Deck 13: Mitochondria, Chloroplasts, and Peroxisomes

A) Mitochondria, but not chloroplasts and peroxisomes
B) Chloroplasts, but not mitochondria and peroxisomes
C) Mitochondria and chloroplasts, but not peroxisomes
D) Mitochondria, chloroplasts, and peroxisomes

A) They produce most of the ATP derived from the breakdown of lipids and carbohydrates.
B) They produce all of the ATP derived from the breakdown of fatty acids.
C) They produce all of the ATP derived from the breakdown of carbohydrates.
D) They produce about 10% of the ATP derived from the sunlight.

A) cisternae.
B) cristae.
C) laminae.
D) lamellae.

A) stroma.
B) intermembrane space.
C) inner membrane space.
D) matrix.

A) Pyruvate
B) Acetate as acetyl CoA
C) Lactic acid
D) Citric acid

A) pyruvate; CO₂, NADH, and FADH₂
B) acetyl CoA; CO₂, NADH, and FADH₂
C) pyruvate; CO₂
D) pyruvate; NADH and FADH₂

A) both mitochondrial membranes.
B) the inner, but not the outer, mitochondrial membrane.
C) the outer, but not the inner, mitochondrial membrane.
D) neither mitochondrial membrane.

A) divide by fission.
B) fuse with one another.
C) be transported to areas of high energy use.
D) All of the above

A) porins.
B) aquaporins.
C) connexins.
D) claudins.

A) synthesize ATP.
B) pump protons.
C) transport pyruvate and fatty acids.
D) direct translocation.

A) outer membrane.
B) intermembrane space.
C) inner membrane.
D) matrix.

A) symbiosis.
B) phagocytosis.
C) endosymbiosis.
D) pinocytosis.

A) a single linear DNA molecule.
B) several linear DNA molecules.
C) several circular DNA molecules.
D) a single circular DNA molecule.

A) progenotes.
B) $\alpha$ -proteobacteria.
C) cyanobacteria.
D) purple sulfur bacteria.

A) no genes of their own.
B) genes for mitochondrial proteins.
C) genes for mitochondrial proteins and rRNAs.
D) genes for mitochondrial proteins, rRNAs, and tRNAs.

A) Some codons code for different amino acids.
B) There are no stop codons.
C) It accommodates less wobble.
D) All of the above

A) mitochondrial ribosomes.
B) mitochondrial DNA polymerases.
C) respiratory complexes and oxidative phosphorylation.
D) helicases.

A) maternal transmission.
B) paternal transmission.
C) random assortment.
D) Mendelian genetics.

A) Lou Gehrig's disease
B) Retinoblastoma
C) Leber's hereditary optic neuropathy
D) Crohn's disease

A) mitochondrial ribosomes from nuclear mRNAs.
B) cytoplasmic ribosomes; they are imported co-translationally as they are being synthesized.
C) cytoplasmic ribosomes; they are imported after they are completely synthesized.
D) mitochondrial ribosomes from mitochondrial mRNAs.

A) hydrophobic $\alpha$ helix.
B) hydrophobic random chain.
C) negatively charged $\alpha$ helix.
D) positively charged $\alpha$ helix.

A) twin brothers with the same mitochondrial disease.
B) chaperones.
C) protein translocators in mitochondrial membranes.
D) transporters of small molecules across the mitochondrial membranes.

A) signal peptidase.
B) presequence protease.
C) ubiquitin-targeted protease.
D) matrix processing peptidase.

A) through a transporter called Oxa translocase.
B) through Tim.
C) through Tim and Tom.
D) directly from the matrix into the lipid bilayer.

A) mitochondrial matrix.
B) mitochondrial intermembrane space.
C) ER.
D) Golgi apparatus.

A) Hsp70
B) Tim23
C) Tom
D) ATP

A) Tim9
B) Tim10
C) Tim22
D) Tom

A) an electrochemical gradient across the inner membrane.
B) a potassium gradient across the inner membrane.
C) ATP and a proton gradient across the inner membrane.
D) ATP and a potassium gradient across the inner membrane.

A) chemiosmotic gradient.
B) hydrolysis of ATP.
C) electrochemical gradient.
D) negative charge of small molecules.

A) Phosphatidylcholine
B) Cholesterol
C) Sphingolipid
D) Cardiolipin

A) do not generate ATP.
B) do not originate by endosymbiosis.
C) do not replicate by division.
D) synthesize their own amino acids and fatty acids.

A) have a porous outer membrane.
B) contain light sensitive pigments.
C) require presequence amino acids on proteins for import.
D) require folded cristae as the site of electron transport.

A) elaioplasts.
B) amino acids.
C) peroxisomes.
D) catalase.

A) 20
B) 150
C) 1,500
D) 3,000

A) all mRNA codons according to the universal code.
B) all the amino acids according to the universal code but have different stop codons.
C) some codons as amino acids that differ from the universal code but use the same stop codons.
D) some codons as amino acids that differ from the universal code and use some different stop codons.

A) free ribosomes in the cytosol.
B) RER membranes in the cytoplasm.
C) ribosomes bound to the outer chloroplast membrane.
D) ribosomes in the chloroplast stroma.

A) Tim and Tom.
B) Tic and Toc.
C) Sec and Tat.
D) import complexes.

A) in the thylakoid lumen.
B) in the stroma and transported across the thylakoid membrane.
C) on the outer chloroplast membrane and transported across the thylakoid membrane by way of its hydrophobic signal sequence.
D) in the cytosol, imported into the stroma, and transported across the thylakoid membrane by way of a second signal sequence.

A) chloroplasts.
B) chromoplasts.
C) amyloplasts.
D) elaioplasts.

A) chromoplasts.
B) etioplasts.
C) elaioplasts.
D) proplastids.

A) stores starch.
B) stores lipid.
C) is arrested in chloroplast development by lack of light.
D) stores pigment.

A) oxidize certain organic molecules and degrade the H₂O₂ produced by these reactions.
B) produce hydrogen peroxide for cells.
C) digest old organelles.
D) digest macromolecules taken up by endocytosis.

A) peroxidase
B) catalase
C) peroxigen
D) glyoxylate

A) Turner's syndrome
B) Zellweger syndrome
C) I-cell disease
D) Leber's hereditary optic neuropathy

A) free ribosomes in the cytosol.
B) RER membranes in the cytoplasm.
C) ribosomes bound to the outer peroxisome membrane.
D) ribosomes inside the peroxisome.

A) budding from the Golgi apparatus.
B) budding from preexisting peroxisomes.
C) de novo assembly from proteins synthesized in the cytosol.
D) budding of vesicles from the ER and growth and division of preexisting peroxisomes.

A) contain enzymes specific to their function.
B) contain their own genomes.
C) do not contain proteins that are imported from the cytosol.
D) are not membrane-bounded.

A) The mitochondrial matrix
B) The cytoplasm
C) The outer mitochondrial membrane
D) The inner mitochondrial membrane