Deck 10: Photosynthesis

A)There would be no difference in results.
B)The bacteria would be relatively evenly distributed along the algal filaments.
C)The number of bacteria present would decrease due to an increase in the carbon dioxide concentration.
D)The number of bacteria present would increase due to an increase in the carbon dioxide concentration.
E)The number of bacteria would decrease due to a decrease in the temperature of the water.

A)split water and release oxygen to the reaction-center chlorophyll
B)harvest photons and transfer light energy to the reaction-center chlorophyll
C)synthesize ATP from ADP and Pi
D)transfer electrons to ferredoxin and then NADPH
E)concentrate photons within the stroma

A)the relationship between heterotrophic and autotrophic organisms.
B)the relationship between wavelengths of light and the rate of aerobic respiration.
C)the relationship between wavelengths of light and the amount of heat released.
D)the relationship between wavelengths of light and the oxygen released during photosynthesis.
E)the relationship between the concentration of carbon dioxide and the rate of photosynthesis.

A)reducing NADP⁺
B)splitting the water molecules
C)chemiosmosis
D)the electron transfer system of photosystem I
E)the electron transfer system of photosystem II

A)oxygen and carbon dioxide
B)carbon dioxide and RuBP
C)water and carbon
D)electrons and photons
E)ATP and NADPH

A)Green and yellow wavelengths inhibit the absorption of red and blue wavelengths.
B)Bright sunlight destroys photosynthetic pigments.
C)Oxygen given off during photosynthesis interferes with the absorption of light.
D)Other pigments absorb light in addition to chlorophyll a.
E)Aerobic bacteria take up oxygen which changes the measurement of the rate of photosynthesis.

A)red and yellow
B)blue and violet
C)green and yellow
D)blue, green, and red
E)green, blue, and yellow

A)Light energy excites electrons in the electron transport chain in a photosynthetic unit.
B)The excitation is passed along to a molecule of P700 chlorophyll in the photosynthetic unit.
C)The P680 chlorophyll donates a pair of protons to NADPH, which is thus converted to NADP⁺.
D)The electron vacancies in P680 are filled by electrons derived from water.
E)The splitting of water yields molecular carbon dioxide as a by-product.

A)Bacteria released excess carbon dioxide in these areas.
B)Bacteria congregated in these areas due to an increase in the temperature of the red and blue light.
C)Bacteria congregated in these areas because these areas had the most oxygen being released.
D)Bacteria are attracted to red and blue light and thus these wavelengths are more reactive than other wavelengths.
E)Bacteria congregated in these areas due to an increase in the temperature caused by an increase in photosynthesis.

A)420 mm
B)475 mm
C)575 mm
D)625 mm
E)730 mm

A)stroma of the chloroplast
B)thylakoid membrane
C)cytoplasm surrounding the chloroplast
D)chlorophyll molecule
E)outer membrane of the chloroplast

A)The absorption spectrum line would be lowest for chlorophyll b somewhat to the right of that for chlorophyll a (500-600).
B)The rate of photosynthesis line for chlorophyll b would be lowest from 600-700 nm.
C)The lines for the two types of chlorophyll would be almost completely opposite.
D)The lines for the two types of chlorophyll would be almost completely identical.
E)The peaks of the line for absorbance of b would be shifted to the left, and for rate of photosynthesis would be shifted to the right.

A)autotrophs and heterotrophs
B)producers and primary consumers
C)photosynthesizers
D)autotrophs
E)green plants

A)PGA.
B)PGAL.
C)glucose.
D)RuBP.
E)O₂.

A)to determine if they have thylakoids in the chloroplasts.
B)to test for liberation of O₂ in the light.
C)to test for CO₂ fixation in the dark.
D)to do experiments to generate an action spectrum.
E)to test for production of either sucrose or starch.

A)there are 700 chlorophyll molecules in the center.
B)this pigment is best at absorbing light with a wavelength of 700 nm.
C)there are 700 photosystem I components to each chloroplast.
D)it absorbs 700 photons per microsecond.
E)the plastoquinone reflects light with a wavelength of 700 nm.

