Deck 6: Photo Synthesis and Cellular Respiration

A) No molecular oxygen would be generated.
B) No electrons would be available to reduce the carbon in CO₂ .
C) Cells could produce ATP but not sugars.
D) Cells could produce O₂ but not sugars.

A) oxygen production; the generation of carbon dioxide during cellular respiration
B) the synthesis of ATP; the synthesis of water
C) photosynthesis; metabolism
D) the catabolic aspects of cellular respiration; the synthesis of ATP

A) Carbon dioxide levels would decrease uncontrollably, making the Earth too warm to support life.
B) Atmospheric oxygen levels would be too low to support life on Earth.
C) Carbon atoms would still be readily available in biologically useful forms, causing organisms to grow and reproduce at the normal rate.
D) Oxygen would bind carbon atoms spontaneously, producing more carbon dioxide.

A) evolve lower stomatal densities to reduce the potential for desiccation.
B) grow smaller and more slowly than they do now.
C) keep their stomata closed most of the time to minimize carbon dioxide poisoning.
D) increase their stomatal densities to take advantage of the abundance of CO₂ .

A) synthesis of macromolecules
B) synthesis of water from hydrogen and oxygen
C) membrane transport
D) cytoskeletal organization

A) quite similar; they both transport electrons and hydrogen ions that are released in catabolic pathways.
B) quite similar; they both transport electrons and hydrogen ions to anabolic pathways.
C) somewhat different; NADPH receives electrons and hydrogen from catabolic processes, whereas NADH delivers those items to anabolic processes.
D) somewhat different; NADH receives electrons and hydrogen from catabolic processes, whereas NADPH delivers those items to anabolic processes.

A) It provides a phosphate group to ATP.
B) It captures light energy and transfers it to the electron transport chain.
C) It provides replacement electrons to the reaction center chlorophyll in photosystem II.
D) It combines with carbon dioxide (CO₂ ) to make glucose.

A) ethanol would not be available as a nutrient for other consumers.
B) lactic acid would accumulate and disable prokaryotic muscle cells.
C) carbon could not be recycled back into the biosphere for use by producers.
D) the only source of NADH for electron transport would be from glycolysis; therefore, ATP production would be greatly reduced.

A) photosynthesis, glycolysis, and oxidative phosphorylation.
B) glycolysis, the Krebs cycle, and oxidative phosphorylation.
C) glycolysis, fermentation, and the Krebs cycle.
D) photosynthesis, the Krebs cycle, and fermentation.

A) Photosynthesis is a catabolic pathway, whereas cellular respiration is an anabolic pathway.
B) Water is formed during photosynthesis but broken apart during cellular respiration.
C) Both photosynthesis and cellular respiration require electron transport chains.
D) Both photosynthesis and cellular respiration produce CO₂ as metabolic end products.

A) ATP
B) NADH
C) CO₂
D) ADP

A) ATP enables the energy to be stored for later use or transferred to other chemical reactions.
B) Chloroplasts are unable to use the energy they capture from the sun.
C) Producing ATP enables the plant to destroy excess energy that was captured from the sun.
D) The mitochondria that capture the sun's energy are unable to use it for respiration.

A) thylakoid membrane.
B) stroma.
C) cytosol.
D) nucleus.

A) They have an intermembrane space and a matrix.
B) They have three membrane-enclosed compartments.
C) Unlike mitochondria, they lack a stroma.
D) They carry out both photosynthesis and respiration.

A) photosynthesis
B) phosphorylation
C) carbon fixation
D) electron transfer

A) All other organisms require oxygen for life processes.
B) The sugars made during photosynthesis are building blocks of DNA.
C) All cells must have chloroplasts to survive.
D) Photosynthesis captures energy that other organisms access when they eat either plants or organisms that eat plants.

A) pyruvate.
B) stroma.
C) chemical bonds.
D) thylakoid disks.

A) accumulation of atmospheric oxygen.
B) declines in historic sea levels as photosynthetic organisms consumed water.
C) gradual warming of Earth's climate as CO₂ slowly accumulated.
D) sequestration of O₂ in Earth's oceans.

A) degrades carbon dioxide.
B) hydrolyzes ATP.
C) splits water.
D) reduces NADPH.

A) nucleus.
B) chloroplast.
C) mitochondrion.
D) cytosol.

A) CO₂ .
B) a three-carbon compound called phosphoglyceric acid.
C) citric acid.
D) glyceraldehyde 3-phosphate.

A) They are more efficient at water uptake than are C3 and C4 plants.
B) They have special adaptations that cool them off in very hot and dry weather.
C) They close their stomata at night and open them at daybreak to conserve water.
D) They open their stomata at night and close them at daybreak to conserve water.

