
B) bilayer, with the fatty acids pointing toward one another.
C) bilayer, with the fatty acids facing outward (facing the interior and exterior of the cell).
D) bilayer, with the phosphorus groups in the interior of the membrane.
E) single layer, with the fatty acids facing the interior of the cell.

A) sometimes water passes through, and sometimes it canʹt.
B) it is permeable to different substances than other cells.
C) only certain molecules can pass through.
D) it has different-sized perforations in the membrane.
E) permeability depends on gradient differences.

A) glycoproteins.
B) phospholipases.
C) steroids.
D) nucleic acids.

A) Enzymes
B) Receptor proteins
C) Recognition proteins
D) Connection proteins
E) Transport proteins

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

A) concentration gradient.
B) lipid solubility of the molecule.
C) temperature.
D) size of the molecule.
E) size of the cell.

A) Receptor protein
B) Cellulose
C) Cholesterol
D) Channel protein
E) Phospholipid

A) active transport.
B) exocytosis.
C) passive transport.
D) pinocytosis.

A) Movement of molecules into or out of a cell using special proteins and not requiring an expenditure of energy
B) Rapid movement of molecules in a solution
C) Movement of molecules into or out of a cell against a concentration gradient
D) Diffusion of molecules within a cell
E) Movement of molecules into or out of a cell down a concentration gradient

A) The red and green ink do not mix at all.
B) The concentration of each ink is higher at one end of the tray than at the other end.
C) The red ink is uniformly distributed in one half of the tray, and the green ink is uniformly distributed in the other half of the tray.
D) No predictions can be made without knowing the size of the ink molecules.
E) The red and green inks are both uniformly distributed throughout the tray.

A) amount of energy being produced by the cell.
B) concentration of carbon dioxide on each side of the membrane.
C) amount of oxygen being exported from the cell.
D) amount of transport protein in the membrane.
E) amount of carbon dioxide outside of the cell.

A) Passive transport
B) Osmosis
C) Endocytosis
D) Active transport
E) Exocytosis

A) require the aid of transport proteins.
B) move from an area of low concentration to an area of high concentration.
C) do so much more quickly than those crossing by simple diffusion.
D) require energy.

A) Receptor proteins
B) Recognition proteins
C) Transport proteins
D) Enzymes
E) Connection proteins

A) no energy required.
B) no gradient.
C) in the air.
D) without a membrane.
E) very slowly.

A) Water would leave the intestines and enter the cells by osmosis.
B) Water would leave the intestines and enter the cells by facilitated diffusion.
C) Water would leave the cells and enter the intestines by facilitated diffusion.
D) The movement of water would not be affected.
E) Water would leave the cells and enter the intestines by osmosis.

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

A) Most molecules are capable of crossing the phospholipid bilayer at any location and at basically the same rate.
B) Energy input is required to transport molecules.
C) The rate of diffusion cannot be influenced by the cell.
D) The cell gains needed materials and gets rid of excess materials very quickly.
E) The process is relatively slow and is driven by concentration gradients.

A) Connection proteins
B) Receptor proteins
C) Enzymes
D) Transport proteins
E) Recognition proteins

A) isolate the cellʹs contents from the external environment.
B) regulate the movement of substances between the cytoplasm of the cell and the extracellular fluid.
C) provide attachments between cells.
D) allow communication between cells.
E) provide an energy source for the cell.

A) a gradient.
B) ATP.
C) water.
D) a membrane.

A) Water will diffuse from solution B to solution A.
B) Water will diffuse from solution A to solution B.
C) Starch will diffuse from solution B to solution A.
D) Starch will diffuse from solution A to solution B.
E) Both water and starch will diffuse from solution B to solution A.

A) gain water; isotonic
B) lose water; hypertonic
C) lose water; hypotonic
D) gain water; hypertonic
E) gain water; hypotonic

A) high solute concentration to a region of low solute concentration.
B) negative osmotic potential to a region of positive osmotic potential.
C) low solute concentration of to a region of high solute concentration.
D) low concentration of water to a region of high concentration of water.
E) hypertonic solution to a region of hypotonic solution.

