Deck 6: Energy Flow in the Life of a Cell

A) At absolute zero (- 273.15°C)
B) At the freezing point (0°C)
C) At the boiling point (100°C)
D) Never

A) endergonic
B) coupled
C) chemical
D) exergonic

A) radioactivity.
B) light.
C) electricity.
D) heat.
E) entropy.

A) 12 molecules of carbon dioxide, CO₂
B) 2 molecules of the monosaccharide glucose, C6H12O6
C) 4 molecules of the monosaccharide pyruvate, C3H₄O₃
D) 1 molecule of the disaccharide maltose, C12H₂2O11

A) Regular exercise
B) Eating a balanced diet and proper nourishment
C) Regular work
D) Sunbathing

A) exergonic; endergonic
B) endergonic; exergonic
C) equilibrium; exergonic
D) enzymatic; endergonic
E) endergonic; enzymatic

A) the amount of useful energy decreases.
B) reactions cause energy to be converted from more useful to less useful forms.
C) there is a natural tendency toward greater disorder in the organization of matter (increase in entropy).
D) all chemical reactions release more energy than they consume.

A) Energy cannot be transferred or transformed.
B) Potential energy equals kinetic energy in a reaction.
C) Energy cannot be created or destroyed.
D) Kinetic energy is stored energy.
E) Exergonic reactions are coupled with endergonic reactions.

A) high- level energy.
B) kinetic energy.
C) potential energy.
D) organization.
E) randomness.

A) 95%
B) 75%
C) 25%
D) 1%

A) Nuclear energy
B) Solar energy
C) Heat energy
D) Chemical energy
E) Thermal energy

A) endergonic process.
B) conversion of kinetic energy to potential energy.
C) exergonic process.
D) enzyme- catalyzed process.
E) release of activation energy.

A) Photosynthesis does not comply with the physical laws of the universe.
B) Low- energy reactants are converted to high- energy products.
C) Activation energy is not required.
D) Sugar has less energy than does the sun.
E) Protein catalysts are not needed.

A) Sunlight functions as an ultimate source of energy for most forms of life on Earth.
B) Chemical reactions inside cells mostly cause an increase in high- level energy.
C) Organisms are able to function efficiently on heat energy alone.
D) Living organisms are unique in that they do not require energy for survival.
E) Living organisms are totally isolated systems that are not subject to the laws of physics.

A) energy is stored by the reactions.
B) the reactants have less energy than do the products.
C) the reactants and products have equal amounts of energy.
D) the reactants have more energy than do the products.

A) one form of energy may be converted to a different form of energy.
B) the total amount of energy within a closed system remains the same.
C) the amount of useful energy decreases when energy is converted from one form to another.
D) the first law of thermodynamics is often called the law of the conservation of energy.

A) A diver on a springboard
B) A glucose molecule
C) A ball that has rolled downhill and stopped
D) A 9- volt battery
E) A water droplet at the top of a waterfall

A) kinetic
B) potential
C) exergonic
D) endergonic

A) The cool air surrounding the car engine
B) A moving car
C) A tank of gasoline
D) A hot car engine
E) An unlit firecracker

A) Presence of a catalyst
B) Low concentration of reactants
C) High temperature
D) Altering pH to 7
E) High concentration of products

A) Photosynthesis requires two reactants: carbon dioxide and water.
B) Sunlight energy enters a plant and is ultimately lost as heat.
C) The exergonic reaction occurs in the plant, and the endergonic reaction occurs in the sunlight.
D) The exergonic reaction occurs in the plant, and the endergonic reaction occurs in the soil.
E) An exergonic reaction occurs in the sunlight, and an endergonic reaction occurs in the plant.

A) there is not enough ATP in body cells.
B) many reactions require large inputs of activation energy.
C) no catalysts are present in body cells.
D) all reactions in the body are endergonic.
E) most biological catalysts are not active at body temperature (37°C).

A) ATP
B) NAD
C) H₂O
D) FAD

A) catalysts increase the reaction rate.
B) catalysts are not permanently altered during reaction.
C) catalysts increase activation energy requirements.
D) biological catalysts are specific enzymes.
E) catalysts can be used repeatedly.

A) manufactures more ATP.
B) catalyzes the reaction.
C) is broken down and liberates energy.
D) enters a metabolic pathway.
E) is phosphorylated.

A) 2, 1, 4, 3
B) 1, 3, 4, 2
C) 2, 3, 1, 4
D) 1, 2, 3, 4
E) 2, 1, 3, 4

A) Protein
B) Phospholipids
C) Glycogen
D) Steroids
E) ATP

A) It converts inorganic phosphates to energy- carrier molecules.
B) It is lost as light energy.
C) It provides the energy needed to drive endergonic reactions in the cell.
D) It polarizes the cell.
E) It functions as a second messenger.