A)NADP is produced.
B)NADPᴴ is reduced to NADP⁺.
C)carbon dioxide is incorporated into PGA.
D)ATP is phosphorylated to yield ADP.
E)light is absorbed and funneled to reaction-center chlorophyll a.

A)CO₂ and glucose
B)H₂O and O₂
C)ADP, Pi, and NADP⁺
D)electrons and H⁺
E)ATP and NADPH

A)chloroplast membranes
B)nuclear membranes
C)free in the cytosol
D)along the outer edge of the nucleoid
E)along the inner surface of the plasma membrane

A)thylakoid membrane
B)plasma membrane
C)inner mitochondrial membrane
D)A and C
E)A, B, and C

A)heat and fluorescence
B)ATP and P700
C)ATP and NADPH
D)ADP and NADP
E)P700 and P680

A)photosynthesis.
B)respiration.
C)both photosynthesis and respiration.
D)neither photosynthesis nor respiration.
E)photorespiration.

A)the stroma to the photosystem II.
B)the matrix to the stroma.
C)the stroma to the thylakoid space.
D)the intermembrane space to the matrix.
E)ATP synthase to NADP+ reductase.

A)They serve as accessory pigments.
B)They dissipate excessive light energy.
C)They cover the sensitive chromosomes of the plant.
D)They reflect orange light.
E)They take up toxins from the water.

A)The isolated chloroplasts will make ATP.
B)The Calvin cycle will be activated.
C)Cyclic photophosphorylation will occur.
D)Only A and B will occur.
E)A, B, and C will occur.

A)establishment of a proton gradient
B)diffusion of electrons through the thylakoid membrane
C)reduction of water to produce ATP energy
D)movement of water by osmosis into the thylakoid space from the stroma
E)formation of glucose, using carbon dioxide, NADPH, and ATP

A)It is the receptor for the most excited electron in either photosystem.
B)It is the molecule that transfers electrons to plastoquinone (Pq)of the electron transfer system.
C)NADP reductase will then catalyze the shift of the electron from Fd to NADP⁺ to reduce it to NADPH.
D)This molecule results from the transfer of an electron to the primary electron acceptor of photosystem II and strongly attracts another electron.
E)This molecule is found far more frequently among bacteria as well as in plants and plantlike Protists.

A)photosystem II
B)photosystem I
C)cyclic electron flow
D)linear electron flow
E)chlorophyll

A)the splitting of water
B)the absorption of light energy by chlorophyll
C)the flow of electrons from photosystem II to photosystem I
D)the synthesis of ATP
E)the reduction of NADP⁺

A)Respiration is the reversal of the biochemical pathways of photosynthesis.
B)Photosynthesis stores energy in complex organic molecules, while respiration releases it.
C)Photosynthesis occurs only in plants and respiration occurs only in animals.
D)ATP molecules are produced in photosynthesis and used up in respiration.
E)Respiration is anabolic and photosynthesis is catabolic.

A)They have a direct, linear relationship.
B)They are inversely related.
C)They are logarithmically related.
D)They are separate phenomena.
E)They are only related in certain parts of the spectrum.

A)The action spectrum of that molecule is such that it is different from other molecules of chlorophyll.
B)The potential energy of the electron has to go back to the ground state.
C)The molecular environment lets it boost an electron to a higher energy level and also to transfer the electron to another molecule.
D)Each pigment molecule has to be able to act independently to excite electrons.
E)These chlorophyll a molecules are associated with higher concentrations of ATP.

A)photosynthesis.
B)respiration.
C)both photosynthesis and respiration.
D)neither photosynthesis nor respiration.
E)photorespiration.

A)photosynthesis.
B)respiration.
C)both photosynthesis and respiration.
D)neither photosynthesis nor respiration.
E)photorespiration.

A)photosynthesis.
B)respiration.
C)both photosynthesis and respiration.
D)neither photosynthesis nor respiration.
E)photorespiration.

A)Photosystem II must have been selected against in some species.
B)Photosystem I must be more ancestral.
C)Photosystem II may have evolved to be more photoprotective.
D)Cyclic flow must be more primitive than linear flow of electrons.
E)Cyclic flow must be the most necessary of the two processes.

