Deck 4: A Tour of the Cell

A) ribosomes, nuclei, mitochondria
B) chloroplasts, ribosomes, pieces of membrane
C) nucleus, ribosomes, chloroplasts
D) nucleus, mitochondria, ribosomes

A) Prokaryotes are unlikely to be able to secrete proteins because they lack an endomembrane system.
B) The mechanism of protein secretion in prokaryotes is probably the same as that in eukaryotes.
C) Proteins that are secreted by prokaryotes are synthesized on ribosomes that are bound to the cytoplasmic surface of the plasma membrane.
D) In prokaryotes, the ribosomes that are used for the synthesis of secreted proteins are located outside of the cell.

A) the relative size and weight of the component.
B) the relative solubility of the component.
C) how hydrophobic the component is.
D) the carbohydrate composition of the component.

A) Diffraction of light by a light microscope distorts the image.
B) Contrast is enhanced by staining with atoms of heavy metal.
C) Electron beams have much shorter wavelengths than visible light.
D) TEM is used to visualize very thin sections of cells.

A) plant cells are capable of having a much higher surface-to-volume ratio than animal cells.
B) plant cells have a much more highly convoluted (folded) plasma membrane than animal cells.
C) plant cells contain a large vacuole that reduces the volume of the cytoplasm.
D) animal cells are spherical, whereas plant cells are elongated.

A) lipids
B) glycogen
C) proteins
D) cellulose
E) nucleic acids

A) Bacteria and Eukarya
B) Bacteria and Protista
C) Archaea and Protista
D) Bacteria and Archaea

A) the loss of all nuclear function
B) the inability of the nucleus to divide during cell division
C) a change in the shape of the nucleus
D) closure of nuclear pores disrupting transport of materials into and out of the nucleus
E) inability of the nucleus to keep out destructive chemicals

A) standard light microscopy
B) super-resolution microscopy
C) transmission electron microscopy
D) scanning electron microscopy

A) phase-contrast light microscope.
B) scanning electron microscope.
C) transmission electronic microscope.
D) confocal fluorescence microscope.

A) smooth ER
B) lysosomes
C) rough ER
D) Golgi vesicles
E) free cytoplasmic ribosomes

A) specimen preparation for light microcopy does not produce artifacts.
B) light microscopy provides for higher resolving power than transmission electron microscopy.
C) light microscopy provides for higher magnification than transmission electron microscopy.
D) light microscopy allows one to view dynamic processes in living cells.

A) lysosomes
B) cytoplasm
C) nuclear envelope
D) Golgi apparatus
E) rough ER

A) producing primarily proteins for secretion.
B) producing primarily cytoplasmic proteins.
C) producing primarily cell wall or extracellular matrix components.
D) producing primarily an abundance of new membranes.
E) enlarging its vacuole.

A) sort cells based on their size and weight.
B) visualize the 3-D structure of cell membranes.
C) isolate organelles to examine their biological functions.
D) examine the distribution of organelles within the cell.

A) microtubules.
B) chloroplasts.
C) ribosomes.
D) nuclear pores.

A) rough ER
B) smooth ER
C) Golgi apparatus
D) nuclear envelope
E) lysosomes

A) cell wall
B) mitochondria
C) chloroplast
D) nucleoid
E) capsule

A) DNA
B) flagella
C) plasma membrane
D) ribosomes
E) endoplasmic reticulum

A) only in the nucleus.
B) only in the nucleus and mitochondria.
C) only in the nucleus and rough ER.
D) in the nucleus, mitochondria, and rough ER.

A) plasma membrane proteins
B) extracellular matrix proteins
C) secreted proteins
D) mitochondrial proteins

A) ribosomal proteins
B) soluble cytosolic proteins
C) mitochondrial proteins
D) lysosomal proteins

A) mitochondria
B) lysosomes
C) central vacuoles
D) peroxisomes

A) lysosome
B) vacuole
C) mitochondrion
D) Golgi apparatus
E) peroxisome

A) only nuclei
B) only mitochondria
C) nuclei and chloroplasts
D) nuclei and lysosomes

A) lysosome
B) peroxisome
C) mitochondrion
D) Golgi apparatus

A) It has a double membrane structure.
B) It is not involved in protein synthesis.
C) It produces a special class of transport vesicles.
D) It is not derived from the endoplasmic reticulum or Golgi.

