Deck 4: The Structure and Function of the Plasma Membrane

A)A person with O blood type would have gangliosides with terminal fucose residues only exposed on their glycolipids.
B)A person with A blood type would have gangliosides with both terminal fucose and terminal N-acetylgalactosamine residues exposed on their glycolipids.
C)A person with B blood type would have gangliosides with terminal fucose and galactose residues on their glycolipids.
D)A person with AB blood type would have gangliosides with terminal fucose, terminal N-acetylgalactosamine and terminal galactose residues exposed on their glycolipids.
E)all statements are correct

A)They are difficult to isolate in soluble form due to their hydrophobic transmembrane domains.
B)They are difficult to isolate in soluble form due to their hydrophilic transmembrane domains.
C)They are too small.
D)They are too large.
E)None of these are correct.

A)heterology modeling
B)homology mapping
C)homology modeling
D)protein mapping
E)homologous characterization

A)freeze-denture replication
B)freeze-fracture replication
C)X-ray crystallography
D)circular dichroism
E)quick-freeze replication

A)an enzyme that adds an N-acetylgalactosamine to the end of the oligosaccharide chain on RBC membrane glycolipids
B)an enzyme that adds a galactose to the end of the oligosaccharide chain on RBC membrane glycolipids
C)an enzyme that adds phospholipids to the end of the oligosaccharide chain on RBC membrane glycolipids
D)no enzymes capable of attaching galactose or N-acetylgalactosamine to the end of the oligosaccharide chain on RBC membrane glycolipids
E)both an enzyme that adds an N-acetylgalactosamine to the end of the oligosaccharide chain on RBC membrane glycolipids and an enzyme that adds a galactose to the end of the oligosaccharide chain on RBC membrane glycolipids

A)integral protein
B)lipid-anchored protein
C)peripheral protein
D)phosphatidylcholine
E)galactocerebroside

A)He could see the lipids in the microscope.
B)Membranes were destroyed by enzymes that degraded lipids.
C)More lipid-soluble solutes entered root hair cells faster than polar solutes.
D)Membranes dissolved in gasoline.
E)Membranes did not dissolve in water.

A)transporting solutes
B)providing a scaffold for biochemical activities
C)energy transduction
D)signal transition
E)signal transduction

A)compartmentalization
B)creating a selectively permeable barrier
C)mediating intercellular interactions
D)helping cells respond to external stimuli
E)all of these are correct choices

A)Protein W
B)Protein X
C)Protein Y
D)Protein Z

A)They are kept cold before use.
B)They are coated with carbohydrates.
C)They are given a synthetic polymer coating that protects them from immune destruction.
D)They are loaded with radioactive isotopes.
E)They are colored red.

A)glycerol + 2 phosphate groups + 1 fatty acid
B)glycerol + 1 phosphate group + 2 fatty acids
C)glycerol + 1 phosphate group
D)glycerol + 3 fatty acids
E)glycerol + 1 phosphate group + 3 fatty acids

A)amphoteric
B)ambidextrous
C)amphipathic
D)rings
E)straight

A)malformed glycolipids can cause neurological disease
B)mice with missing glycolipids had muscular tremors
C)they are the site at which bacterial toxins like those that cause botulism and cholera first bind cells
D)they are the site at which the influenza virus first binds a cell
E)all of these are correct

A)72 µm²
B)36 µm²
C)18 µm²
D)144 µm²
E)30 µm²

A)Protein W
B)Protein X
C)Protein Y
D)Protein Z

A)integral protein
B)lipid-anchored protein
C)peripheral proteins
D)transmembrane protein
E)both integral protein and transmembrane protein

A)an enzyme that adds an N-acetylgalactosamine to the end of the oligosaccharide chain on RBC membrane glycolipids
B)an enzyme that adds a galactose to the end of the oligosaccharide chain on RBC membrane glycolipids
C)an enzyme that adds phospholipids to the end of the oligosaccharide chain on RBC membrane glycolipids
D)no enzymes capable of attaching galactose or N-acetylgalactosamine to the end of the oligosaccharide chain on RBC membrane glycolipids
E)both an enzyme that adds an N-acetylgalactosamine to the end of the oligosaccharide chain on RBC membrane glycolipids and an enzyme that adds a galactose to the end of the oligosaccharide chain on RBC membrane glycolipids

A)They were not stable enough to last until their target destination.
B)Immune system phagocytes removed them from the bloodstream before they could exert an effect.
C)They could not hold water soluble and lipid soluble drugs.
D)They were targeted incorrectly.
E)They expanded osmotically and lysed before reaching their target.

A)about 10 amino acids
B)about 20 amino acids
C)at least 40 amino acids
D)about 2-3 amino acids
E)None of these are correct.

