Deck 7: Inside the Cell

A) primarily producing proteins for secretion
B) primarily producing proteins in the cytosol
C) constructing an extensive cell wall or extracellular matrix
D) digesting large food particles
E) enlarging its vacuole

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

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

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

A) DNA
B) a cell wall
C) a plasma membrane
D) ribosomes
E) an endoplasmic reticulum

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

A) endosymbiosis of an aerobic bacterium in a larger host cell-the endosymbiont evolved into mitochondria
B) anaerobic archaea taking up residence inside a larger bacterial host cell to escape toxic oxygen-the anaerobic bacterium evolved into chloroplasts
C) an endosymbiotic fungal cell evolving into the nucleus
D) acquisition of an endomembrane system and subsequent evolution of mitochondria from a portion of the Golgi apparatus

A) DNA
B) a cell wall
C) a mitochondrion
D) a plasma membrane

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

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

A) the endoplasmic reticulum
B) the Golgi apparatus
C) the lysosome
D) mitochondrion
E) membrane-bound ribosomes

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

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

A) vacuoles
B) chloroplasts
C) mitochondria
D) lysosomes
E) nuclei

A) Transport vesicles fuse with one side of the Golgi and leave from the opposite side.
B) Proteins in the membrane of the Golgi may be sorted and modified as they move from one side of the Golgi to the other.
C) Lipids in the membrane of the Golgi may be sorted and modified as they move from one side of the Golgi to the other.
D) Soluble proteins in the cisternae (interior) of the Golgi may be sorted and modified as they move from one side of the Golgi to the other.
E) All of the listed responses correctly describe polarity characteristics of the Golgi function.

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

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) failure of chromosomes to carry genetic information
E) inability of the ribosomes to produce proteins

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

A) a membrane-enclosed nucleus
B) mitochondria
C) the endoplasmic reticulum
D) the nucleoid
E) ribosomes

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

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
E) in the nucleus, mitochondria, chloroplasts, and peroxisomes

A) mitochondria
B) ribosomes
C) peroxisomes
D) lysosomes
E) endoplasmic reticulum

A) Prokaryotes have cells but eukaryotes do not.
B) Eukaryotic cells have more intracellular organelles than prokaryotes.
C) Prokaryotes are not able to carry out aerobic respiration, relying instead on anaerobic metabolism.
D) Prokaryotes are generally larger than eukaryotes.

A) deposit end-products of digestion in the endoplasmic reticulum
B) facilitate movement between stacks of the Golgi
C) are formed from products synthesized by the endoplasmic reticulum and processed by the Golgi
D) are composed largely of phospholipids

A) It is too large.
B) It lacks a nuclear localization signal (NLS).
C) It contains errors in its amino acid sequence.
D) It lacks a signal sequence.

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

A) No ribosomes are attached to its surface.
B) There is no supply of free amino acids that it can easily access.
C) It stores calcium, which is a known inhibitor of protein synthesis.
D) It has no DNA to direct synthesis of proteins.

A) lysosomes
B) Golgi apparatus
C) ribosomes
D) mitochondria

A) a bacterium
B) an animal but not a plant
C) nearly any eukaryotic organism
D) a plant but not an animal
E) any kind of prokaryotic organism

A) play a role in storage
B) synthesize large quantities of lipids
C) actively export protein molecules
D) import and export protein molecules

A) interconnection of most intracellular membranes to the nuclear envelope
B) transportation of membrane lipids among the membranes of the endomembrane system by small membrane vesicles
C) function of the Golgi apparatus in sorting and directing membrane components
D) modification of the membrane components once they reach their final destination
E) synthesis of different lipids and proteins in each of the organelles of the endomembrane system

A) DNA
B) amino acids
C) mRNA
D) phospholipids

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

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

A) in the extracellular matrix
B) in the Golgi apparatus
C) in lysosomes
D) in mitochondria
E) in the nucleolus

A) It regulates the movement of proteins and RNAs into and out of the nucleus.
B) It synthesizes the proteins required to copy DNA and make mRNA.
C) It selectively transports molecules out of the nucleus but prevents all inbound molecules from entering the nucleus.
D) It assembles ribosomes from raw materials that are synthesized in the nucleus.