A) plasma membrane
B) chloroplasts
C) mitochondria
D) nuclear envelope

A) vacuoles.
B) chloroplasts.
C) mitochondria.
D) lysosomes.
E) nucleoli.

A) the endoplasmic reticulum
B) the Golgi apparatus
C) the lysosome
D) mitochondrion

A) rough ER
B) vacuole
C) mitochondrion
D) Golgi apparatus
E) peroxisome

A) ribosome
B) lysosome
C) smooth endoplasmic reticulum
D) mitochondrion

A) only in the nucleus
B) only in the nucleus and mitochondria
C) only in the nucleus and chloroplasts
D) in the nucleus, mitochondria, and chloroplasts

A) lysosome
B) vacuole
C) mitochondrion
D) Golgi apparatus
E) peroxisome

A) peroxisomes
B) Golgi apparatus
C) plastids
D) nuclei

A) detoxification of toxins
B) protein modification and sorting
C) synthesis of cytoplasmic proteins
D) assembly of ribosomal subunits

A) ribosomes
B) chloroplasts
C) mitochondria
D) nuclear envelope

A) a bacterium.
B) an animal, but not a plant.
C) an archaeal or eukaryotic organism.
D) any eukaryotic organism.

A) the transport and exchange of membrane lipids among organelles of the endomembrane system by small membrane vesicles.
B) the function of the Golgi apparatus in modifying, sorting, and directing membrane components to their final destinations.
C) the modification of membrane components once they reach their final destination.
D) the synthesis of different lipids and proteins in each of the organelles of the endomembrane system.

A) extracellular matrix
B) gap junctions
C) tight junctions
D) middle lamella
E) desmosomes

A) in the cytoplasm
B) on the nucleoid membrane
C) on the endoplasmic reticulum
D) on the plasma membrane

A) form cleavage furrows during cell division.
B) migrate by amoeboid movement.
C) separate chromosomes during cell division.
D) extend pseudopods.
E) maintain the shape of the nucleus.

A) gap junctions
B) cellulose fibers
C) integrins
D) plasmodesmata

A) cell walls
B) gap junctions
C) tight junctions
D) middle lamella
E) desmosomes

A) combine the hydrogen with water molecules to generate hydrogen peroxide.
B) combine the hydrogen with hydrogen peroxide to generate water.
C) combine the hydrogen with hydrogen peroxide to generate oxygen and water.
D) combine the hydrogen with oxygen molecules to generate hydrogen peroxide.

A) They have pores that regulate the exchange of water and small molecules between cells and their environment.
B) They are composed of complex mixtures of lipids and carbohydrates.
C) They provide a rigid structure that prevents the uptake of excess water into cells.
D) They are constructed of polymers that are synthesized in the cytoplasm and then transported out of the cell for assembly.

A) mitochondria
B) microtubules
C) Golgi apparatus
D) centrosomes
E) peroxisomes

A) perform amoeboid movement.
B) form cleavage furrows.
C) contract muscle fibers.
D) extend pseudopodia.
E) move vesicles around the cell.

A) endosymbiosis of an oxygen-using bacterium in a larger host cell-the endosymbiont evolved into mitochondria.
B) endosymbiosis of an oxygen-using photosynthetic bacterium in a larger host cell-the endosymbiont evolved into mitochondria.
C) endosymbiosis of an oxygen-using scavenger bacterium in a larger host cell-the endosymbiont evolved into lysosomes.
D) evolution of an endomembrane system and subsequent evolution of mitochondria from a portion of the Golgi.

A) Transport vesicles move between organelles of the endomembrane system independently from the cytoskeleton.
B) Microfilaments are structurally rigid and resist compression, whereas microtubules resist tension (stretching).
C) Movement of cilia and flagella is the result of motor proteins causing microtubules to move relative to each other.
D) Chemicals that block the assembly of the cytoskeleton would cause little effect on the cell's response to external signals and stimuli.

