Deck 5: Membranes and Transport

A) the nucleus
B) lysosomes
C) vesicles
D) the plasma membrane
E) the Golgi complex

A) proteins
B) phospholipids
C) cholesterol
D) functions
E) layers

A) transport proteins
B) recognition proteins
C) receptor proteins
D) cell adhesion proteins
E) nuclear proteins

A) transport proteins
B) recognition proteins
C) receptor proteins
D) cell adhesion proteins
E) nuclear proteins

A) the constant movement of the hydrophilic tails in the interior of the membrane
B) a thin layer of water found sandwiched between the two layers of phospholipids
C) the phospholipid molecules that vibrate, spin, and exchange places within the same layer of the bilayer
D) the free movement of cholesterol molecules within the membrane
E) the frequent flip-flop of phospholipids from one side of the membrane to the other

A) phospholipids and cellulose
B) phospholipids, protein, and sterols
C) protein and sterols
D) glycolipids and proteins
E) phospholipids and glycolipids

A) Cells that had high radioactivity levels after treatment contain iodine transporters.
B) Cells that had high radioactivity levels after treatment lack iodine transporters.
C) Cells that had high radioactivity levels after treatment had a mutation in genes encoding iodine transporter proteins.
D) Cells that had high radioactivity levels after treatment lack clathrin.
E) Cells that had high radioactivity levels after treatment lack lysosomes.

A) aquaporins
B) cell adhesion proteins
C) carrier proteins
D) microtubules
E) receptors

A) transport proteins
B) recognition proteins
C) receptor proteins
D) cell adhesion proteins
E) nuclear proteins

A) fat
B) wax
C) phospholipid
D) neutral fat
E) triglyceride

A) sterols only
B) proteins only
C) phospholipids only
D) sterols and phospholipids
E) sterols, phospholipids, and proteins

A) brain
B) heart
C) muscle
D) lungs
E) bones

A) are arranged in a single layer
B) are arranged in a bilayer with the polar heads of each layer located at the membrane surface
C) are arranged in a bilayer with the fatty acid tails located at the membrane surface
D) are arranged in a bilayer but the phospholipids have no specific orientation
E) dissociate into their lipid and protein components

A) increase the rate of diffusion
B) store cellular energy
C) facilitate ion transport
D) maintain membrane fluidity
E) receive chemical signals

A) Frye and Edidin
B) Watson and Crick
C) Singer and Goldstein
D) S. Singer and G. Nicolson
E) Brown and Goldstein

A) transport proteins
B) recognition proteins
C) receptor proteins
D) cell adhesion proteins
E) nuclear proteins

A) cell wall
B) outer matrix
C) extracellular matrix
D) glycocalyx
E) lipid raft

A) carbohydrate groups are attached to the molecules
B) the molecules are bound to the glycocalyx
C) the molecules are found on both the interior and exterior of the membrane
D) the molecules are attached to the membrane by ionic bonds
E) the molecules are rarely found on the membrane exterior

A) cytoskeletal proteins
B) integral membrane proteins
C) transcription factor proteins
D) peripheral membrane proteins
E) protein hormones

A) increase in cholesterol content only
B) increase in protein content only
C) increase in the number of double covalent bonds in phospholipids
D) increase in both cholesterol and protein content
E) increase in both cholesterol and double covalent bonds in phospholipids

A) passive transport
B) diffusion
C) facilitated transport
D) osmosis
E) active transport

A) ATP hydrolysis
B) concentration gradients
C) glucose metabolism
D) GTP hydrolysis
E) lipid phosphorylation

A) The fused cell will still be half red and half green.
B) The red and green fluorescent labels will be uniformly distributed throughout the entire membrane.
C) The red and green labels will be distributed in intermingled patches.
D) The red and green labels will flash intermittently.
E) The red and green labels will be distributed in a swirling pattern.

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

A) active transport only
B) passive transport only
C) both active and passive transport
D) osmosis
E) transport of all types of molecules

A) alcohols or amino acids; two fatty-acid tails
B) glycoproteins; one fatty-acid tail
C) two fatty-acid tails; sterols
D) variable proteins; cholesterol
E) water; choline

A) the controlled transport of ions and molecules across the membrane
B) cell-cell binding
C) recognition of other cells as being "foreign" or "self"
D) reception of chemical signals from other cells
E) participation in metabolic reactions

A) The osmotic pressure is equilibrated on both sides of the membrane.
B) Solute molecules no longer diffuse across the membrane.
C) Solute molecules continue to diffuse across the membrane.
D) Transporter proteins are inhibited to prevent movement across the membrane.
E) Channel proteins are gated to prevent movement across the membrane.