A) allow reactions to occur at body temperature.
B) increase the body temperature of organisms.
C) can enable organisms to evade the laws of thermodynamics.
D) are structural proteins that make up bodily tissues.
E) bind irreversibly to substrates.

A) glucose.
B) NADPH.
C) ATP.
D) ADP.
E) DNA.

A) adenine and the first phosphate group.
B) ribose and the first phosphate group.
C) two phosphate groups.
D) adenine and ribose.

A) Energy- carrier molecule
B) Substrate
C) Enzyme
D) Amino acid
E) Steroid

A) Between the sugar and the phosphate
B) Attached to the nucleotide
C) In the bonds between phosphate groups
D) Attached to the phosphate group
E) Inside the phosphate

A) Enzymes are proteins that function as biological catalysts.
B) Enzymes are highly specific for the molecules to which they attach.
C) The activity of enzymes can be regulated by factors in their environment.
D) Enzymes provide energy for the reactions they catalyze.
E) An enzyme may be used many times for the same specific reaction.

A) Two reactions, where the product of the first reaction is the reactant of the second reaction
B) Two reactions that occur in the same organelle
C) Reactions that occur during sexual reproduction
D) Two reactions that occur simultaneously
E) A reaction that occurs right after another reaction

A) Metergonic
B) Endergonic
C) Exergonic
D) Spontaneous

A) product.
B) allosteric inhibitor.
C) activation energy.
D) active site.
E) substrate.

A) protein.
B) enzyme- substrate complex.
C) active site.
D) enzyme.
E) electron carrier molecule.

A) The relationship is temporary.
B) The enzyme and the reactant molecule are both permanently changed.
C) The resultant product and the enzyme are permanently bonded together.
D) Covalent chemical bonds stabilize the relationship.
E) One enzyme typically has many reactants with which it will associate.

A) activation energy.
B) denaturing of proteins.
C) electron carriers.
D) competitive inhibition.

A) Enzymes are not permanently changed by the reactions they promote.
B) All enzymes are proteins.
C) Enzymes are highly specific.
D) Enzyme activity is regulated.
E) Enzymes usually speed up chemical reactions.

A) Competitive inhibitor only
B) Noncompetitive inhibitor only
C) Allosteric inhibitor only
D) Substrate only
E) Both substrate and competitive inhibitor

A) the enzyme is working at an optimal temperature.
B) an inhibitor has bound the enzyme at the active site.
C) the enzyme is working at its maximal rate.
D) its three- dimensional structure has changed and the enzyme can no longer function properly.

A) substrate activation.
B) feedback inhibition.
C) allosteric activation.
D) denaturation.
E) irreversible inhibition.

A) Add more inhibitor.
B) Lower the temperature of the reaction.
C) Add a coenzyme.
D) Add more substrate.
E) Allow the reaction to reach equilibrium.

A) An acidic environment causes bacterial enzymes to fail or work less efficiently.
B) An acidic environment increases the activation energy more quickly in bacteria.
C) An acidic environment encourages endergonic reactions in the bacterial cells.
D) An acidic environment causes the bacteria to grow more rapidly.

A) The activation energy of the reaction decreases.
B) The energy of the products is higher than that of the energy of the reactants.
C) The reaction is endergonic.
D) The reaction requires a catalyst.
E) The reaction is at equilibrium.

A) increasing the temperature to 38°C and keeping the pH at 7.3.
B) increasing the pH and maintaining the temperature at 37°C.
C) decreasing the pH and increasing the temperature.
D) increasing both temperature and pH.

A) lead.
B) nerve gas.
C) arsenic.
D) mercury.

A) the precise location on the enzyme to which they bind.
B) the temperature at which they work best.
C) their pH.
D) their energies of activation.

A) At high concentrations of substrate, the activation energy of the reaction decreases.
B) The enzyme is no longer specific for the substrate.
C) At high concentrations of substrate, the reaction is endergonic.
D) At high concentrations of substrate, all of the enzyme active sites are being occupied by substrate molecules.
E) At high concentrations of substrate, the activation energy of the reaction increases.

A) acts as a noncompetitive inhibitor.
B) functions as an enzyme when sulfotransferase is absent.
C) is a competitive inhibitor.
D) lowers the activation energy of chemical reactions.

A) a heavy metal (such as lead) may block the enzymes non- active site.
B) by first synthesizing the enzyme in an inactive form.
C) by feedback inhibition.
D) a gene coding for the enzyme may be turned off.