A)photosynthesis.
B)respiration.
C)both photosynthesis and respiration.
D)neither photosynthesis nor respiration.
E)photorespiration.

A)thylakoid membranes of chloroplasts
B)stroma of chloroplasts
C)inner membrane of mitochondria
D)matrix of mitochondria
E)cytoplasm

A)using mutated organisms that can grow but that cannot carry out cyclic flow of electrons and compare their abilities to photosynthesize in different light intensities
B)using plants that can carry out both linear and cyclic electron flow, or only one or another of thee processes, and measuring their light absorbance
C)using bacteria that have only cyclic flow and look for their frequency of mutation damage
D)using bacteria with only cyclic flow and measuring the number and types of photosynthetic pigments they have in their membranes
E)using plants with only photosystem I operative and measure how much damage occurs at different wavelengths.

A)Formation of a molecule of glucose would require 9 "turns."
B)G3P more readily forms sucrose and other disaccharides than it does monosaccharides.
C)Some plants would not taste sweet to us.
D)The formation of starch in plants involves assembling many G3P molecules, with or without further rearrangements.
E)G3P is easier for a plant to store.

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

A)stroma of the chloroplast
B)thylakoid membranes
C)outer membrane of the chloroplast
D)electron transport chain
E)thylakoid space

A)light reactions alone
B)the Calvin cycle alone
C)both the light reactions and the Calvin cycle
D)neither the light reactions nor the Calvin cycle
E)occurs in the chloroplast but is not part of photosynthesis

A)on the side facing the thylakoid space.
B)on the ATP molecules themselves.
C)on the pigment molecules of PSI and PSII.
D)on the stroma side of the membrane.
E)built into the center of the thylkoid stack (granum).

A)use ATP to release carbon dioxide
B)use NADPH to release carbon dioxide
C)split water and release oxygen
D)transport RuBP out of the chloroplast
E)synthesize simple sugars from carbon dioxide

A)The pH within the thylakoid is less than that of the stroma.
B)The pH of the stroma is higher than that of the other two measurements.
C)The pH of the stroma is higher than that of the thylakoid space but lower than that of the cytosol.
D)The pH of the thylakoid space is higher than that anywhere else in the cell.
E)There is no consistent relationship.

A)It represents cell processes involved in C₄ photosynthesis.
B)It represents the type of cell structures found in CAM plants.
C)It represents an adaptation that maximizes photorespiration.
D)It represents a C₃ photosynthetic system.
E)It represents a relationship between plant cells that photosynthesize and those that cannot.

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

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

A)addition of a pair of electrons from NADPH
B)inactivation of RuBP carboxylase enzyme
C)regeneration of ATP from ADP
D)regeneration of rubisco
E)a gain of NADPH

A)light reactions alone
B)the Calvin cycle alone
C)both the light reactions and the Calvin cycle
D)neither the light reactions nor the Calvin cycle
E)occurs in the chloroplast but is not part of photosynthesis

A)light reactions alone
B)the Calvin cycle alone
C)both the light reactions and the Calvin cycle
D)neither the light reactions nor the Calvin cycle
E)occurs in the chloroplast but is not part of photosynthesis

A)light reactions alone
B)the Calvin cycle alone
C)both the light reactions and the Calvin cycle
D)neither the light reactions nor the Calvin cycle
E)occurs in the chloroplast but is not part of photosynthesis

A)light reactions alone
B)the Calvin cycle alone
C)both the light reactions and the Calvin cycle
D)neither the light reactions nor the Calvin cycle
E)occurs in the chloroplast but is not part of photosynthesis

A)light reactions alone
B)the Calvin cycle alone
C)both the light reactions and the Calvin cycle
D)neither the light reactions nor the Calvin cycle
E)occurs in the chloroplast but is not part of photosynthesis

A)light reactions alone
B)the Calvin cycle alone
C)both the light reactions and the Calvin cycle
D)neither the light reactions nor the Calvin cycle
E)occurs in the chloroplast but is not part of photosynthesis

