Deck 6: Energy for Life

A) split water to release electrons.
B) funnel electrons to a central chlorophyll a molecule.
C) produce NADPH.
D) give off oxygen when stimulated by light.
E) combine hydrogen ions with an electron to form water.

A) granum.
B) chlorophyll.
C) cytoplasm.
D) stroma.
E) christae

A) The additional pigments are able to absorb other light wavelengths that chlorophyll cannot.
B) The additional pigments can only absorb violet or ultraviolet light.
C) Chlorophyll is unable to absorb visible light.
D) When chlorophyll breaks down, the additional pigments can absorb the same wavelengths of light.
E) When the additional pigments break down, the chlorophyll can absorb other wavelengths of light. Plants use a variety of pigments in order to absorb a broader portion of the visible light spectrum.

A) capture solar energy; converts the captured energy to chemical potential energy
B) can occur only in the light; can occur only in the dark
C) require the presence of ATP; makes ATP
D) can only function if the stomata are open; can only occur if the stomata are closed
E) use products manufactured in the dark reactions; creates products used in the dark reactions

A) NADP⁺
B) carbon dioxide
C) ATP
D) ATP synthase
E) RuBP

A) to regenerate the starter molecule RuBP
B) to attract the next CO₂ molecule to enter the Calvin cycle
C) to reduce the molecules of G3P to form glucose
D) to join acetyl CoA into pyruvate, preparing it to enter the citric acid cycle
E) to fix carbon dioxide to RuBP

A) ATP and NADPH
B) H⁺ and ATP
C) G3P and ATP
D) H⁺ and G3P
E) G3P and NADPH

A) ATP and NADPH; ADP and NADP
B) CO₂ and H₂O; glucose and O₂
C) ATP and CO₂; glucose and O₂
D) glucose and O₂; CO₂ and H₂O
E) ADP and NADH; ATP and NADPH

A) water; carbon dioxide
B) carbon dioxide; water
C) carbohydrate; carbon dioxide
D) carbon dioxide; carbohydrate
E) carbon dioxide; oxygen

A) stroma.
B) thylakoid membrane.
C) chlorophyll.
D) thylakoid space.
E) leaf space.

A) They participate in the Calvin cycle.
B) They funnel solar energy to chlorophyll a in the reaction center.
C) They split the water molecule to supply electrons to the chlorophyll a in the reaction center.
D) They change the color of the leaves to discourage predators.
E) They have no purpose.

A) crabgrass is a type of cactus, so it grows better in dry climates.
B) as the climate changes, homeowners are not caring for their yards as well.
C) crabgrass is a tropical plant that likes hot, dry climates.
D) crabgrass is a type of C₃ plant that does well in dry climates.
E) crabgrass is a type of C₄ plant that does well in dry climates.

A) ATP and NADP⁺.
B) ADP + P_i.
C) ADP + P_i and NADP⁺.
D) ATP and NADPH.
E) NADPH and NADP⁺.

A) transfer of electrons to the reaction center of photosystem I
B) generation of ATP from ADP + P_i
C) splitting of water, releasing an electron
D) generation of NADPH from NADP⁺
E) conversion of 3PG to G3P

A) H2O → PSII → electron transport chain → PSI → electron transport chain → NADPH
B) H2O → PSII → chlorophyll b → PSI → chlorophyll a → NADPH
C) NADPH → PSII → electron transport chain → PSI → electron transport chain → NADP+
D) NADP+ → PSII → electron transport chain → PSI → electron transport chain → NADPH
E) PSI → electron transport chain → PSII → electron transport chain → NADPH

A) mesophyll.
B) thylakoid space.
C) thylakoid membrane.
D) stroma.
E) cytoplasm.

A) Hydrogen ions flow down a concentration gradient from the thylakoid space to the stroma through ATP synthase, releasing energy that can be used to produce ATP from ADP + Pi.
B) Water splits, releasing electrons that flow from the stroma to the thylakoid space and attach to the active site of ATP synthase.
C) Electrons from the reaction site center of photosystem II are funneled to ATP synthase, which uses the energy to produce ATP from ADP + Pi.
D) Hydrogen ions in the thylakoid space combine with electrons from the stroma at ATP synthase, releasing energy that can be used to produce ATP from ADP + Pi.
E) A hydrogen ion from NADPH is used by ATP synthase to power the production of ATP from ADP + Pi, and an electron is released, splitting water.