A)Nothing happens.
B)The membrane becomes less fluid.
C)The membrane becomes more fluid.
D)The membrane fluidity fluctuates back and forth from high to low.
E)The membrane fluidity fluctuates back and forth from low to high.

A)phospholipase
B)lipase
C)hydroxyurease
D)protease
E)trypsin

A)Lineweaver-Burk plot
B)Michaelis-Menten plot
C)hydrophilicity plot
D)hydropathy plot
E)titration plot

A)site-directed mutagenesis
B)site-directed hydropathy
C)hydropathy plots
D)electron paramagnetic resonance (EPR)spectroscopy
E)infrared spectroscopy

A)visualization in the electron microscope
B)observationwith a special stain in the light microscope
C)treatment of intact red blood cells with phospholipases
D)treatment of intact red blood cells with trypsin
E)treatment of liver cells with phospholipases

A)membrane budding
B)membrane fragmentation
C)membrane fusion
D)signal transduction and membrane fusion
E)both membrane budding and membrane fusion

A)cell movement
B)cell division
C)formation of intercellular junctions
D)endocytosis
E)all of these are correct

A)hydrophobicity
B)hydrophilicity
C)membrane fluidity
D)their amphipathic nature
E)their amphoteric nature

A)transition temperature
B)temperature optimum
C)transition series
D)pH optimum
E)gelation temperature

A)its structure
B)its orientation within the lipid bilayer
C)its concentration in each cell
D)both its structure and its orientation within the lipid bilayer

A)exclusively circular
B)predominantly hydrophilic
C)predominantly hydrophobic
D)predominantly antiparallel
E)totally parallel

A)site-directed mutagenesis
B)site-directed amenuensis
C)hydropathy plots
D)electron paramagnetic resonance (EPR)spectroscopy
E)infrared spectroscopy

A)both actin and spectrin
B)both actin and ankyrin
C)hemoglobin
D)spectrin
E)both ankyrin and spectrin

A)mechanical support for membrane
B)enzyme activity
C)receptor activity
D)anchor for integral proteins
E)factors that transmit transmembrane signals

A)phenylalanine
B)alanine
C)cysteine
D)methionine
E)proline

A)The glycolipids in the outer leaflet of the membrane may serve as receptors.
B)The presence of phosphatidylinositol primarily in the inner leaflet is involved in signal transduction.
C)The cell has the ability to maintain a charge differential in the two membrane leaflets.
D)Appearance of phosphatidylserine on the outer surface of aging lymphocytes marks them for destruction by macrophages.
E)Phosphatidylserine on the surface of platelets serves as a signal for blood solubilization.

A)hemophilia
B)sickle cell anemia
C)hemolytic anemias
D)leukemia
E)erythroblastosis

A)dehydrogenases
B)desaturases
C)phospholipases
D)acyltransferases
E)phospholipid synthesizing enzymes

A)macrodomains, phosphoglycerides
B)microdomains, integral proteins
C)microdomains, phosphoglycerides
D)liquid crystals, phosphoglycerides
E)liquid crystals, microdomains

A)negatively charged cholesterol
B)positively charged sphingolipids
C)negatively charged phospholipids
D)positively charged phospholipids
E)negatively charged sphingolipids

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

A)Mobility is unchanged.
B)Mobility is increased because the fences that normally restrict their diffusion are removed.
C)Mobility is decreased because the fences that normally restrict their diffusion are removed.
D)Mobility is increased because the treatment raises the temperature.
E)Mobility is decreased because the treatment lowers the temperature.

A)It moves at a much faster rate than the wild type protein.
B)It moves at a much slower rate than the intact protein.
C)It does not move at all.
D)It is not inserted into the membrane so nothing can be learned about their mobility.
E)It flips to the opposite leaflet.

A)lipid islands
B)collections
C)lipid rafts
D)lipid domains
E)dense bilayers

A)Flippases are enzymes which are transiently stable and expressed at low concentrations.
B)For flip-flop to occur, it would be necessary for the hydrophilic head of a phospholipid to move through the hydrophobic part of the bilayer, an extremely unlikely event.
C)For flip-flop to occur, it would be necessary for the hydrophobic head of a phospholipid to move through the hydrophilic part of the bilayer, an extremely unlikely event.
D)Other membrane activities like flexing and lateral shift inhibit phospholipid flip-flop.

A)denaturation
B)osmosis
C)diffusion
D)transport
E)defusion

A)The cell is half red and half green.
B)The red and green labels are uniformly distributed across the entire membrane.
C)The red and green labels are distributed in intermingled patches.
D)The cell appears to be yellow in color.
E)The cell appears to be brown in color.