A) microtubules and motor proteins
B) actin filaments and microtubules
C) actin filaments and motor proteins
D) centrioles and motor proteins

A) laminin
B) tubulin
C) actin
D) myosin

A) plasma membrane → primary cell wall → cytoplasm → vacuole
B) secondary cell wall → plasma membrane → primary cell wall → cytoplasm → vacuole
C) primary cell wall → plasma membrane → cytoplasm → vacuole
D) primary cell wall → plasma membrane → lysosome → cytoplasm → vacuole
E) primary cell wall → plasma membrane → cytoplasm → secondary cell wall → vacuole

A) plasma membrane → transport vesicle → Golgi → transport vesicle → rough ER
B) Golgi → rough ER → transport vesicle → plasma membrane
C) rough ER → transport vesicle → lysosome → transport vesicle → plasma membrane
D) rough ER → transport vesicle → Golgi → transport vesicle → plasma membrane
E) rough ER → transport vesicle → Golgi → transport vesicle → lysosome → plasma membrane

A) peroxisomes
B) desmosomes
C) gap junctions
D) extracellular matrix
E) tight junctions

A) motile cilia centrioles
B) centrioles only
C) both eukaryotic and bacterial flagella
D) eukaryotic flagella only
E) eukaryotic flagella and motile cilia

A) Cilia and flagella are derived from the centrioles.
B) Motor proteins such as dynein must have evolved before any of these four kinds of structures.
C) Centrioles are derived from cilia and/or flagella.
D) Natural selection for cell motility repeatedly selected for microtubular arrays in circular patterns in the evolution of each of these structures.

A) nuclear lamina
B) nuclear lamina and extracellular matrix.
C) smooth ER and Golgi apparatus.
D) Golgi apparatus and extracellular matrix.

A) the nuclear envelope
B) membrane proteins
C) the extracellular matrix
D) cytoskeletal structures
E) cellulose fibers in the cell wall

A) microtubule; muscle contraction
B) ribosome; protein synthesis
C) Golgi; protein trafficking
D) nucleolus; production of ribosomal subunits

A) plasmodesmata.
B) intermediate filaments.
C) tight junctions.
D) desmosomes.
E) gap junctions.

A) transmission electron microscopy
B) cell fractionation
C) light microscopy using stained sections of kidney tissue
D) light microscopy of living unstained material
E) scanning electron microscopy

A) microfilaments and intracellular vesicle transport
B) microtubules and cleavage furrow formation
C) microfilaments and flagellar motility
D) intermediate filaments and cytoplasmic streaming
E) microtubules and chromosome movement

A) fibronectin.
B) proteoglycans.
C) integrins.
D) collagen.
E) middle lamella.

A) mitochondrion
B) ribosome
C) nuclear envelope
D) chloroplast

A) muscle cell
B) nerve cell
C) phagocytic white blood cell
D) bacterial cell

A) mitochondria.
B) ribosomes.
C) peroxisomes.
D) lysosomes.

A) Cell membranes do not distinguish the types of ions and molecules passing through them.
B) Large molecules, such as proteins and RNA molecules, do not readily get through one, much less two, adjacent cell membranes.
C) Cell-to-cell communication requires physical attachment of one cell to another.
D) Maintenance of tissue integrity and barriers to fluid leakage requires cells to adhere tightly to one another.

A) the ultrastructure of the two livers is very similar.
B) the liver of the non-drinker has expansive rough ER compared to the alcoholic's liver.
C) the liver of the alcoholic has expansive smooth ER compared to the non-drinker's liver.
D) the liver of the alcoholic has substantially more lysosomes than the non-drinker's liver.

A) mitochondria and chloroplasts.
B) chloroplasts and peroxisomes.
C) peroxisomes and chloroplasts.
D) chloroplasts and mitochondria.
E) mitochondria and peroxisomes.

A) The ad agency is misrepresenting the ability of the toy microscope to magnify.
B) The toy microscope does not have the same fine control for focus of the specimen.
C) The toy microscope has good magnification, but has low resolution and therefore poor-quality images.
D) The college microscope produces greater contrast in the specimens.

A) chloroplast
B) wall made of cellulose
C) mitochondrion
D) centriole

A) ER → Golgi → nucleus
B) nucleus → ER → Golgi
C) ER → Golgi → vesicles that fuse with plasma membrane
D) ER → lysosomes → vesicles that fuse with plasma membrane

A) nuclear envelope
B) chloroplast
C) Golgi apparatus
D) plasma membrane