Deck 8: Energy-Releasing Pathways

A)the heat produced is used to drive biological reactions.
B)the oxygen in the compounds that are broken apart is used as an energy source.
C)the energy released is channeled into molecules of ATP.
D)ATP is converted into ADP.
E)ADP is released as a waste product.

A)oxygen
B)sulfur
C)nitrogen
D)magnesium
E)phosphorus

A)can be produced by photosynthesis.
B)is produced in the degradation of organic compounds such as glucose.
C)is generated in anaerobic respiration.
D)is formed in aerobic respiration.
E)does all of these.

A)high oxygen consumption.
B)constant fever.
C)flushed skin.
D)weakness.
E)all of these.

A)is the reverse of the process of photosynthesis.
B)involves the physical exchange of gases.
C)is a mechanism of tapping the energy found in the bonds between atoms in organic compounds.
D)can occur only if there is a supply of glucose available because no other compound can be the energy source for cellular respiration.
E)occurs only in animal cells.

A)photosynthetic enzymes and ATP.
B)CO₂ and H₂O.
C)iron and glucose.
D)NAD and FAD
E)none of these.

A)generate ATP.
B)utilize oxygen.
C)have a well-defined nucleus.
D)produce carbon dioxide.
E)generate ATP and respire.

A)one ATP molecule
B)two ATP
C)three ATP
D)one ATP molecule must be taken away from glucose
E)four ATPs

A)cAMP
B)ADP
C)ATP
D)glucose
E)NADPH

A)the energy currency of a cell.
B)produced by the destruction of ADP.
C)produced but not expended in the process of photosynthesis.
D)produced during the phosphorylation of any organic compound.
E)none of these.

A)photosynthetic
B)cytoplasm
C)mitochondria
D)the Krebs cycle
E)gap junction

A)Marfan's syndrome.
B)Friedrich's ataxia.
C)type I diabetes.
D)Alzheimer's disease.
E)all of these.

A)aerobic respiration
B)anaerobic respiration
C)alcoholic fermentation
D)lactate fermentation
E)all liberate the same amount, but through different means

A)hydrogen
B)carbon
C)oxygen
D)H₂O
E)NAD⁺

A)high oxygen consumption.
B)constant fever.
C)flushed skin.
D)abnormally shaped mitochondria.
E)low number of mitochondria

A)printed currency
B)checks
C)credit
D)gold reserves
E)automated tellers

A)loss of coordination.
B)iron buildup in mitochondria.
C)serious heart problems.
D)abnormally shaped mitochondria.
E)weak muscles.

A)photosynthesis.
B)ATP production.
C)glucose breakdown.
D)aerobic respiration.
E)all of these.

A)I >>> II >>> III.
B)II >>> I >>> III.
C)III >>> I >>> II.
D)II >>> III >>> I.
E)I >>> III >>> II.

A)phosphoglycerate (PGA)
B)phosphoenol pyruvate (PEP)
C)phosphoglyceraldehyde (PGAL)
D)fructose bisphosphate
E)all of these

A)PEP
B)PGAL
C)fructose-1,6-biphosphate
D)pyruvate
E)phosphoglycerate (PGA)

A)occurs during glycolysis.
B)requires the presence of oxygen.
C)is a precursor for the phosphorylation of glucose.
D)is the source for the majority of the ATP produced in aerobic respiration.
E)does not occur during the Krebs cycle.

A)1
B)2
C)4
D)36
E)38

A)ribosomes.
B)cytoplasm.
C)nucleus.
D)mitochondria.
E)chloroplasts.

A)NADP.
B)pyruvate.
C)NAD⁺.
D)NADH.
E)H₂O.

A)a dividend
B)a credit
C)a debt
D)an investment
E)liquidity

A)in the mitochondrion and ER, respectively.
B)in separate parts of the mitochondrion.
C)inside and outside the mitochondrion, respectively.
D)in the same mitochondrial compartment.
E)cytoplasmic reactions.

A)substrate-level phosphorylation occurs.
B)oxaloacetate is regenerated.
C)electrons and H⁺ are transferred to coenzymes NAD⁺ and FAD.
D)molecules of carbon dioxide are formed.
E)all of these occur.

A)phosphoglycerate
B)pyruvate
C)oxaloacetate
D)PGAL
E)fructose bisphosphate

A)energy.
B)carbon dioxide.
C)oxygen.
D)hydrogen.
E)all except oxygen.

A)substrate.
B)coenzyme.
C)the electron transfer chain.
D)ATP.
E)the Krebs cycle.

A)acetyl-CoA.
B)oxaloacetate.
C)pyruvate.
D)citrate.
E)acetyl-CoA and oxaloacetate.

A)glycolysis.
B)acetyl-CoA formation.
C)fermentation.
D)the Krebs cycle.
E)the citric acid cycle.

A)occurs in the mitochondria.
B)happens to glucose only.
C)results in the production of pyruvate.
D)occurs in the cytoplasm.
E)results in the production of pyruvate and occurs in the cytoplasm.

A)glycolysis
B)ethanol production
C)acetyl-CoA formation
D)the Krebs cycle
E)glycolysis and the Krebs Cycle

A)PGAL.
B)pyruvate.
C)acetyl-CoA.
D)lactate.
E)acetaldehyde.

A)phosphoglyceraldehyde (PGAL)
B)oxaloacetate
C)phosphoglycerate (PGA)
D)pyruvate
E)citrate

A)photolysis.
B)glycolysis.
C)oxidative phosphorylation.
D)substrate-level phosphorylation.
E)the Krebs cycle.