A)diffusion
B)osmosis
C)denaturation
D)metabolism
E)solubility

A)Molecule AA with an octanol-water partition coefficient of 5
B)Molecule AB with an octanol-water partition coefficient of 0.5
C)Molecule AC with an octanol-water partition coefficient of 50
D)Molecule AD with an octanol-water partition coefficient of 0.05

A)They carry a relatively uniform positive charge distribution
B)They carry a relatively uniform negative charge distribution.
C)They are all the same molecular weight.
D)They are all the same size.
E)They all have the same degree of hydrophobicity.

A)glycophorin A
B)glycophorin D
C)band 3
D)glyceraldehyde 3-phosphate
E)alpha-actinin

A)It moves much greater distances than the intact protein.
B)It moves much smaller distances than the intact protein.
C)It does not move at all.
D)It is not inserted into the membrane so nothing can be learned about their mobility.
E)It flips to the opposite leaflet.

A)actin and tropomyosin
B)spectrin
C)band 3
D)ankyrin
E)all of these are correct

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

A)The cell is half red and half green.
B)The red and green labels are uniformly distributed across the entire membrane.
C)The red and green labels are distributed in intermingled patches.
D)The cell appears to be yellow in color.
E)The cell appears to be brown in color.

A)the presence of solid barriers
B)the presence of elastic barriers
C)the attachment of the proteins to the cytoskeleton
D)the attachment of the proteins to the endoplasmic reticulum
E)the presence of rubber in the membrane

A)FRAP
B)SPT
C)fluorescence recovery after photobleaching
D)optical tweezer manipulation
E)SDS-PAGE

A)the largest
B)the smallest
C)the most negative
D)the most positive
E)both the largest and the most negative

A)able to establish and maintain membrane lipid asymmetry
B)interact with neighboring epithelial cells, or the basal membrane
C)block post-synaptic membrane signals
D)transport proteins across the membrane
E)all of the above

A)Na⁺ ions, K⁺ ions
B)Na⁺ ions, glucose
C)glucose, Na⁺ ions
D)glucose, K⁺ ions
E)K⁺ ions, glucose

A)It must be pumped during the cycle.
B)It must be phosphorylated during the cycle.
C)It must be protonated during the cycle.
D)It must be methylated during the cycle.
E)It must be acetylated during the cycle.

A)the Na⁺/K⁺-ATPase
B)a gated Na⁺ pump
C)a voltage-gated Na⁺ channel
D)the ligand-gated Na⁺ channel
E)a voltage-gated Na⁺ facilitated transporter

A)the cell body
B)nodes of Ranvier
C)dendrites
D)axon terminals
E)neuron nucleus

A)opening of a voltage-gated K⁺ channel
B)opening of a voltage-gated Na⁺ channel
C)closing of a voltage-gated K⁺ channel
D)opening of a ligand-gated Na⁺ channel
E)opening of a voltage-gated K⁺ facilitated transporter

A)hyperpolarization
B)depolarization
C)termination
D)a refractory period
E)an action potential

A)via a direct connection
B)via a spark
C)via a neurotransmitter
D)via Na⁺ ions
E)via plasmodesmata

A)axon hillock
B)cell body
C)dendrites
D)axon
E)terminal knob

A)myasthenia gravis
B)multiple sclerosis
C)muscular dystrophy
D)diabetes mellitus
E)lupus erythematosus

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

A)saltatory
B)myelinated
C)rapid fire
D)jump stop
E)leap frog

A)conformational shifts
B)rigidity
C)softness
D) $\alpha$ -helix secondary structure
E) $\beta$ -pleated sheet secondary structure

A)negative, 3, 2
B)negative, 2, 3
C)positive, 3, 2
D)positive, 2, 3
E)negative, 4, 3

A)a full action potential
B)a partial action potential
C)no action potential
D)a proportional action potential
E)a reversal of the direction of the neural impulse

A)Dendrites
B)Axon
C)Axon hillock
D)Terminal knob
E)Cell body

A)an active antiport
B)an active uniport
C)a passive antiport
D)an active symport
E)a passive symport

A)excitation
B)irritability
C)irritation
D)irrigation
E)receptiveness

A)hyperpolarized, efflux, Na⁺
B)depolarized, influx, Na⁺
C)depolarized, influx, K⁺
D)hyperpolarized, influx, Na⁺
E)depolarized, efflux, Na⁺

A)axon hillock
B)cell body
C)dendrites
D)axon
E)terminal knob

A)a higher positive charge
B)a higher negative charge
C)the presence of an inactivating peptide in the opening of the channel pore
D)removal of a peptide from the channel protein
E)covalent addition of a peptide to the cytoplasmic end of the channel protein