A) algae
B) fungi
C) animals
D) invertebrates
E) vertebrates

A) loss of electrons; gain of electrons
B) gain of water; loss of water
C) gain of electrons; loss of electrons
D) loss of water; gain of water
E) gain of protons; loss of protons

A) This plant is unlike any other plant that has ever been discovered and is a completely new category of plant.
B) This plant very likely carries out C₄ photosynthesis.
C) This plant falls into the category of CAM-type plants.
D) This plant uses chemosynthesis rather than photosynthesis.
E) This is a C₃ type of plant.

A) to shield the Calvin cycle reactions from O₂ in the leaf spaces.
B) to allow O₂ to enter bundle sheath cells.
C) because rubisco is only found in mesophyll cells.
D) so that they are adjacent to stomata.
E) so that H₂O is not available to mesophyll cells.

A) H⁺ gradient.
B) NADP⁺.
C) G3P.
D) NADPH.
E) CO₂.

A) glucose.
B) glyceraldehyde 3-phosphate G3P).
C) sucrose.
D) 3-phosphoglycerate 3PG).
E) ribulose 1,5-bisphosphate RuBP).

A) allow water to enter leaf spaces during the daylight hours.
B) open stomata only at night, limiting water loss because of heat and low humidity.
C) allow NADPH and ATP to enter leaf spaces.
D) limit the Calvin cycle reactions to nighttime only.
E) limit water uptake from the soil during daytime hours.

A) chlorophyll a
B) chlorophyll b
C) carotenoids
D) NADP⁺
E) electron transport proteins

A) CO₂ and H₂O
B) RuBP
C) CO₂
D) NADP⁺
E) H₂O

A) NADPH reduction, CO₂ fixation, and NADP⁺ regeneration.
B) NADPH reduction, CO₂ fixation, and RuBP regeneration.
C) CO₂ fixation, CO₂ reduction, and RuBP regeneration.
D) CO₂ fixation, CO₂ reduction, and NADP⁺ regeneration.
E) CO₂ reduction, NADPH reduction, and CO₂ regeneration.

A) glucose
B) fructose
C) glyceraldehyde 3-phosphate G3P)
D) ATP
E) RuBP carboxylase

A) both C₃ and CAM.
B) C₄.
C) CAM.
D) both C₄ and CAM.
E) C₃.

A) chlorophyll a
B) NADP⁺
C) H₂O
D) CO₂
E) O₂

A) the bundle sheath cells in C3 plants have chloroplasts, while those in C4 plants do not.
B) the bundle sheath cells in C4 plants have chloroplasts, while those in C3 plants do not.
C) the bundle sheath cells in C3 plants are arranged in columns just beneath the upper epidermis, while those in C4 plants are arranged in a ring around veins.
D) the bundle sheath cells in C4 plants are arranged in columns just beneath the upper epidermis, while those in C3 plants are arranged in a ring around veins.
E) There is no difference in bundle sheath cells in C3 and C4 plants.

A) cool, moist
B) hot, moist
C) cool, dry
D) hot, dry
E) semi-tropical

A) CAM
B) C₃
C) C₄
D) both C₄ and CAM
E) both C₃ and CAM

A) mesophyll cells.
B) the stomata.
C) both mesophyll and bundle sheath cells.
D) bundle sheath cells.
E) epidermal cells of the leaf.

A) 3-phosphoglycerate 3PG)
B) ribulose 1,5-bisphosphate RuBP)
C) glyceraldehyde 3-phosphate G3P)
D) NADPH
E) 1,3 bisphosphoglycerate BPG)

A) ATP supplies energy and NADPH supplies electrons for reducing power.
B) ATP supplies energy and NADPH fixes CO₂ so it can enter the cycle.
C) Both ATP and NADPH supply energy to the Calvin cycle.
D) NADPH supplies energy and ATP supplies electrons for reducing power.
E) ATP and NADPH are joined into the starter molecule, RuBP, to form glucose.

