Photosynthesis (Chapter 12)

Question 1

______ is a herbicide that blocks electron transport in the photosystem I protein complex, leading to plant cell death.

Answer 1

Paraquat

Question 2

The photosynthetic electron transport system and carbon fixation (Calvin cycle) reactions together convert ______, ______, and ______ into ______, ______, and ______.

Answer 2

sunlight energy, CO2 and H2O

chemical energy (ATP, NADPH), molecular oxygen, and the triose phosphate glyceraldehyde-3-phosphate.

Question 3

Whys is photosynthesis important for non photosynthetic organisms?

Answer 3

They provide metabolic fuel in the form of carbohydrate

Question 4

True o False: Glyceraldehyde-3-phosphate feeds into the anabolic gluconeogenesis pathway where it is used as a precursor for glucose synthesis.

Answer 4

True

Question 5

True or False: The emergence of photosynthetic organisms on Earth led to significant increases in the level of O2 in the atmosphere and directly affected the evolution of multicellular organisms that use aerobic respiration for energy conversion.

Answer 5

True

Question 6

True or False: The ability to fix CO2 into organic compounds was a later evolutionary trait.

Answer 6

False, it was an earlier evolutionary trait

Question 7

How many steps are there in the photosynthetic electron transport and photophosphorylation system?

Answer 7

5

Question 8

What is the first step in the photosynthetic electron transport and photophosphorylation system?

Answer 8

Photon (4) absorption by the PSII leads to activation of the photosynthetic electron transport system and generation of O2

Question 9

In the first step, ______ e- are generated from the _______ (oxidation/reduction) of ______ water molecules.

Answer 9

4

oxidation, 2

Question 10

What is the second step in the photosynthetic electron transport and photophosphorylation system?

Answer 10

Electrons flow through the photosynthetic electron transport system, which includes the electron carriers (PQ), (PC), and (Cytb6f).

Question 11

What is the function of step 2?

Answer 11

Electron flow through cytochrome b6f results in the buildup of a chemiosmotic proton gradient across the thylakoid membrane.

Question 12

What is the third step in the photosynthetic electron transport and photophosphorylation system?

Answer 12

Photon absorption by PSI continues the series of electron transfer reactions.

Question 13

True or False: In the third step, the final electron acceptor in this pathway is NADPH, which is oxidized to form NADP+.

Answer 13

False, NADP+ which is reduced to form NADPH.

Question 14

What is the fourth step in the photosynthetic electron transport and photophosphorylation system?

Answer 14

The process of photophosphorylation occurs, in which ATP synthesis is catalyzed by the chloroplast ATP synthase complex.

Question 15

Why does the fourth step occur?

Answer 15

In response to proton flow from the thylakoid lumen into the stroma

Question 16

What is the fifth step in the photosynthetic electron transport and photophosphorylation system?

Answer 16

CO2 fixation by the Calvin cycle leads to the formation of glyceraldehyde-3-phosphate

Question 17

What is G-3-P used for?

Answer 17

Used to make hexose sugars

Question 18

True or False: Energy conversion from ATP hydrolysis and NADPH oxidation is used to drive the Calvin cycle reactions.

Answer 18

True

Question 19

The ______ disks are folded regions of the thylakoid membrane where proteins in the photosynthetic electron transport system are located.

Answer 19

thylakoid

Question 20

The aqueous compartment outside of the thylakoid membrane, but inside the inner chloroplast membrane is the _______.

Answer 20

Stroma

Question 21

What part of the chloroplast contains all of the calvin cycle enzymes?

Answer 21

Stroma

Question 22

The thylakoid membrane can be found in a stack of thylakoid disks called a ______ or in an unstacked region called the ______.

Answer 22

granum, lamella.

Question 23

True or False: Photosynthetic electron transport leads to proton translocation into the stroma and the production of NADPH in the thylakoid lumen.

Answer 23

False, translocation into the thylakoid lumen and the production of NADPH in the stroma.

Question 24

Why is the AT synthase complex orientated outward from the lumen?

Answer 24

So that ATP synthesis occurs in the stromal compartment

Question 25

What does photosynthesis accomplish for the cell?

Answer 25

The photosynthetic electron transport system converts light energy into redox energy, which is used to generate ATP by chemiosmosis and reduce NADP+ to form NADPH

Calvin cycle enzymes use the energy available from ATP and NADPH to reduce CO2 to form glyceraldehyde-3-phosphate, a triose phosphate that can be used to synthesize glucose.

Photosynthetic cells use the triose phosphates produced by the Calvin cycle as a chemical energy source for mitochondrial respiration, which is independent of light.

