Deck 22: Metabolic Pathways for Carbohydrates

A) use oxidation but not reduction.
B) break down large molecules into smaller ones.
C) take place in the mitochondria.
D) use energy.
E) give off energy.

A) inorganic phosphate.
B) inert pyrophosphate.
C) insoluble phosphate.
D) isomers of phosphate.
E) irreversible phosphorylation.

A) acetyl CoA is produced.
B) monomers are produced from macromolecules.
C) macromolecules are made from monomers.
D) glycogen is converted to glucose.
E) excess nutrients are stored as fats.

A) They are more complex than eukaryotic cells.
B) They are larger than eukaryotic cells.
C) They contain mitochondria.
D) They are found in animals.
E) They do not contain a nucleus.

A) sucrose.
B) glucose phosphate.
C) adenosine triphosphate.
D) ribonucleic acid.
E) NAD⁺.

A) product.
B) enzyme.
C) metabolite.
D) food.
E) cofactor.

A) in the mitochondria.
B) on the endoplasmic reticulum.
C) in the nucleus.
D) on the ribosomes.
E) in the cytosol.

A) FAD
B) NAD+
C) FMN
D) NADH
E) FADH₂

A) carbon dioxide, water, and ammonia.
B) glucose, lipids, and glycogen.
C) lipids, oxygen, and water.
D) RNA and DNA.
E) lipids and carbohydrates.

A) endothermic.
B) exothermic.
C) isothermic.
D) an oxidation.
E) a reduction.

A) metabolism.
B) catabolism.
C) anabolism.
D) glucogenesis.
E) gluconeogenesis.

A) one
B) two
C) three
D) four
E) five

A) catabolic reaction.
B) anabolic reaction.
C) digestion reaction.
D) phosphorylation reaction.
E) β-oxidation reaction.

A) release energy.
B) take in energy.
C) occur mainly in the liver.
D) occur outside the cell membrane.
E) take place in the nucleus of the cell.

A) sucrose breakdown.
B) protein digestion.
C) glucose oxidation.
D) glycogen production.
E) ATP → ADP + Pi

A) adenosine, ribose, and triphosphate.
B) aniline and triphosphate.
C) alanine, ribose, and triphosphate.
D) adenine, ribose, and triphosphate.
E) adenosine, deoxyribose, and triphosphate.

A) metabolism.
B) catabolism.
C) anabolism.
D) glycolysis.
E) transamination.

A) digestion
B) muscle contraction
C) transport across cell membranes
D) sending nerve signals
E) synthesis of an enzyme

A) the citric acid cycle.
B) production of pyruvate.
C) production of acetyl CoA.
D) buildup of macromolecules from monomers.
E) digestion of large molecules.

A) an excess of galactose intake.
B) a deficiency of β-galactosidase.
C) a deficiency of lactase.
D) an overabundance of glucose.
E) overproduction of amylase.

A) anabolic process.
B) catabolic process.
C) glucose storage process.
D) protein degradation process.
E) lipid hydrolysis process.

A) mouth.
B) stomach.
C) pancreas.
D) small intestine.
E) large intestine.

A) glyceraldehyde-3-phosphate.
B) lactic acid.
C) glucose-6-phosphate.
D) fructose-6-phosphate.
E) acetyl CoA.

A) copper ion and ATP.
B) iron.
C) calcium ion and ATP.
D) lipid hydrolysis.
E) carbon dioxide.

A) flavin adenosine dinucleotide.
B) folic acid diphosphate.
C) fumarate alcohol dehydrogenase.
D) folate adenosine diphosphate.
E) flavin adenine dinucleotide.

A) electron transport
B) oxidative phosphorylation
C) citric acid cycle
D) glycolysis
E) β-oxidation

A) an acid group.
B) an amino group.
C) a C=O group.
D) an alcohol group.
E) a thiol group.

A) aerobic
B) anaerobic
C) anabolic
D) one-step
E) five-step

A) requires oxygen.
B) uses up 4 ATP molecules.
C) requires acetyl CoA.
D) is an anabolic pathway.
E) produces 2 ATP molecules.

A) niacin adenine dinucleotide.
B) nicotinic acid diphosphate.
C) nicotinamide diphosphate.
D) nicotine adenosine dinucleotide.
E) nicotinamide adenine dinucleotide.

A) pyruvate.
B) citrate.
C) sucrose.
D) oxaloacetate.
E) ribose.

