Deck 13: Metabolism

A) glucose
B) NADH
C) pyruvate
D) ATP
E) citrate

A) oxidative phosphorylation
B) electron transport phosphorylation
C) membrane bound ATPase
D) substrate-level phosphorylation
E) the oxidation of NADH

A) By a coenzyme.
B) By covalent modification.
C) Through the binding of an effector molecule.
D) Through the binding of a competitive inhibitor.
E) By substrate binding.

A) electrons from NADH.
B) membrane-associated electron transport chain.
C) an ATP synthase.
D) phosphoenolpyruvate.
E) a proton motive force.

A) Uses inorganic carbon as an energy source and organic carbon as a carbon source.
B) Uses inorganic carbon as an electron source and organic carbon as a carbon source.
C) Uses organic carbon as an electron source and inorganic carbon as a carbon source.
D) Uses organic carbon as an electron source and a carbon source.
E) Uses inorganic carbon as an energy source and a carbon source.

A) is an endergonic reaction.
B) will require an input of energy.
C) is not a spontaneous reaction.
D) is an energy yielding reaction.
E) will absorb energy.

A) chemoorganoautotroph
B) chemoorganoheterotroph
C) photolithoheterotroph
D) photoorganoautotroph
E) photolithoautotroph

A) Oxidized ferredoxin to be a good electron donor.
B) Oxidized ferredoxin to be a good electron acceptor.
C) Reduced ferredoxin to be a good electron donor.
D) Reduced ferredoxin to be a good electron acceptor.
E) Cannot be determined without knowledge of the other reactant.

A) An oxidation/reduction reaction.
B) Oxidative phosphorylation.
C) Substrate-level phosphorylation.
D) An aldolase catalyzed reaction.
E) An electron transport reaction.

A) Two pyruvate, two ATP, and two NADH.
B) Two pyruvate, four ATP, and four NADH.
C) Two CO₂, four pyruvate, two ATP, and four NADH.
D) Two CO₂, two pyruvate, four ATP, and four NADH.
E) Two CO₂, two pyruvate, two ATP, and two NADH.

A) Oxygen is oxidized to water.
B) Oxygen is being reduced in the reaction.
C) Hydrogen is being reduced in the reaction.
D) The electron donor in this reaction is reduced.
E) The electron acceptor in this reaction is oxidized.

A) glucose
B) iron
C) NAD⁺
D) cytochrome c
E) a kinase

A) two ATP and two NADH
B) two ATP, two NADH, and two CO₂
C) four ATP and two NADH
D) two ATP and two CO₂
E) four ATP, two NADH, and two CO₂

A) ethanol
B) glucose
C) pyruvate
D) acetyl-CoA
E) 3-phosphoglyceraldehyde

A) inorganic molecules as energy sources and inorganic carbon as a carbon source.
B) organic molecules as electron sources and inorganic carbon as a carbon source.
C) organic molecules as energy sources and organic carbon as a carbon source.
D) inorganic molecules as electron sources and organic carbon as a carbon source.
E) inorganic molecules as energy sources and organic carbon as a carbon source.

A) one
B) two
C) four
D) six
E) ten

A) It is endergonic.
B) It has a positive ΔG⁰'.
C) It will require an input of energy.
D) It is spontaneous.
E) It is energetically unfavorable.

A) pyruvate, ribose-5-phosphate, and NADPH
B) NADPH, ribose-5-phosphate, and erythrose-4-phosphate
C) pyruvate, citrate, and erythrose-4-phosphate
D) pyruvate, erythrose-4-phosphate, and ribose-5-phosphate
E) citrate, NADPH, and ribose-5-phosphate

A) The reoxidation of NADH by an electron transport chain.
B) A process that occurs in the absence of oxygen.
C) An energy producing process found in all anaerobes.
D) The direct reoxidation of NADH by an internal organic molecule.
E) The use of a terminal electron acceptor other than oxygen.

A) light
B) CO₂
C) H₂S
D) H₂O
E) nitrate

A) A carotenoid molecule with an atom of iron in the center.
B) A porphyrin molecule with an atom of iron in the center.
C) A phycoerythrin with an atom of iron in the center.
D) A porphyrin molecule with an atom of magnesium in the center.
E) A phycoerythrin molecule with an atom of magnesium in the center.

A) amylases
B) proteases
C) reductases
D) dehydrogenases
E) lipases

A) A fermentation product is produced.
B) The terminal cytochrome oxidase is replaced by a cytochrome reductase.
C) Glucose is only partially oxidized to CO₂.
D) NADH dehydrogenase is replaced by NADH oxidase.
E) Glycolysis.