Question 26

True or False: Photosynthetic organisms are autotrophs because they derive energy from light rather than from organic materials.

Answer 26

True

Question 27

What is the overall net reactions of the photosynthetic electron transport system

Answer 27

2 H2O + 8 photons + 2 NADP+ + ~3 ADP + ~3 Pi

—> O2 + 2 NADPH + 2 H+ + ~3ATP

Question 28

What is the overall net reactions of the Calvin cycle.

Answer 28

3 CO2 + 6 NADPH + 9 ATP + 5 H2O —–> glyceraldehyde-3-phosphate + 6NADP+ + 9 ADP + 8 Pi

Question 29

What are the four key enzymes of the photosynthetic electron transport system and the Calvin cycle?

Answer 29

photosystem II (P680 reaction center),

cytochrome b6f (proton translocation),

photosystem I (P700 reaction center)

Rubisco

Question 30

Photon absorption by chlorophyll molecules results in ______, ______, or ______.

Answer 30

resonance energy transfer, fluorescence, photooxidation

Question 31

What occurs during resonance energy transfer?

Answer 31

The energy released by the excited chlorophyll molecule returning to the ground state (Chl1* → Chl1) is transferred to a nearby chlorophyll molecule, which causes it to be in the excited state (Chl2 → Chl2*)

Question 32

What occurs during fluorescence?

Answer 32

(Chl1* → Chl1)

Question 33

True or False: Fluorescence does result in useful work being performed by the plant as a result of light absorption.

Answer 33

False, does not result in useful work

Question 34

What occurs during photo oxidation?

Answer 34

An electron from the excited chlorophyll molecule is passed directly to a nearby acceptor molecule of higher (more positive) reduction potential, such as pheophytin (Pheo)

Question 35

What is the result of photooxidation?

Answer 35

This separation of charge creates a positively charged chlorophyll molecule (Chl1* → Chl+) and a negatively charged acceptor molecule (Pheo → •Pheo-).

Question 36

True or False: Chlorophylls a and b have two absorbance peaks at the same ends of the solar spectrum.

Answer 36

False, opposite end of the spectrum

Question 37

Carotenoids, such as β-carotene, absorb in the ______ range, which is why they appear ______(reflected light).

Answer 37

blue, orange

Question 38

The phycobilins absorb light in the middle of the solar spectrum and are primarily found in ______ photosynthetic organisms.

Answer 38

Marine

Question 39

______ functions as a solar panel that harvests light energy for PSII and PSI reaction centers in the thylakoid membrane.

Answer 39

LHC II

Question 40

A series of ______ reactions passes the energy along to LHC I surrounding the reaction centers, where photooxidation takes place.

Answer 40

Resonance-energy

Question 41

The ______ of electron flow in the photosynthetic electron transport system illustrated the redox energy made available by light absorption at reaction center complexes is used to establish a proton gradient across the thylakoid membrane and to reduce NADP+.

Answer 41

Z-scheme

Question 42

The Z-scheme is an example of a ______ electron transfer.

Answer 42

Noncyclic

Question 43

When electrons move from ferredoxin back to the cytochrome b6f complex, it is known as ______ electron transfer.

Answer 43

Cyclic

Question 44

True or False: In cyclic electron transfer, it produces more ATP and less NADPH.

Answer 44

True

Question 45

True or False: Components of the photosynthetic electron transport systems in bacteria resemble those in plant chloroplasts, suggesting an evolutionary relationship.

Answer 45

True

Question 46

The photosynthetic electron transport systems in purple bacteria (PSII-like) and green sulfur bacteria (PSI-like) use ______ pathways to oxidize organic or inorganic substrates rather than H2O.

Answer 46

anoxygenic

Question 47

______ and plant chloroplasts are similar in that they both use oxygenic photosynthetic pathways (oxidize H2O to generate O2).

Answer 47

Cyanobacteria

Question 48

True or False: In cyanobacteria, they use use cytochrome b6f, cytochrome c6 and plastoquinone for both oxidative phosphorylation and photophosphorylation.

Answer 48

True

Question 49

In cyanobacteria oxidative phosphorylation, electrons flow from ______ to ______.

Answer 49

NADH –> O2

Question 50

In photophosphorylation, electrons flow from ______ to ______.

Answer 50

H20 —-> NADP+

Question 51

Both processes are accompanied by proton movement across the membrane, known as a ______ cycle.

Answer 51

Q

Question 52

How do electrons flow through in electron carriers in PS II? (slide 20)

Answer 52

Electrons extracted from H2O

• —> OEC
• –> Tyr(z)
• –> P680 (photooxidation)
• –> Pheo
• –> PQ(a)
• –> PQ(b)
• –> PQ(b)H2 (diffuses through thylakoid membrane to deliver e- to Cytb6f)

Question 53

How many electrons does it take to reduce 2 PQB to 2 PQBH2.