A) a gradient.
B) transport proteins.
C) ATP.
D) a membrane.
E) aquaporins.

A) hypotonic; hypertonic
B) hypertonic; isotonic
C) hypertonic; hypotonic
D) isotonic; hypertonic
E) isotonic; isotonic

A) Exocytosis
B) Facilitated diffusion
C) Aquaporin transport
D) Simple diffusion
E) Osmosis

A) facilitated diffusion.
B) osmosis.
C) facilitated transport.
D) simple diffusion.
E) active transport.

A) Cell A has a higher concentration of sucrose than cell B.
B) Cell A was hypertonic to the solution, and cell B was hypotonic.
C) Cell B has a higher concentration of sucrose than cell A.
D) Cell A was hypotonic to the solution, and cell B was hypertonic.
E) Cells A and B were isotonic to each other.

A) facilitated diffusion.
B) active transport.
C) simple diffusion.
D) osmosis.
E) exocytosis.

A) The cells remain unchanged due to equal water concentrations inside and outside the cells.
B) The cells swell and burst because water moves into them.
C) The cells shrivel up because water leaves them.
D) The cells remain unchanged due to equal solute concentrations inside and outside the cells.
E) They become white blood cells.

A) Infusion
B) Active transport
C) Exocytosis
D) Osmosis
E) Facilitated diffusion

A) hydrolysis.
B) osmosis.
C) facilitated diffusion.
D) exocytosis.
E) active transport.

A) there are a limited number of carrier proteins in the membrane.
B) facilitated diffusion requires ATP energy.
C) as the concentration gradient increases, molecules interfere with one another.
D) the diffusion constant depends on the concentration gradient.
E) the increased concentration gradient causes a situation far from equilibrium.

A) isotonic
B) hypertonic
C) hypotonic

A) simple diffusion.
B) osmosis.
C) facilitated diffusion.
D) endocytosis.
E) active transport.

A) 20°C.
B) 30°C.
C) 60°C.
D) 10°C.

A) beaker A is hypertonic relative to beaker B.
B) beaker A is hypotonic relative to beaker B.
C) beaker A is isotonic relative to beaker B.

A) Simple diffusion; hydrogen ions moved into the vesicle through a channel protein.
B) Active transport; hydrogen ions moved out of the vesicle with the help of ATP energy.
C) Facilitated diffusion; hydrogen ions moved into the vesicle through a channel protein.
D) Pinocytosis; water moved from outside the vesicle to inside.
E) Osmosis; water moved from inside the vesicle to outside.

A) Sugar diffuses in and water diffuses out until equilibrium is reached.
B) Water enters the cell because the solution is hypotonic to the cell.
C) There is no movement of water.
D) Water leaves the cell because the solution is hypertonic to the cell.

A) permeable.
B) hypertonic.
C) hydrophilic.
D) isotonic.
E) hypotonic.

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

A) desmosomes.
B) tight junctions.
C) gap junctions.
D) plasmodesmata.

A) exocytosis.
B) reception.
C) pinocytosis.
D) phagocytosis.
E) recognition.

A) swell via osmosis.
B) shrivel via active transport.
C) shrivel via facilitated diffusion.
D) shrivel via osmosis.
E) swell via facilitated diffusion.

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

A) desmosomes.
B) tight junctions.
C) gap junctions.
D) plasmodesmata.

A) turgor pressure will build up in the cell.
B) water will move out of the vacuoles by osmosis.
C) water will move out of the cytosol by osmosis.
D) the plasma membrane will shrink away from the cell wall.
E) osmosis will occur.

A) plasmodesmata.
B) osmotic channels.
C) tight junctions.
D) gap junctions.
E) desmosomes.

A) move away from danger.
B) ingest nutrients.
C) pump hydrogen molecules across the membrane.
D) release substances from the cell.
E) create new cells.

A) desmosomes.
B) tight junctions.
C) gap junctions.
D) plasmodesmata.

A) gap junctions.
B) desmosomes.
C) phospholipases.
D) tight junctions.

A) internal proteins.
B) gap junctions.
C) plasmodesmata.
D) desmosomes.
E) tight junctions.