L19 + 20 photosynthesis

Question 1

What is solar energy captured and converted to?

Answer 1

Chemical potential as ATP and NADPH

Question 2

What are ATP and NADPH used for after the light has been converted to them?

Answer 2

To convert cO2 to sugar phosphates (and then carbohydrates)

Question 3

What is the net reaction of photosynthesis?

Answer 3

CO2 + H2O —-> (CH2O) + O2

Question 4

What drives the oxidation of water and the reduction of CO2?

Answer 4

Solar energy. Which is converted into ATP and NADPH

Question 5

Which electrons pass through the electron- transport chain?

Answer 5

The electrons from water oxidation

Question 6

What else are the light reactions known as?

Answer 6

The light-dependent reactions

Question 7

What are the light reactions?

Answer 7

-Electrons from the H2O oxidation drive the formation of a protein gradient. The gradient is then used to make ATP.
(the chemiosmotic synthesis of ATP)

• Electrons from H2O oxidation eventually reduce NADP+ to NADPH
• O2 is by-product of water oxidation

Question 8

What does oxidation of water lead to?

Answer 8

ATP synthesis
Reduction of NADP+ to NADPH
O2 as a by-product

Question 9

What are the dark reactions also known as?

Answer 9

The light-independent or carbon-fixation reactions

Question 10

What are the dark reactions?

Answer 10

Reduction of gaseous CO2 to carbohydrate

Requires reducing power and energy- which is provided by NADPH and ATP

Question 11

What are photosystems I and II?

Answer 11

Pigment-protein complexes that contain many proteins and pigmnts embedded in the thylakoid membrane

Question 12

What are the pigments in PSI and PSII?

Answer 12

Chlorophyll and carotenoid

Question 13

What are electrons conducted by in the photosystems?

Answer 13

From H2O bound in PSII to NADP+ bound in PSI

Question 14

WHat are PSII and PSI linked by?

Answer 14

Cytochrome b6f complex (a third non-pigmented protein complex)

Question 15

What is light captured by and where is it trapped?

Answer 15

Captured by antenna pigments and transferred among themselves until it reaches the special-pair chlorophyll molecules. The special pair acts as an energy trap.

Question 16

What is the Z scheme?

Answer 16

Shows th electron transfer steps in their redox potential. The more positive the redox potential (v), the lower on the graph it is. (P680 = +1.0, is at the bottom of the graph)

Question 17

What is the main order of complexes in the z scheme?

Answer 17

H20-oxidized—- P680, P680–> cytochrome bf complex—> P700, P700. then goes down the slope until it turnds NAD+ to NADPH

Question 18

What is the order of the PSs?

Answer 18

PSII then PSI. wrong way round with cytochrome bf complex in middle

Question 19

What does the absorption of light do to P680 and P700?

Answer 19

Light converts the chlorophyll dimers P680 and P700 (poor reducing agents) to P680* and P700* (good reducing agents)

Question 20

After releasing their electrons are P680* and P700* good reducing or oxidising agents?

Answer 20

Good oxidising agents

Question 21

What is recombination in photosynthesis and why is this bad?

Answer 21

The electrons are attracted to go back to P680 which is inefficient. The system has evolved so that less than 1% does this.

Question 22

In the pH gradient in photosynthesis, what is more acidic, the lumen of the stroma?

Answer 22

The lumen. pH difference of 3 units.

Question 23

What is photophosphorylation?

Answer 23

Sythesis of ATP which is dependent upon light energy

Question 24

What does chloroplast ATP synthase consist of?

Answer 24

Two major particles: Cfo and CF1
CFo spans the membrane, forms a pore for H+
CF1 protrudes into the stroma and catalyzes atp synthesis from ADP and Pi

Question 25

How many protons move through chloroplast ATP synthase for 1 ATP to be made?

Answer 25

3 protons –> 1ATP

Question 26

In the z scheme, for every 4 electrons transferred to 2nadph, how many protons are moved across the membrane and how many ATP are made?

Answer 26

8H+ moved across

2-3 ATP made

Question 27

For each CO2 fixed, how many NADPHs and ATP are required?

Answer 27

2nadph and 3 atp needed

Question 28

What is cyclic electron transfer around the b6f complex thought to generate?

Answer 28

An extra proton for every electron extracted from water

Question 29

In the absence of Co2, what happens to electrons generated by PSI?

Answer 29

They can be recycled through the b6f complex to maintain energy (ATP) production.
Makes more ATP to be able to fix CO2

Question 30

What do the dark reactions convert?

Answer 30

CO2–> carbohydrates

Question 31

What are the dark reactions powered by?

Answer 31

ATP and NADPH

Question 32

Where do the dark reactions happen and how?

Answer 32

In the chloroplast stroma by the reductive pentose phosphate cycle (RPP cycle) or Calvin cycle

Question 33

WHat are the 3 main steps in the Calvin cycle?

Answer 33

1. fixation of atmospheric CO2
2. reduction of CO2 to carbohydrate
3. regeneration of the molecule that accepts CO2

Question 34

What does ribulose 1,5-biphosphate carboxylase oxygenase (rubisco) do?

Answer 34

The first enzyme in the calvin cycle. Takes the CO2 and the 5 carbon sugar ribose and forms 2 3-carbon molecules. (3-phosphoglycerate)

Question 35

Why is rubisco inefficient?

Answer 35

It’s slow and poorly sleective. Binds to O2 sometimes instead of CO2 which wastes lots of energy. Rubisco has to be present in very high levels- most abundant protein on the planet.

Question 36

When is rubisco acitve and inactive?

Answer 36

active in the light. inactive in the dark

Question 37

What do plants convert RPP assimilated carbon into?

Answer 37

1. sucrose- in cytosol
2. starch- in chloroplast
3. cellulose- in cell wall

Question 38

In photosynthesis does the lumen or stroma have more H+?

Answer 38

The lumen

Question 39

How many electrons do you need before you have enough oxidizing power to produce oxygen?

Answer 39

4 electrons

Question 40

What does PQ do in photosynthesis?

Answer 40

It is like UQ in respiration. carries the electron from P680 to the plastocyanin attached to the cytochrome bf complex (carries a pair of electrons i think)

Question 41

How many electrons do you need before you have enough oxidising power to produce oxygen?

Answer 41

4 electrons

Question 42

What does PSI do to NADp+?

Answer 42

reduces nadp+ to nadph

Question 43

What does PsII do to water?

Answer 43

oxidizes 2H20 to O2 and 4H+ (on the lumen side of the membrane)

Question 44

Where is plastocyanin?

Answer 44

Attached to cytochrome bf complex in between the photosystems. Transfers electrons over P700

Question 45

In the membrane what are the steps or photosynthesis?

Answer 45

PSII with P680. water gets oxidizes here. the PQ takes over electrons to cutochrome bf complex (plastocyanin attached takes the electrons).
then PSI has P700.
Ferredoxin is attached and reduces NADP+ to NADPH