Answer 53

4

Question 54

In the PQ cycle, ______ H+ are translocated by the combined reactions in PSII and cytochrome b6f and An additional ____ H+ are generated by the oxidation of 2 H2O to form O2, leading to a net gain of ____ H+ in the thylakoid lumen.

Answer 54

8, 4, 12

Question 55

How do electrons flow through in electron carriers in PS I? (slide 22)

Answer 55

PC —> into two separate pathways that are the same

• –> P700 (photooxidation)
• –> Chl
• –> ChlA0
• –> Phylloquinone
• –> Fx (both pathways meet here)
• –> Fa
• –> Fb
• –> ferrodoxin
• –> ferredoxin-NADP+ reductase

Question 56

True or False: The electrons from ferredoxin are used to reduce the FAD moiety in ferredoxin-NADP+ reductase, which then reduces NADP+ to form NADPH in the stroma.

Answer 56

True

Question 57

True or False: Cyclic photophosphorylation between PSI and cytochrome b6f generates an electrochemical proton gradient independent of H2O oxidation and NADP+ reduction.

Answer 57

True

Question 58

What occurs when NAD+ levels are limiting?

Answer 58

Photooxidation of chloroplast P700 leads to electron flow between ferredoxin and the plastoquinone pool (PQ cycle), resulting in proton translocation by cytochrome b6f and ATP synthesis.

Question 59

In mitochondria and bacteria, protons are pumped ______ of the organelle or cell, and F1 is on the ______ of the membrane; in plant thylakoids, protons are pumped ______ the flattened discs within chloroplasts, and CF1 is on the ______ of the disc membrane.

Answer 59

out, in

into, outside

Question 60

True or False: Exactly the same mechanism of energy conversion (from proton gradient to ATP) occurs in mitochondria, chloroplasts and bacteria.

Answer 60

True

Question 61

ATP is synthesized in the ______ of mitochondria, the ______ of chloroplasts, and the ______ of bacteria.

Answer 61

matrix, stroma, cytosol

Question 62

The Calvin cycles converts triphosphates into hexose phosphates, the building blocks for what three primary carbohydrates in plant cells?

Answer 62

Starch, sucrose and cellulose

Question 63

Pentose phosphates are Calvin cycle intermediates and also form? .

Answer 63

Carbohydrate backbone for DNA and RNA.

Question 64

What is stage 1 of the calvin cycle?

Answer 64

Ribulose-1,5-bisphosphate (RuBP), a C5 molecule, is combined with CO2 in a reaction catalyzed by rubisco to form a transient C6 molecule, which is rapidly cleaved into two C3 molecules of 3-phosphoglycerate

Question 65

What is stage 2 of the calvin cycle?

Answer 65

3-phosphoglycerate is reduced to glyceraldehyde-3-phosphate in reactions involving ATP and NADPH

Question 66

What is stage 3 of the calvin cycle?

Answer 66

5 glyceraldehyde-3-phosphate (5 x C3) are used to resynthesize 3 ribulose-1,5-bisphosphate (3 x C5) in a series of “carbon shuffle” reactions that require ATP.

Question 67

Glyceraldehyde-3-phosphate and dihydroxyacetone phosphate are used in the stroma to synthesize ______ for energy storage

Answer 67

Starch

Question 68

Glyceraldehyde-3-phosphate and dihydroxyacetone are transported into cytosol where they are used to synthesize ______ for export to plant tissues or catabolized by ______ for energy conversion.

Answer 68

Sucrose, glycolysis

Question 69

What enzyme converts glyceraldehyde-3-phosphate and dihydroxyacetone?

Answer 69

Triose phosphate isomerase

Question 70

What enzyme converts What enzyme converts glyceraldehyde-3-phosphate and dihydroxyacetone simpler glucose and fructose molecules?

Answer 70

Aldolase

Question 71

The ______ cycle in plants provides a mechanism for fats stored in seeds to be converted to sucrose for export to developing plant tissues prior to the onset of photosynthesis.

Answer 71

Glyoxylate

Question 72

Two unique glyoxylate cycle enzymes, ______ and ______, are localized to cell organelles called glyoxysomes in plant cells.

Answer 72

isocitrate lyase, malate synthase

Question 73

______ serves as the central metabolic intermediate in this pathway by transporting the four carbons obtained from two acetyl-CoA molecules to the mitochondria, where ______ is converted to malate for use in the citrate cycle or for export to the cytosol.

Answer 73

Succinate (x2)