A) lysosomes
B) Golgi apparatus
C) ribosomes
D) mitochondria

A) view the structure of cell membranes
B) sort cells based on their size and weight
C) determine the size of various organelles
D) separate the major organelles
E) separate lipid-soluble from water-soluble molecules

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) signal sequences (peptides)
B) random transport vesicles
C) attachment of ribosomes to outer mitochondrial pores and direct deposition into the inner mitochondrial compartment
D) mRNAs that are manufactured in the nucleus but translated by mitochondrial ribosomes

A) conformational changes in ATP that thrust microtubules laterally
B) a motor protein called radial spokes
C) the quick inward movements of water by osmosis
D) a motor protein called dynein

A) on the outside of vesicles
B) on the inside surface of the cell membrane
C) on the inside surface of the vesicle
D) on the outer surface of the nucleus
E) on the ER

A) growth of actin filaments to form bulges in the plasma membrane
B) setting up microtubule extensions that vesicles can follow in the movement of cytoplasm
C) reinforcing the pseudopod with intermediate filaments
D) cytoplasmic streaming

A) Kinesin has two intertwined polypeptides that make up the stalk and enable it to contract and shorten.
B) Kinesin has a tail region that binds to vesicles and two heads that can attach to microtubules.
C) The kinesin tail has an ATP binding site to fuel its activities.
D) Kinesin has two heads to attach to the vesicle being moved and a tail region that attaches to microtubules.

A) adding radiolabeled actin subunits to a mixture of actin filaments in which conditions are favorable for polymerization
B) adding radiolabeled actin subunits to a mixture of actin filaments in which conditions favor depolymerization
C) determining the ionic charge of the ends of the actin filaments

A) Cilia and flagella arise from centrioles.
B) Loss of basal bodies should prevent cells from dividing in two.
C) Motor proteins such as dynein must have evolved before any of these four kinds of structure.
D) Cilia and flagella evolved separately in the same ancestral eukaryotic organism.
E) Natural selection for cell motility repeatedly selected for microtubular arrays in circular patterns in the evolution of each of these structures.

A) The cytoskeleton of eukaryotes is a static structure most resembling scaffolding used at construction sites.
B) Although microtubules are common within a cell, actin filaments are rarely found outside of the nucleus.
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 have little effect on a cell's response to external stimuli.
E) The cytoskeleton is produced by transport vesicles of the endomembrane system.

A) abnormally shaped RBCs
B) an insufficient supply of ATP in the RBCs
C) an insufficient supply of oxygen-transporting proteins in the RBCs
D) adherence of RBCs to blood vessel walls, causing plaque formation

A) Ribosomes attached to the endoplasmic reticulum require fewer amino acids to function.
B) The 20 amino acids serve as a signal (peptide) sequence that directs the forming polypeptides to the endoplasmic reticulum, where they are cleaved off during processing.
C) The 20-amino-acid sequence helps the endoplasmic reticulum package these proteins for shipping to the Golgi.
D) The protein has a different function in the cytosol than in the endoplasmic reticulum.

A) an axon
B) contractile microfilaments
C) endoplasmic reticulum
D) motor proteins

A) They initially contain signal sequences that allow their entrance into the endoplasmic reticulum.
B) They are manufactured on free ribosomes in the cytoplasm.
C) They are glycosylated in the Golgi apparatus.
D) They travel to the nucleus in a transport vesicle with a specific signal.

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

A) receive "modified" enzymes and are thus unable to break down carbohydrates
B) do not receive enzyme shipments from the Golgi apparatus
C) have unstable membranes
D) stick to transport vesicles and impede the transfer of enzymes

A) the portion of the molecule that binds to the vesicle being transported
B) the stalk
C) the portion of the molecule that binds to the microtubular track along which the vesicle is being transported
D) a location midway between the vesicle binding site and the portion of the molecule that binds to microtubular tracks

A) Microfilaments form the nuclear lamina.
B) Microtubules help animal cells divide in two.
C) Microfilaments cause ciliary bending.
D) Intermediate filaments contribute to cytoplasmic streaming.
E) Microtubules move chromosomes.

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

A) nucleolus-production of ribosomal subunits
B) lysosome-intracellular digestion
C) ribosome-protein synthesis
D) Golgi-protein trafficking
E) microtubule-muscle contraction

A) tubulin
B) laminin
C) actin
D) intermediate filaments
E) secretory vesicles

A) mitochondria and chloroplasts
B) membrane proteins of the inner nuclear envelope
C) free ribosomes and ribosomes attached to the ER
D) components of the cytoskeleton
E) cellulose fibers in the cell wall