A) NADH oxidation, ATP synthesis, and flagella rotation
B) NADH oxidation, ATP synthesis, and nutrient transport
C) ATP synthesis, flagella rotation, and nutrient transport
D) NADH oxidation, flagella rotation, and nutrient transport
E) oxygen reduction and ATP synthesis

A) glucose and ATP
B) glucoseonly
C) ATPonly
D) glucose and NADPH
E) ATP and NADPH

A) Fermentation reactions.
B) Anaerobic respiration.
C) Electrons moving through an electron transport system to generate a proton motive force.
D) Glycolysis and TCA cycle reactions.
E) Using reduced inorganic molecules as electron acceptors for the electron transport system.

A) Calvin cycle
B) pentose phosphate pathway
C) Parnas pathway
D) β-oxidation pathway
E) reductive TCA pathway

A) NADH, ATP, CO₂, and oxaloacetate
B) NADH, FADH₂, and ATP
C) NADH, FADH₂, and oxaloacetate
D) NADH, FADH₂, CO₂, and ATP
E) NADH, FADH₂, CO₂, and oxaloacetate

A) nitrate (NO₃⁻)
B) sulfate (SO₄²⁻)
C) sulfur (S⁰)
D) ferric iron (Fe³⁺)
E) hydrogen sulfide (H₂S)

A) sulfur
B) glucose
C) water
D) carbon dioxide
E) nitrate

A) flavoproteins
B) iron-sulfur proteins
C) ATPase
D) quinones
E) cytochromes

A) cyanobacteria
B) cyanobacteria and purple non-sulfur bacteria
C) cyanobacteria and green sulfur bacteria
D) cyanobacteria, purple sulfur bacteria, and green sulfur bacteria
E) purple sulfur, purple non-sulfur, and green sulfur bacteria

A) an acetyl group + CO₂.
B) lactic acid
C) citrate
D) ethanol + CO₂
E) acetic acid and CO₂

A) cyclic photophosphorylation
B) the Calvin cycle
C) reverse electron flow
D) the reverse TCA cycle
E) the Parnas pathway

A) The electron transport system accepts electrons directly from glucose.
B) In bacteria, the electron transport system is located in the cytoplasm.
C) A proton motive force is generated as electrons move through the system to a terminal acceptor.
D) In prokaryotes, protons are transported into the cell as electrons move through the system.
E) ATP is produced by a process called substrate-level phosphorylation.

A) If an end product of the pathway binds to the allosteric site of the enzyme.
B) If a competitive inhibitor binds to the active site of the enzyme.
C) If the coenzyme fails to bind to the active site of the enzyme.
D) If an end product of the pathway binds to the active site of the enzyme.
E) If a noncompetitive inhibitor binds to the active site of the enzyme.

A) Substrate-level phosphorylation.
B) A proton motive force driven ATP synthase.
C) Electron driven NADPH synthase.
D) Carbon dioxide fixation.
E) Chlorophyll a.

A) In the cytoplasm.
B) In the periplasmic space.
C) Within a biological membrane.
D) Either in the cytoplasm or within a membrane.
E) Within the cell wall.

A) 430 nm and 662 nm
B) 550 nm
C) 750 nm and 850 nm
D) 900 nm
E) 800 nm and 950 nm

A) one
B) two
C) four
D) eight
E) sixteen

A) The reduction of nitrate to dinitrogen.
B) The production of nitrate from ammonia.
C) The reduction of dinitrogen to nitrate.
D) The assimilation of nitrate by the cell.
E) The assimilation of ammonia by the cell.

A) nitrate
B) nitrite
C) hydroxylamine
D) dinitrogen
E) nitric oxide

A) glycolysisonly
B) the TCA cycleonly
C) glycolysis and TCA cycle
D) the pentose phosphate pathway and glycolysis
E) glycolysis, TCA cycle, and the pentose phosphate pathway

A) glycine and glutamate
B) glycine and serine
C) glutamine and glutamate
D) glutamine and serine
E) serine and glutamate

A) energy generating reactions
B) carbon dioxide fixing reactions
C) glycolytic reactions
D) reducing power generating reactions
E) part of photosystem II

A) ribulose 1,5-bisphosphate carboxylase
B) ribulose 1,5-bisphosphate kinase
C) ribose 1,5-bisphosphate carboxylase
D) ribose 1,5-bisphosphate kinase
E) ribose 1,5-bisphosphate transcarboxylase

A) dinitrogen
B) nitrate
C) nitrite
D) ammonia
E) nitric oxide

A) The production of nitrate from ammonia.
B) The incorporation of nitrate into cellular material.
C) Anaerobic reduction of nitrate.
D) Nitrogen fixation.
E) The production of nitrate from nitrite.

A) fatty acids and sterol
B) fatty acids and glycerol
C) fatty acids and hopanoids
D) hopanoids and sterols
E) glycerol and hopanoids

A) The reduction of sulfate to elemental sulfur.
B) The reduction of sulfate for incorporation into cellular material.
C) The reduction of sulfate to sulfide for excretion by the cell.
D) A type of anaerobic respiration.
E) An energy yielding process.

A) carbon dioxide fixation
B) generation of reducing power
C) glucose breakdown
D) energy generation
E) respiration