A) photosystem I; photosystem II
B) the reaction center; the antenna complex
C) photosystem II; photosystem I
D) the stroma; the intermembrane space

A) capture of energy from sunlight.
B) synthesis of sugars like glucose, fructose, and sucrose.
C) production of pyruvate.
D) breakdown of complex molecules and the subsequent release of energy.

A) CO₂ to ribulose 1,5-bisphosphate (RuBP) instead of O₂ .
B) O₂ to RuBP instead of CO₂ .
C) CO₂ to O₂ , forming sucrose instead of glucose.
D) CO₂ to a molecule that contains four carbons.

A) It is oxidized by photosystem I.
B) It is reduced by photosystem I.
C) It is reduced by photosystem II.
D) It is oxidized by photosystem II.

A) cannonball that reaches the high point of its flight and then returns to the ground.
B) bowling ball bouncing down a flight of stairs and landing temporarily on each step.
C) pair of sunglasses that intercepts ultraviolet radiation before it reaches our eyes.
D) newly baked pie cooling on the counter before it can be cut and eaten.

A) to increase the efficiency of cellular respiration by producing additional molecules of ATP
B) to release O₂ as a by-product so that cellular respiration can continue
C) to create lactic acid that will stimulate muscle contraction
D) to recycle NADH back into NAD+ so that the cell can continue glycolysis

A) chlorophyll.
B) ATP synthase.
C) sucrase.
D) rubisco.

A) mitochondria in plant cells convert solar power to the chemical power that is used to run the brain.
B) cellular respiration is powered by sunlight.
C) the antenna complex in chloroplasts acts like a tiny solar panel, collecting sunlight to make the sugars we consume to run our brain.
D) mitochondria in plant cells use solar power to split water molecules, creating the energy that runs the brain.

A) reaction center.
B) antenna complex.
C) thylakoid.
D) stoma.

A) the buildup of lactic acid during fermentation.
B) signals sent to the nervous system by O₂ -starved cells.
C) the accumulation of pyruvate in the absence of oxidative phosphorylation.
D) the lack of ATP needed to regulate the pain receptors in our muscle cells.

A) pyruvate
B) glucose
C) lactic acid
D) ethanol

A) catabolism.
B) fermentation.
C) glycolysis.
D) carbon fixation.

A) lactic acid fermentation.
B) carbon dioxide synthesis in our lungs.
C) oxidative phosphorylation in muscle cell mitochondria.
D) the dark reactions of photosynthesis.

A) The cycle uses ATP and NADPH to produce sugars.
B) The cycle moves electrons from photosystem II to photosystem I.
C) The cycle moves light-energized electrons to photosystem II.
D) The cycle absorbs light from the light reactions.

A) require no oxygen.
B) produce molecular oxygen.
C) produce ATP.
D) produce citric acid.

A) carbon
B) phosphorous
C) hydrogen
D) oxygen

A) The chloroplast would be unable to maintain the proton gradient required for ATP production.
B) The chloroplast would be unable to capture ATP directly from the sun.
C) The chloroplast would be unable to perform the Calvin cycle.
D) The chloroplast would be unable to perform anaerobic respiration.

A) electrons from the thylakoid matrix to the cytosol.
B) acetyl CoA into the Krebs cycle.
C) protons into the mitochondrial intermembrane space.
D) pyruvate into the first reaction of glycolysis.

A) glycolysis
B) the Krebs cycle
C) the electron transport chain
D) the Calvin cycle

A) rotenone
B) carbonic anhydrase
C) cyanide
D) carbon monoxide

A) oxidative phosphorylation.
B) the Calvin cycle.
C) the electron transport chain.
D) the Krebs cycle.

A) the Krebs cycle.
B) glycolysis.
C) photosynthesis.
D) the electron transport chain.

A) The folds protect the proteins in the inner membrane from the toxic by-products of cellular respiration.
B) The folds increase the space available for electron transport chains and ATP synthase molecules, increasing the efficiency of ATP production.
C) The extra folds make the mitochondrion more efficient at capturing carbon dioxide.
D) The antenna complexes in the inner membrane form clusters that force the membrane into folds.

A) It must be mitochondrial, with oxygen provided by one big breath at the beginning of the sprint.
B) It must be mitochondrial, with oxygen provided by circulating hemoglobin that is already saturated with oxygen.
C) It must be glycolytic; the process is entirely anaerobic and the race will be over before NADH+ reserves are depleted.
D) It must be fermentative, which explains why most sprinters experience cramping after the race ends.

A) phosphate group transfers from ATP.
B) electrons that are transferred from NADPH.
C) electrons that are transferred from NADH.
D) electrons that are removed from CO₂ during its oxidation.

A) NADH and carbon dioxide.
B) water and carbon dioxide.
C) ADP and NADP+.
D) acetyl CoA and sugars.

A) mitochondrial matrix.
B) cytosol.
C) thylakoid membrane.
D) outer mitochondrial membrane.