A)donate electrons
B)act as reducing agents
C)act as oxidizing agents
D)transport protons within the mitochondria and chloroplasts
E)both oxidize and reduce during electron transport

A)The light reactions provide ATP and NADPH to the Calvin cycle, and the cycle returns ADP, Pi, and NADP⁺ to the light reactions.
B)The light reactions provide ATP and NADPH to the carbon fixation step of the Calvin cycle, and the cycle provides water and electrons to the light reactions.
C)The light reactions supply the Calvin cycle with CO₂ to produce sugars, and the Calvin cycle supplies the light reactions with sugars to produce ATP.
D)The light reactions provide the Calvin cycle with oxygen for electron flow, and the Calvin cycle provides the light reactions with water to split.
E)There is no relationship between the light reactions and the Calvin cycle.

A)cell I only.
B)cell II only.
C)neither cell I nor cell II.
D)both cell I and cell II.
E)cell I during the night and cell II during the day.

A)NADPH → O₂ → CO₂
B)H₂O → NADPH → Calvin cycle
C)NADPH → chlorophyll → Calvin cycle
D)H₂O → photosystem I → photosystem II
E)NADPH → electron transport chain → O₂

A)carbon dioxide molecules.
B)3-phosphoglycerate molecules
C)ATP molecules.
D)ribulose bisphosphate molecules.
E)RuBP carboxylase molecules.

A)Only heterotrophs require chemical compounds from the environment.
B)Cellular respiration is unique to heterotrophs.
C)Only heterotrophs have mitochondria.
D)Autotrophs, but not heterotrophs, can nourish themselves beginning with CO₂ and other nutrients that are inorganic.
E)Only heterotrophs require oxygen.

A)Cell I
B)Cell II
C)Cell I at night
D)Cell II at night
E)neither Cell I nor Cell II

A)fix CO₂ into organic acids during the night.
B)fix CO₂ into sugars in the bundle-sheath cells.
C)fix CO₂ into pyruvate in the mesophyll cells.
D)use the enzyme phosphofructokinase, which outcompetes rubisco for CO₂.
E)use photosystems I and II at night.

A)carbon fixation
B)oxidation of NADPH
C)release of oxygen
D)regeneration of the CO₂ acceptor
E)consumption of ATP

A)substrate-level phosphorylation in glycolysis.
B)oxidative phosphorylation in cellular respiration.
C)the Calvin cycle.
D)carbon fixation.
E)reduction of NADP⁺.

A)C₄ plant.
B)C₃ plant.
C)CAM plant.
D)heterotroph.
E)chemoautotroph.

A)They do not participate in the Calvin cycle.
B)They use PEP carboxylase to initially fix CO₂.
C)They are adapted to cold, wet climates.
D)They conserve water more efficiently.
E)They exclude oxygen from their tissues.

A)creation of a pH gradient by pumping protons across the thylakoid membrane
B)carbon fixation in the stroma
C)reduction of NADP⁺ molecules
D)removal of electrons from chlorophyll molecules
E)ATP synthesis

A)Cells would carry on more photosynthesis.
B)Cells would carry on the Calvin cycle at a much slower rate.
C)Less ATP would be generated.
D)There would be more light-induced damage to the cells.
E)More sugars would be produced.

A)In both cases, only photosystem I is used.
B)Both types of plants make sugar without the Calvin cycle.
C)In both cases, rubisco is not used to fix carbon initially.
D)Both types of plants make most of their sugar in the dark.
E)In both cases, thylakoids are not involved in photosynthesis.

A)light energy.
B)CO₂ and ATP.
C)H₂O and NADPH.
D)ATP and NADPH.
E)sugar and O₂.

A)Each one minimizes both water loss and rate of photosynthesis.
B)C4 compromises on water loss and CAM compromises on photorespiration.
C)Each one both minimizes photorespiration and optimizes the Calvin cycle.
D)CAM plants allow more water loss, while C4 plants allow less CO₂ into the plant.
E)C4 plants allow less water loss but Cam plants but allow more water loss.