A) glyceraldehyde 3-phosphate G3P)
B) chlorophyll a
C) electron transport protein
D) rubisco
E) NADP⁺

A) carbon fixation and Calvin cycle reactions
B) carbon fixation and light reactions
C) light reactions and Calvin cycle reactions
D) glyceraldehyde 3-phosphate G3P) formation and glucose phosphate formation
E) 1,3 bisphosphoglycerate BPG) formation and glucose phosphate formation

A) glucose
B) galactose
C) glucose phosphate
D) fructose
E) 3PG

A) thylakoid membrane; stroma
B) stroma; thylakoid space
C) thylakoid space; thylakoid membrane
D) stroma; thylakoid membrane
E) thylakoid space; stroma

A) 1
B) 2
C) 3
D) 6
E) 12

A) H⁺ and electrons
B) electrons and ATP
C) H⁺ and ATP
D) H⁺ and CO₂
E) electrons and CO₂

A) a nonprotein helper that works with an enzyme.
B) another enzyme that assists an enzyme with a chemical reaction.
C) another enzyme in the same biochemical pathway.
D) a carbohydrate that assists an enzyme.
E) a protein that is not an enzyme.

A) inability of rubisco to obtain O₂
B) C₄ plants need energy to move fixed carbon compounds into bundle sheath cells
C) need for stomata to close to conserve H₂O
D) need for energy to move H₂O into bundle sheath cells
E) inability of ATP synthase to utilize H⁺ gradient for energy

A) oxidation
B) reduction
C) phosphorylation
D) metabolism
E) an enzyme-substrate complex

A) the movement of hydrogen ions against their concentration gradient into the thylakoid space.
B) the splitting of H₂O, which releases electrons.
C) solar energy captured by the light reactions changing the shape of the enzyme.
D) electrons transferred from NADPH causing the enzyme to change shape.
E) the movement of hydrogen ions down their concentration gradient from the thylakoid space to the stroma.

A) reduction
B) oxidation
C) phosphorylation
D) metabolism
E) an enzyme-substrate complex

A) photosystem I
B) photosystem II
C) rubisco
D) electron transport chain
E) ATP synthase

A) A and B
B) B and C
C) A and D
D) B only
E) C only

A) interconnecting stomata.
B) flattened sacs of thylakoid membrane.
C) pores that open to allow gas exchange.
D) the sites of the Calvin cycle and production of sugars.
E) enzymes that bind CO₂.

A) 2
B) 3
C) 4
D) 5
E) 6

A) NADPH; ATP
B) NADP⁺; ATP
C) RuBP; ATP
D) NADPH; RuBP
E) rubisco; RuBP

A) G3P and CO₂ have the same amount of energy.
B) G3P has less energy than CO₂.
C) Neither G3P nor CO₂ contain any chemical energy.
D) G3P has more energy than CO₂.
E) There is not enough information provided to answer the question.

A) A and B
B) A and D
C) B and D
D) B and C
E) C and D

A) reflect and transmit yellow and orange wavelengths of light.
B) absorb yellow and orange wavelengths of light.
C) absorb or transmit yellow and orange wavelengths of light.
D) absorb or reflect yellow and orange wavelengths of light.
E) absorb all wavelengths of light and then transmit yellow and orange wavelengths.

A) CO₂ fixation and CO₂ reduction
B) CO₂ reduction and RuBP regeneration
C) CO₂ fixation and RuBP regeneration
D) CO₂ fixation, CO₂ reduction, and RuBP regeneration
E) CO₂ reduction and RuBP oxidation

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

A) starch
B) cellulose
C) glucose phosphate
D) NADP⁺
E) sucrose

A) the energy released can be used to establish an H⁺ ion gradient.
B) the energy released is stored in the stroma.
C) NADP⁺ does not enter the thylakoid space.
D) CO₂ remains in the stroma for the Calvin cycle reactions and does not enter the thylakoid space.
E) glyceraldehyde 3-phosphate G3P) is produced in the thylakoid space.

A) When the stomata close during heat stress, RuBP carboxylase is not exposed to the increase in oxygen . concentration experienced in the leaf. This allows the plant to avoid trying to use oxygen.
B) When the stomata close during heat stress, RuBP carboxylase is exposed to the increase in oxygen
Concentration experienced in the leaf. This allows the plant to avoid trying to use oxygen.
C) When the stomata open during heat stress, RuBP carboxylase is not exposed to the increase in oxygen concentration experienced in the leaf. This allows the plant to avoid trying to use oxygen.
D) When the stomata close during heat stress, RuBP carboxylase is exposed to the increase in oxygen
Concentration experienced in the leaf. This allows the plant to use oxygen for photosynthesis.
E) When the stomata open during heat stress, RuBP carboxylase is not exposed to the increase in oxygen