A)anaerobic respiration.
B)photophosphorylation.
C)the electron transfer chain.
D)substrate-level phosphorylation.
E)the Krebs cycle.

A)pyruvate.
B)acetyl-CoA.
C)fructose bisphosphate.
D)oxaloacetate.
E)citrate.

A)pyruvate.
B)acetyl-CoA.
C)fructose bisphosphate.
D)oxaloacetate.
E)citrate.

A)2
B)3
C)4
D)6
E)either 2 or 3

A)pyruvate
B)acetyl-CoA
C)hydrogen ions
D)electrons
E)oxygen

A)calcium
B)hydrogen
C)oxygen
D)phosphorus
E)sodium

A)4 NADH.
B)1 FADH₂.
C)1 ATP.
D)3 CO₂.
E)all of these.

A)pyruvate
B)acetyl-CoA
C)hydrogen ions
D)electrons
E)NADH

A)NAD⁺
B)FAD
C)oxygen, O₂
D)water
E)all of these

A)NAD⁺.
B)CO₂.
C)ADP.
D)NADP⁺.
E)O₂.

A)carbon atoms.
B)oxygen atoms.
C)hydrogen atoms.
D)phosphorus atoms.
E)water molecules.

A)oxygen.
B)acetyl CoA.
C)FADH.
D)CO_2..
E)NADPH.

A)on the inner membrane of the mitochondria.
B)on the inner membrane of the chloroplasts.
C)in the fluid part of the chloroplast.
D)throughout the cytoplasm of the cell.
E)on the plasma membrane of eukaryotes.

A)TPN.
B)NADP⁺.
C)NAD⁺.
D)FAD.
E)cytochrome oxidase.

A)glycolysis.
B)acetyl-CoA formation.
C)the Krebs cycle.
D)substrate-level phosphorylation.
E)electron transfer phosphorylation.

A)NAD⁺
B)FAD⁺
C)ADP
D)NADH
E)NADP⁺

A)glycolysis.
B)alcoholic fermentation.
C)anaerobic electron transfer.
D)electron transfer phosphorylation.
E)the Krebs cycle.

A)glycolysis
B)acetyl-CoA formation
C)the Krebs cycle
D)electron transfer phosphorylation
E)substrate-level phosphorylation

A)acetyl-CoA formation
B)conversion of PGAL to PGA
C)regeneration of reduced NAD⁺
D)oxidative phosphorylation
E)substrate-level phosphorylation

A)2
B)3
C)4
D)6
E)12

A)liver
B)heart
C)kidney
D)liver and heart
E)liver, heart, and kidney

A)Candida albicans.
B)Lactobacillus acidophilus.
C)Saccharomyces cerevisiae.
D)Pseudomonas aeruginosa.
E)Giardia lamblia.

A)Oxygen can't pick up electrons.
B)No more water will be formed.
C)No more ATP will be formed.
D)The affected individual will not survive.
E)All of these are a consequence.

A)slow-twitch fibers.
B)fibrous connective tissue.
C)polymerated red blood cells.
D)fast-twitch fibers.
E)a mixture of slow- and fast-twitch muscles.

A)may occur in a muscle under anaerobic conditions.
B)produces more ATP than is liberated in the hydrogen transfer series.
C)breaks down glucose in reaction with oxygen.
D)is restricted to yeasts.
E)does none of these.

A)Hemoglobin
B)Mitochondria
C)Myoglobin
D)Fermentation
E)None of these

A)the guts of farm animals.
B)swamps.
C)mountain streams.
D)sediments of lakes and oceans.
E)canned goods.

A)aerobic fermentation.
B)aerobic respiration.
C)anaerobic muscle recovery.
D)anaerobic fermentation.
E)none of these.

A)carbon dioxide.
B)oxygen.
C)glucose.
D)water.
E)ATP.

A)pyruate; NADH; Lactic acid.
B)pyruvate; Lactic acid; NADH.
C)lactic acid; FADH; pyruvate.
D)lactate; pyruvate; ATP.
E)none of these.

A)SO₂
B)H₂
C)H₂SO₄
D)S
E)SO₄

A)CO₂ will be one of the products as pyruvate is converted to lactate.
B)the two NADH molecules produced during glycolysis will (depending on the organism) be used to reduce pyruvate to either lactate or ethanol and CO₂.
C)ATP will be required to convert pyruvate to either lactate or ethanol and CO₂.
D)oxidative phosphorylation occurs either on the plasma membrane or on derivatives of the plasma membrane.
E)none of these will occur.

A)4
B)2
C)3
D)32
E)0

A)ethyl alcohol.
B)acetaldehyde.
C)pyruvate.
D)lactate.
E)citrate.

A)pale color
B)many mitochondria
C)form ATP only by aerobic respiration
D)operate during marathon runs
E)found in abundance in migrating ducks

A)temporary.
B)due to oxygen deficiency.
C)an NAD⁺ regenerator.
D)temporary and due to oxygen deficiency.
E)temporary, due to oxygen deficiency, and an NAD₊ regenerator.

A)ethyl alcohol.
B)acetaldehyde.
C)pyruvate.
D)lactate.
E)citrate.

A)acetaldehyde
B)carbon dioxide
C)NADH
D)acetaldehyde and carbon dioxide only
E)acetaldehyde, carbon dioxide, and NADH

A)slow-twitch fibers
B)fibrous connective tissue
C)polymerated red blood cells
D)fast-twitch fibers
E)all of these

A)slow-twitch fibers
B)fibrous connective tissue
C)polymerated red blood cells
D)fast-twitch fibers
E)all of these