A) cell requirements for pyruvate.
B) allosteric control.
C) ATP needs.
D) feedback inhibition.
E) All of the above.

A) a CH₂ group.
B) a C=O bond.
C) phosphorylation.
D) ADP from ATP.
E) a C-C bond.

A) activate enzyme A.
B) undergo phosphorylation.
C) provide energy for the citric acid cycle.
D) produce acyl groups for reaction.
E) help break down macromolecules.

A) a loss of hydrogen or electrons by a compound.
B) a gain of hydrogen or electrons by a compound.
C) a gain in oxygen.
D) a loss of electrons.
E) an energy-releasing reaction.

A) glucose phosphatase.
B) alcohol dehydrogenase.
C) amylase.
D) lactase.
E) maltase.

A) oxidation.
B) direct phosphorylation.
C) reduction.
D) transamination.
E) oxidative phosphorylation.

A) one
B) two
C) three
D) four
E) five

A) oxidation of alcohols to aldehydes.
B) formation of carbon-carbon double bonds.
C) decarboxylation reactions.
D) phosphorylation reactions.
E) β-oxidation reactions.

A) cytosol
B) nucleus
C) mitochondria
D) lysosomes
E) endoplasmic reticulum

A) lactate.
B) triacylglycerols.
C) amino acids.
D) fructose.
E) glucose.

A) glyceration.
B) gluconeogenesis.
C) glucogenesis.
D) glycogenesis.
E) glycolysis.

A) 2 ATP
B) 4 ATP
C) 6 ATP
D) 8 ATP
E) 12 ATP

A) fermentation
B) glycolysis
C) gluconeogenesis
D) β-oxidation
E) dehydrogenation

A) glycogenesis.
B) glycogenolysis.
C) gluconeogenesis.
D) lactate production.
E) glucagon production.

A) 6 ATP.
B) 6 ATP and 2 NADH.
C) 2 ATP and 2 NADH.
D) 2 ATP and 4 NADH.
E) 12 ATP.

A) glycogenesis.
B) glycogenolysis.
C) gluconeogenesis.
D) lactate production.
E) glucagon production.

A) mouth
B) stomach
C) pancreas
D) small intestine
E) large intestine

A) ATP
B) ADP
C) AMP
D) cyclic AMP
E) GTP

A) ADP.
B) UTP.
C) Pi.
D) pyrophosphate.
E) pyruvate.

A) acetyl CoA.
B) pyruvate.
C) ATP.
D) carbon dioxide.
E) NAD+.

A) heart and lung.
B) liver and muscle.
C) spleen and bone.
D) pancreas and muscle.
E) fat cells and muscle.

A) pyruvic acid and lactic acid.
B) ethanol and acetyl CoA.
C) dihydroxyacetone phosphate and pyruvic acid.
D) dihydroxyacetone phosphate and glyceraldehyde 3-phosphate.
E) glyceraldehyde 3-phosphate and pyruvic acid.

A) glycolysis
B) β-oxidation
C) metabolism
D) anabolism
E) catabolism

A) triacylglycerols.
B) fructose.
C) sucrose.
D) Coenzyme A.
E) ATP.

A)the production of glucose from noncarbohydrate molecules
B)the flow of lactate and glucose between muscle and liver
C)the synthesis of glycogen from glucose for storage purposes
D)breaking down of macromolecules
E)the conversion of glucose to lactic acid
F)the conversion of pyruviate to ethanol and CO₂
G)lipid metabolism

A)the production of glucose from noncarbohydrate molecules
B)the flow of lactate and glucose between muscle and liver
C)the synthesis of glycogen from glucose for storage purposes
D)breaking down of macromolecules
E)the conversion of glucose to lactic acid
F)the conversion of pyruviate to ethanol and CO₂
G)lipid metabolism

A)the production of glucose from noncarbohydrate molecules
B)the flow of lactate and glucose between muscle and liver
C)the synthesis of glycogen from glucose for storage purposes
D)breaking down of macromolecules
E)the conversion of glucose to lactic acid
F)the conversion of pyruviate to ethanol and CO₂
G)lipid metabolism

A)the production of glucose from noncarbohydrate molecules
B)the flow of lactate and glucose between muscle and liver
C)the synthesis of glycogen from glucose for storage purposes
D)breaking down of macromolecules
E)the conversion of glucose to lactic acid
F)the conversion of pyruviate to ethanol and CO₂
G)lipid metabolism