A) diffuse to a different location by osmosis
B) diffuse to a different location by active transport
C) concentrate at the top of the container
D) diffuse equally throughout the container
E) stay at the bottom of the container

A) a specific protein will transport certain polar or charged molecules but not others
B) only one specific integral membrane protein per membrane is involved in this process
C) the energy molecule ATP is specifically required for transport
D) only specific hydrophobic molecules can be transported
E) transport of molecules occurs only in specific cells

A) plasma
B) chloroplast
C) Golgi complex
D) lysosome
E) endoplasmic reticulum

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

A) voltage-gated
B) ligand-gated
C) charge-gated
D) electric-gated
E) positive-gated

A) H₂O
B) proteins
C) amino acids
D) steroid hormones
E) CO₂

A) Phospholipids are found only in certain membranes.
B) Certain proteins are unique to each membrane.
C) Only certain membranes are constructed from molecules with dual solubility.
D) Only certain membranes of a cell are selectively permeable.
E) Some membranes have hydrophobic surfaces exposed to the cytoplasm, while others have hydrophilic surfaces facing the cytoplasm.

A) does not exhibit specificity for a particular type of molecule
B) requires the input of energy
C) depends on a concentration gradient
D) goes against the concentration gradient
E) allows nonpolar uncharged molecules to diffuse across a membrane

A) pores made of water molecules
B) required for water to enter a cell
C) found only in bacterial cells
D) specific channels for water transport
E) useful for cell signaling

A) movement of a molecule from an area of high concentration to an area of low concentration
B) ability of a substance to pass through any membrane
C) ability of only certain molecules to pass across a membrane
D) need for carrier proteins to transport some molecules across a membrane
E) ability of molecules to be transported across a membrane

A) ionic
B) large, polar
C) large, hydrophilic
D) small, hydrophobic
E) large, hydrophobic

A) a selectively permeable membrane must be present
B) a concentration gradient cannot exist
C) cellular energy must be expended
D) pure water must be on one side of the membrane
E) only solutes can pass through the membrane

A) electrochemical gradient
B) turgor pressure
C) membrane potential
D) chemical gradient
E) electron potential

A) Different types of aquaporin proteins allow different rates of water diffusion.
B) Different aquaporin proteins are localized to different membranes in the cell.
C) Different types of aquaporin proteins are produced in different cell types.
D) Different types of aquaporin proteins alter the amount of water retention within a cell.
E) Different aquaporin proteins have different functions within the cells.

A) active transport only
B) endocytosis only
C) osmosis only
D) both osmosis and active transport
E) both diffusion and osmosis

A) hydrogen
B) potassium
C) sodium
D) calcium
E) magnesium

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

A) osmosis only
B) active transport only
C) endocytosis only
D) both diffusion and osmosis
E) both osmosis and active transport

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

A) turgor
B) osmotic
C) diffusion
D) concentration
E) plasmolysis

A) hemolysis
B) an increase in turgor pressure
C) plasmolysis
D) a lack of solutes in the cell
E) a higher than normal concentration of water in the cell

A) equal to
B) greater than
C) less than
D) that depends on
E) that alters

A) plasmolysis
B) diffusion
C) active transport
D) the cell from bursting
E) the cell from shrinking

A) negative; negative
B) positive; negative
C) positive; positive
D) negative; positive
E) neutral; positive

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

A) chemical
B) electrochemical
C) negative
D) electrical
E) active

A) The water molecules will be evenly distributed in the container, with more glucose molecules on one side than the other.
B) The volumes of the solution will be different, with a higher volume on the side that originally contained the higher concentration of glucose.
C) The volumes of the solution will be different, with a lower volume on the side that originally contained the higher concentration of glucose.
D) The glucose concentration of the two solutions will be identical on both sides of the membrane, but the volumes will remain unchanged.
E) The volume and concentrations will be unchanged on both sides of the membrane.

A) produce concentrated urine
B) recognize thirst
C) make large volumes of dilute urine
D) control sweating
E) salivate

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

A) turgor
B) osmotic
C) diffusion
D) concentration
E) plasmolysis

A) isotonic
B) hypertonic
C) hypotonic
D) protonic
E) aquatonic

A) to pump protons down a concentration gradient
B) when replicating
C) to secrete protein and wastes from the cell
D) to ingest nutrients
E) as a means of cellular protection

A) As the driving ion moves in, the transport ion moves in.
B) As the driving ion moves in, the transport ion moves out.
C) As the driving ion moves out, the transport ion moves in.
D) As the driving ion moves out, the transport ion moves out.
E) As long as both ions are moving together, they can go either in or out.

A) nucleus
B) lysosome
C) endoplasmic reticulum
D) plasma membrane
E) mitochondria

A) endoplasmic reticulum
B) plasma membrane
C) the Golgi complex
D) lysosomes
E) microbodies

A) antiport
B) active diffusion
C) symport
D) facilitated diffusion
E) osmosis

A) bulk endocytosis
B) receptor mediated endocytosis
C) exocytosis
D) primary active transport
E) secondary active transport

A) iron
B) mercury
C) lead
D) manganese
E) zinc

A) As the driving ion moves in, the transport ion moves in.
B) As the driving ion moves in, the transport ion moves out.
C) As the driving ion moves out, the transport ion moves in.
D) As the driving ion moves out, the transport ion moves out.
E) As long as both ions are moving together, they can go either in or out.

A) clathrins
B) cholesterols
C) antibodies
D) aquaporins
E) microtubules

A) two sodium ions in and two potassium ions out
B) two sodium ions in and three potassium ions out
C) two sodium ions out and three potassium ions in
D) three sodium ions in and two potassium ions out
E) three sodium ions out and two potassium ions in